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Hedera helix - invasive English Ivy growing on a native tree
Hedera helix – invasive English Ivy growing on a native tree
Heracleum mantegazzianum invasive herbaceous plant with flowers
Heracleum mantegazzianum invasive herbaceous plant with flowers

What is an Invasive Species?

What is an invasive species and what makes a species invasive?  Most invasive organisms do not at all behave invasively in their natural environment, so what makes them invasive when they enter a new environment?  How do we remove invasive species once they become established? These are all good questions to ask.  

A decent definition of invasive species given by The National Wildlife Federation on their website is: “An invasive species can be any kind of living organism—an amphibian (like the cane toad), plant, insect, fish, fungus, bacteria, or even an organism’s seeds or eggs—that is not native to an ecosystem and causes harm. They can harm the environment, the economy, or even human health. Species that grow and reproduce quickly, and spread aggressively, with the potential to cause harm, are given the label ‘invasive.’”

I would also add to that definition the harm they can do to native species. However, most definitions focus on the economic impact on humans, and at least this one lists the environment first. I suppose the harm to native species is probably implied in the ‘environment’ term.

What Makes a Species Invasive?

So, what makes a species invasive?  There are a few factors that make them invasive.   Invasive organisms already tend to be opportunistic r-strategist species that can reproduce rapidly in large numbers.  Then you add that species to a new environment it is not native to then it typically has no predators or other checks on its population. This allows its population to rapidly expand beyond its already high reproductive rate. 

Another huge, often overlooked factor contributing to the invasiveness of different organisms is what gives them a foothold in the new environment anyway.  Invasive species tend to have a low level of ecological specialization and tend not to tolerate competition for resources. This means that disturbed habitats make an ideal environment for many of them. All they need is a few individuals to survive to reproductive maturity and they can invade the disturbed environment. Disturbed areas are ideal for opportunistic species because little else will thrive in that environment, so they have little or no competition.

Take by far the majority of invasive plants. For example, they tend to thrive in disturbed habitats but will not invade an old-growth forest or even a second-growth forest.  But provide a recently cleared road, a clear-cut, cleared lot for development, etc, and they will take over. 

And to further complicate matters, not all species treated as invasive are even introduced.  Take the common cattail, Typha latifolia, for example.  It is native throughout North America but has, in recent decades, been forming monocultures throughout its native range.  This has led some people to believe it is invasive and needs to be controlled. However, what is actually creating the monocultures is wetland disruption. Our wetlands are being degraded with high nutrient input, heavy metals, and other toxins, as well as an altered water regime due to human activities.  These are all conditions that the cattail, and little else, will thrive in, thus creating the monoculture. Check out my blog on whether cattails are really an invasive native species or do human perceptions need to change? 

Why Are Invasive Species a Problem?

So if habitat disturbance is one of the main reasons a species becomes invasive, then why should we worry about them at all? If the habitat is no longer suitable for other species, should we not leave it to those who can live there?

The short answer is no. First of all, we need to be far more diligent with ecological restoration following disturbances, not just so we can prevent invasive species. We need to restore the ecosystem values, including biodiversity and the clean water, soil, and air we benefit from with restoration.

And most importantly, invasive species further threaten our already threatened native species by displacing them and using their land and resources. Sometimes they may even eat the native species, or their young, as is the case of the American Bullfrog for example. The American Bullfrog will quite literally eat anything it can fit in its mouth, including native fish, mollusks, salamanders, our native frogs and their young, and they will even eat their own young.

We need to protect our native species and the gene pools they still carry. Genetic diversity is the key to survival through environmental change. We have now created environmental change and the resultant extinction rates on a scale this planet has only seen before on cataclysmic scales of disaster, such as the asteroid impacts that have caused at least a few of our mass extinctions in the past. If we hope to have healthy, thriving ecosystems at the end of this, then we need to save as many of our native species as possible. One of the many ways we can do that is by controlling and, where possible, eradicating invasive species.

The Zebra Mussel

Take the zebra mussel, for example, which grows prolifically in pristine and polluted water alike, threatening our native mussels, fish, and aquatic ecosystems.  Freshwater mussels also face pollution, river channelization, siltation, etc. But now that they are also facing invasion by the zebra mussel, they are rapidly being extirpated in many areas and many species now face extinction.  The zebra mussel is a biofouling organism that smothers other mollusks and competes with other suspension feeders for food.  Stopping the degradation of our environment cannot stop the invasive mussel. 

Prevention, of course, does help. We can be diligent about cleaning our boats and gear between waterways. You may have heard the whole “Don’t Move a Mussel” campaign and have seen the boat checkpoints on our major highways. But any waterway connected to an infected one, regardless of preventative measures or how clean and pristine the water is, is still at risk of the spread of the invasive mussel. 

That is why we must understand the ecology of the invasive organism and try to find other means of control once they have already become established in the environment. That is why we need to address each invasive species on an individual basis to try to find methods of control.

What to Do About Invasive Species and Their Removal

Prevention is Best

In order to manage invasive species, the best strategy is to prevent them in the first place.  We need to put way more effort into ecological restoration following any type of man-made disturbance.  Methods that can be used include successional advancement, modification of the disturbance to make it unsuitable for the invasives, and planting native species to encourage competition because many invasives do not tolerate competition.  

While habitat disturbance by far is the biggest reason many species become invasive, that does not mean we should ignore the invasive organisms and only focus on the disturbance.  We are human beings, we disturb habitats; that is the nature of humanity.  That is why we need to be responsible when we do, like replanting with native vegetation as quickly as possible. However, as with anything in life, the answer is not that simple. We cannot simply alter our disturbance of the environment and expect that this will solve the invasive species issue. In many cases, the environment is already altered and cannot be restored to its original condition. In other cases, the invasive organism is already there and will not just ‘go away’ even if we can restore the ecosystem. We need instead to find a way to remove invasive species once they have become established.

Physical Control for Invasive Species Removal

Physical removal is almost always the best way to deal with invasive species removal. Physical control methods involve cutting, digging, burning, etc. The methods will vary for each species we are trying to remove. In future blogs, I will explain in detail for each species the best means of physical control.

Chemical Control for Invasive Species Removal

The common practice of using herbicides or pesticides is not at all effective in the long term. The use of chemicals to control invasive species is a form of disturbance in itself through the chemical alteration of the ecosystem. Chemical control also opens up gaps that allow invasive organisms to get a foothold. The best way to manage invasive species is to understand their ecology and make the environment more suitable for native than invasive species. 

Biological Control for Invasive Species Removal

Biological control methods are extremely risky and should only be carried out by professionals after years of rigorous study. Biological control involves using a predator, herbivore, disease, or some other agent to control an invasive species once it is established in the environment.

The problem with biological control is that the agent used must be entirely specific to only the target organism before releasing it into the environment. This is often difficult to determine since the control agent is also not native to the environment and could behave differently when released there. Take the example of the mongoose and the rat. The mongoose was released in Hawaii in the late 1800’s to help control the rat. To this day, there are still rats in Hawaii, but the mongoose has helped to completely decimate many native bird populations.

Conclusion

This introduces my new series of nature blogs on invasive species.  I will, of course, mostly focus on plants as that is my area of expertise, but I will discuss other organisms as well.  Each week I will describe an invasive organism, its distribution, and habitat preferences. Then I will discuss the various methods of prevention and different methods of control and eradication we can implement if they are already established in an area. Every organism is unique, so every approach also has a unique perspective.  

If you want to learn more about invasive organisms, check out the various invasive species organizations I listed in the resources below. Your local region likely also has its own local chapter where you can get involved in education, organized biological removal, and more. And if you have any questions or suggestions for a topic, I should cover, please Contact Me.

References and Resources

Dictionary of Botanical Terms – Lyrae’s Nature Blog Dictionary of Botanical Terms

Economic Cost of Invasive Species in Mexico In: Zenni RD, McDermott S, García-Berthou E, Essl F (Eds) The economic costs of biological invasions around the world. NeoBiota 67: 459-483. https://doi.org/10.3897/neobiota.67.63846 https://neobiota.pensoft.net/article/63846/

Invasive Alien Species of Mexico Official Checklist https://trilat.org/test-docman/annual-meetings/2013-annual-meeting-1/281-2013-invasive-alien-species-official-list-for-mexico-1/file

Invasive Species Council of BC https://bcinvasives.ca/

Invasive Species Council of Canada https://canadainvasives.ca/

National Invasive Species Council (United States) https://www.doi.gov/invasivespecies

North America Invasive Species Management Association https://naisma.org/

Polster, D.F. 2004. Restoration Encyclopedia: Invasive Species in Ecological Restoration. Paper presented at the 16th International Conference of the Society for Ecological Restoration International. August 24 – 26, 2004. Victoria, B.C.

Ricciardi, Anthony, Richard J Neves and Joseph B Rasmussen, 1998.  Impending extinctions of North American freshwater mussels (Unionoida) following the zebra mussel (Dreissena polymorpha) invasion.  Journal of Animal Ecology (1998), 67, 613-619.  

The National Wildlife Federation https://www.nwf.org/Educational-Resources/Wildlife-Guide/Threats-to-Wildlife/Invasive-Species

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If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


Botanical Dictionary of Terms

Androecium and Gynoecium of Guaiacum coulteri. From the Botanical Dictionary of Terms Page
Androecium and Gynoecium of Guaiacum coulteri
Palmate leaf of Oplopanax horridus - on the Botanical Dictionary Page
Palmate leaf of Oplopanax horridus

Table of contents

When I first started learning about plants I found the number of botanical terms daunting to say the least.  I constantly complained “if you ask 10 botanists to describe a flower shape how many different words will you get for that shape?”  The answer, I said, was “10”.  While that may be a bit of an exaggeration for sure, I have found the number of synonyms in botany astounding. So I started compiling my own botanical dictionary so that I could refer back to it when I came across yet another obscure term. Then what I do is use the terms that I like, usually those that I find most commonly used. 

One day I want to also write a ‘Botanists Thesaurus” to deal with synonyms.  But for now here is my collection of all the botany terms I have come across so far in my own studies. I have started adding synonyms and antonyms but only some definitions have those.  Many of these terms you may never come across, but many you will.  Keep this bookmarked for a handy botanical reference. You can use the “Control F” function in your browser to search for a specific term.  Otherwise it is in alphabetical order and you can use the table of contents or scroll through to find the term you are looking for.  Please Contact Me if you have any terms that you think are missing and should be added to my collection.  

A – Botanical Dictionary

  • ~ is used to denote approximately, or synonymous with (families, genus, species). 
  • ab- A prefix meaning “from, away from, or outside”.
  • abaxial – The surface of an organ facing away from the organ’s axis, e.g. the lower surface of a lateral organ such as a leaf or petal. Contrast adaxial.
  • abiotic – abiotic factors or components are non-living factors that impact an ecosystem such as the soil type, slope, altitude, moisture level etc. Abiotic factors are part of the ecosystem and can impact the associated living things, but they are not living.
  • abort – To abandon development of a structure or organ.
  • abscission -The shedding of an organ that is mature or aged, as of a ripe fruit or an old leaf.
  • abscission zone – A specialized layer of tissue that allows an organ to be shed by abscission when it is ripe or senescent. Such tissue is commonly formed, for example, at the base of a petiole or pedicel.
  • acaulescent – Having no apparent stem, or at least none visible above the ground surface. Examples include some species of Agave, Oxalis… Antonym of caulescent (possessing stem)
  • accessory Fruit – a fruit in which some of the flesh is derived not from the floral ovary but from some adjacent tissue exterior to the carpel.  Parts included are calyx, hypanthium, perianth and receptacle.  Eg include Strawberries (pseudocarp) and Apples (pomes).
  • accrescent – Increasing in size with age, such as a calyx that continues to grow after the corolla has fallen, e.g. in Physalis peruviana.
  • accumbent – Lying against another part of the plant; when applied to a cotyledon, it means that one edge of the cotyledon lies along the radicle.
  • achene – A dry, one-seeded indehiscent fruit.  Some achenes can also be found in aggregate and accessory fruits (example achenectum and pseudocarps). 
  • achenecetum – An aggregation of achenes, as in Ranunculus.
  • achlamydeous – Flowers lacking perianth, with no sepals, petals or tepals.
  • acicular – Slender or needle-shaped.
  • acrocidal capsule – One that dehisces through terminal slits, or fissures, as in Staphylea.
  • acropetal – adj: acropetally Moving from roots to leaves, e.g. of molecular signals in plants.
  • acrophyll – The regular leaves of a mature plant, produced above the base, opp to bathyphyll.
  • acrosarcum – Seeds embedded in fleshy pulp without distinct endocarp as in the Cactaceae; with persistent accessory calyx
  • acrostichoid – (describing a type of sorus) Covering the entire abaxial surface of a frond, usually densely so, as in Elaphoglossum and Acrostichum.
  • actino– A prefix that indicates a radial pattern, form, or morphology.
  • actinocytic – star-celled – stomata with guard cells that are surrounded by at least five radiating cells forming a star-like circle
  • actinodromous – (leaf venation) Palmate or radially arranged venation with three or more primary veins arising at or near the base of the leaf and either reaching the margin or not.
  • actinomorphic – Regular or radially symmetrical; may be bisected into similar halves in at least two planes. Applies e.g. to steles and flowers in which the perianth segments within each whorl are alike in size and shape. Compare regular; contrast asymmetrical, irregular, zygomorphic.
  • actinomycetes – A group of gram-positive bacteria (order Actinomycetales) that produce various bio-active agents including antibiotics, enzymes, and vitamins. 
  • aculeate – Armed with prickles, e.g. the stem of a rose.
  • accuminate – Tapering gradually to a point. Contrast acute and mucronate.
  • acute – 1.  Sharply pointed, but not drawn out. Contrast accuminate.  2.  Converging at an angle of less than 90°. Contrast obtuse.
  • acyclic – Flowers, arranged in spirals instead of whorls (eg Magnolia). Compare cyclic.
  • ad– A prefix meaning “near or towards”; also meaning “added to”.
  • adaxial – The surface of an organ facing towards the organ’s axis, e.g. the upper surface of a lateral organ such as a leaf or petal. Contrast abaxial.
  • adelphia, plural: adelphiae – a bundle or structure of stamens forming one unit in an adelphous flower; for example, the stamen tube around the pistil of Hibiscus.
  • Adelphous – Having organs, particularly filaments such as stamens, connected into one or more adelphiae, whether in the form of bunches or tubes, such as is commonly seen in families such as Malvaceae. Usage of the term is not consistent; some authors include closely bunched filaments, while others include only adelphiae in which filaments are connected at their bases at least. See for example, Sims: “…the filaments are so closely pressed that they have the appearance of being monadelphous…”.[2] Compare derived terms such as monadelphous, having stamens growing in a single bunch or tube, for example in Hibiscus, and diadelphous growing in two bunches.
  • adherent – Slightly united to an organ of another kind, usually to a part of another whorl, e.g. a sepal connected to a petal. Contrast adnate.
  • adnate – Adj: adnation. Grown from or closely fused to an organ of a different kind, especially along a margin, e.g. a stamen fused to a petal. Adnate anthers have their halves attached to the filament through most of their length. (Contrast connate.)
  • adpressed – Lying close and flat and pointing toward the apex of the plant or structure, usually referring to leaves growing up against the stem (= “appressed”). adventitious. A structure such as a bud or root that is produced on an unusual part of the plant (i.e., roots that come from stems).
  • adventitious – Produced in an unpredictable or unusual position, e.g. an adventitious bud produced from a stem rather than from the axil of a leaf. Adventitious roots may develop from nodes of prostrate stems of some plant species, or from the hypocotyl rather than from the radicle of a germinating monocotyledon.
  • adventive – Introduced accidentally (usually referring to a weed).
  • aerenchymatous –A soft plant tissue containing air spaces, found especially in many aquatic plants. Oxygen transport from above-ground parts to roots of wetland plants is facilitated by aerenchyma.
  • aerial – Of the air; growing or borne above the surface of the ground or water.
  • aestivation – Arrangement of sepals & petals or their lobes in an unexpanded bud. Contrast vernation.
  • aff. (affinis) – With affinity to others, akin to; often used for a provisionally recognized but unnamed taxon considered close to that name, perhaps a hybrid or extreme variant.
  • agglutinate – firmly stuck together in a stiff mass
  • aggregate fruit – A cluster of fruits formed from the free carpels of a single flower, e.g. Rubus. A fruit that develops from the merger of several ovaries that were separated in a single flower. Compare multiple fruits.
  • alate – Having a wing or wings.
  • aleurone –  is a protein found in protein granules of maturing seeds and tubers. The term also describes one of the two major cell types of the endosperm, the aleurone layer. The aleurone layer is the outermost layer of the endosperm, followed by the inner starchy endosperm.
  • alkaloid – Any of a loosely defined class of organic compounds found in the tissues of many species of plants. Alkaloid molecules have one or more alkaline-reacting nitrogen atoms in their carbon structures. Many alkaloids are commercially important as drugs or poisons, e.g. caffeine, morphine, quinine, and strychnine, each of which occurs naturally in certain plants.
  • alternate – 1.  (adj.) (of leaves or flowers) Born singly at different levels along a stem, including spiraled parts. Contrast opposite. 2.  (prep.) Occurring between something else, e.g. stamens alternating with petals.
  • alterniperianth – adjective. Especially of a stamen positioned between the perianth divisions, used with flowers that have tepals instead of sepals and petals. 
  • alternipetalous – adjective. Especially of a stamen positioned between the petals or divisions of the corolla.
  • alternisepalous – adjective. Especially of a stamen positioned between the sepals or divisions of the calyx.
  • alveolate – Having generally uniform, regularly and closely disposed, transversely polygonal depressions overall, the pattern resembling the external aspect of a honeycomb.
  • ament – A synonym of catkin.
  • amoeboid tapetum – a tapetum that breaks down early and the contents of the cell (protoplasm) extrude between the young pollen grains providing a more efficient way of nourishing them. 
  • amphisarcum – A simple, indehiscent fruit with the pericarp differentiated externally into a dry crust and internally into one or more fleshy layers. Eg Crescentia alata.
  • amphipacific – the divided (separated) distribution of aquatic organisms of various subspecies or similar species in the northern half of the Pacific Ocean.
  • amphitropous – When the ovule is bent so that both ends are near each other. Contrast anatropous, campylotropous, and orthotropous.
  • amplexicaul – With the base dilated and clasping the stem, usually of leaves.
  • amylum  star – a vegetative propagative body filled with starch (amylum) and located around the lower nodes of certain stoneworts.
  • anastomose – Branching and then rejoining, as with leaf venation.
  • anastomosis – A connection or fusion of two or more veins that are normally diverging or branching, thereby forming a network.
  • anatropous – (of an ovule) Inverted so that the micropyle faces the placenta (this is the most common ovule orientation in flowering plants). Contrast amphitropous, campylotropous, and orthotropous.
  • androdioecious – Having bisexual flowers and male flowers on separate individuals. Contrast andromonoecious, polygamodioecious, polygamomonoecious, and polygamous.
  • androecium – A collective name for the male reproductive parts of a flower; the stamens of a flower considered collectively. Contrast gynoecium. Abbreviated A; (A 3+3 indicates six stamens in two whorls)
  • androgynophoreA stalk bearing both the androecium and gynoecium of a flower above the level of insertion of the perianth, formed from growth of receptacle.
  • androgynous – Having male and female flowers in the same inflorescence.
  • androphore – The stalk or column supporting the stamens in certain flowers, formed from growth of receptacle or more often from fusion of filaments eg Malvaceae.
  • andromonoecious – Having bisexual flowers and male flowers on the same individual plant.
  • andromedotoxin  – a toxic compound C31H50O10 found in various plants (as members of the genus Andromeda) of the heath family (Ericaceae) that lowers the blood pressure of animals when taken in small doses. Contrast androdioecious, gynomonoecious, polygamodioecious, polygamomonoecious, and polygamous.
  • anemophilous – Adapted to pollination by wind.
  • anemophily – Adaptation to pollination by wind.
  • anisocytic – unequal celled, guard cells between 2 large subsidiaries and 1 smaller one.
  • anisomerous or anisomery – The condition of having a floral whorl with a different (usually smaller) number of parts from the other floral whorls.
  • anisophyllous – having leaves of two or more shapes and sizes. Contrast isophyllous
  • anisotomic – Branching, with branches having unequal diameters (ie trunk and branch) Contrast isotomic.
  • anomalicidal or Irregular Dehiscent Capsule – One that dehisces irregularly, as in Ammannia.
  • anomocytic – irregularly celled stomata
  • annulus – 1.  A ring-like structure. Pappus bristles are sometimes attached to a ring called an annulus or disk at the top of the achene beak. In some pollen grains, the exine around the apertures is either thicker or thinner. In pores, this border is termed an annulus. Certain flowers have ring-like constrictions at the mouth of the flower (Huernia, Aristolochia). 2.  A ring of specialized cells on the sporangium.
  • anterior – Positioned in front of, towards the apex. Compare distal.
  • anthemoid – In Asteraceae, a style with a brush-like tuft of sweeping hairs at the tip of each style branch.
  • anther – The pollen-bearing part of a stamen.
  • antherode – A sterile anther of a staminode.
  • anthecium – Fruit derived from spikelet with only 1 floret, disarticulation always above glumes
  • anthela – a cymose corymb with the lateral flowers higher than the central ones.
  • anthesis – 1.  (of a flower) The period during which pollen is presented and/or the stigma is receptive. 2.  (of a flowering plant) The period during which flowers in anthesis are present. Not defined for some cases, such as when pollen is released in the bud.
  • anthocarp – A type of fruit in which part of the flower persists attached to the pericarp (ie Nyctaginaceae)
  • anthocyanin adj: anthocyanic – red, violet or blue pigment found in certain plants and flowers. While this pigment is mainly found in higher plant’s fruits and flowers, it can also be found sometimes in the plant’s roots, stems and leaves
  • anthophore – A stalk-like structure located between the calyx and the other parts of the flower, produced by elongation of the internode between the calyx and the corolla, it supports the corolla, androecium and gynoecium.
  • anticlinal – Pointing up, away from, or perpendicular to a surface. Contrast periclinal.
  • antipetalous – Used of inner parts of flowers, most often stamens, that are in equal number to and aligned with the petals. Also spelled antepetalous. 
  • antrorse – Directed towards or upwards, e.g. of hairs on a stem. Contrast retrorse.
  • anxiolytic – a medicine used to prevent or reduce anxiety; herbal anxiolytics are much less habit-forming than the pharmaceutical alternatives.
  • apetalous – Lacking petals.
  • apex – pl. apices – The tip; the point furthest from the point of attachment.
  • aphananthous – (of flowers) Inconspicuous or not showy, as opposed to phaneranthous or showy.
  • aphlebia – pl. aphlebiae – Imperfect or irregular leaf endings commonly found on ferns and fossils of ferns from the Carboniferous Period.
  • aphyllous – naturally leafless plants, aka switch plants with their photosynthetic functions transferred from leaves to green photosynthetic stems (eg: Cacti).
  • apical – adj. apiculate. At or on the apex of a structure, usually a shoot, a stem, or the trunk of a tree, e.g. an apical meristem or an apical bud. In placentation where one or few ovules attach to the top of a simple or compound ovary
  • apicifixed – anthers attached to the filament at the top and pointing back toward the filament like a hook.
  • apiculus – the short pointed bud of a spore
  • apiphily – A form of pollination whereby pollen is distributed by honey bees.
  • apo– A prefix meaning “away from, separate, without”.
  • apocarpous Having separate carpels, not fused.
  • apomixis – also apomixy, adj apomictic – A type of asexual reproduction whereby viable seeds or spores are produced asexually, without fertilization, such that the genetic material they contain is a clone of the parent’s genetic material. A plant produced in this way is called an apomict.
  • apomorphy – In cladistics, a “different form” from the form of an ancestor (i.e., an innovation) of use in determining membership in a clade.
  • apopetalous – Having separate petals, not fused (sympetalous).
  • apophysis – 1.  The external part of a cone scale.  2.  An outgrowth of an organ or enlargement of a stem.
  • apotropous – Ovules turned away from the placenta 
  • appendage – A secondary part attached to a main structure; an external growth that seldom has any obvious function, hence appendiculate.
  • appendiculate – Having the nature of or bearing appendages.
  • appressed – Pressed closely but not fused, e.g. leaves against a stem, hairs on a leaf.
  • arachnoid – Cobwebby, from being covered with entangled fine white hairs.
  • arborescent – Tree-like in growth or general appearance.
  • arbuscule – hyphal coils, the site of nutrient transfer between the fungus and plant roots in mycorrhiza. 
  • archaeophyte – A non-native plant that has nonetheless been present in a particular geographic area for some time. Contrast neophyte.
  • arctotoid – In the Compositae, a style with a ring of sweeping hairs borne on the shaft of the style proximal to the style branches.
  • areolate – Having or being composed of areoles, as an areolate crustose lichen.
  • areole – 1.  A space between the threads of a net, e.g. that part of a leaf surface defined by each of the elements of a vein network; as with cacti, the area between the veinlets of a leaf. 2.  A structure on the stem node of a cactus; the region of a cactus upon which spines and flowers are borne. 3.  In lichenology, a polygonal piece of a thallus surface where a crustose lichen is broken up like old dried and cracked paint, or like the polygonal “islands” of dried mud in a dry lake bed.
  • aril – A membranous or fleshy appendage formed by expansion of the funicle which partly or wholly covers a seed, e.g. the fleshy outer layer of lychee fruit, or that found in members of the Sapindaceae.
  • arista – adj: aristate – having a spiny or stiff bristle tip, as in the awns of some grasses
  • articulated – jointed, the joints are usually where the plant will break apart easily.
  • ascus or Pl asci – a saclike structure produced by Ascomycota fungi in which usually 4 or 8 sexually produced spores (ascospores) are formed.
  • asperous – having a rough surface
  • auriculate – Having two lobes, often curved near the base. ear-shaped parts or appendages. auricular.
  • autogamous – capable of self-fertilization.
  • autotroph – An organism capable of synthesizing its own food from inorganic substances using light or chemical energy. Green plants, algae, and certain bacteria are autotrophs
  • axil – The upper angle between one part of a plant and another, e.g. the stem and a leaf.
  • axile – On an axis; of a placenta, on the central axis of the ovary where the septa join the central placenta
  • axillary – Born in or arising from the axil, usually referring to the axil of a leaf.
  • axis – The main stem of a whole plant or inflorescence; the line along which this stem extends.

B

  • baccate – bearing berries – berry like
  • baccacetum – an aggregate of berries e.g. Actaea.
  • baculiform – Rod-like; longer than wide. Compare cylindrical.
  • balausta – a fleshy accessory fruit like the pomegranate, succulent within and many-seeded, with a firm rind, and tipped with the persistent lobes of the calyx.
  • barb – A rear-facing point, as in a fish hook.
  • barbed – Having barbs pointing in one direction.
  • barbellate – Having barbed hairs (barbellae) down the sides.
  • basal – Situated or attached at the base, as in placentation with ovules attached at base of ovary.
  • basicidal capsule – One that dehisces through basal slits or fissures, as in some species of Aristolochia.
  • basifixed – Something attached by its base, e.g. an anther attached to the filament. Compare dorsifixed.
  • basipetal – Developing sequentially from the apex towards the base (i.e. with the youngest towards the base), e.g. of flowers in an inflorescence. Also, moving from leaves to roots ie molecular signals in plants.
  • bathyphyll – A specialized leaf produced at the base of a plant, usually when the plant is immature, and which serves to anchor the plant to a substrate; especially notable in Teratophyllum of the Dryopteridaceae. Contrast acrophyll.
  • beak – A prominent, pointed terminal projection, especially of a carpel or fruit.
  • berberine – a quaternary ammonium salt from the protoberberine group of benzylisoquinoline alkaloids found plants like Berberis vulgaris (barberry), Berberis aristata (tree turmeric), Mahonia aquifolium (Oregon grape), Hydrastis canadensis (goldenseal), Xanthorhiza simplicissima (yellow root),
  • berry – A type of indehiscent fruit from one ovary, without a stone pit, with the seeds immersed in the pulp, e.g. a tomato, bluebeberry.
  • bi– A prefix meaning “two”; e.g. bisulcate, having two sulci or grooves.
  • bidentate – having tooth-like projections that are themselves dentate again.
  • bifacial – In leaves where the upper and lower surfaces are different
  • bifid – Forked; cut in two for about half its length. Compare trifid.
  • bifoliate – sometimes bifoliolate – of a compound leaf having precisely two leaflets, usually in a symmetrical pair, e.g. leaf of Colophospermum mopane. Compare jugate lobed leaf, e.g. most Bauhinia spp.
  • bifurcate – bifurcated – to divide or fork into 2 branches
  • bifusiform – Fusiform with a pinch in the middle.
  • bilabiate – Having two lips, e.g. the form of the petals in many irregular flowers.
  • bilateral – 1.  Having two distinguishable sides, such as the two faces of a dorsiventral leaf. 2.  Arranged on opposite sides, e.g. leaves on a stem; cf. distichous and opposite. 3.  Bilaterally symmetrical, as in a leaf with a symmetrical outline.
  • biloculate – Having two loculi, e.g. in anthers or ovaries.
  • biome – a large area characterized by its vegetation, soil, climate, and wildlife.
  • biotic –  living or once living components of a community, organisms, such like plants, fungi,  animals etc. Biotic may refer to life, the condition of living organisms or biotic material derived from living organisms, in ecology it is the sum of living/organic components of an ecosystem. 
  • bipinnate – Doubly pinnate; e.g. a compound leaf with individual leaflets pinnately divided.
  • bipinnatisect – A pinnatisect leaf with deeply dissected segments.
  • bitegmic – (of an ovule) Covered by two integuments. Contrast unitegmic.
  • biternate – leaf compound with division in two, Ternate, with each division divided into three.
  • bivalve – adj. bivalvate. Having two valves or hinged parts. Contrast trivalve.
  • blade – The lamina or flattened part of a leaf, excluding the stalk or petiole.
  • bloom – A fine white or bluish waxy powder occurring on stems, leaves, and fruits. Easily rubbed off. 
  • bole – The trunk of a tree, usually the portion below the lowest branch. Compare canopy.
  • boreal – A forest that grows in regions of the northern hemisphere with cold temperatures. Made up mostly of cold tolerant coniferous species such as spruce and fir. 
  • bostrychoid – Arranged on a conical surface (like a snail shell); used to describe inflorescences in which the buds are arranged in an almost helical manner on the outside of a long, tapering, conical rachis.
  • botryoid – a raceme with a terminal flower, often improperly called a raceme but it is a determinant inflorescence not indeterminate.  
  • brachiate – having widely diverging branches, bibrachiate is with 2 wide diverging branches. 
  • bract – A modified leaf associated with a flower or inflorescence and differing in shape, size, or colour from other leaves (and without an axillary bud).
  • bracteate – Possessing bracts.
  • bracteole – A small bract borne singly or in pairs on the pedicel or calyx; synonymous with bractlet.
  • bracteolate – Possessing bracteoles (bractlets).
  • bractlet – See bracteole.
  • branchlet – A small branch.
  • brevideciduous – A plant that loses all of its leaves only briefly before growing new ones, so that it is leafless for only a short time, e.g. approximately two weeks.
  • bristle – adj. bristly. A straight, stiff hair (smooth or with minute teeth); the upper part of an awn (when the latter is bent and has a lower, stouter, usually twisted part, called the column).
  • brochidodromous – Pinnate leaf venation in which the secondary veins do not terminate at the leaf margin, but are joined in a succession of prominent arcs.
  • brochus – pl. brochi – Width of one lumen of a pollen grain reticulum and half of the width of the surrounding muri (walls), hence heterobrochate and homobrochate, where the lumina are of different or similar sizes, respectively.
  • bulb – adj: bulbaceous A thick storage organ, usually underground, consisting of a stem and leaf bases (inner ones fleshy).
  • bulbel – A bulb arising from another bulb. See bulblet.
  • bulbil – A small, deciduous bulb or tuber formed in the axil of a leaf or pinna; vegetative propagation.
  • bulblet – Pl. bulbets. A bulb arising from another bulb; a bulbel.
  • bullate – Having rounded or globular blisters on the surface.
  • bur / burr – 1.  A prickly fruit.  2.  A rough or prickly propagule consisting of a seed or fruit and associated accessory floral parts (usually bracts).
  • buttress root – A root growing from an above-ground stem or trunk, and providing support, e.g. commonly of Ficus macrophylla.
  • byssoid—A growth form of a lichen thallus that is wispy, like teased wool.

C – Botanical Dictionary

  • C – In lichenology, “C” is an abbreviation for the test result of placing 5% solution of calcium hypochlorite or sodium hypochlorite (e.g. household bleach without additives) on the cortex or medulla of a lichen, to note the change in color, with no reaction noted as “C−”, and production of a bright colour noted as “C+”.
  • caducous – Falling off early, e.g. the sepals of poppies, which fall off when the petals begin to open. compare persistent and fugacious.
  • caespitose – Tufted or turf-like, e.g. the growth form of some grasses.
  • calcarate – possessing a spur.
  • calcareous – A soil type or a lichen substrate rock type that is rich in calcium carbonate.
  • calceolate – a corolla that is shoe or slipper shaped, the labellum in many Orchids
  • callose – Hardened; thickened; callous.
  • callus – pl. calli – 1.  A protruding mass of tissue. 2.  Undifferentiated tissue growth formed in response to wounding; may be grown in vitro. 3.  In orchids, fleshy outgrowths from the labellum which can be variously shaped from papillae to plates. 4.  In grasses, a hardened extension from the base of a floret (formed from the rachilla joint and/or the base of the lemma) which may or may not elongate and is often covered in hairs or bristles.
  • calybium – a  hard one-loculed dry fruit derived from an inferior ovary, as in Quercus; sometimes  a synonym of glans, but typically glans contains the persistent cupulate involucre that a claybium lacks. .
  • calyciflorus – Having petals and stamens attached to the calyx.
  • calycode – an ambiguous calyx – usually used only in the Santalaceae.  Perhaps sepaline-petaloid.
  • calycophyll – A leaf-like structure formed from a sepal or calyx lobe which enlarges, usually many-fold, before or after anthesis, especially when most other sepals or calyx lobes retain their original size. More extreme than an accrescent calyx, calycophylls are found in Rubiaceae. Compare semaphyll and pterophyll.
  • calyculate – Having an epicalyx.
  • calyculus – 1.  A cup-shaped structure formed from bracts resembling an outer calyx. 2.  In some Asteraceae, a circle of bracts below the involucre
  • calyptra – A hood or lid. See operculumcalyptrate – with a hood or lid. Galeate is a synonym. 
  • calyx – calyxes or calyces – Collective term for the sepals of one flower; the outer whorl of a flower. Compare corolla.
  • calyx tube – A tube formed by the fusion of the sepals (calyx), at least at the base.
  • camaraindehiscent dry fruit, pericarpium of one carpel, coriaceous, slightly fleshy or dry, seeds free (e.g. Fabaceae, Krameriaceae, Posidoniaceae, Sapindaceae).
  • camaretum – apocarps more than one seeded, pericarp is free (e.g. Damasonium of Alismataceae, Uvaria of Annonaceae, Curatella of Dilleniaceae)
  • camariumschizocarp of cameras; mericarps of monocarps with seeds free of pericarp, indehiscent or tardily dehiscent (e.g. Malva of Malvaceae, Alectryon of Sapindaceae, Tribulus of Zygophyllaceae)
  • cambium – A tissue layer that provides partially undifferentiated cells for plant growth.
  • campanulate – Bell-shaped.
  • campo rupestre – campo rupestre is used to characterize the montane vegetation of the Espinhaço Range in Brazil but recently has also been broadly applied to define high altitude fire-prone areas dominated by grasslands and rocky outcrops. In Spanish campo means rural or countryside and literally translated together campo rupestre means “rock field”.
  • camptodromous – Pinnate venation in which the secondary veins curve toward the margins, in some cases becoming nearly parallel with them, and not reconnecting with other veins to form loops.
  • campylodromous – a type of leaf venation in which a series of more or less equal primary veins originate from a common point at the base, arch upward, and reunite toward the apex; e.g., species of Aristolochia.
  • campylotropous – When the ovule is oriented transversely (i.e. inverted with its axis at right angles to its stalk) and with a curved embryo sac. Compare amphitropous, anatropous, and orthotropous.
  • canaliculate – Channeled; having a longitudinal groove.
  • canescent – Approaching white in color, as in a leaf covered with white down or wool, a synonym of hoary, sometimes used to denote greyish down instead of white.
  • capillary – 1. A tube, pore or passage with a narrow, internal cross-section. 2. Slender; hair-like.
  • capitate – 1.  (of an inflorescence) Having a knob-like head, with the flowers unstalked and aggregated into a dense cluster. 2.  (of a stigma) Like the head of a pin.
  • capitulum – pl capitula. A dense cluster of sessile or subsessile flowers or florets, e.g. a flower head in the daisy family, Asteraceae. See pseudanthium.
  • capsule – A dry fruit formed from two or more united carpels and dehiscing when ripe (usually by splitting into pieces or opening at summit by teeth or pores).
  • carcerulus – A type of schizocarpic capsule (fruit) that breaks up on maturity into one-seeded segments or nutlets, as in the Lamiaceae, Malvaceae..
  • carduoid – In the Asteraceae, having a style with a ring of sweeping hairs borne on the shaft of the style below the style branches.
  • carina – See keel. Adj: carinate. 
  • carinal canal – A longitudinal cavity in the stems of Equisetum and extinct Equisetopsida, coinciding with a ridge in the stem surface.
  • carneous – Flesh-coloured, especially as applied to some flowers.
  • carnose, carnous – Fleshy or pulpy in texture, especially as applied to some tissues or organs. Contrast coriaceous and corneous.
  • carpel – The basic female reproductive organ in angiosperms, either consisting of a single sporophyll or a single locule of a compound ovary, with a style and a stigma. The gynoecium is the collective term for all of the carpels of a single flower.
  • carpopodium – On achenes (Cypselas), an elongation of the base of the gynoecium which looks distinct; the abscission zone, where the achene is separated from the receptacle.
  • cartilaginous – Hard and tough; gristly. Compare corneous and coriaceous.
  • caruncle – A small piece of flesh-like tissue, typically lumpy or warty, growing on the testa near the hilum. Contrast aril. Adj: carunculate. 
  • caryophyllus – resembling Pink family Caryophyllaceae – 5 petals all spreading outwards
  • caryopsis – A dry, indehiscent, one-seeded fruit in which the seed coat is adnate to the fruit wall, derived from a one-loculed superior ovary, e.g. in most grasses.
  • casparian strip – A continuous band of suberin in the radial primary cell walls of the endodermis in vascular plant stems and roots that forms a permeability barrier to the passive diffusion of external water and solutes into the vascular tissue.
  • cassideous – Hood-, helmet- or bonnet-shaped; generally referring to floral anatomy, e.g. in the flowers of Aconitum, Satyrium, etc.
  • cataphyll – Any plant structure which is morphologically a leaf but which has at most an incidental or transient photosynthetic function. They are either shed when their main function has been completed, or are incorporated into structures where, when dead, they serve a protective or supportive purpose.
  • catenulate – In the shape of a chain; formed of parts or cells connected as if chained together, e.g. some diatoms, algae, and cyanobacteria such as Anabaena. See also concatenate.
  • catkin – A spike, usually pendulous, in which the mostly small flowers are unisexual and without a conspicuous perianth, e.g. in willows, poplars, oaks, and casuarinas. The individual flowers often have scaly bracts and are generally wind-pollinated. Catkins shed as a unit.
  • caudate – Having a narrow, tail-like appendage or tip, a drip tip. Contrast acuminate, cuspidate, mucronate.
  • caudex – pl. caudices – The stem of a plant, especially a woody one; also used to mean a rootstock, or particularly a basal stem structure or storage organ from which new growth arises. Compare lignotuber.
  • caudiciform – Stem-like or caudex-like; sometimes used to mean “pachycaul“, meaning “thick-stemmed”.
  • caulescent – possessing a well-developed stem above ground, similar to cauline. Antonym of acaulescent (lacking an apparent stem)
  • cauliflorous or cauline – leaves borne directly on aerial stem or caulis or usually referring to older stems when describing flowers or fruits born directly on the stem.
  • cenanthous – (of a perianth) Lacking both stamens and pistil, i.e. with neither androecium nor gynoecium.
  • cenobium – Separating nutlets which are dry,indehiscent (do not split at maturity) 4-parted fruits with a hard pericarp around a gynobasic style, as in the Boraginaceae and Lamiaceae.
  • centrifixed – Of a two-branched organ attached by its center, e.g. a hair or anther.
  • ceraceous – Having a waxy appearance, colour, or texture, e.g. flowers of many species of Ceropegia, and the waxy fruit of some species of Myrica.
  • cernuous – Nodding, falling headlong or face down; inclined, stooping, or bowing forwards. Applied to many species with a nodding, stooping habit, such as many Narcissus and Dierama species. Many plant species bear the specific epithet “cernua”.
  • cerrado – a vegetation type in tropical Brazil composed of savannas and grasslands amid humid and dry forests. In Spanish, cerrado means closed, thick or dense but in Brazil it describes an arid ecosystem with spp adapted to live with seasonal climate in the highlands of Central Brazil.  The second largest biome in South America after the Amazon. 
  • cespitose – An alternative spelling of caespitose.
  • chalaza – In plant ovules, the chalaza is located opposite the micropyle opening of the integuments. It is the tissue where the integuments and nucellus are joined.
  • chartaceous – Having a papery texture.
  • chamber – A cavity of an ovary.
  • channeled – Sunken below the surface, resulting in a rounded channel.
  • chasmogamous – Of flowers that are pollinated when the perianth is open. Compare cleistogamous.
  • chasmophyte – A plant adapted to growing in crevices or hollows, cliff faces. Compare cremnophyte.
  • chimera – An individual composed of two or more genetically distinct tissues, most commonly as a result of a graft and sometimes by mutations that occur during cell division or seed development.
  • chiropterophilous – Pollinated by bats.
  • chlorenchyma – Plant tissue consisting of parenchyma cells that contain chloroplasts and forming the basic green tissue of plant leaves and stems. 
  • chlorophyllous – usually leaves, possessing chlorophyll.  Also achlorophyllous is without chlorophyll. 
  • chlorosis – An abnormal lack or paleness of color in a normally green organ.
  • ciliate – sing. cilium; pl. cilia adj. ciliated – Having very small hairs or hair-like protrusions more or less confined to the margins; ciliolate is minutely ciliate.   
  • cincinni/cincinnus – a monochasium on which successive axes arise alternately in respect to the preceding one.  Syn: scorpioid cyme or boraginoid cincinni – borage like cincinni.
  • circinate – Spirally coiled with the tip innermost, e.g. circinate vernation of developing fern fronds.
  • circinotropous – The funicle in this case is especially long that it creates a nearly full circle around the ovule whose micropyle is ultimately pointing upwards.
  • circumboreal – adj is a floristic region within the holarctic zone of Eurasia and North America, plants that inhabit the boreal zone at all longitudes. Compare with holarctic which despite the name extends further south covering all of Europe, most of Asia and almost all of North America. 
  • circumscissilecapsules that open along a transverse circular line (circumferentially) as in Plantago. Note that Papaveraceae are also called circumscissile capsules but technically they are operculate capsules. Synonym pyxis. 
  • cirrhous or cirrhose – a leaf ending in a tendril at the apex.
  • cladode – A photosynthetic branch or stem, often leaf-like and usually with foliage leaves either absent or much reduced. Compare phyllode.
  • cladodromous – with a single central vein from which secondary veins radiate on each side to the margins, pinnate with branching to the leaf margins.
  • clathrate – Shaped like a net or lattice; pierced with apertures, as with a cage.
  • clavate or claviform – Club-shaped.
  • clavicipitaceous – endophytes (parasitic fungi) that grow within their plant host without manifesting symptoms of disease or harming their host.
  • clavuncula – In the Apocynaceae, an enlarged, drum-shaped stigma of which the sides and lower surface are the receptive zones. Coherent with the anthers or not.
  • claw – 1 Narrow stalk-like basal part of a petal, sepal or bract. 2 In Melaleuca united part of stamen bundle.
  • cleft – a split or indentation up to half way down the center, eg petals. 
  • cleistogamous – Having flowers which self-pollinate and never open fully, or which self-pollinate before opening. Compare chasmogamous.
  • cline – adj clinal – A continuous morphological variation in form within a species or between two species.
  • coalescent – Having plant parts fused or grown together to form a single unit.
  • coccum fruit opening along two sutures, unequal in length, often woody.  But not of the Fabales order (often Connaraceae, Myristicaceae, and Proteaceae).
  • coccarium – mericarps of coccum monocarps in a schizocarpic fruit that open along 2 sutures eg: Euphorbiaceae, Hamamelidaceae, Zanthoxylum (Rutaceae), and others. 
  • cochleariform – Concave and spoon-shaped.
  • cochleate – Coiled like a snail’s shell.
  • coenobium – An arranged colony of algae that acts like a single organism.
  • coenocyte – A single cell with multiple nuclei, formed when nuclear division not followed by cytokinesis.
  • coleoptile – One type of sheath in the structure of monocotyledonous seeds. The coleoptile is a protective sheath or cap (pileus), generally more or less pointed, that covers the monocotyledonous plumule as it emerges from the soil. It generally turns green and contributes to photosynthesis until its function is superseded by the main growth of the seedling. Contrast this with the coleorhiza, which remains underground until it is superseded as the roots emerge.
  • coleorhiza – One type of sheath in the structure of monocotyledonous seeds. The coleorhiza connects the coleoptile to the radicle and protects the monocotyledonous radicle during germination. Unlike the coleoptile, the coleorhiza is associated with the root and does not emerge from the soil during germination. Contrast coleoptile.
  • collenchyma – A specialized tissue consisting of living cells with unevenly thickened cellulose and pectin cell walls that performs a support function in organs such as leaves and young stems that are composed of primary plant tissues.
  • colleter – A multicellular, glandular hair that usually produces a mucilaginous substance and is located on sepals, stipules, or petioles, or on nearby parts of stems; commonly found on plants of order Gentianales.
  • colpi – Eudicots usually have three apertures that run from the proximal side of the pollen grain to the distal side named colpi and the pollen type of the Eudicots is called tricolpate.
  • columella -In flowering plants, the central axis of the cone or fruit, e.g. in Callitris.
  • column – 1.  A structure extending above the ovary and incorporating the style and stamens also known as the gynostegium, e.g. in orchids and milkweeds.  2.  In grasses, the lower, stouter, and usually twisted part of an awn, distinct from the slender upper part or bristle.
  • columnar – Shaped like a column.
  • coma – 1.  A tuft of hairs from testa or funiculus at one or both ends of some seeds, e.g. in Strophanthus, Asclepias, or Alstonia.  2.  Sterile bracts, e.g. in Curcuma, Ananas, or Eucomis.  3.  Sterile flowers, e.g. in Muscari and Leopoldia, at the apex of some inflorescences.  4.  A tuft of hairs at the base of some flowers, e.g. in Pfaffia gnaphalioides. 5.  A tuft of hairs at the apex or base of some spikelets.  6.  An axil tuft of hairs in inflorescences in some Poaceae, e.g. in Eragrostis comata.
  • commelinids – Clade of monocots distinguished by cell walls containing ferulic acid.  
  • commissure (commissural) – The seam or face at which two carpels adhere. See also fissure and suture
  • comosecoma: the hair of the head. A tuft of hairs surrounding the terminal or basal tips of some fruits, seeds, leaf or branches. A coma arises from the seed or other part, while a pappus is a modified calyx.
  • compound – Composed of several parts, e.g. a leaf composed of multiple leaflets, a gynoecium composed of multiple carpels, or an inflorescence made up of multiple smaller inflorescences.
  • compound palmate – Having leaflets that radiate from a central point (usually at the top of a petiole), like spread-out fingers radiating from the palm of a hand. Compare palmate.
  • compressed – Flattened lengthwise, either laterally (from side to side) or dorsally (from front to back).
  • concatenate – Joined together in a chain-like form. See also: concatenate and catenate.
  • concolorous – Having the same colour throughout; uniformly coloured.
  • concrescent – the growing together of related parts, tissues or cells.  The union of cell walls by means of a concreting substance. 
  • conduplicate – Arranged such that two sides of a flat surface are folded along the midline to face each other. See also ptyxis, aestivation, and vernation.
  • cone – A type of fruit, usually woody, ovoid to globular, including scales, bracts, or bracteoles arranged around a central axis, e.g. in gymnosperms, especially conifers and Casuarina.
  • conflorescence – A rarely used term describing substantial differences between the overall structure of an inflorescence and that of its individual branches, e.g. the bottlebrush multiple-flower head of members of the genus Callistemon.
  • connate -Fused to another organ(s) of the same kind, e.g. petals in a corolla tube. Compare adnate.
  • connective – The part of an anther that connects the anther cells.
  • connivent – Coming into contact or converging, but not fused.  Syn: Cohering?
  • conspecific – Belonging to the same species.
  • contiguous – adjoining, touching, but not united.
  • contort – (of sepals or petals) A type of imbricate aestivation in which one side of each segment overlaps one of the adjacent segments and the other side is overlapped by the other adjacent segment. See convolute.
  • contorted – Twisted out of the normal shape; in aestivation with 1 side over its neighbor and the other side under its other neighbor.
  • contortuplicate – in aestivation where it is both contorted (1 side each over and under its nearest neighbors) and plicate (folded lengthwise).
  • convolute – 1.  Referring to the arrangement of floral or foliar organs in a bud when each organ or segment has one edge overlapping the adjacent organ or segment; a form of imbricate arrangement. See contort. 2.  (of leaves) A type of venation in which one leaf is rolled up inside another. 3. Type of vernation of two leaves at a node where one half of each leaf is exposed and the other half is wrapped inside the other leaf.
  • corcle – A plant embryo, plumule, or plumule plus radicle.
  • cordate – Heart-shaped, with the notch lowermost; of the base of a leaf, like the notched part of a heart. Contrast obcordate.
  • coriaceous – Leathery; stiff and tough, but flexible. Compare corneous. Also subcoriaceous is almost leathery.
  • corm – A fleshy, swollen stem base, usually underground and functioning in the storage of food reserves, with buds naked or covered by very thin scales; a type of rootstock. Adjectives derived from “corm” include “cormose” and “cormous”.
  • corneous – Horny in texture; stiff and hard, but somewhat tough. Compare coriaceous.
  • corolla – A collective term for the petals of a flower. Pertaining to corolla is corolline. Compare calyx.
  • corona – adj: coronate 1.  In flowering plants, a ring of structures that may be united in a tube, arising from the corolla or perianth of a flower and standing between the perianth lobes and the stamens. The trumpet of a daffodil is a corona.  2.  In grasses, a hardened ring of tissue surmounting the lemma in some species.
  • corpuscule also corpuscle – any minute particle.  Corpusculum  is a structure connecting the two translators of the pollinia of Apocynaceae subfamily Asclepiadoideae
  • cortex – pl. cortexes or cortices – In lichens, the “skin” or outer layer of thallus tissue that covers the medulla. Fruticose lichens have one cortex encircling the branches, even flattened, leaf-like forms; foliose lichens have different upper and lower cortices; crustose, placodioid, and squamulose lichens have an upper cortex but no lower cortex; and leprose lichens lack any cortex.
  • corticolous – Growing on bark or on wood with the bark stripped off. Compare lignicolous.
  • corymb – adj corymbose An inflorescence with branches arising at different points but reaching about the same height, giving the flower cluster a flat-topped appearance.
  • costa or costae (pl) or adj costate – A rib. Adj having veins or ridges, especially parallel ones.
  • costapalmate – Having a definite costa (midrib), unlike the typical palmate or fan leaf, but with the leaflets arranged radially as in a palmate leaf.
  • crassinucellate – Ovaries/ovules – with many parietal cells and a large nucleus.  
  • craspedium –  a one-carpellate fruit splitting transversely into one-seeded segments; seed-bearing segments separate from each other and from the persistent replum (ie Mimosa). Sometimes incorrectly called a loment, but they are both schizocarps, but the craspedium leaves behind a persistent replum
  • craspedodromous – Pinnate venation in which the secondary veins terminate at the margins, often as teeth. Simple is simple pinnate ending at the margins, semicraspedodromous is ;mixed craspedodromous is a mix of both craspedodromous and camptodromous
  • crateriform – In the shape of a saucer or shallow cup; hemispherical or more shallow.
  • cremnophyte – A plant adapted to growing on or hanging from cliffs or crevices. Compare chasmophyte.
  • cremocarp – also called schizocarpic mericarps, or carpopodium. Separating mericarps which are dry, seed-like fruits derived from an inferior ovary, as in the Apiaceae.
  • crenate – Having blunt or rounded teeth; scalloped.
  • crenulate – Minutely scalloped.
  • crispate – of a leaf having curly or wavy edges.
  • crisped – Finely curled, as with the edges of leaves and petals.
  • cristarque  cell – A sclereid which contains a druse and has the lignin deposited excentrically on the cell wall to form a cup shape, or in cross-section, a ∪-shape.
  • cross venulation – Also cross-venules – leaf venation going horizontally across the leaf
  • crozier – characteristic coiled inflorescence in Boraginaceae also used for Ascomycota fungi characteristic feature at the base of their asci that also look like a hook-topped shepherd’s staff.
  • cruciform – Cross-shaped, as in 4 petaled flowers.
  • crustaceous – Hard, thin and brittle.
  • crustose – Forming a closely applied surface layer or crust.
  • cryptocotylar – a type of seed germination in which the cotyledons remain within the seed coat at germination.
  • cryptogam – Any of the “lower plants” which produce spores and do not have stamens, ovaries, or seeds; literally, plants whose sexual reproductive organs are not conspicuous. This group typically includes the ferns, bryophytes, and algae, and sometimes fungi (including lichenized fungi). Compare phanerogam.
  • cucullate – also cucullus  Hood-like or hooded, commonly referring to the shape of leaves or petals, e.g. Pelargonium cucullatum. Similarly derived terms include cuculliform and cuccularis.
  • culm – In grasses, sedges, rushes, and some other monocots, an aerial stem bearing the inflorescence, extending strictly from the base of the plant to the lowest involucral bract (or base of the inflorescence).
  • cultigen – A plant whose origin or selection is primarily due to intentional human activity.
  • cuneate – Wedge-shaped, with straight sides converging at a base.
  • cupule – A cup-shaped structure composed of coalescent bracts, such as the cup of an acorn. See calybium.
  • cupular – Shaped like a cupule.
  • cupulate – Bearing cupules.
  • cupuliform – Nearly hemispherical, shaped like a cupola or dome.
  • cusp – A hard, pointed tip, stiffer and more formidable than a mucronate, hence cuspidate.
  • cuspidate – Tipped with a cusp, as with some leaves.
  • cuticle – A waterproofing layer covering the epidermis of aerial plant surfaces and composed of the polymers cutin, and/or cutan and waxes.
  • cyanthiform – in the shape of a deep cup or saucer
  • cyathium – pl. cyathia, adj cyathiform  – An inflorescence of unisexual flowers surrounded by involucral bracts, especially the flowers of Euphorbia.
  • cyathophyll – in Euphorbia, the bract-like structure on which the involucre sits, usually but not always occurring in twos. They may sometimes be brightly colored and confused with petals.
  • cyclic – Flowers, arranged in whorls.  Compare acyclic arranged in spirals (Magnolia)
  • cyclocytic – Stoma surrounded by at least 4 cells arranged in a ring around the stoma
  • cylindrical – rod-like and two to three times as long as wide. Compare baculiform.
  • cyme – adj. Cymose – A type of inflorescence in which the main axis and all lateral branches end in a flower (each lateral may be repeatedly branched). A cymule is a small cyme
  • cymose – Having a cyme or cymes.
  • cypsela – A type of dry, one-seeded, indehiscent fruit formed from a one loculed inferior ovary with accessory hypanthium or calyx developing into terminal wings or bristles.
  • cystoliths – is a botanical term for outgrowths of the epidermal cell wall, usually of calcium carbonate, formed in a cellulose matrix in special cells called lithocysts, generally in the leaf of plants. 

D

  • deciduous – plants that tend to lose their leaves at maturity or annually in winter or dry seasons when they need to conserve energy.
  • declinate – Curving downwards, and then upwards at the tip. Often qualified, e.g. declinate-ascendant.
  • decompound – Divided to more than one level, e.g. in bipinnate leaves, in which the leaflets of what would otherwise be a pinnate leaf are themselves pinnately divided.
  • decorticate – 1.  (intr. v.) To shed the outer bark of a tree, usually seasonally as part of the natural growth cycle. 2.  (tr. v.) To strip the peel, crust, bark, or other surface tissues from a plant or from harvested material, such as in extracting fibre from harvested Agave leaves.
  • decumbent – Having branches growing horizontally along the ground but which are turned up at the ends.
  • decurrent – Extending downwards beyond the point of insertion, e.g. when the base of a leaf or a fungal gill is prolonged downwards along the stem in a raised line or narrow wing.
  • decussate – Opposite with successive pairs borne at right angles to the last; generally applied to the arrangement of leaves.
  • dedoublement – where 2 or more structures are found but where only one is expected.
  • definite – Of a constant number, e.g. twice as many stamens as petals or sepals (or less), or an inflorescence ending in a flower or an aborted floral bud, typically a cymose inflorescence. Contrast indefinite.
  • deflexed – Bent downwards. Contrast inflexed.
  • dehiscent – Breaking open at maturity to release contents; refers e.g. to the opening of fruits to release seeds, of anthers to release pollen, and of sporangia to release spores. Contrast indehiscent.
  • deltoid – Shaped like the uppercase Greek letter Δ, i.e. like a more or less equilateral triangle.
  • dendroid – adj: dendritic – Tree-like; branching like a tree.
  • dentate – Toothed, especially in reference to leaf margins.
  • denticidal – capsules dehiscing apically and leaving a ring of ‘teeth’ behind. Eg in Cerastium.
  • denticulate – Finely toothed; a diminutive form of dentate.
  • determinate – Limited, usually in growth. Contrast indeterminate.
  • diacytic – Cross celled stomata guard cells surrounded by 2 subsidiary cells that each circle one end of the opening and contact each other opposite to the middle of the opening. 
  • diadelphous – Referring to a class of adelphous structure in which the stamens or similar organs are connected in two adelphiae instead of just one.
  • diaspore – Any reproductive part of a plant adapted for dispersal and for establishing new plants; may be a disseminule such as a seed, or other parts such as specialized buds, branches, inflorescences, or fruits.
  • dichasium – pl: dichasia – A cymose inflorescence with all branches below the terminal flower in regular opposite pairs. Compare monochasium and pleiochasium.
  • dichlamydeous – Having a perianth which is divided into a separate calyx and corolla. Compare homochlamydeous.
  • dichotomous – symmetrically branching or forking into two equal branches. This may result from an equal division of the growing tip, or may be sympodial, in which the growing tip is aborted and replaced. Typically refers to mode of branch growth, as in Aloidendron dichotomum, but also to other organs, such as the venation patterns on leaves, the thorns of various species of Carissa (which morphologically are branches), and the thalli or hyphae of various algae and fungi.
  • diclesium – Achene or nut surrounded by a persistent accessory calyx, as in Mirabali
  • diclesarium.  Fruitlets of a schizocarp developing within an accrescent perianth 
  • dicot – also dicotyledon have two cotyledons, or embryonic leaves, found in the seed embryo. Unlike monocots, dicots are not a monophyletic group and instead, a number of lineages diverged earlier than the monocots did. Dicots differ from monocots in six distinct structural features: the flowers (parts usually in 4’s or 5’s), leaves (usually palmate, pinnate or other vein, rarely parallel), roots (usually fibrous or tap roots, rarely with storage organs), stems (able to produce secondary growth, different vascularization), and pollen grains. However, the root of these differences stems from the very early embryonic stages of the angiosperm, providing the biggest difference of all between monocots and dicots: the seed.  Note that there  are always exceptions to the rule. Some of the early-diverging dicots seem to have typical monocot characteristics such as scattered vascular bundles, trimerous flowers, and monosulcate pollen grains and approximately 2% of angiosperms don’t fit into either category.  Early basal angiosperms and those that do not fit are typically classified in this book under the Basal Angiosperms. 
  • didynamous – having four stamens disposed in pairs of unequal length —used especially of plants of the families Scrophulariaceae and Labiatae.
  • digitate digitately – With segments spreading from a common center, like the fingers of a hand. See also palmate and palmatisect.
  • dimorphic – also: dimorphous – Occurring in two different forms (with respect to shape and/or size), e.g. of stamens, fronds, or leaves. See also monomorphic (having a single form) and polymorphic (having many forms).
  • dioecious – (of vascular plants) Having male and female reproductive structures which develop only on different individuals and never on the same individual. Contrast monoecious.
  • dioicous – (of a bryophyte gametophyte) Having male and female reproductive structures which develop only on different individuals and never on the same individual. Contrast monoicous.
  • diplostemonous – Having stamens arranged in two whorls, with the outer whorl alternating with the petals while the inner whorl is opposite the petals. Compare obdiplostemonous and haplostemonous.
  • diplotegium – A fruit, a pyxis derived from an inferior ovary.
  • disc – Also spelled disk. A plate or ring of structures derived from the receptacle, and occurring between whorls of floral parts. In some groups, especially Sapindales, the nectary is in the form of a prominent disk. In daisies, the central part of the capitulum is a disk so flowers born there are called disk flowers or florets.
  • discoid – Resembling a disc or plate, having both thickness and parallel faces and with a rounded margin. Also used to describe the flower head of Asteraceae where there are no ray florets but only disc florets.
  • discolorous – (of leaves) Having upper and lower surfaces of different colours.
  • disjunct – Occurring in widely separated geographic areas, distinctly separate; applies to a discontinuous range in which one or more populations are separated from other potentially interbreeding populations with sufficient distance so as to preclude gene flow between them.
  • disk floret – A floret occurring most typically in the disk of the capitulum of flowers in the family Asteraceae, and to some extent in other plants that bear a flowering head with a disk, such as Scabiosa.
  • dissected – Deeply divided; cut into many segments.
  • dissepiment – A partition or septum in a plant part, usually referring to septa between the loculi of capsules or of other fruits with multiple partitions.
  • distal– Remote from the point of origin or attachment; the free end. Contrast proximal.
  • distichous – Arranged in two opposite rows (and hence in the same plane); aka two-ranked
  • distinct – Separate or free; not united.
  • distyly – Adj: distylous. The condition in which the flowers of a species occur in two forms that differ only by the length of the style and stamens, flowers of only one of these forms appear on any one plant. Compare heterostyly.
  • dithecal – . having two thecae or receptacles.
  • divaricate – Wide-spreading.  Adj: divaricately 
  • divergent – Spreading in different directions, generally upward.
  • domatia – sing. domatium – Any hollow structure formed by a plant that is inhabited by ants or mites.
  • dorsal – From Latin dorsum, a ridge or the back of an animal. Partly because the term originally referred to animals rather than plants, usage in botany is arbitrary according to context and source. In general “dorsal” refers to “the rear or back or upper surface”, but in botanical usage such concepts are not always clearly defined and may be contradictory. For example: facing away from the axis (abaxial) in a lateral organ of an erect plant. Related anatomical terms of location include ventral, lateral.
  • dorsifixed – Attached at or by the back, e.g. anthers on a filament.
  • dorsiventral – Having structurally and visibly different upper and lower surfaces, e.g. some leaves.  Dorsiventral leaves orient themselves at an angle to the main axis and perpendicular to the direction of sunlight. Most dicots have dorsiventral leaves.  Compare bilateral and isobilateral.
  • double cyme – with a complete cyme branching off each side of the main axis. 
  • drip tip – A long, narrow, acuminate, caudate, or cuspidate extension at the tip of a leaf or leaflet. Commonly an adaptation to rainy conditions, as it promotes shedding of water by its dripping from the narrow tip. The term “drip tip” is not anatomically descriptive in the way that say, acuminate or cuspidate, are; rather it is a description of the functional shape that aids dripping, irrespective of the specific geometry of the shape itself.
  • drupe – A type of succulent fruit formed from one carpel; the single seed (pyrene) is enclosed by a stony layer of the fruit wall, e.g. in peaches and olives. 
  • drupecetum – An aggregation of drupelets, as in Rubus.
  • drupelet – A small drupe formed from one of the carpels in an apocarpous flower. Drupelets usually form a compound fruit, as in Rubus, but they may become widely separated, as in Ochna.
  • druse – A globular mass of calcium oxalate crystals, usually the crystals radiating from an organic core.

E – Botanical Dictionary

  • ebracteate – Lacking bracts; synonymous with ebracteolate.
  • echinate –  Bearing or covered with spines or bristles; prickly. or adj biology covered with spines, …
  • ecological amplitude – The range of environmental conditions in which an organism can survive.
  • ectomycorrhizal – Fungi that do not penetrate the root cell walls and instead form an inter-cellular interface (Hartig net) made of a lattice of hyphae between the epidermal and cortical root cells. 
  • ectoparasite – adj: ectoparasitic. A parasite, such as a flea, that lives on the outside of its host. Compare with endoparasite.
  • edaphic – Of or influenced by the soil. 
  • elaiosome – An external structure attached to the seed of many species of plants. Elaiosomes generally look fleshy and in some species they are rich in oils or other nutritious materials. Their functions vary and are not always obvious; commonly they attract ants or other animals that aid in dispersal, but they may also repel other animals from eating the seed.
  • elephophily – A form of pollination whereby pollen or spores are distributed by the feet of elephants, as in Rafflesia arnoldii.
  • elaminate – without leaf blades
  • elater – a cell (or structure attached to a cell) that is hygroscopic and changes shape in response to changes in moisture. Elaters come in many forms but are always associated with plant spores.
  • elfin – Elfin forest or stunted forest is a short gnarled forest of generally 1 -10 m height. The trunks, branches and forest floor are covered in moss, lichens, orchids and epiphyte plants. 
  • ellipsoid – A three-dimensional shape that is elliptical in all sections through the long axis.
  • elliptical – Also elliptic. – Planar, shaped like a flattened circle, symmetrical about both the long and the short axis, tapering equally both to the tip and the base; oval.
  • emarginate – Notched at the apex (notch usually broad and shallow).
  • embryo – The young plant contained by a seed prior to germination.
  • embryogeny – the formation and growth of an embryo. Adj: embryogenic, embryogenetic.
  • emergent – A plant taller than the surrounding vegetation or, among aquatic plant species, one that bears flowers and commonly leaves above the surface of the water. Aquatic examples include water lilies, reeds, and papyrus. Some pondweeds such as Stuckenia are not emergent until they flower, at which time only their flowers appear above the water surface.
  • emerse – risen or standing out of water, surrounding leaves, etc.
  • enantiostyly – the condition in which the gynoecium protrudes laterally, to the right (dextrostyly) or to the left (sinistrostyly) of the androecium, e.g. Senna.
  • enation – an outgrowth from the plant surface of epidermal and subdermal tissue but not vascularized (but may have microphylls) 
  • endocarp – The innermost layer of the wall of a fruit; in a drupe, the stony layer surrounding the seed.
  • endodermis – The innermost layer of the cortex of vascular plant roots, also in the stems of pteridophytes. The radial walls are impregnated with suberin to form a permeability barrier known as the Casparian strip.
  • endogenous – arising from within
  • endomycorrhizal – Fungi that penetrate the cortical cells of the root and forms arbuscules and vesicles. 
  • endophloic – Also endophloeodal. (of crustose lichens) Having the thallus growing within rather than upon the bark of trees. Compare epiphloedal and corticolous (growing on the surface of wood or bark) and endolithic (growing within rock).
  • endoparasite –  A parasite that lives within the body of the host. 
  • endophyte – pl endophytes – is an endosymbiont, often a bacterium or fungus, that lives within a plant for at least part of its life cycle without causing apparent disease; ubiquitous in plants. 
  • endosperm – 1.  (angiosperms) A nutritive tissue surrounding the embryo of the seed, usually triploid, originating from the fusion of both polar nuclei with one gamete after the fertilization of the egg. 2.  (gymnosperms) The prothallus within the embryo sac.
  • endospory – The production of spores that germinate into a reduced multicellular gametophyte contained within the spore wall. Contrast exospory.
  • endozoochorous – Seed dispersal via ingestion by vertebrates (mostly birds and mammals), also endozoochory which is the dispersal mechanism for most tree species. Results from coevolution from a mutualistic relationship in which a plant surrounds seeds with an edible, nutritious fruit as a good food for animals that consume it.
  • endosymbiont – a type of symbiosis in which one organism lives inside the other, the two typically behaving as a single organism.
  • ensiform – Shaped like the blade of a sword.
  • entire – 1. Not divided.  2. (of a margin) Smooth, not lobed or toothed (but possibly wavy or scalloped).
  • entomophily – A form of pollination whereby pollen or spores are distributed by insects.
  • epicalyx – An involucre resembling an outer calyx, e.g. as in Hibiscus.
  • epicarp – the outer layer of the wall of a fruit, i.e. the “skin”.
  • epicormic – Used to refer to buds, shoots, or flowers developing from the old wood of trees, especially after injury or fire.
  • epicotyl – The part of the plant axis or stem between the cotyledonary node and the first foliage leaves.
  • epicuticular wax – A layer of crystalline or amorphous wax deposited on the surface of the cuticle.
  • epidermis – An organ’s outermost layer of cells, usually only one cell thick.
  • epigeal – germination where cotyledons emerge above the surface after germination.
  • epigynous – Borne on the ovary; describes floral parts when attached above the level of the ovary and arising from tissue fused to the ovary wall. Compare hypogynous and perigynous.
  • epilithic – Growing on stone. Compare lithophytic, a plant growing on stone.
  • epimatium – specialized ovuliferous scale that bears and encloses a single inverted ovule.  Found in Araucaria araucana and certain Podocarpaceae
  • epinecral – Dead (necral) tissue above the surface of the cortex of a lichen.
  • epipetalous – Of stamens that are attached to the petals.
  • epipetric – Growing on rock or stone, lithophytic, epilithic.
  • epiphloedal – Growing on the surface of bark. Contrast endophloedal (growing inside, not on, the bark) and epilithic (growing on rock, not bark).
  • epiphyllous – Growing on the surface of a leaf, especially the upper surface, as in flowers
  • epiphyte – A plant, alga or fungus that grows on another plant without deriving nourishment from it but using it for support.
  • epiphytic – Of an epiphyte; living on the surface of a plant. Compare epilithic, lithophytic.
  • epitepalous – Of stamens that are attached to the tepals.
  • epitropous – ovules turned towards placenta, reverse of apotropous.  Synonym of anatropous???
  • epizoochory – A type of seed dispersal that occurs when seeds or fruits physically adhere to the outside of vertebrate animal bodies.
  • epruinose – Not pruinose.
  • epulvinate – without a pulvinus – without a swelling at the base
  • equitant – (of a leaf) Folded lengthwise and clasping another leaf.
  • erect – Upright, more or less perpendicular to the ground or point of attachment. Compare patent (spreading) and erecto-patent, between erect and patent.
  • ericoid – Having leaves like those of the European heaths (Erica); small and sharply pointed.
  • erose – (of a margin) Irregular as though nibbled or worn away.
  • ethereal – A plant product, usually somewhat volatile, giving the odors and tastes characteristic of the particular plant; usually, the steam distillates of plants or of oils obtained by pressing the rinds of plants. See also: volatile oil.
  • even-pinnate – Having an even number of leaflets in a compound leaf; synonymous with paripinnate.
  • ex – In nomenclature, indicating that the preceding author proposed the name but did not legitimately publish it, and that the succeeding author referred to the first author when legitimately publishing the name. 
  • exalbuminous – In seeds having no endosperm, i.e. no albumen, e.g. in Fabaceae and Combretaceae.
  • excentric – Off center, to one side
  • exocarp – The outer layer of the pericarp, often the skin of fleshy fruits.
  • exospory – Production of spores that germinate free-living multicellular gametophytes. Contrast endospory
  • exotegmic – Pertaining to the outer portion of the integument.
  • exotesta – The outer layer of the testa (seed coat). It is derived from the outer integument of the ovule.
  • exserted – Projected beyond, e.g. stamens beyond the corolla tube. Also exsert. 
  • exstipulate – Lacking stipules.
  • extinction – the loss or dying out of a species due to environmental forces or evolutionary changes. The species ceases to exist.
  • extirpation – the local extinction of a species in an area, though that species still continues to exist elsewhere.
  • extrastaminal – Outside the stamens or androecium, usually referring to the location of a nectary disk.
  • extrorse – (of anther locules) Opening towards the outside of the flower. Contrast introrse and latrorse.
  • evergreen – plants that do not lose their leaves during the growing season and retain them into the following year.

F

  • F1 hybrid – A single cross; a plant breeding term for the result of a repeatable cross between two pure lines. 
  • F2 hybrid – A plant breeding term for the result of a plant arising from a cross between two F1 hybrids; may also refer to self-pollination in a population of F1 hybrids.
  • fabiform – Shaped like a kidney bean.  Synonym of or similar to reniform?
  • facultative – Of parasites, optional. Compare obligate.
  • falcate – Curved like the blade of a scythe.
  • farina – powdery, pale yellow crystalline secretion consisting of flavonoids in Primula and other species
  • farinose – also farinaceous.  A powder coating that is mealy.
  • fascicle – adj fasciculate – A cluster, e.g. a tuft of leaves, stamens, flowers etc all arising from the same node. In stamens usually branching from a single primorida.
  • fasciculate – Branching in clusters like a bundle of sticks or needles; having fascicles.
  • fastigiate – shrub or tree having branches sloping upwards erect and more or less parallel to the main stem. Erect and parallel. 
  • faveolate – Honeycombed; having regular, angled pits. Compare foveolate.
  • faucal – Pertaining to the fauces; located in the throat of a calyx or corolla.
  • fauces – The throat of a calyx or corolla; the conspicuously widened portion between the mouth and the apex of the tube. In Boraginaceae, the site of distinctive appendages.
  • felted – Covered with very dense, interlocked and matted hairs with the appearance of felt or woolen cloth.
  • fenestrate – Having holes or large translucent areas. Compare punctate with small translucent patches.
  • ferruginous – Ruddy or rust-colored.
  • fiber – 1.  A fiber cell. .  Any flexible, strong, stringy, and very elongate structure.
  • fiber  cell – a type of cell that is found in sclerenchyma, it is much elongated and dies soon after an extensive modification of its cell wall. The cell wall is usually thickly lignified, sometimes gelatinous.
  • fibrous root – not a taproot, usually formed by thin, moderately branching roots growing from the stem, found in all monocots and many dicots.
  • filament – 1.The stalk of a stamen.  2. any very narrow, thread-like structure that is one or a few cells thick.
  • filamentous – consisting of filaments or fibres, hairlike.
  • filantherous – typical stamen with distinct filaments and anthers, and without appendages. 
  • filiform – thread-like. e.g. stamen filaments, or leaf shapes. Often misspelled filliform. 
  • fimbria – slender hair-like process (plural: fimbriae)
  • fimbriate – Fringed.
  • fissure – A split or crack, often referring to fissured bark; a line or opening of dehiscence.
  • fistule – A tube-shaped cavity.
  • fistulose – Hollow; usually applied to a tube-shaped cavity, as in a reed.
  • flabellateFan-shaped.
  • flaccid – Limp; tending to wilt. Compare turgid.
  • flavonoids – plant compounds that are found in almost all fruits and vegetables. … Along with carotenoids, they are responsible for the vivid colors in fruits and vegetables. Flavonoids are the largest group of phytonutrients, with more than 6,000 types. Some of the best-known flavonoids are quercetin and kaempferol.  Flavanols are a class of flavonoids that have the 3-hydroxyflavone backbone. 
  • flexistyly – Depending on the degree of maturation of the stamens, the style moves up or down (cataflexistyle or (ana-)hyperflexisyle).
  • flexuous (flexuose) – Bent alternately in different directions; zig-zag.
  • floccose – Having soft and woolly tufts of hairs that tend to rub off easily.
  • floral leaves – The upper leaves at the base of the flowering branches.
  • floral diagram – A graphical means to describe flower structure, usually a schematic cross-section through a young flower.
  • floral formula – A description of flower structure using numbers, letters and various symbols.
  • floral tube – An imprecise term sometimes used as a synonym of hypanthium or corolla or calyx tube.
  • floret – A small flower, usually referring to the individual true flowers clustered within an inflorescence, particularly those of the grasses and the pseudanthia of daisies.
  • foetid – malodorous or offensive smelling
  • foliaceous – Leaf like in texture and form, but not a leaf (eg petals, stamen)
  • foliate – Preceded by a number: having a certain number of leaflets; ie 3-foliate, “having three leaflets
  • foliicolous – A growth habit of certain lichens, algae, and fungi that grow on the leaves of vascular plants.
  • follicle – A dry fruit formed from one carpel, splitting along a single suture, to which the seeds are attached. Compare pod (of legume).
  • follicetum – An aggregation of follicles, as in Caltha.  Also schizocarpic follicles. 
  • foliole – A small leaf-like appendage on the front or back.  Foliolose – bearing folioles. 
  • foliose – Leaf-like; flattened like a leaf.
  • forb – Any non-woody flowering plant that is not a grass, sedge, or rush.
  • forma (in common usage, form) – A taxonomic category subordinate to species and within the taxonomic hierarchy, below variety (varietas), and usually differentiated by a minor character.
  • foveolate – Having regular tiny pits. Compare faveolate.
  • free – Not united with other organs of the same type; not attached at one end.
  • free central – Of placentation, ovules attached to a free-standing column in the centre of a unilocular ovary.
  • frond – A leaf of a fern, cycad, or palm.
  • frutescent – Shrub-like (fruticose) or becoming shrub-like.
  • fruticose – Shrubby; having the branching character of a shrub.
  • fruit – A seed-bearing structure present in all angiosperms, formed from the mature ovary and sometimes associated floral parts upon fertilization.
  • fugacious – Disappearing, falling off, or withering. Compare persistent and caducous.
  • funicle (funiculus) – The stalk of an ovule.
  • funnelform – Having a form gradually widening from the base to apex; funnel-shaped.
  • furcate – Forked, usually applied to a terminal division; with two long lobes.
  • fused – Joined together.
  • fusiform – Rod-shaped and narrowing gradually from the middle towards each end; spindle-shaped.

G – Botanical Dictionary

  • galbulus – In gymnosperms, a fleshy cone (megastrobilus); chiefly relates to cones borne by junipers and cypresses, which are often mistakenly called berries.
  • gamete – A cell or nucleus that fuses with another of the opposite sex during sexual reproduction.
  • gametophore – Specialized structures on the gametophytes of some bryophytes, for example many  Marchantiales; in such species the gametes are produced on the gametophores, which amount to sex organs.
  • gametophyte – The haploid multicellular phase in the alternation of generations of plants and algae that bears gametes. In bryophytes the gametophyte is the dominant vegetative phase; in ferns and their allies it is a small free-living plant known as the prothallus; in gymnosperms and angiosperms the gametophytes are reduced to microscopic structures dependent on the sporophyte, male gametophytes contained in pollen grains and females contained within the ovules.
  • gemma – an asexual reproductive structure found in liverworts and mosses.
  • gamopetaly/gamopetalous –  petals joined or connate
  • gamosepaly/gamosepalous –  sepals joined or connate
  • geniculate – bent abruptly, knee like 
  • geoflorous – flower heads that are born near ground level, stalkless
  • geophilous – Growing or rooting in the ground.
  • geophyte – A perennial plant, for example the potato or daffodil, which in spring propagates from an underground organ such as a bulb, tuber, corm or rhizome.
  • germination – 1.  of seeds, describing the complex sequence of physiological and structural changes that occur from resting to growth stage.  2.  of a pollen grain; production of a pollen tube when contacting a stigma receptive to it.  3.  of a spore of fungi/bacterium; change of state – from resting to vegetative.
  • gibbous (gibbose) – (of part of an organ) Swollen, usually with a pouch-like enlargement at the base.
  • glabrescent – Becoming glabrous, almost glabrous.
  • glabrous – 1.  Lacking surface ornamentation such as hairs, scales or bristles; smooth. 2.  In lichenology, having no indumentum.
  • gland – A secretory structure within or on the surface of a plant. A glandule is a small gland.
  • glandarium – a schizocarp of glandetums (pseudocarp) with accrescent receptacle.
  • glans – Nut subtended by a cupulate, dry involucre, as in Quercus. (accessory structure Involucre), sometimes referred to as a calybium, but a calybium lacks the accessory.
  • glandular hair – A hair tipped with a gland.
  • glaucous – Describes the external surface of a plant part that has a whitish covering, in some cases with a bluish cast. Often applied to plants with a woolly or arachnoid surface, but properly referring to pruinose surfaces, meaning those with a waxy bloom. The surface of the young leaves of many eucalyptus provide good examples, and so do some xerophytes.
  • globose/globulose – Also globular. Roughly spherical.
  • glochid – A tiny barbed hair or bristle, e.g. the fine defensive hairs in cactus species such as Opuntia.
  • glomerules – adj: glomerate Dense compact cluster of flowers formed by condensation of a cyme, eg Cornaceae, Fagacea
  • glumesglume – bracts subtending the floret(s) of a sedge, or similar plant; in grasses forming the lowermost organs of a spikelet (there are usually 2 but 1 is sometimes reduced; or rarely, both are absent).
  • glutinous – Sticky, about the same as viscid or viscous.
  • graminoid – granular (of a surface) Covered with small rounded protuberances.
  • graminaceous – Pertaining to, or resembling, the grasses; often used in relation to growth
  • guard cell – Each of two cells surrounding the stoma which control gas exchange between the apoplast of the plant and the external environment.
  • guttate – Having droplet-shaped spots. Compare punctate and maculate.
  • guttation – the secretion of liquid water from uninjured plant parts. See hydathode.
  • guttulate – Having or appearing to be spotted with oil droplets; of spores, having oil droplets inside.
  • gynobasic – Of a style, arising near the base of the gynoecium, e.g. between the lobes of the ovary.
  • gynodioecious – where some plants bear only bisexual flowers and others bear only female flowers.
  • gynomonoecious – Of a species, with bisexual flowers and female flowers on the same plant.
  • gynoecium – The collective term for the female reproductive parts of a flower or for the carpels of a flower, whether united or free. Contrast androecium. Abbreviation: G. For instance, G indicates a superior ovary; G(5) indicates having five fused carpels.
  • gynophore – A stalk supporting the gynoecium and situated above the level of insertion of floral parts, formed from growth of receptacle, whereas a stipitate gynoecium is a stalk that is formed from an elongated ovary.
  • gynostegium – A compound organ in milkweeds (Asclepiadaceae) and orchids formed by fusion of the filaments of the stamens with the style and stigma. Also known as the column.
  • gynostemiumcompound structure formed by the fusion of the stamens and pistil into a single organ.  Is this a synonym of gynostegium or is this more fused than the other?

H

  • habit – The general external appearance of a plant, including size, shape, texture and orientation.
  • hafter – A flat attachment that forms when the thallus of a fruticose or foliose lichens comes in contact with a substrate, different from rhizines and hapters.
  • hair – A single elongated cell or row of cells borne on the surface of an organ.
  • half-inferiorOf ovary, partly below and partly above the level of attachment of the other floral parts. Compare inferior, superior.
  • halonate – Having a transparent coating, or being of a spore‘s outer layer.
  • halophyteA plant adapted to living in highly saline habitats; accumulates high [] of salt in its tissues.
  • haplostemonous – Having a single series of stamens equal in number to the proper number of petals, and alternating with them. Compare diplostemonous, obdiplostemonous.
  • hapter – An attachment that may form when a foliose lichen thallus comes in contact with a substrate.
  • harmomegathy – process by which pollen in arid environments close off their apertures to conserve water
  • hastate – Triangular in outline, the basal lobes pointing outwards, so the base appears truncated; may refer only to the base of a leaf. Compare sagittate which refers to basal lobes pointing backwards.
  • haustorium – haustoria or haustorial roots – in parasitic plants, a structure developed for penetrating the host’s tissues. 
  • head – See capitulum, a pseudanthium.
  • helicoid – Coiled; of a cymose inflorescence, when the branching is repeatedly on the same side (the apex is often recurved), synonym drepanium. Compare scorpioid cyme. Adj: helically 
  • helophyte – adj: helophytic – helophyte (plural helophytes) Any plant typically found in marshy ground whose buds overwinter under water.
  • hemi-legume – A legume fruit in which the seed or seeds and one valve of the pod are dispersed as a unit. The valve catches the wind and blows away with the seeds, as in Acacia tenuifolia, Peltogyne paniculata.
  • hemiparasitic a plant (such as mistletoe) that possesses chlorophyll and typically carries out photosynthesis but is partially parasitic on the roots or shoots of a plant host: semi parasitic hemiparasite  species — compare holoparasitic.
  • hemitropous – half inverted, half amphitropous, when ovule is half inverted so that raphe terminates about halfway between the chalaza and the orifice.
  • herb – Any vascular plant that does not develop a woody stem at any point during its life cycle, 
  • herbaceous – Not woody; usually green and soft in texture.
  • hermaphrodite – A synonym of bisexual.
  • hesperidium – A thick-skinned septate berry with the bulk of fruit derived from glandular hairs, eg Citrus.
  • heteranthery – adj. heterantherous – the presence of different types of stamens in a flower,
  • heteroblastic – Having parts, especially leaves, that are distinctly different between juvenile and adult.
  • heteromorphic – Having two or more distinct morphologies (e.g. of different size and shape).
  • heteromycotrophic – (adjective heteromycotrophic) – a plant that is a mycotroph as part of its method of nutrition, usually with inadequate photosynthesis and hence often not green; a facultative mycotroph
  • heterophyllous – plants with more than one type of leaf 
  • heterospory – The production of spores of two different sizes (small and large) by sporophytes of plants
  • heterostyly – The condition of a species having flowers with different style and stamen lengths, but with all the flowers of any one plant being identical. see:distyly.  Adj: heterostylous. Contrast homostylous plants with only one type of flower (normal condition).  Also heterodistylous sometimes used for 2 different types.
  • heterothetic compound raceme – a compound raceme not terminating in a raceme; a panicle.
  • hilum – The scar on a seed coat where it separates from its stalk (funicle).
  • hip – The fruit of a rose; an aggregation of achenes surrounded by an urceolate receptacle and hypanthium, as in Rosa. (accessory structures Receptacle and Hypanthium)
  • hippocrepiform – Horseshoe-shaped.
  • hirsute – Bearing coarse, rough, longish hairs. See indumentum.
  • hispid – Bearing long, erect, rigid hairs or bristles, harsh to touch; hispidulous is minutely hispid w sparse or short rigid hairs.
  • hoary – covered with a greyish to whitish layer of very short, closely interwoven hairs, frosted appearance; similar to canescent, sometimes used interchangeably.
  • holarcticthe biogeographic realm that encompasses the majority of habitats found throughout the northern continents of the world, most of the northern hemisphere. 
  • holoparasitic – a parasitic plant (such as dodder) not capable of photosynthesis and obtains all nutrients and water from a host plant In addition to being the only angiosperms lacking leaves. Also holoparasite  
  • holotype – A type chosen by the author of a name. Compare lectotypes.
  • homeothetic compound raceme – a compound raceme terminating in a raceme; a panicle.
  • homochlamydeous – Having a perianth which is not divided into a separate calyx and corolla. Contrast dichlamydeous.
  • homodromous – Running in the same direction, ie twining stems, succession of leaves etc 
  • homologies – also homologous – similarity of the structure, physiology, or development of different species of organisms based upon their descent from a common evolutionary ancestor.
  • hyaline – Translucent; usually delicately membranous and colourless.
  • hybrid – A plant produced by the crossing of parents belonging to two different named groups, e.g. genera, species, varieties, subspecies, forma and so on; i.e. the progeny resulting within and between two different plants. An F1 hybrid is the primary product of such a cross. An F2 hybrid is a plant arising from a cross between two F1 hybrids (or from the self-pollination of an F1 hybrid).
  • hydathodes  – water secreting pores found on epidermis of leaf margins in some aquatic species. 
  • hydrophily – A form of pollination whereby pollen is distributed by the flow of waters.
  • hydrophyte  – A plant that grows wholly or partly submerged in water. Because they have less need to conserve water, hydrophytes often have a reduced cuticle and fewer stomata.
  • hydroxyl – in chemistry this is an OH- (oxygen and hydrogen atom bonded together) functional group that attaches to some molecules affecting it’s chemistry. For example alcohols contain a hydroxyl group and some phytochemicals possess hydroxyl. 
  • hygrophyte – A plant which grows in wet conditions or water logged soil. 
  • hygroscopic – a plant sensitive to moisture; caused by moisture; moving when moistened and then dried, as the elaters of Equisetum or the peristome of mosses.
  • hymenoptera – a large order of insects that includes the bees, wasps, ants, and sawflies. These insects have four transparent wings and the females typically have a sting.
  • hypanthium – A tube or cup-like structure in a flower that includes the bases of sepals, petals, and stamens, and may or may not be connected (adnate) to the ovary.
  • hyper-resupinate – In botany, describing leaves or flowers that are in the usual position, but are borne on a petiole or pedicel, respectively, that is twisted 360 degrees. The term is used to describe organs, such as orchid flowers, that are usually resupinate. Compare resupinate.
  • hypocarpium – An enlarged fleshy structure that forms below the fruit, from the receptacle or hypanthium.
  • hypocotyl – Of an embryo or seedling, the part of the plant axis below the cotyledon and node, but above the root. It marks the transition from root to stem development.
  • hypocrateriform – salvershaped: a corolla consisting of a straight tube surmounted by a flat and spreading limb, as in the cowslip and phlox.
  • hypercrateriform – a corolla tube that spreads abruptly.  See salverform
  • hypodermis – the tissue immediately beneath the epidermis of a plant especially when modified to serve as a supporting and protecting layer. 
  • hypogynous – Borne below the ovary; used to describe floral parts inserted below the ovary‘s level of insertion. Compare epigynous, perigynous.
  • hypothallus – the hypothallus is the outgrowth of hyphae from under the margin of the thallus of a crustose lichen, connecting the island-like areoles into a single lichen.
  • hysteranthous – A type of growth in which new leaves appear after flowering. Also spelled histeranthous. Compare proteranthous and synanthous.

I – Botanical Dictionary

  • idioblast – A cell, especially of a leaf, differing markedly from surrounding cells. They often synthesize specialized products such as crystals.
  • imbricate – From the Latin for “tiled”. Overlapping each other; of perianth parts, edges overlapping in the bud (the convoluted arrangement is a special form of imbrication). Dormant buds of many deciduous species are imbricately covered with protective cataphylls called bud scales.
  • imparipinnate – Pinnate leaf with an odd # of pinnae (terminated by single leaflet). Compare paripinnate.
  • incertae sedis – Of unknown taxonomic affinity; relationships obscure.
  • Incised – Cut deeply and (usually) unevenly (a condition intermediate between toothed and lobed).
  • included – Enclosed, not protruding, e.g. stamens within the corolla.
  • incomplete flower – A flower which lacks one or more of its usual parts (petals, sepals, stamens, pistil)
  • incurved – Bent or curved inwards; of leaf margins, when curved towards the adaxial side.
  • indefinite – variable in number, and as a rule numerous, e.g. more than twice as many stamens as petals or sepals, but no particular standard number of stamens. In another usage it is a synonym for the preferable term indeterminate, meaning the condition in which an inflorescence is not terminated by a flower, but continues growing until limited by physiological factors. Compare numerous. Contrast definite.
  • indehiscent – Not opening in any definite manner at maturity; usually referring to fruit. Contrast dehiscent.
  • indeterminate – usually referring to a stem or inflorescence in which there is no particular terminal bud or meristem that stops growth and ends the extension of the stem, which continues until physiological factors stop the growth. Racemes of some Xanthorrhoeaceae, such as many Aloes, and of many Iridaceae, such as Watsonias, are indeterminate. Contrast determinate.
  • indumentum – a collective term for a surface covering of any kind of trichomes, e.g. hairs, scales.
  • induplicate – folded upwards, or folded with the two adaxial surfaces together.
  • indurated – A soft tissue becoming hardened 
  • indusium – 1.membrane covering the sporangia of some ferns. 2. a cup enclosing the stigma Goodeniaceae.
  • inferior – of an ovary) At least partly below the level of attachment of other floral parts. Contrast superior.
  • inflated – swollen, like a bladder.
  • inflexed – bent sharply upwards or forwards. Compare deflexed.
  • inflorescence – several flowers closely grouped together to form an efficient structured unit; the grouping or arrangement of flowers on a plant.
  • infraspecific – denotes taxonomic ranks below species level, for example subspecies.
  • infrageneric – denoting taxonomic ranks below the genus level ie subgenera, sections, and series.
  • infructescence – the grouping or arrangement of fruits on a plant.
  • infundibular (infundibuliform) – funnel-shaped, for example in the corolla of a flower.
  • inrolled – rolled inwards.
  • insectivorous – catching, and drawing nutriment from, insects.
  • insertion, point of – The point at which one organ or structure (such as a leaf) is joined to the structure which bears it (such as a stem).
  • inserted – growing out from
  • integument – in general, any covering, but especially the covering of an ovule.
  • intercalary – (e.g. of growth) occurring between the apex and the base of an organ
  • intercalary meristem – a meristem located between the apex and the base of an organ
  • interjugary glands – in pinnate leaves, glands occurring along the leaf rachis between the pinnae (below the single and often slightly larger, gland at or just below the insertion of pinnae). Compare jugary.
  • internode – The portion of a stem between two nodes.
  • interpetiolar – (of stipules) Between the petioles of opposite leaves, e.g in Rubiaceae.
  • interstaminal –  situated between the stamens
  • intramarginal – inside but close to the margin, for example a vein in a leaf.
  • intrastaminal – inside the stamens or androecium, usually referring to the location of a nectary disk.
  • introrse – anther locules opening towards the center of flower (at least in bud). Compare extrorse, latrorse.
  • involucel – secondary involucre in compound inflorescences 
  • involucre – A structure surrounding or supporting, usually a head of flowers. In Asteraceae, it is the group of phyllaries (bracts) surrounding the inflorescence before opening, then supporting the cup-like receptacle on which the head of flowers sits. In Euphorbiaceae it is the cuplike structure that holds the nectar glands, nectar, and head of flowers, and sits above the bract-like cyathophyll structure. Involucres occur in Marchantiophyta, Cycads, fungi, and many other groups.
  • involute – Rolled inwards, for example when the margins of a leaf are rolled towards the adaxial (usually upper) surface. Compare revolute.
  • iridescent – Having a reflective coloured sheen produced by structural coloration, as in the speculum of the mirror orchid Ophrys speculum.
  • iridoids – a type of monoterpenoids in the general form of cyclopentanopyran, found in a wide variety of plants and some animals. They are biosynthetically derived from 8-oxogeranial. Iridoids are typically found in plants as glycosides, most often bound to glucose.
  • irregular – Not able to be divided into two equal halves through any vertical plane. See also asymmetrical. Compare zygomorphic, actinomorphic, and regular.
  • isidium – pl. isidia – A warty of club-like structure in lichens that breaks off and forms new lichens without sexual reproduction. Isidia are dispersed by mechanical means, compare to soredia dispersed by wind.
  • isobifacial – (of flat structures, especially leaves) Having both surfaces similar, usually referring to cell types or to the number and distribution of stomata.
  • isobilateral – leaves are parallel to the main axis and to the direction of the sun.  Common in monocots 
  • isomerousHaving an equal number of parts in the whorls. Anisomerous having unequal # of parts
  • isophyllous – having leaves on the plant that are all the same. Compare anisophyllous. 
  • isostemous – number of stamens equals the number of petals or sepals 
  • isotomic – Having branches of equal diameter. Compare anisotomic.

J

  • jugary – associated with a jugum or something yoke-like; see for example jugary gland.
  • jugary gland – A gland occurring on the rachis of a pinnate or bipinnate leaf on a jugum, the junction or attachment of pairs of pinnae or pinnules, as in some Acacia species. Compare interjugary.
  • jugate – yoke-like; describing a structure of paired items joined together as in a jugum or something yoke-like, such as some leaves and fruit.
  • jugum – applied to various yoke-like organs, usually in the sense of their being paired, such as a pair of pinnae on a rachis.

K

  • K, K+, K- – In lichenology, “K” is the abbreviation for the outcome of a test in which a 10% solution of potassium hydroxide (KOH — hence “K”) is placed on lichen tissues. Color change is noted by “K-” for none, and K+ for a yellow to red or purple color.
  • k – strategists – species whose populations fluctuate at or near the carrying capacity (K) of the environment they live in. K-selected species typically have long gestation periods, slow maturation, and long life spans. They are sometimes referred to as equilibrium species.
  • keel – adj. Keeled – A prominent longitudinal ridge like the keel of a boat, e.g. the structure of the corolla formed by the fusion of the lower edge of the two abaxial anterior petals of flowers in the Fabaceae.
  • key innovation – A novel phenotypic trait that allows subsequent evolutionary radiation and success
  • Klausenfrucht – Klausen or Klausenfrucht (German) is a special type of fruit in Lamiaceae and Boraginaceae. A dry, dehiscent fruit formed from a superior ovary with axile or basal placentation, with an adherent calyx, from more than one carpel and usually breaking apart into 1-seeded units by separating each carpel by false septa. One unit is a half carpel, mostly there are four units, seeds. English terms are eremocarp, schizocarp, mericarp or nutlets.
  • knee – abrupt bend in a root or stem, commonly at a node; a cypress knee, or pneumatophore, is a type of bend or knob in the root of some plants, especially conifers such as some of the Taxodioideae, that shows as a projection of the root above ground level or mud level.

L

  • labellum – lip; one of three or five petals which is (usually) different from the others, e.g. in Orchidaceae, Zingiberaceae, Cannaceae and Stylidiaceae.
  • labiate – lipped; where a corolla is divided into two parts, called an upper and lower lip, the two resembling an open mouth with lips.
  • lacerate – jagged, as if torn.
  • lacinia – In foliose lichens, a linear to elongate lobe, usually arising from or at the end of a larger lobe
  • laciniate – Of lobes – with ends irregularly divided into deeply divided, narrow, pointed segments; Of margins – deeply divided into pointed segments in an irregular manner.
  • lactones – a phytochemical of cyclic esters, a ring of two or more carbon atoms and a single oxygen atom with a ketone group at one of the carbons adjacent to the other oxygen. 
  • lacuna – An empty space, hole, cavity, pit, depression, or discontinuity.
  • lamella – a thin, plate-like layer. (pl. lamellae; adjective lamellate composed of an assemblage of layers)
  • lamina – the blade of a leaf or the expanded upper part of a petal, sepal or bract.
  • laminal – of, or pertaining to, the upper surface, such as the cortex of a lichen.
  • lanate – covered in or composed of woolly hairs; synonym of woolly.
  • lanceolate – longer than broad, narrowly ovate, broadest in the lower half and tapering to the tip, like a lance or spear head; (sometimes, and incorrectly, used to mean narrowly elliptic).
  • lapachol – natural phenolic compound isolated from the bark of the lapacho tree that causes skin irritation upon contact. 
  • lateral – attached to the side of an organ, e.g. leaves or branches on a stem. For more detail see dorsal.
  • laterocyticstomata orientation with The guard cells were surrounded by a ring of subsidiary cells in the laterocytic type 
  • latex – a milky fluid that exudes from such plants such as spurges, figs and dandelions.
  • laticiferouslatex-bearing, producing a milky juice.
  • latrorse – a type of anther dehiscence in which the anthers open laterally toward adjacent anthers. cf. introrse, extrorse.
  • lauroid – resembling Laurus, the laurel genus, particularly its leaves.
  • lax – loose, not compact. Of bundles of hyphae in lichens – not stiff and not agglutinate.
  • leaf gap – a parenchymatous area in the stele above (distal to) a leaf trace.
  • leaf opposed – when an inflorescence is born at a node opposite the leaf (not in the axil), seen in some epiphytes. 
  • leaf scar – A healing layer forming on a stem where a leaf has fallen off.
  • leaf trace – A vascular bundle connecting the stele to a leaf.
  • leaflets – The ultimate segments of a compound leaf.
  • lecanorine – of lichens, having apothecia with rims of tissue similar to the tissue of the thallus (Lecanora)
  • legume – 1.  a fruit characteristic of the family Fabaceae, formed from one carpel and either dehiscent along both sides, or indehiscent. 2.  a crop species in the family Fabaceae. 3. a plant of the family Fabaceae. 
  • lemma – the lower of 2 bracts enclosing a grass flower.
  • lenticels – one of many raised pores in the stem of a woody plant that allows gas exchange between the atmosphere and the internal tissues
  • lenticular – 1.  lens-shaped.  2.  covered in lenticels
  • lepidote – covered with small scales.
  • leprose – powdery
  • leptocaul – growth form where the tree is branched many times, stems and leaves not usually large. 
  • liana – a woody climbing plant, rooted in the ground (liane is also used).
  • libriform – of a fibre of woody tissue, elongated and having a pitted thickened cell wall.
  • lichenicolous – growing on or in lichens, often but not necessarily as parasites
  • ligneous / Lignified – having hard lignified tissues or woody parts, woody
  • lignum – Dead wood, typically in the context of a substrate for lichens.
  • lignicolous – Growing on wood tissue after bark as fallen or been stripped off (compare to corticolous)
  • lignotuber – a woody swelling of the stem below or just above the ground; contains adventitious buds from which new shoots can develop, e.g. after fire.  Lignotuberous. 
  • ligulate1.  bearing a ligule.  2.  strap-shaped. Also eligulate is without a ligule
  • ligule1.  A small membranous appendage on the top of the sheath of grass leaves.  2.  A minute adaxial appendage near the base of a leaf, e.g. Selaginella.  3. An extended, strap-like corolla in some daisy florets.
  • linear – Very narrow in relation to its length, with the sides mostly parallel. See Leaf shape.
  • lithophytic –  plant growing on rocks; an epilithic plant.
  • lobe – adj: lobate. Part of a leaf (or other organ), often rounded and formed by incisions to about halfway to the midrib.
  • lobulate – Having small lobes 
  • loculicidal – A capsule that dehisces longitudinally into the center cavity of the locule, as in Epilobium. Compare septicidal.
  • locule – A chamber containing seeds within an ovary, pollen within an anther or spores in a sporangium.
  • lodicule – One of two or three minute organs at the base of the ovary of a grass flower, representing parts of a strongly reduced perianth.
  • lomentum or loment – A pod-like indehiscent fruit that develops constrictions between the segments and at maturity breaks transversely into one-seeded segments instead of splitting open, a type of schizocarpic fruit. lomentaceous = adj. 
  • longicidal – (of anthers) Opening lengthwise by longitudinal slits. Compare poricidal.
  • lunate – Crescent-shaped.
  • lumen – The cavity bounded by a plant cell wall.
  • lumpers – taxonomists who prefer to lump more related genera together in the same more variable family rather than split them into smaller less variable families (the splitters).  
  • lyrate – Lyre-shaped; deeply lobed, with a large terminal lobe and smaller lateral ones.
  • lysigenous – Formed by the breaking down of adjoining cells; often applied to secretory cells 

M – Botanical Dictionary

  • maculate – stained, spotted, compare immaculate
  • malacophilouspollination by slugs
  • mallee – A growth habit in which several woody stems arise separately from a lignotuber; a plant with such a growth habit, e.g. many Eucalyptus species; vegetation characterized by such plants.
  • mangrove – Any shrub or small tree growing in salt or brackish water, usually characterized by pneumatophores; any tropical coastal vegetation characterized by such species.
  • marcescent – Retention of dead plant organs that are normally shed
  • margin – the edge of a structure, as in the edge of a leaf blade.
  • marginal – Occurring at or very close to a margin.
  • mast – Edible fruit and nuts produced by woody species of plants (e.g. acorns and beechmast) which is consumed on the ground by wildlife species and some domestic animals.
  • mealy – Covered with coarse, floury powder.
  • medulla – 1.  In a lichen, the typically undifferentiated tissue underneath the cortex of the thallus, or between the upper and lower cortex if both are present. The medulla is analogous to the tissues underneath the epidermis (skin) of a leaf. The uppermost region commonly contains most of the photobionts.  2.  pith. See also medullary rays in wood.
  • medifixed – attached by the middles, as in anthers. 
  • megasporangium – the larger of two kinds of sporangium produced by heterosporous plants, producing large spores that contain the female gametophytes. Compare microsporangium.
  • megaspore – the larger of two kinds of spores produced by a heterosporous plant, giving rise to the female gametophyte. Compare microspore.
  • megasporophyll – in heterosporous plants, a modified leaf bearing one or more megasporangia. Compare microsporophyll.
  • megastrobilus – the larger of two kinds of cones or strobili produced by gymnosperms, being female and producing the seeds. Compare microstrobilus.
  • membranousthin, translucent and flexible, seldom green.
  • mericarpone segment of a fruit (a schizocarp) that splits at maturity into units derived from the individual carpels, or a carpel, usually 1-seeded, released by the break-up at maturity of a fruit formed from 2 or more joined carpels.
  • meristem – Any actively dividing plant tissue.
  • mesic – Moist, avoiding both extremes of drought and wet; pertaining to conditions of moderate moisture or water supply; applied to organisms (vegetation) occupying moist habitats.
  • mesocarp – The fleshy portion of the wall of a succulent fruit inside the skin and outside the stony layer (if any), surrounding the seed(s); sarcocarp.
  • mesomorphic – soft and with little fibrous tissue, but not succulent.
  • mesophyll – 1.  The parenchyma tissues between the upper and lower epidermis. They vary in function, but usually include the photosynthetic tissue of a leaf  2.  In ecology, the blade of a leaf or leaflet that has a surface area 4500–18225 mm2; a plant, or vegetation, that has mesophyll (sized) leaves.
  • mesophyllous – (of vegetation) Of moist habitats and having mostly large and soft leaves.
  • mesophyte – A plant thriving under intermediate environmental conditions of moderate moisture and temperature, without major seasonal fluctuations.
  • micropyle – an opening at the apex of an ovule.
  • microsporangium – The smaller of two kinds of sporangium produced by a heterosporous plant, producing microspores that contain the male gametophyte. Compare megasporangium.
  • microspore – The smaller of two kinds of spores produced by a heterosporous plant. Compare megaspore.
  • microsporogenesis – The formation of microspores inside the microsporangia of seed plants. A diploid cell in the microsporangium, called a microsporocyte, undergoes meiosis and gives rise to four haploid microspores.
  • microsporophyll – Heterosporous plants modified leaf bearing 1+ microsporangia. Com: megasporophyll
  • microstrobilus – The smaller of two kinds of cones or strobili produced by gymnosperms, being male and producing the pollen. Compare megastrobilus.
  • midrib – Also midvein. The central and usually most prominent vein of a leaf or leaf-like organ.
  • mid petaline band – a band on the petals of some flowers – eg Ipomoea
  • mixotrophic – plants gaining energy from both photosynthesis and mycorrhizal fungi; an autotroph and a parasite.  
  • monad – A single individual that is free from other individuals, not united with them into a group. The term is usually used for pollen to distinguish single grains from tetrads or polyads.
  • monocot – also monocotyledon – as the name implies, are defined by having seeds that contain a single (mono-) embryonic leaf known as a cotyledon. This is a monophyletic group that constitutes a majority of our agricultural biomass and include many important crop staples including, but not limited to, rice, wheat, corn, sugar cane, bamboo, onion, and garlic.  Monocots differ from dicots in six distinct structural features the flowers (parts usually in 3’s), leaves (usually parallel vein), roots (usually adventitious with storage organs), stems (lack secondary growth, different vascularization), and pollen grains (monosulcate, meaning that the pollen has a single furrow or pore through the outer layer.). But the root of these differences stem from the very early embryonic stages of the angiosperm, providing the biggest difference of all between monocots and dicots, is the seed. Note there are always exceptions to the rule. Some monocots may have a feature typically found in dicots, or vice versa and approximately 2% of angiosperms don’t fit into either the monocot or the dicot category and are classified in this book as basal angiosperms.
  • moniliform – Resembling a string of beads.
  • monocarpicFlowering and setting seed only once before dying. See also semelparous.
  • monochasium – A cymose inflorescence with branches arising singly. Compare dichasium, pleiochasium.
  • monochlamydeous – Flowers with only one set of floral envelopes, ie either a corolla or a calyx 
  • monoecious – (of vascular plants) Hermaphroditic, with all flowers bisexual, or with male and female reproductive structures in separate flowers but on the same plant, or of an inflorescence that has unisexual flowers of both sexes. Contrast dioecious.
  • monoicous – (of bryophyte gametophytes) Hermaphroditic or bisexual, where both male and female reproductive structures develop on the same individual. Contrast dioecious.
  • monogeneric – (of a genus or species) consisting of only one type of animal or plant.
  • monograph – Of a group of plants, a comprehensive treatise presenting an analysis and synthesis of taxonomic knowledge of that taxon; the fullest account possible (at the time) of a family, tribe or genus. It is generally worldwide in scope and evaluates all taxonomic treatments of that taxon including studies of its evolutionary relationships with other related taxa, and cytological, genetic, morphological, palaeobotanical and ecological studies. The term is often incorrectly applied to any systematic work devoted to a single taxon. Compare revision.
  • monomerous – monomeric – Gynoecium consisting of a single carpel, not fused. 
  • monomorphic – Of one type, rather than several. See dimorphic (two types), polymorphic (many types).
  • monophyletic – or monophylogeny, is a term used to describe a group of organisms that are classified in the same taxon and share a most common recent ancestor. A monophyletic group includes all descendants of that most common recent ancestor.
  • monophyllous – Having a single leaf.
  • monopodial – A mode of stem growth and branching in which the main axis is formed by a single dominant meristem. Contrast sympodial.
  • monostromatic – Being a single cell thick, as in the alga Monostroma.
  • monosulcate – of pollen has a single furrow or pore through the outer layer.
  • monothecal – having a sole compartment or cell. a monothecal stamen/anther. 
  • monotypic – Containing only one taxon of the next lower rank, e.g. a family with only one genus (also referred to as monogeneric), or more often applied to a genus that includes only a single species.
  • morphology – The shape or form of an organism or part thereof.
  • mucro – Diminutive: mucronule. Sharp, short point, at the tip of the leaf or the tip of the midrib of compound leaf.
  • mucronate – Terminating in a mucro (a sharp stiff point).
  • multiple fruit – A cluster of fruits produced from more than one flower and appearing as a single fruit, often on a swollen axis, as with many species of the family Moraceae. Compare aggregate fruit.
  • muricate – Covered with short hard protuberances.
  • muticous – lacking an awn, spine or point
  • mycelium – The “vegetative” (nonreproductive) part of a fungus, mostly composed of aggregations of hyphae. It functions in substrate decomposition and absorption of nutrients.
  • mycobiont – The fungal component of a lichen. Compare photobiont.
  • mycorrhiza – pl. mycorrhizae; adj. mycorrhizal One of several types of symbiotic association between a fungus and the roots of a plant.
  • mycotroph – adj. mycotrophic – A plant that obtains most or all of its carbon, water, and nutrients by associating with a fungus.
  • mycoheterotroph – Mycoheterotrophy is a symbiotic relationship between certain kinds of plants and fungi where the plant gets all or part of its food from parasitism upon fungi instead of or as well as photosynthesis. A mycoheterotroph is the parasitic plant partner and the interface between the two is the roots of the plant and the mycelium of the fungus, closely resembling mycorrhiza except that the flow of carbon is from the fungus to the plant instead of vice versa.
  • myriophyllin – Idioblasts (myriophyllin cells) with condensed tannins present in some species.
  • myrosin – When herbivores damage plant tissues, myrosinase released from myrosin cells catalyzes hydrolysis of glucosinolates to produce toxic compounds against herbivores. Myrosin cells specifically develop adjacent to phloem cells (on the abaxial side of vasculature) and are called myrosin phloem cells.

N

  • nectar – Usually sweet, nutrient-rich fluid produced by the flowers of many plants and collected by insects.
  • nectary – adj. Nectariferous, nectaries – A specialized gland that secretes nectar.
  • neophyte – A plant that has recently been introduced to a geographic area. Contrast archaeophyte.
  • neoteny – arresting of normal development of all cells except the germ line, resulting in sexually mature organisms with juvenile characteristics.  
  • neotropical – denoting a phytogeographical kingdom comprising Central and South America but excluding the southern parts of Chile and Argentina and excluding most of Mexico. 
  • nerve – Another name for a vein.
  • node – The part of a stem from which leaves or branches arise.
  • Nomen conservandum – (Latin) A conserved name, usually a name that became so much better known than the correct name, that a substitution was made.
  • nucellus – the tissue of the ovule of a seed plant that surrounds the female gametophyte. It is enclosed by integuments and is not of epidermal origin.
  • nucleotide – an organic molecule that is the building block of DNA and RNA that also function in cell signaling, metabolism and enzymatic reactions. A nucleotide is made up of three parts: a phosphate group, a 5-carbon sugar and a nitrogenous base.
  • nuculanium – a dry drupe composed of a thin outer layer (exocarp), a thick, fibrous middle layer (mesocarp), and a hard inner layer (endocarp) surrounding a large seed. As in coconuts.  The “meat” of the seed is endosperm tissue and a small, cylindrical embryo is embedded in this nutritive tissue. “Coconut water” is a liquid endosperm that has not developed into solid tissue composed of cells. 
  • nucular – Nut-shaped; of or relating to a nucule — a section of a compound (usually hard) fruit.
  • numerous – Stamens are described as numerous when there are more than twice as many as sepals or petals, especially when there is no set number of them. Compare indefinite
  • nut – A one-seeded, dry, indehiscent (does not split at maturity) fruit with a hard pericarp, usually derived from a one-loculed ovary
  • nutlet – 1.  A small nut.  2.  One of the lobes or sections of the mature ovary of some members of the Boraginaceae, Verbenaceae, and Lamiaceae.
  • nyctinastic – the periodic movement of flowers or leaves caused by nightly changes in light intensity or temperature; these same plants usually also respond to touch (ie: Mimosa).

O

  • ob– A prefix meaning “inversely”; usually the same shape as that described by the word stem, but attached by the narrower end. See obcordate, oblanceolate and obovate.
  • obconic – (of a fruit, hypanthium, pistil, or calyx) Shaped like an inverted cone, attached at the apex.
  • obcordate – (of a leaf blade) Broad and notched at the tip; heart-shaped but attached at the pointed end.
  • obdeltate – triangular leaf blade broader at the tip then then base.
  • obdiplostemonous – Having stamens arranged in two whorls, and having twice as many stamens as petals, with the outer whorl being opposite the petals. Compare diplostemonous, haplostemonous.
  • oblanceolate – Having a lanceolate shape but broadest in the upper third.
  • obligate – (of parasites) Unable to survive without a host. Contrast facultative.
  • oblique – Slanting; of a leaf or stem, larger on one side of the midrib than the other; asymmetrical.
  • obloid – Having a three-dimensional oblong shape, e.g. a fruit.
  • oblong – Having a length a few times greater than the width, with sides almost parallel and ends rounded.
  • obovate – (of a leaf) Having a length about 1.5 times the width, and widest above the centre.
  • obsolete -Not evident, or at most rudimentary or vestigial.
  • obturator – Part of the ovary that chemically guides the pollen tube into the micropyle.
  • obtrapeziform – trapeziform, but attached by the narrower trapezoidal base (e.g. of a leaf)
  • obtuse – Blunt or rounded; having converging edges that form an angle of more than 90°. Compare with acute.
  • ochrea – Also spelled ocrea. Adj: ochreate, ochreolate probably refers to small ochrea on inflorescences. A sheath formed from two stipules encircling the node.  In Polygonaceae, Moraceae, grasses etc 
  • odd-pinnate – Also imparipinnate. Having an odd number of leaflets in a compound pinnate leaf, such that there is only one terminal leaflet.
  • oligosaccharide – oligosaccharides are any carbohydrate made of 3 to 6 units of monosaccharides (simple single carbohydrate sugars).  Intermediate between monosaccharides and polysaccharides in terms of size, complexity and molecular mass. 
  • ontogeny – ontogenetically, ontogenesis, ontogenetic.  The sequence of developmental stages through which an organism passes as it grows.
  • operculate capsule – Fruit that dehisces through pores, which are covered by a flap or lid, as in Papaver.
  • operculum (calyptra) – A lid or cover that becomes detached at maturity, e.g. in Eucalyptus, a cap covering the bud and formed by the fusion or cohesion of perianth parts.
  • opposite – 1.  Describing leaves or flowers borne at the same level but on directly opposite sides of their common axis.  2.  Describing the occurrence of something on the same radius as something else, e.g. anthers opposite sepals. Compare alternate.
  • oppositiperianth – adjective. Especially of a stamen placed in front of or opposite the perianth, used with flowers that have tepals instead of sepals and petals. 
  • oppositisepalous – adjective. Especially of a stamen placed in front of or opposite the petals or divisions of the corolla.
  • oppositisepalous – adjective. Especially of a stamen placed in front of or opposite the sepals or divisions of the calyx.
  • orbicular – Flat and more or less circular.
  • ornithophilous –  pollination of flowers by birds.
  • ortet – The original single parent plant from which a clone ultimately derives.
  • orthotropous – When an ovule is erect upright. With the micropyle directed away from the placenta; atropous. Compare amphitropous, anatropous, campylotropous.
  • ostiole – pl. ostioles – a small hole or opening through which algae or fungi release their mature spores. The term is also used in higher plants, for example to denote the opening of the fig inflorescence through which fig wasps enter to pollinate and breed.
  • oval – See elliptical.
  • ovary – The basal portion of a carpel or group of fused carpels, enclosing the ovules.
  • ovate – Shaped like a section through the long-axis of an egg and attached by the wider end.
  • ovoid – Egg-shaped, with wider portion at base; 3-D object, ovate in through long-axis.
  • ovule – Loosely, the seed before fertilization; a structure in a seed plant within which one or more megaspores are formed (after fertilization it develops into a seed).

P – Botanical Dictionary

  • pachycaul – with a disproportionately thick trunk
  • pachycladus – with disproportionately thick stems
  • palea(pl. paleae or paleas) 1.the upper of two bracts enclosing a grass flower, major contributors to chaff in harvested grain. 2. Chaffy scales on the receptacles of Asteraceae. 3. Chaffy scales on the stipe of ferns.
  • paleate – Bearing paleae or chaffy scales, as in description of the receptacle of a capitulum of Asteraceae.
  • paleaceous – Chaff-like in texture.
  • paleotropical – denoting a region comprising the tropical parts of the Old World.
  • palmate – 1.  leaf with veins radiating out from a central point (usually at the top of a petiole), resembling spread out fingers pointing away from the palm.  2.  A compound palmate leaf has leaflets that radiate from a central point (usually at the top of a petiole).
  • palmatifidDeeply divided into several lobes arising from more or less the same level.
  • palmatisectIntermediate between palmate and palmatifid, i.e. the segments are not fully separated at the base; often more or less digitate.
  • paludal – Growing in marshland 
  • panduriform – (of a leaf shape) having rounded ends and a contracted center. fiddle-shaped, pandurate. unsubdivided, simple – (botany) of leaf shapes; of leaves having no divisions or subdivisions.
  • panicledj. Paniculate – A compound raceme; an indeterminate inflorescence in which the flowers are borne on branches of the main axis or on further branches of these.
  • papilionate – papilionaceousButterfly-like; having a corolla like that of a pea.
  • papilla – pl. papillae; adj. papillose or papillate A small, elongated protuberance on the surface of an organ, usually an extension of one epidermal cell.
  • pappus – In daisy florets, a tuft or ring of hairs or scales borne above the ovary and outside the corolla (representing the reduced calyx); a tuft of hairs on a fruit.
  • paracytic – Stomata with one or more subsidiary cells parallel to the opening between guard cells 
  • parallelodromous – multiple parallel veins originating at base and converging towards apex (ie monocots) 
  • paramo – Páramo can refer to a variety of alpine tundra ecosystems above the continuous timberline but more specifically it is a Neotropical high mountain biome with vegetation composed mainly of giant rosette plants, shrubs and grasses.
  • paraperigonium – Also paraperigone. An anomalous secondary outgrowth of the perianthal meristem with ramifying vasculature. See also perigonium, perianth, and corona.
  • paraphyletic – also paraphyly – a term used in evolutionary biology to describe a group of plants which contains a common ancestor and some, but not all, of the descendants.  
  • parasite – An organism living on or in a different organism, from which it derives nourishment. Some plant species are parasitic. Compare saprophyte and epiphyte.
  • parenchyma – A versatile ground tissue composed of living primary cells which performs a wide variety of structural and biochemical functions in plants.
  • parietal – Attached to the marginal walls of a structure, e.g. ovules attached to placentas on the wall of a syncarpous unilocular ovary. See placentation.
  • paripinnate – Having an even number of leaflets (or pinnae), i.e. terminated by a pair of pinnae as opposed to a single pinna. Compare imparipinnate.
  • parthenocarpy – The development or production of fruit without fertilization. Compare stenospermocarpy.
  • patelliform – Disk shaped with a narrow rim
  • patent – Also patulous. Spreading; standing at 45–50° to the axis. See also erecto-patent.
  • pauciflor – Having few flowers per inflorescence. Compare pluriflor and uniflor.
  • pectinate – Pinnately divided with narrow segments closely set like the teeth of a comb.
  • pedate – Having a terminal lobe or leaflet, and on either side of it an axis curving outwards and backwards, bearing lobes or leaflets on the outer side of the curve.
  • pedicel – adj. pedicellate The stalk of a single flower; also be applied to the stalk of a capitulum in the Asteraceae.
  • peduncle – adj. pedunculate – The stalk of an inflorescence.
  • peltate – Shield-like, with the stalk attached to the lower surface and not to the margin; subpeltate is almost peltate.
  • pellucid – Transmitting light; for example, said of tiny gland dots in the leaves of e.g. Myrtaceae and Rutaceae that are visible when held in front of a light.
  • peloric – Flowers having a mutation such that a normally asymmetric flower becomes radially symmetric. 
  • pendulousHanging an ovule attached onto a placenta on the top of the ovary. Compare suspended.
  • penicillate – Tufted like an artist’s brush; with long hairs towards one end.
  • penninervation – adj. penninerved – With pinnately arranged veins.
  • pentangular  – 5 sided
  • pentamerous – In five parts, particularly with respect to flowers, five parts in each whorl. See also trimerous and tetramerous.
  • pepo – A type of berry formed from an inferior ovary and containing many seeds, usually large with a leathery non-septate rind as in Cucurbita.
  • perennating – Of an organ that survives vegetatively from season to season. A period of reduced activity between seasons is usual.
  • perfect – (of a flower) Bisexual; containing both male and female reproductive parts in the same inflorescence. Contrast imperfect.
  • perfoliate – With its base wrapped around perforated the stem (so that the stem appears to pass through it), e.g. of leaves and bracts.
  • perforate – With many holes. Used to describe the texture of pollen exine, and also to indicate that tracheary elements have a perforation plate. See also fenestrate.
  • perforation plate – in a tracheary element, part of the cell wall that is perforated; present in vessel members but not in tracheids. Should not be confused with a pit.
  • perianth – The collective term for the calyx and corolla of a flower (generally used when the two are too similar to be easily distinguishable). Abbreviation: P; for instance, P 3+3 indicates the calyx and corolla each have 3 elements, i.e. 3 sepals + 3 petals.
  • pericarp – The wall of a fruit, developed from the ovary wall.
  • periclinal – Curved along parallel to a surface. Compare anticlinal.
  • pericycle – A cylinder of parenchyma or sclerenchyma cells that lies just inside the endodermis and is the outermost part of the stele of plants.
  • perigone – used in reference to a perianth tube with tepals instead of sepals and petals. 
  • perigonium – In flowering plants, synonym of perianth.
  • perigynium – A sac from a modified tubular bract, or when fully closed an utricle around the pistillate flower of sedges
  • perigynous – Borne around the ovary, of perianth segments and stamens arising from a cup-like or tubular extension of receptacle (free from ovary but extends above its base). Compare epigynous, hypogynous.
  • peristem – Nutritive tissue in seeds derived from the nucellus, surrounds the embryo. 
  • peristome – an anatomical feature that surrounds an opening to an organ or structure; the one or two circles of small, pointed, tooth-like appendages around the orifice of a capsule or urn of mosses, appearing when the lid is removed.
  • persistent – Remaining attached to the plant beyond the usual time of falling, for instance sepals not falling after flowering, flower parts remaining through maturity of fruit. Compare deciduous, caducous.
  • personatebilabiate corolla with 2 lips but with the throat closed by a prominent palate (snapdragon)
  • perule – adj. perulate – 1.  The scales covering a leaf or flower bud, or a reduced scale-like leaf surrounding the bud. Buds lacking perulae are referred to as “naked”.  2.  In Camellias the final bracts and sepals become indistinguishable and are called perules.  3.  A kind of sac formed by the adherent bases of the two lateral sepals in certain orchids.
  • petal – In a flower, one of the segments or divisions of the inner whorl of non-fertile parts surrounding the fertile organs, usually soft and conspicuously coloured. Compare sepal.
  • petaloid – Like a petal; soft in texture and coloured conspicuously.
  • petiolar petiolary – Associated with a petiole, as in petiolary glands.
  • petiolate – (of a leaf) Having a petiole. Contrast sessile.
  • petiole – The stalk of a leaf.  
  • petiolule – The stalk of a leaflet in a compound leaf.
  • petricolous – Rock-dwelling; living on or among rocks.
  • phaneranthous – showy flowers that advertise to pollinators, as opposed to aphananthous (unshowy)
  • phanerogam – Gymnosperms and angiosperms; plants producing stamens and gynoecia; literally plants with conspicuous sexual reproductive organs. Compare cryptogams.
  • phenolic – are aromatic benzene ring compounds with one or more hydroxyl groups produced by plants mainly for protection against stress. The functions of phenolic compounds in plant physiology and interactions with biotic and abiotic environments are difficult to overestimate. 
  • phenology – The study of the timing of seasonal biological phenomena, ie flowering, leaf emergence etc.
  • phlobaphene – reddish, alcohol-soluble, water-insoluble phenolic substances that can be extracted from plants or result from treatment of tannin extracts with mineral acids.
  • phloemA specialized conducting tissue in vascular plants, transports sucrose from leaves to other organs.
  • photobiont – In a lichen, the component that does the photosynthesis, the green algae (Chlorophyta) or blue-green algae (Cyanobacteria). (compare to mycobiont, the fungal component.) Also called phycobiont.
  • photorespiration – a process in plant metabolism where the enzyme RuBisCO (Ribulose-1,5-bisphosphate carboxylase/oxygenase) oxygenates Ribulose-1,5-bisphosphate (RuBP) wasting some of the energy produced by photosynthesis.
  • phototoxic – also phototoxin – Phototoxic effects are usually skin irritation in mammals that stem from chemical exposure by plants, in addition to the presence of light.
  • phyllary – An individual bract within an involucre or involucel.
  • phyllid – A leaf-like extension of the stem in Bryophytes
  • phyllode adj. phyllodineous – A leaf with the blade much reduced or absent, and in which the petiole and or rachis perform the functions of the whole leaf, e.g. many acacias. Compare cladode.
  • phyllopodium – (in ferns) A short outgrowth of the stem on which the frond is borne and which remains attached to the rhizome after the frond has been shed.
  • phyllotaxy – the arrangement of leaves on a stem or axis.
  • phyllosphere – The above-ground surface of plants as a habitat for epiphytic microorganisms.
  • phytochemistry –  is the study of phytochemicals, which are chemicals derived from plants. … The compounds found in plants are of many kinds, but most are in four major biochemical classes, the alkaloids, glycosides, polyphenols, and terpenes. Phytochemistry can be considered a sub-field of botany or chemistry.
  • phytomelan – Also phytomelanin; adj. phytomelanous A black, inert, organic material that forms a crust-like covering of some seeds, commonly found in Asparagales, Asteraceae, etc.
  • phytonutrients – are natural chemicals or compounds produced by plants. They keep plants healthy, protecting them from insects and the sun. 
  • phytotoxin – substances that are toxic to the growth of plants; or toxic chemicals produced by plants themselves that function as defensive agents against predators. 
  • pileate – Having a cap, a pileus.
  • pileus – A cap or cap-shaped structure, such as the cap of mushrooms or the plumule of some monocots.
  • piliform -Having the shape of a cap, a pileus.
  • pilose – covered with soft, weak, thin and clearly separated hairs, which are usually defined as long and erect and sometimes ascending.
  • pinna – (plural pinnae) a primary segment of a compound leaf.
  • pinnate – a compound leaf with leaflets arranged on each side of a common petiole or axis; also applied to how the lateral veins are arranged in relation to the main vein.
  • pinnatifid – Pinnately lobed.
  • pinnatisect – pinnately divided almost to midrib but segments still confluent.
  • pinnule or pinnula – Usage varies: ultimate free division (or leaflets) of a compound leaf, or a pinnate subdivision of a multi pinnate leaf.
  • piriform – pear shaped. Also spelled pyriform
  • pistil – 1.  a single carpel when the carpels are free.  2.  a group of carpels when the carpels are united by the fusion of their walls.
  • pistillate flower – a flower containing one or more pistils but no stamens. Aka a female flower.
  • pistillodepistillodial.  A sterile or rudimentary pistil.
  • pit – In tracheary elements, a section of the cell wall where the secondary wall is missing, and the primary wall is present. Pits generally occur in pairs and link two cells.
  • pith – The central region of a stem, inside the vascular cylinder; the spongy parenchymatous central tissue in some stems and roots.
  • placenta – The tissue within an ovary to which the ovules are attached.
  • placentation – Arrangement of ovules inside ovary; axile, free-central, parietal, marginal, basal, or apical.
  • placodioid – The form of a lichen thallus which radiates outward with the ends of the radiating arms peeling up from the substrate, but which lack a cortex on the underside (unlike foliose lichens).
  • plastochron – The time between successive leaf initiation events.
  • pleiochasium – pl. pleiochasia. An inflorescence in which several buds come out at the same time. cf. monochasium, dichasium.
  • plesiomorphic – An ancestral character state
  • plicate – Pleated; folded back and forth longitudinally like a fan, such as the leaves of fan palm species; plicate flowers have corollas with folds in them. The concept often appears in specific names in forms such as Kumara plicatilis and Acacia plicata. Commonly such names are not correctly appropriate, but are applied to distichous structures rather than plicate.
  • plinerved – (of leaves) A suffix indicating that the main nerves are lateral and arise from a point distinctly above the base of the leaf. Combined with a numerical prefix to form words like 3-plinerved, 5-plinerved, etc. Eg Dissotis of Melastomataceae. 
  • plumose – Like a feather; with fine hairs branching from a main axis.
  • plumule – The part of an embryo that gives rise to the shoot system of a plant. Compare radicle.
  • pluriflor – Having many flowers per inflorescence. See also pauciflor and uniflor.
  • pluriovulate – Having many ovules as in placentae, carpels or ovaries.
  • pneumatophore – A vertical appendage, aerial at low tide, on the roots of some plants. Pneumatophore functions are unclear, but possibly related to gas exchange, or to root anchoring. Pneumatophores typically occur on mangrove roots, but some versions occur on species of conifers, such as some in the Taxodioideae.
  • pod – 1. A legume, the fruit of a leguminous plant, a dry fruit of a single carpel, splitting along two sutures. 2. A siliqua and silicula, fruit of Brassicaceae, a dry fruit composed of two carpels separated by a partition.
  • pollen – powdery mass shed from anthers (of angiosperms) or microsporangia (of gymnosperms); the microspores of seed plants; pollen-grains.
  • pollinium pl pollinia – pollen-grains cohering by waxy texture or fine threads into a single body or mass. 
  • pollinarium – noun. Pl: pollinaria.  The structure in an orchid flower which becomes attached to an insect during pollination. Includes the pollinia, caudicle, and viscidium. 
  • pollen transmitting tissue – the tissue in the style of a flower through which the pollen tubes grow.
  • pollination – The transfer of pollen from a male organ (such as an anther) to the receptive region of a female organ (such as a stigma).
  • polygamodioecious – Having bisexual and male flowers on some plants and bisexual and female flowers on others. Compare androdioecious, andromonoecious, dioecious, monoecious etc.
  • polygamomonoecious – having male, female and bisexual flowers on the same plant. Compare androdioecious, andromonoecious, polygamodioecious, polygamous.
  • polygamous – having bisexual and unisexual flowers on the same plant.
  • polymorphic – Of several different kinds (in respect to shape and/or size), hence polymorphism. See also monomorphic (a single type) and dimorphic (two types)
  • polyploid – Also polyploidy – a condition in which the cells of an organism have more than two paired (homologous) sets of chromosomes. Most species whose cells have nuclei (eukaryotes) are diploid, meaning they have two sets of chromosomes—one set inherited from each parent.
  • polysaccharides – complex carbohydrates formed from a chain of numerous smaller monosaccharides or oligosaccharides.
  • polystemonous  – having numerous stamens; the number of stamens being at least twice the number of sepals or petals, but not strictly three or four times that number.
  • polystichous –  arranged in several rows or series.
  • pome – A berry-like fruit, adnate to a fleshy receptacle, with cartilaginous endocarp, as in Malus. (accessory structures Receptacle and Hypanthium). Fruit is partly from ovary wall but mostly hypanthium
  • pomarium –  fruiting receptacle of a schizocarpic fruit divided into many cavities, an aggregate of many apocarps. e.g. Ravensara of Lauraceae, Siparuna of Monimiaceae.
  • poricidal – Opening by pores, as in Triodanis.  Note Poppies are often called poricidal, which they are, but their pores are covered by a cap and are called operculate capsules.  Compare longicidal.
  • porrect – extending horizontally outward and forwards. 
  • posterior – Positioned behind or towards the rear. Contrast anterior.
  • posticous – adj: posticously 1. posterior. 2. situated on the outside of an anther (extrorse
  • precocious – appearing or developing early; example when precocious flowers appear before the leaves
  • prickle – Prickly – A hard, pointed outgrowth from the surface of a plant (involving several layers of cells but not containing a vein); a sharp outgrowth from bark, detachable without tearing wood. Compare thorn.
  • primary species – In lichens, a species reproducing mainly by sexual reproduction rather than by vegetative reproduction.
  • primary vein – The single vein or array of veins that is conspicuously larger than any others in a leaf. In pinnate venation, the single primary vein can generally be found in the middle of the leaf; in palmate venation, several such veins radiate from a point at or near the base of the leaf.
  • primordia – an organ or tissue in its earliest recognizable stage of development
  • prolate – elongated along the polar diameter (opposed to oblate)
  • prop roots – adventitious roots that supports the plant, for example the aerial roots of the mangrove tree or of corn, some palms etc
  • propagule – In lichens, a part of the thallus that has both fungal and algal parts and can break off for vegetative reproduction, e.g. an isidium, phyllidium, phyllocladium, or soredium).
  • prophyll – A leaf formed at the base of a shoot, usually smaller than those formed later.
  • procumbent – Spreading along the ground but not rooting at the nodes; not as close to ground as prostrate.
  • propagule – Any structure capable of generating a new plant; includes seeds, spores, bulbils, etc.
  • prostrate – Lying flat on the ground; commonly rooting at nodes that touch the soil surface.
  • protandrous – Having male sex organs which mature before the female ones, e.g. a flower shedding pollen before the stigma is receptive. Compare protogynous.
  • proteinase – An enzyme that breaks down proteins into smaller components. 
  • proteranthous – With new leaves appearing before flowers. See also hysteranthous and synanthous.
  • prothallus – A #gametophyte plant, usually flattened and delicate, e.g. in ferns and fern allies.
  • protocorm – a tuber-shaped body with rhizoids that is produced by the young seedlings of various orchids and some other plants having associated mycorrhizal fungi.
  • protogynous – Having female sex organs which mature before the male ones, e.g. a flower shedding pollen after the stigma has ceased to be receptive. Compare protandrous.
  • proximal – Adj: proximally – Near the point of origin or attachment. Compare distal.
  • pruinose – Covered with a powdery, waxy material; having a bloom.
  • pseudanthium – A type of inflorescence occurring in the Asteraceae and Euphorbiaceae, in which multiple flowers are grouped together to form a flower-like structure, commonly called a head or capitulum.
  • pseudo– – A prefix meaning “false, not genuine”
  • pseudanthial – “false flower” – composite flower or capitulum
  • pseudobasifixed – (of an anther) Connected to the filament of the stamen by connective tissue which extends in a tube around the filament tip. See also basifixed and dorsifixed.
  • pseudobulb is a thickened, bulb-like internode in orchids, but not an actual bulb.
  • pseudocarp – An aggregation of achenes embedded in an accessory fleshy receptacle, as in Fragaria
  • pseudodrupe – Two-four loculed nut surrounded by an accessory fleshy involucre, as in Juglans
  • pseudostipule – An enlarged, persistent axillary bud scale that resembles a stipule; ie Bignoniaceae.
  • pseudoverticillate – Having the appearance of being whorled (verticillate), without actually being so.
  • psilate – of pollen – lacking ornamentation. 
  • puberulent – Also puberulous. Covered with minute soft erect hairs, diminutive of pubescent, similar but with very short hairs instead of short. 
  • pubescent – Downy; covered with short, soft hairs, especially erect hairs.
  • pulverulent – Having powdery or crumbly particles as if pulverized.
  • pulviniform – Pulvinar; cushiony; pillowy; pad-like. In botany, cushion-shaped.
  • pulvinuspulvinate – a swelling at either end of a petiole of a leaf or petiolule of a leaflet, e.g. in Fabaceae, that permits leaf movement.
  • punctate – (from Latin puncta= puncture or prick-mark) marked with an indefinite number of dots, or with similarly small items such as translucent glands or tiny hollows.
  • punctiform – Dot-like or in the shape of a prick-mark.
  • pungent – Having a sharp, hard point.
  • pustuleA blister-like swelling.
  • pustulateHaving pustules.
  • pyramidal(of a growth habit) Conical or pyramid-shaped. Most familiar in some coniferous trees, especially species adapted to snowy climates
  • pyrene1. The stone of a drupe, consisting of the seed surrounded by the hardened endocarp.  2. The fleshy fruit with each seed surrounded by a bony endocarp, as in Ilex.
  • pyriformPear-shaped; a term for solid shapes that are roughly conical in shape, broadest one end and narrowest at the other. As a rule the distal third of their length is the broadest, and they are narrowest near the proximal end, the base, where the stalk, if any, attaches.
  • pyrophile – Plants which need fire for their reproduction.
  • pyrophyte – Plants which have adapted to tolerate fire.

Q

  • quincuncial – in aestivation – with 5 parts where 2 petals or sepals are outside all others, 2 are inside all others and the 5th is outside on one margin and inside on the other.
  • (q.v.) – q.v. (quod vide) used to tell readers to look in another place in the same book for a piece of information; specific to botany means undivided, whole; in reference to a Family that contains more component genus ie lumped instead of split. See also s.s.

R – Botanical Dictionary

  • r – strategists – species whose populations are governed by their maximum reproductive capacity, r. They are generally capable of reproduction at a relatively young age, however, many offspring die before they reach reproductive age. They are often referred to as opportunistic species because they typically have a very low level of specialization, in that they can survive in less than ideal environmental conditions.
  • raceme – adj. Racemose – An indeterminate inflorescence in which the main axis produces a series of flowers on lateral stalks, the oldest at the base and the youngest at the top. Compare spike. Racemules are small racemes or the ultimate raceme unit.  Also racemiform is raceme like. 
  • racemose corymb – a raceme in which the pedicels of the lower flowers are longer than those of the upper ones so that the appearance of the inflorescence overall is that of a flat flower
  • rachilla (rhachilla) – the axis of a grass spikelet, above the glumes.
  • rachis pl. rachises or rachides – The axis of an inflorescence or a pinnate leaf; for example ferns; secondary rachis is the axis of a pinna in a bipinnate leaf distal to and including the lowermost pedicel attachment.
  • radial – With structures radiating from a central point as spokes on a wheel 
  • radiate – (of daisies, of a capitulum) With ray florets surrounding disc florets.
  • radical – Springing from the root; clustered at base of stem.
  • radicle – The part of an embryo giving rise to the root system of a plant, the first organ to appear. Compare plumule.
  • ramet – An individual member of a clone.
  • ramicaul – a single-leafed stem, as in Pleurothallis orchids.
  • ramified – ramification is the divergence of the stem and limbs of a plant into smaller ones, i.e. trunk into branches, branches into increasingly smaller branches 
  • ramiflorus –  Of a plant: having flowers or fruit borne directly on (older or larger) branches. Also: (of a flower or fruit) growing from a branch; designating or relating to this habit of growth.
  • raphe – longitudinal ridge on the side of ovules or seeds
  • raphides – any of numerous needle-shaped crystals, usually of calcium oxalate, that occur in many plant cells as a metabolic product.
  • ray – 1.  zygomorphic (ligulate) flowers in a radiate flowerhead, that is, ray-florets/flowers, for example Asteraceae.  2.  each of the branches of an umbel.
  • receptacle – the axis of a flower, in other words, floral axis; torus; for example in Asteraceae, the floral base or receptacle is the expanded tip of the peduncle on which the flowers are inserted. 
  • receptacular – pertaining to or growing on the receptacle
  • recurved – bent or curved backwards or downwards.
  • reduplicate – folded outwards, or with the two abaxial surfaces together.
  • reflexed – bent sharply back or down.
  • regma – a capsule with two or more lobes and as many one-seeded, two-valved cells, which separate at maturity, splitting elastically from the persistent axis (carpophore), as in Geranium. It is a schizocarp.
  • reniform – Kidney-shaped. Also subreniform almost kidney shape.
  • replum – fruits – the remain after framework of some pods that remain after the valves drop off, a result of persistent false septa
  • resin – a solid or highly viscous substance secreted for their protective benefits in response to injury. The resin protects the plant from insects and pathogens.
  • resupinate – 1.  In botany, describing leaves or flowers that are in an inverted position because the petiole or pedicel, respectively, is twisted 180 degrees. compare: #hyper-resupinate  2.  In lichenology, referring to either having or being a fruiting body that lies flat on the substrate, with the hymenium either over the whole surface or at the periphery.
  • reticulate – reticulodromous.  Forming a network (or reticulum), often used in venation where veins join one another at more than one point.
  • retincacula – also retinaculum – A small gland or process to which bodies are attached; as, the glandular retinacula to which the pollinia of orchids are attached, or the hooks which support the seeds in many acanthaceous plants.
  • retrorse – Bent backwards or downwards. Compare antrorse.
  • retuse – Having a blunt (obtuse) and slightly notched apex.
  • revolute – rolled under (downwards or backwards), for example when the edges of leaves are rolled under towards the midrib. Compare involute.
  • rhizine – The “root” or “trunk” projection of a foliose lichen that attaches the lichen to the substrate (what the lichen is growing on)
  • rhizodermis – the root epidermis, the outermost primary cell layer of the root
  • rhizoids – a short, thin filament found in fungi and in certain plants and sponges that anchors the growing (vegetative) body of the organism to a substratum and that is capable of absorbing nutrients. In fungi, the rhizoid is found in the thallus and resembles a root.
  • rhizome – a perennial underground stem usually growing horizontally. See also stolon. Abbreviation: rhiz.
  • rhizomatous – adj. a plant whose above ground stem is derived from a below ground stem (rhizome). cf. arhizomatous (arhizomatic)
  • rhizosphere – the below-ground surface of plants and adjacent soil as a habitat for microorganisms.
  • rhytidome – the dead region of the bark that lies outside the periderm.
  • rhombic – like a rhombus: an oblique figure with four equal sides. Compare trapeziform, trullate.
  • rhomboid – a four-sided figure with opposite sides parallel but with adjacent sides an unequal length (like an oblique rectangle); see also rhombic.
  • rhomboidal – a shape, for instance of a leaf, that is roughly diamond-shaped with length equal to width.
  • rimose – with many cracks, as in the surface of a crustose areolate lichen.
  • root – a unit of a plant’s axial system which is usually underground, does not bear leaves, tends to grow downwards, and is typically derived from the radicle of the embryo.
  • root hairs – outgrowths of the outermost layer of cells just behind the root tips, water-absorbing organs.
  • root microbiome – the dynamic community of microorganisms associated with plant roots.
  • root nodules –  found on the roots of plants, primarily legumes, that form a symbiosis with nitrogen-fixing bacteria. Under nitrogen-limiting conditions, capable plants form a symbiotic relationship with a host-specific strain of bacteria
  • rootstock – 1. the part of a budded or grafted plant which supplies the root system, also simply called a stock. 2.  plants selected to produce a root system with some specific attribute, e.g. a virus-free rootstock.
  • rosaceous – with 5 or more wide spreading roundish petals like a rose eg Rosa.
  • rosette – Adj: rosulate. When parts are not whorled or opposite but appear so, due to the contractions of internodes, e.g. the petals in a double rose or a basal cluster of leaves (usually close to the ground) in some plants.
  • rostellate – possessing a beak (rostellum). Synonym of rostrate
  • rostrate – having a beak resembling that of a bird.
  • rotate – circular and flattened, wide spreading; for example a corolla with a very short tube and wide spreading wheel like lobes (for instance some Solanaceae).
  • RuBisCO – An enzyme found in chloroplasts involved in fixing atmospheric carbon dioxide during photosynthesis and in oxygenation of the resulting compound during photorespiration.
  • ruderal – a plant that colonizes or occupies disturbed waste ground. See also weed.
  • rudiment – In the structure of a plant, an item that is at best hardly functional, either because it is immature and has not yet completed its development (such as a leaf still incompletely formed inside a bud), or because its role in the organism’s morphology cannot be completed and therefore is futile (such as the leaf rudiment at the tip of a phyllode, that will be shed while immature, because the leaf function will be taken over by the phyllode). Compare cataphyll, vestige.
  • rudimentary – Being of the nature of a rudiment; at most barely functional because incompletely developed; begun, but far from completed, either temporarily or permanently. Compare vestigial.
  • rufus – reddish – brown color
  • rugose – Also rugae – wrinkled, either covered with wrinkles, or crumpled like a wrinkled leaf, either as a stiffening structure, or in response to disease or insect damage.
  • rugulose – finely wrinkled.
  • ruminate – (usually applied to endosperm) Irregularly grooved or ridged; appearing chewed, e.g. the endosperm in certain members of Myristicaceae.
  • runcinate – Sharply pinnatifid or cleft, with the segments directed downward.
  • rupicolous – rupestral, saxicolous, growing on or among rocks. Compare epilithic and lithophytic.

S – Botanical Dictionary

  • saccate – Pouched or shaped like a sack.
  • sagittate – Shaped like the head of an arrow; narrow and pointed but gradually enlarged at the base into two straight lobes directed downwards; may refer only to the base of a leaf. Compare hastate.
  • salverform – Trumpet-shaped; having a long, slender tube and a flat, abruptly expanded limb.
  • samara – A dry, indehiscent fruit with its wall expanded into a wing, e.g. in the genus Acer. A samaroid is adj – samara like, subsamaroid is almost a samaroid.  
  • samaracetum – An aggregation of samaras, as in Liriodendron.
  • samphire – A common name given to various edible coastal plants, such as Salicornia spp. (Amaranthaceae), Crithmum maritimum (Apiaceae) and Limbarda crithmoides (Asteraceae).
  • sanguine – from Latin sanguineus, blood-coloured: crimson; the colour of blood.
  • saponin – any of various mostly toxic glycosides that occur in plants (such as soapwort or soapbark) and are characterized by the property of producing a soapy lather making it useful as a surfactant, some natural saponins are harvested for use as surfactants (detergents).
  • saprophyte – adj. Saprophytic – A plant, or loosely speaking, a fungus or similar organism, deriving its nourishment from decaying organic matter such as dead wood or humus, and usually lacking chlorophyll. Compare parasite, saprotroph and epiphyte.
  • saprotroph – adj. saprotrophic – An organism deriving its nourishment from decaying organic matter. Contrast parasite and epiphyte.
  • sarcotestaouter, usually softer fleshy part of a testa in various seeds (esp cycads).
  • sarment – A long, slender, prostrate stolon, commonly called a runner.
  • sarmentose – Reproducing by sarments; strawberry plants are the most familiar example.
  • saxicolous – Growing on stone, like some lichens.
  • scabrous – Also scabrid. Rough to the touch, with short hard protrusions or hairs.
  • scalariform – Ladder-like in structure or appearance.
  • scale – 1.  A reduced or rudimentary leaf, for example around a dormant bud.  2.  A flattened epidermal outgrowth, such as those commonly found on the leaves and rhizomes of ferns.
  • scandent – Climbing, by whatever means. 
  • scape – adj. scapose – A stem-like flowering stalk of a plant with radical leaves, a leafless flower stalk with leaves only at the base.  A long naked or nearly naked peduncle often growing directly from the rhizome or bulb.
  • scapose/scapiflorous/scapigerous – Having a scape.
  • scarious – Dry and membranous.
  • schizocarp – A dry fruit formed from more than one carpel but breaking apart into individual carpels (mericarps) when ripe. There are many types of schizcarops.
  • schizocarpic berries – Separating berries which have a fleshy pericarp, as in Phytolacca.
  • schizocarpic follicles – Separating follicles which are dry, dehiscent (splits at maturity) fruits derived from one carpel, splitting along one suture, as in Apocynaceae.  Also called follicetum. 
  • schizocarpic nutlets – Separating nutlets which are dry,indehiscent (do not split at maturity) 4-parted fruits with a hard pericarp around a gynobasic style, as in the Boraginaceae and Lamiaceae. Aka cenobium
  • schizogenous – of intercellular space in plants formed by the splitting of the common wall of contiguous cells.  Often applied to secretory cells. 
  • scion – The aerial part of a graft combination, induced by various means to unite with a compatible understock or rootstock.
  • sclereid – A cell with a thick, lignified, cell wall that is shorter than a fiber cell and dies soon after the thickening of its cell wall.
  • sclerenchyma –  A strengthening or supporting tissue composed of sclereids or a mix of sclereids & fibers.
  • sclerophyll – sclerophyllous – A plant with hard, stiff leaves; structures stiffened with thick-walled cells.
  • scorpioid cyme – Branching alternately on one side and then the other; a type of monochasium on which the successive axes arise alternately in respect to the preceding one.  Synonym cincinni or cincinnus. Compare helicoid cyme.
  • scrobiculate – Having very small pits.
  • scrubland – Dense vegetation dominated by shrubs.
  • scurf – adj. scurfy.  Minute, loose, membranous scale like particles on the surface of some plant parts, such as leaves.  
  • secondary metabolite – Chemicals produced by a plant that do not have a role in so-called primary functions such as growth, development, photosynthesis, reproduction, etc.
  • secondary species – In lichens, a “species” taxon of lichen reproducing only by vegetative means, whose components reproduce mainly by sexual means – cf. primary species.
  • secretory tissue – tissues concerned with the secretion of gums, resins, oils and other substances in plants.
  • secund – Having all the parts grouped on one side or turned to one side (applied to inflorescences).
  • segment – A part or subdivision of an organ, e.g. a petal is a segment of the corolla. A term sometimes used when the sepals and petals are indistinguishable.
  • self-pollination – (also selfing) The acceptance by stigmas of pollen from the same flower or from flowers on the same plant, which means they are self-compatible.
  • semaphyll – A structure such as a bract or sepal (if the remainder of the perianth is inconspicuous) which has become modified to attract pollinators.
  • semelparity – When a plant flowers once then dies.
  • semicarpous – nearly apocarpous, barely fused carpels 
  • seminal roots – Any of the adventitious roots that grow from the base of the stem during early seedling growth and take over the functions of the radicle.
  • semiterete – Rounded on one side but flat on the other. See also terete.
  • sensitive – A descriptive term for stigmas that, in response to touch, close the two lobes of the stigma together, ending the receptivity of the stigma, at least for the time that the lobes are closed together. Mimulus is perhaps the best-known example.
  • sensu lato – (of a plant group) In a broad sense.
  • sensu stricto – (of a plant group) In a narrow sense.
  • sepal – In a flower, one of the segments or divisions of the outer whorl of non-fertile parts surrounding the fertile organs; usually green. Compare petal.
  • septicidalA capsule that dehisces (splits at maturity) longitudinally through the septa, along partitions between loculi. As in Penstemon.  Compare loculicidal
  • septifragaldehiscing by breaking away of the valves from the septa
  • septum – pl. septa – A partition, e.g. the membranous wall separating the two valves of a seed pod.
  • seriate – Arranged in rows.  biseriate – arranged in 2 rows, triseriate arranged in 3 rows etc.
  • sericeous – Silky with dense appressed soft silky hairs; similar to strigose but soft instead of stiff hairs.
  • serrate – Toothed with asymmetrical teeth pointing forward; like the cutting edge of a saw.
  • serrulate – Finely serrate.
  • sessile – Attached without a stalk, e.g. of a leaf without a petiole or a stigma, when the style is absent.
  • seta – pl. setae; adj. setose, setaceous – A bristle or stiff hair (in Bryophytes, the stalk of the sporophyte). A terminal seta is an appendage to the tip of an organ, e.g. the primary rachis of a bipinnate leaf in Acacia.
  • sheath – A tubular or rolled part of an organ, e.g. the lower part of the leaf in most grasses.
  • shoot – The aerial part of a plant; a stem and all of its dependent parts (leaves, flowers, etc.).
  • shrublet – dwarf shrub
  • sigmoid – Shaped like the letter ‘S’.
  • silicle – A dry, dehiscent (splits at maturity) fruit derived from two or more carpels that dehisce along two sutures and which has a persistent partition after dehiscence and is as broad as, or broader, than long.
  • silicula – a stout siliqua (in contrast to a siliqua, not more than twice as long as wide).
  • silique –  dry, dehiscent fruit (in contrast to a silicula,more than twice as long as wide) formed from a superior ovary of two carpels, with two parietal placentas and divided into two loculi by a ‘false’ septum.
  • silky – densely covered with fine, soft, straight, appressed hairs, with a lustrous sheen, satiny to the touch.
  • simple – Undivided or unsegmented, e.g. a leaf not divided into leaflets (note, however, that a simple leaf may still be entire, toothed or lobed) or an unbranched hair or inflorescence.
  • sinuate or sinuose – Having deep, wave-like depressions along margins, but mostly flat. Compare undulate.
  • Sinus – A notch or depression between two lobes or teeth in the margin of an organ.
  • s.l. – sensu lato – in the broad sense refers to more broadly described families.     
  • solitary – Single, of flowers that grow one plant per year, one in each axil, or widely separated on the plant; not grouped in an inflorescence.
  • soralia – In a lichen, the structure that bears soredium for non sexual reproduction.
  • soredium – pl. soredia – In a lichen, a small groups of algal cells surrounded by fungal filaments that form in soralia, which break off and grow new lichens without sexual reproduction after being dispersed by wind. Compare to an isidium, which breaks off and is dispersed by mechanical means.
  • sorus – pl. sori A cluster of sporangia. Sori typically occur in ferns, some Algae and some fungi. In many fern species the sorus is covered by a protective indusium
  • spadix – A spicate (spike-like) inflorescence with the flowers crowded densely, even solidly, around a stout, often succulent axis. Particularly typical of the family Araceae
  • spathe adj. spathaceous or spatheate – A large bract en-sheathing an inflorescence. Traditionally any broad, flat blade.  Without a spathe: espatheate. 
  • spatheolate – a small bract en-sheathing an individual flower.
  • spathulate  or spatulate – Spoon-shaped; broad at the tip with a narrowed projection extending to the base.
  • spica adj. spicate or spiciform – Another name for a spike.
  • spicule – adj spiculate – A small sharp crystal, such as one of silicate or calcium carbonate supporting the soft tissue of certain plants and invertebrates.
  • spike – adj. spicate – An unbranched, indeterminate inflorescence in which the flowers are without stalks. Compare raceme.
  • spikelet – A subunit of a spike inflorescence, especially in grasses, sedges and some other monocotyledons, consisting of one to many flowers and associated bracts or glumes.
  • spine – adj. Spinose or spiniferous  – A stiff, sharp structure formed by the modification of a plant organ that contains vascular tissue, e.g. a lateral branch or a stipule; includes thorns. Also spinulose is small spinose. 
  • spinescent – Ending in a spine; modified to form a spine.
  • spiralOf arrangement, when plant parts are arranged in a succession of curves like the thread of a screw, or coiled in a cylindrical or conical manner.
  • spiraperturate –  pollen grains of Berberis, Eriocaulon spp with spiral apertures or with somewhat aperturoid weak streaks which probably derived from colpi, rugae, or sulci etc. S
  • spirocyclic –  also known as ‘Hemicyclic’. having flowering parts such as stamens and carpels are arranged spirally in Ranunculaceae. The arrangement of Spirocyclic flower is spiral and whorled.
  • spirodistichous – referring to a type of leaf arrangement in which the leaves are initially distichous but later appear spirally arranged. 
  • splash-cup (sporangia) – A cup-like structure in fungi such as Nidulariaceae and in cryptogams such as some mosses. The cups function in spore dispersal, in which the energy of raindrops falling into the cup causes the water to splash back out carrying the spores.
  • splitters – taxonomists who prefer to split genera up into less variable smaller families (which make identification and family descriptions more specific and useful) than lump them together in more variable families. 
  • sporangium (sporangia) – A structure in which spores are formed and where mature spores are released
  • sporangiophoreAn organ bearing sporangia, e.g. the cones of Equisetum.
  • sporeA haploid propagule, produced by meiosis in diploid cells of a sporophyte that can germinate to produce a multicellular gametophyte.
  • sporocarpA fruiting body containing spores.
  • sporophyllIn pteridophytes, a modified leaf that bears a sporangium or sporangia.
  • Sporophyte – The haploid multicellular phase in the alternation of generations of plants and algae that produces the spores. Compare gametophyte.
  • sport – A naturally occurring variant of a species, not usually present in a population or group of plants; a plant that has spontaneously mutated so that it differs from its parent plant.
  • spreading – Extending horizontally (in branches). Standing out at right angles to an axis (leaves or hairs).
  • spur – 1.  a short shoot.  2.  a conical or tubular outgrowth from the base of a perianth segment, often containing nectar.
  • squamule – (plural squamules, squamulae) small scales; In lichens, squamules are overlapping plate-like forms, sometimes overlapping so much as to become leaf-like, but which lack a lower cortex, unlike the leafy forms of foliose lichens – adjective: squamulose
  • squamulose – Covered with small scales (squamules). In lichens, being composed of squamules.
  • squarrose – Having tips of leaves, stems, etc. radiating or projecting outwards, e.g. in the moss Rhytidiadelphus squarrosus.
  •  s.s. – sensu stricto –in the strict sense refers to families more broken down and strictly defined.
  • stachysporous – sporangia borne directly on a more or less modified stem
  • stalk – The supporting structure of an organ, usually narrower in diameter than the organ itself.
  • stamen – adj. staminate – The male organ of a flower, consisting (usually) of a stalk called the filament and a pollen-bearing head called the anther.
  • staminate flower Also male flower. – A flower with stamens but no pistil.
  • staminode – adj: staminodal.  A sterile stamen, often rudimentary, sometimes petal-like.
  • staminophore – A structure, around the apex of eucalypt, myrtaceae hypanthia, that supports the stamens.
  • standard – The large posterior petal of pea-flowers.
  • standard specimen – A representative specimen of a cultivar or other taxon which demonstrates how the name of that taxon should be used.
  • stele – the primary vascular system (including phloem, xylem, and ground tissue) of plant stems and roots.
  • stellateadj: stellately as in stellately spreading.  Star-shaped.  Star shaped hairs common in Malvaceae.
  • stem – The plant axis, either aerial or subterranean, which bears nodes, leaves, branches and flowers.
  • stenospermocarpy – The development or production of fruit that is seedless or has minute seeds because of the abortion of seed development. Compare parthenocarpy.
  • stigmaThe pollen-receptive surface of a carpel or group of fused carpels, usually sticky; usually a point or small head at the summit of the style.
  • stipeGenerally a small stalk or stalk-like structure. The stalk of a frond of a fern; the stalk supporting the pileus of a mushroom; the stalk of a seaweed (ie kelp); the stalk-like support of a gynoecium or a carpel
  • stipellastipel; pl. stipellae – One of two small secondary stipules at the base of leaflets in some species.
  • stipitate – stalked; borne on a stipe; of an ovary, borne on a gynophore.
  • stipulate – Bearing stipules.
  • stipule – A small appendage at the bases of leaves in many dicotyledons.
  • stipel – adj: stipellate . A small stipule at the base of leaflets and not at the base of the leaf as is the case with a true stipule.  Stipels are only found in compound leaves.
  • stolon – Also runner.  A slender, prostrate or trailing stem, producing roots and sometimes erect shoots at its nodes. See also rhizome.
  • stoloniferous – Having stolons.
  • stoma – pl. stomata – A pore or small hole in the surface of a leaf (or other aerial organ) allowing the exchange of gases between tissues and the atmosphere.
  • stone cell – a sclereid cell, such as the cells that form the tissue of nut shells and the stones of drupes.
  • striateStriped with parallel, longitudinal lines or ridges.
  • strigoseCovered with appressed, straight, rigid, bristle-like hairs; the appressed equivalent of hispid.  Finely strigose is strigulose. 
  • strobiluspl. strobili adj: strobiloid or strobiliform.  A cone-like structure consisting of sporophylls (e.g. conifers and club mosses) or sporangiophores (e.g. in Equisetopsida) borne close together on an axis.
  • styleAn elongated part of a carpel or a group of fused carpels between the ovary and the stigma.
  • stylodium – An elongate stigma that resembles a style; a false style, found in the Poaceae and Asteraceae.
  • stylopodium – A swelling on top of the ovary, at the base of the styles, found in flowers of the Apiaceae.
  • stylulus – The elongated apex of a free carpel which functions like the style of a syncarpous ovary, allowing pollen tubes from its stigma to enter the locule of only that carpel.
  • subcoriaceous – Slightly leathery or coriaceous.
  • subentire – almost entire, slightly indented.
  • suberose – relating to or resembling cork, corky. 
  • subglobose – Inflated, but less than spherical. See also globose.
  • subpyramidal – shrubs, almost pyramidal in shape
  • subshrub – subshrubs. Also undershrub. A small shrub which may have partially herbaceous stems, but generally a woody plant less than 1 meter (3.3 ft) high.
  • subtend – To stand beneath or close to, as in a bract at the base of a flower.
  • subterranean – below the ground
  • subquadrangular – Not quite square. Compare quadrangular.
  • subturgid – slightly turgid
  • subulate – Narrow and tapering gradually to a fine point.
  • subvaginate – less than sheathed but not quite unsheathed. Vaginate is synonym of sheathed. 
  • succulent – 1.  Juicy or fleshy.  2.  A plant with a fleshy habit.
  • succession and successional advancement – the natural progression from one ecosystem type to another. There are typically a number of different stages, each generally with increasing structural complexity.
  • sucker – A shoot of more or less subterranean origin; an erect shoot originating from a bud on a root or a rhizome, sometimes at some distance from the stem of the plant.
  • syconium – A syncarp (multiple fruit) with the achenes borne on the inside of a hollowed-out, compound, fleshy receptacle or peduncle, as in Ficus.
  • suffrutex – pl. suffrutices – A subshrub or undershrub.
  • sulcateFurrowed; grooved. May be single (monosulcate), two (bisulcate) or many (polysulcate). Also sulcus, sulci.
  • superficial – On the surface.
  • superiorOf an ovary, borne above the level of attachment of the other floral parts, or above the base of a hypanthium. Contrast inferior and half-inferior.
  • suspended – Of an ovule, when attached slightly below the summit of the ovary. Compare pendulous.
  • sutureA junction or seam of union. See fissure and commissure.
  • sward – Extensive, more or less even cover of a surface, e.g. a lawn grass. Compare tussock.
  • switch plantsplants with photosynthetic functions transferred from leaves to other organs, usually stems.
  • sympatric – Having more or less similar or overlapping ranges of distribution.
  • sympodial – A mode of growth in which the main axis is repeatedly terminated and replaced with a lateral branch. Examples occur in Combretaceae, including the genera Terminalia and Combretum. cf. monopodial
  • syconium – also syncarp A hollow infructescence containing multiple fruit, such as that of a fig; formed from 2+ carpels of one flower or the aggregated fruits of several flowers, ie an entire inflorescence.
  • syn– Also sym-. A prefix meaning “with, together”.
  • symmetrical –  Capable of being divided into at least two equal, mirror-image halves (e.g. zygomorphic) or having rotational symmetry (e.g. regular or actinomorphic). Compare irregular and asymmetrical.
  • sympetalous – Having united (connate or fused) petals, not free (#apopetalous)
  • synandriuman androecium with fused anthers
  • synangium – A fused aggregate of sporangia, e.g. in the trilocular sporangia of the whisk fern Psilotum.
  • synanthous – A type of growth in which new leaves and flowers appear and die back at the same time. See also hysteranthous and proteranthous.
  • synapomorphy – a characteristic present in an ancestral species and shared exclusively (in more or less modified form) by its evolutionary descendants.
  • synaptospermy – The dispersal of diaspores as units, where each bears more than one seed, for example where each diaspore comprises an entire inflorescence, as in Brunsvigia or multi-seeded fruit as in Tribulus zeyheri. Ephemeral synaptospermy is the term for when the diaspores split into units containing fewer or single seeds each, as in most tumbleweeds. True synaptospermy is when the diaspore generally remains entire until germination, as commonly happens in species of Grielum.
  • syncarpous(of a gynoecium) Composed of united carpels.
  • synflorescence – A flower cluster segregated from any other flowers on the same plant, together with the stems and bracts (reduced leaves) associated with it. Certain plants produce inflorescences, whereas others produce only solitary flowers. 
  • synonym – An outdated or ‘alternative’ name for the same taxon.
  • synoecious – A synonym of bisexual.
  • synovariousthe fusion of ovaries and carpels but the style and stigmas remain separate. 
  • synsepalum – fused sepals 
  • synstylousthe fusion of styles but the ovary carpels remain separate. Compare synstylovarious.  
  • synstylovariousthe fusion of styles and ovary. Compare synstylous.
  • syntepalous – Having fused tepals. See also sympetalous (having fused petals).

T – Botanical Dictionary

  • tapetum – a specialized layer of nutritive cells found within the anther of flowering plants between the sporangenous tissue and the anther wall. Tapetum is important for the nutrition and development of pollen grains, as well as a source of precursors for the pollen coat.
  • taproot – The primary descending root of a plant with a single dominant root axis.
  • tartareous – Having a surface that is course, thick, rough, and crumbling.
  • tegmen – The inner layer of the testa (seed coat). It develops from the inner integument of the ovule.
  • tendril – Any slender organ modified from a stem, leaf, leaflet, or stipule and used to cling to an object.
  • tenuinucellate – ovules with no nucellar tissue separating embryo sac and epidermis 
  • tepal – A segment of a perianth, either sepal or petal; usually used when all perianth segments are indistinguishable in appearance.
  • Tepuis – A tepui, or tepuy is a table-top mountain or mesa found in the Guiana Highlands of South America, especially Venezuela and western Guyana. The word tepui means “house of the gods” in the native language of the Pemon, the indigenous people who inhabit the Gran Sabana.
  • terete – Also semiterete. Circular in cross-section; more or less cylindrical without grooves or ridges.
  • terminal – Situated at the tip or apex.
  • ternate – In groups of three; of leaves, arranged in whorls of three; of a single leaf, having the leaflets arranged in groups of three.
  • terpene – terpenes  are a large and diverse class of organic compounds produced by a variety of plants but especially conifers (and some insects). They often have a strong odor and seem to protect the plants by deterring herbivores and attracting predators and parasites of herbivores.
  • terrestrial – Of or on the ground; of a habitat, on land as opposed to in water (aquatic), on rocks (lithophytic), or on other plants (epiphytic).
  • testa – The seed coat.
  • tetracytic – Refers to stomata that possess one or more pairs of lateral subsidiary cells oriented parallel with the guard cells. Tetracytic. Refers to stomata that possess both lateral and polar subsidiary cells. Terms applied to stomata in which development is well documented.
  • tetrad – A group of four; usually used to refer to four pollen grains which remain fused through maturity
  • tetragonal – Square; having four corners; four-angled (cross-sections of stem Lamiaceae herbs).
  • tetradynamous – a flower has six stamens, two outer shorter than the inner four
  • teratological – the science of animal or plant monstrosities that deals with malformations or monstrous or abnormal growths in the animal or plant kingdoms.
  • tetramerous – In four parts, particularly with respect to flowers; four parts in each whorl. See also trimerous and pentamerous.
  • tetraploid – Organisms that possess 4 times more chromosomes than a haploid cell. tetraploid. nucleus, cell or organism that has four copies of the normal haploid chromosome set.
  • tetraspore – The asexual spore of red algae. It is so named because each sporangium produces just four spores. See Rhodophyceae.
  • thallus – the “vegetative” part (part other than sexual fruitbodies) of a lichen that has both the fungus (mycobiont) and photobiont; plural thalli
  • theca – One of the usually two synangia in which pollen is produced in flowering plants. It consists of two fused sporangia known as pollen sacs. The wall between the pollen sacs disintegrates before dehiscence, which is usually by a common slit. Pl: thecae  
  • thorn – A sharp, stiff point, usually a modified stem, that cannot be detached without tearing the subtending tissue; a spine. Compare prickle.
  • throat – The opening of a corolla or perianth.
  • thyrse – A branched inflorescence in which the main axis is indeterminate (racemose) and the lateral branches determinate (cymose).
  • tomentose or tomentum – A dense covering of short, matted hairs, similar to woolly but shorter hairs; tomentulose is slightly tomentose. Tomentose is often used as a general term for bearing an indumentum, but this is not a recommended use.
  • toothed – Having a more or less regularly incised margin.
  • trapeziform – 1.  Like a trapezium (a four-sided figure with two parallel sides of unequal length). 2.  Like a trapezoid (a four-sided figure, or quadrilateral, with neither pair of sides equal); sometimes used erroneously as a synonym for rhombic.
  • treelet – An erect, single-stemmed, woody plant less than 5 centimeters dbh and more than 2 meters tall; differences between treelets and unbranched shrubs or trees are sometimes unclear.
  • triad – A group of three.
  • triangular – Planar and with 3 sides.
  • tribrachiate – the style divides into three petal-like (petaloid) style branches (sometimes also referred to as ‘stylodia’), almost to the base of the style.
  • trichome – In non-filamentous plants, any hair-like outgrowth from the epidermis, e.g. a hair or bristle; sometimes restricted to unbranched epidermal outgrowths.
  • tridentate – used to describe either having 3 teeth, or having teeth that are themselves bidentate. 
  • trifid – Split into three parts. See also bifid.
  • trifoliate – A compound leaf of three leaflets; for example, a clover leaf.
  • trifoliolate – See trifoliate.
  • trigonous – Triangular in cross-section and obtusely angled. Compare triquetrous.
  • trilacunar – The node with a single gap and a single trace to a leaf is known as unilacunar; the node with three gaps and three traces to a leaf (one median and two lateral) is known as trilacunar; and the node with several to many gaps and traces to a leaf is known as multi-lacunar.
  • trimerous – In 3 parts, particularly flowers with 3 parts in each whorl. See tetramerous and pentamerous.
  • Trine – 3 fold; having 3 of something. 
  • trinerved – Having three nerves or veins.
  • tripinnate – having bipinnate leaflets that are themselves pinnately divided. 
  • triplinerved – (of leaves) Having three main nerves with the lateral nerves arising from the midnerve above the base of the leaf.
  • triploid – applied to a cell that has three sets (3n) of chromosomes in its nucleus, or to an organism composed of such cells (as opposed e.g. to haploid (n) or diploid (2n) cells or organisms). See also polyploid.
  • triquetrous – More or less triangular in cross-section, but acutely angled (with 3 distinct longitudinal ridges). Compare trigonous.
  • tristichous – Arranged in 3 rows 
  • tristylous – also tristyly condition in which three different style lengths and corresponding stamen lengths are found in the same species, the flower morphs are short styled, intermediate styled, and long styled. 
  • trivalve – Divided into three valves. Also trivalvar. See also bivalve.
  • trophophyll – A vegetative, nutrient-producing leaf or microphyll whose primary function is photosynthesis. It is not specialized or modified for some other function. Compare sporophyll.
  • trullate – Ovate but angled, as with a bricklayer’s trowel; inversely kite-shaped. Compare rhombic.
  • truncate – Cut off squarely; having an abruptly transverse end.
  • trunk – The upright, large and typically woody main stem of a tree.
  • truss – A compact cluster of flowers or fruits arising from one centre; evident in many rhododendrons.
  • tryma – Two-four loculed nuts surrounded by a dehiscent (splitting at maturity) involucre at maturity, as in most species of Carya. (accessory structure Involucre)
  • trymariumschizocarp of  trymas released at maturity by splitting accessory perianth
  • tuber – Any of many types of specialized vegetative underground storage organs. They accumulate food, water, or in protection from death by fire, drought, or other hard times. Tubers generally are well differentiated from other plant organs; for example, informally a carrot is not generally regarded as a tuber, but simply a swollen root. In this they differ from the tuber of a sweet potato, which has no special root-like function. Similarly, corms are not generally regarded as tubers, even though they are underground storage stems. Tubers store food for the plant, and also have important roles in vegetative reproduction. They generally are of two main types: stem tubers formed by the swelling of an underground stem growing from a root, or from structures such as underground stolons. Stem tubers generally produce propagative buds at their stem nodes, forming a seasonal perennating organ, e.g. a potato. The main other class is the root tuber, also called tuberoid. They differ from stem tubers in features such as that they do not form nodes.
  • tubercle – A small wart-like outgrowth or protuberance of tissue.
  • tuberculate or tubercled – Covered in tubercles. See tubercle or warty.
  • tuberoid – Alternative name for underground storage organ formed by swelling of a root; occurs in orchids.
  • tuberous – Resembling a tuber or producing tubers.
  • tubular – Having the form of a tube or cylinder.
  • tufted – Densely fasciculate at the tip.
  • tunic – The outer covering of some bulbs and corms.
  • tunicate – (of bulbs) Consisting of concentric coats.
  • turbinate – Shaped like a spinning top or beetroot.
  • turgid – Swollen with liquid; bloated; firm. Compare flaccid.  Adj: turgescent 
  • tussock – A dense tuft of vegetation, usually well separated from neighboring tussocks, for example in some grasses. Compare sward.
  • two-ranked – Having leaves arranged in 2 rows in the same plane, on opposite sides. See distichous.

U

  • umbel – adj umbellate – racemose inflorescence in which all the individual flower stalks arise in a cluster at the top of the peduncle and are of about equal length; in a simple umbel, each stalk is unbranched and bears only one flower. A cymose umbel looks similar to an ordinary umbel but its flowers open centrifugally.  The secondary umbels of compound umbels are known as umbellules or umbellets.
  • umbelliform – a compressed cyme that resembles an umbel
  • umbonate – umbo – Having an umbo, with a conical or blunt projection arising from a flatter surface, as on the top of a mushroom or in the scale of a pine cone.
  • unciform – Hook-shaped.
  • uncinate – Having a hook at the apex.
  • undershrub – A low shrub, often with flowering branches that die off in winter. Compare subshrub.
  • undulate – Wavy and not flat. Compare sinuate.
  • uniflor – Having a single flower (uniflory). Compare pauciflor (few) and pluriflor (many).
  • unifoliate  – having a single leaf or leaflike part | 
  • unilocular – Having one loculus or chamber, e.g. the ovary in the families Proteaceae and Fabaceae.
  • uniserial – Arranged in a single row or series. Unbranched. Uniseriate.
  • uniseriate – Arranged in a single row or series. Unbranched. Uniserial.
  • unisexual –  Of one sex; bearing only male or only female reproductive organs, dioecious, dioicous. See Sexual reproduction in plants.
  • unitegmic – (of an ovule) Covered by a single integument. See also bitegmic, having two integuments.
  • urceolate – Shaped like an urn or pitcher, with a swollen middle and narrowing top. Examples include the pitchers of many species of the pitcher plant genera Sarracenia and Nepenthes.
  • utricle – 1.  A small bladder; a membranous bladder-like sac from the ovary wall, thin pericarp, becomes more or less bladdery or inflated at maturity enclosing an ovary or fruit. 2.  In sedges, a fruit in which the fruit is loosely enclosed by a modified tubular bract, see perigynium.
  • urticating – trichomes with hollow points that secrete an acrid fluid that cause burning and itching sensations. Eg: Euphorbiaceae, Urticaceae.

V – Botanical Dictionary

  • vallecular canal – A resin canal coinciding with a longitudinal groove in the seeds of Asteraceae. A longitudinal cavity in the cortex of the stems of Equisetum, coinciding with a groove in the stem surface.
  • valvate – (of sepals and petals in bud) Meeting edge-to-edge but not overlapping.
  • valve – A portion of an organ that fragments or splits open, e.g. the teeth-like portions of a pericarp in a split (dehisced) capsule or pod when ripe.
  • variant – A plant or group of plants showing some measure of difference from the characteristics associated with a particular taxon.
  • variegated – Irregularly marked with blotches or patches of another colour.
  • vascular – Referring to the conducting tissues (xylem and phloem) of vascular plants. Adj: vascularization 
  • vascular bundle – A bundle of vascular tissue in the primary stems of vascular plants, consisting of specialized conducting cells for the transport of water (xylem) and assimilate (phloem).
  • vasculum – A container used by botanists for collecting field specimens.
  • vein – Also nerve. A strand of tissue, e.g. in the leaves of vascular plants. 
  • veinlet – A small vein; the ultimate (visible) division of a vein.
  • velamen – A spongy tissue covering the aerial roots of orchids and some other epiphytes.
  • velutinous/Velvety – Densely covered with fine, short, soft, erect hairs.
  • venation – The arrangement of veins in a leaf.
  • ventral – adj: ventrally – From Latin venter, meaning “belly”. The opposite of dorsal. Partly because the term originally referred to animals rather than plants, usage in botany is arbitrary according to context and source. In general “ventral” refers to “the belly or lower part”, but in botanical usage such concepts are not always clearly defined and may be contradictory. For example: facing towards the axis (adaxial) in referring to a lateral organ of an erect plant
  • ventrifix – attached on the inner side
  • vernation – The arrangement of unexpanded leaves in a bud; the order in which leaves unfold from a bud.
  • vernonioid – In the Compositae, style with sweeping hairs borne on abaxial surfaces of style branches.
  • verruciform – Wart-like in form.
  • verrucose – Having warts, synonym of tuberculose.
  • verruculose – Minutely verrucose; minutely warty
  • versatile – (of anthers) Swinging freely about the point of attachment to the filament.  Compare non-versatile, unable to swing freely at the point of attachment.
  • verticillate – Arranged in one or more whorls, i.e. several similar parts arranged at the same point of the axis, e.g. leaf arrangement. Compare pseudoverticillate (appearing whorled or verticillate but not actually) and subverticillate almost verticillate but not quite. 
  • verticillaster – pairs of opposite axillary, usually sessile, cymes, common in Lamiaceae; they appear whorled but are not.
  • vesicular – (of hairs) Bladder-like; vesciculous, bearing such hairs.
  • vessel – A capillary tube formed from a series of open-ended cells in the water-conducting tissue of a plant.
  • vestigial – Reduced in form and function from the normal or ancestral condition.
  • vexillary – in aestivation where a larger petal (i.e. the standard) overlaps other smaller petals, often seen in the Fabaceae family. 
  • vilano – the whorl of sepals, another name for calyx
  • villouscovered with long, soft, shaggy hairs, not entangled (then woolly).
  • vine – 1.  Scandent plants climbing by means of trailing or twining stems or runners.  2.  Such a stem or runner. 3.  A member of the genus Vitis.
  • virgate – Diminutive: virgulate – Wand-shaped, twiggy, especially referring to erect, straight stems. In mycology, referring to a pileus with radiating ribs or lines.
  • viridiplantae – A clade of autotrophic organisms that includes the green algae, Charophyta and land plants, all of which have cellulose in their cell walls, chloroplasts derived from primary endosymbiosis with Cyanobacteria that contain chlorophylls a and b and lack phycobilins.
  • viscous or viscid – Sticky; coated with a thick, resinous secretion.
  • viviparous – 1.  Referring to seeds or fruits which germinate before being shed from the parent plant. 2. The development of plantlets on non-floral organs, e.g. leaves.
  • volva – a cup-shaped structure that sheathes the base of the stalk of certain mushrooms. 

W

  • warty – A surface covered with small round protuberances, especially in fruit, leaves, twigs and bark. See tuberculate.
  • watershoot – An erect, strong-growing, or epicormic shoot developing from near the base of a shrub or tree, but distinct from a sucker.
  • weed – 1.  Any plant growing where it is not wanted; commonly associated with disrupted habitats. See also ruderal.  2.  An unwanted plant which grows among agricultural crops.  3.  A naturalized, exotic, or ecologically “out-of-balance” indigenous species outside of the agricultural or garden context, which, as a result of invasion, adversely affects the survival or regeneration of indigenous species in natural or partly natural vegetation communities.[14]
  • wild – Originating from a known wild or purely natural habitat (wilderness).
  • whorl – A ring of organs borne at the same level on an axis (e.g. leaves, bracts, or floral parts).
  • wing –  1.  A membranous expansion of a fruit or seed which aids in dispersal, for instance on pine seeds. 2.  A thin flange of tissue extending beyond the normal outline of a structure, e.g. on the column of some orchids, on stems, on petioles.  3.  One of the two lateral petals of a flower of subfamily Faboideae of family Fabaceae, located between the adaxial standard (banner) petal and the two abaxial keel petals.
  • woolly – Very densely covered with long, more or less matted or intertwined hairs, resembling sheep wool, similar to tomentose but usually longer hairs.

X

  • xerochastic – dehiscence were seeds are released by successive dehiscence of the locules.
  • xeromorph – A plant with structural features (e.g. hard or succulent leaves) or functional adaptations that prevent water loss by evaporation; usually associated with arid habitats, but not necessarily drought-tolerant. Compare xerophyte.
  • xerophyte – A plant generally living in a dry habitat, typically showing xeromorphic or succulent adaptation; a plant able to tolerate long periods of drought. Compare xeromorph.
  • xylem – A specialized water-conducting tissue in vascular plants.

Z – Botanical Dictionary

  • zonate – Having light and dark circular bands or rings, typically on leaves or flowers.
  • zygomorphic – Bilaterally symmetrical; symmetrical about one vertical plane only; applies to flowers in which the perianth segments within each whorl vary in size and shape. Contrast actinomorphic and irregular.  
  • zygote – A fertilized cell, the product of fusion of two gametes.

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Phytolacca Americana American Pokeweed - Native Plant of the Week

The berries of Phytolacca americana American Pokeweed - Native Plant of the Week Photo by Lyrae Willis, Nashville, TN
The berries of Phytolacca americana American Pokeweed – Native Plant of the Week Photo by Lyrae Willis, Nashville, TN

American Pokeweed Phytolacca americana – Native Plant of the Week

Introduction

American Pokeweed, Phytolacca americana, was a new plant for me in that I only recently ‘discovered’ it in my recent travels to the eastern USA. It grows prolifically like a weed, hence the name “Pokeweed”. It has tiny little flowers but gorgeous clusters of green berries on purple-red stems that later turn dark purple. I think what I love most about it is the contrast of the green or purple berries on those bright fuchsia-red stems. I also respect the large size of this native herbaceous perennial and its hardiness. It often grows on the edge of roads, poking out between the edge of the bushes and the sidewalks. It gets trimmed back, trampled on, and yet it still returns.

Toxicity of American Pokeweed

Phytolacca americana is poisonous to humans and most other mammals. The roots are the most toxic, followed by the mature leaves, stems, and ripe fruit. Symptoms of poisoning include severe gastritis, vomiting, sweating, bloody diarrhea, blurred vision, and loss of consciousness. People seldom die, but young children, who may eat the berries, are the most susceptible. Since the toxins can be absorbed through the skin it is recommended to limit direct contact with your skin. Birds and other small animals, however, are immune to its toxic effects.

Its toxicity is the reason this beautiful native plant is often viewed as a pest plant because it sometimes harms people, pets, or livestock. I think it is sad when native species are treated as ‘pests’ because they were here before we ever were, so who is the pest, really? Maybe we just need to be better educated about the dangers of poisonous plants. I think I may also just have a soft spot in my heart for any native plant viewed as a pest. In either case, I think it is a beautiful plant. I wanted to learn more about it and share it with others so maybe they too can better understand this misunderstood native plant. If you like misunderstood native plants as I do, be sure to check out my blog on whether cattails are really an invasive native species or do human perceptions need to change?

Description of American Pokeweed

Stem & Leaves

American Pokeweed or Phytolacca americana is a member of the Phytolaccaceae family, part of the Caryophyllales Order. It is a very tall herbaceous perennial, growing anywhere from less than 1 m to just over 3 m tall with angular-ridged greenish to fuchsia-red stems. The stems are often, though not always branched.

The large leaves grow to 35 cm long and 18 cm wide on 1-6 cm long leaf stalks (petioles). Leaf blades are ovate to lance-shaped and are entire (not toothed). The leaf tips (apex) are thin and pointed (acuminate) and its base is rounded or heart-shaped (cordate). Leaves are arranged alternately on the reddish stems.

Flowers & Fruits

The flowers of Phytolacca americana American Pokeweed - Native Plant of the Week Photo by Lyrae Willis, Fulton County, IN, USA
The flowers of Phytolacca americana American Pokeweed – Native Plant of the Week Photo by Lyrae Willis, Fulton County, IN, USA

The flowers grow in elongated racemes (clusters). Each small, perfect, radially symmetric flower has 4-5 white, greenish-white, pinkish, or purplish sepals each 2.5-3.5 mm long. The flowers have no petals, though the sepals do appear petal-like. There are 9-12 stamens in a single whorl. Usually, however, the flowers have 10 stamens. Flowers have 6-12 carpels (a carpel is the female reproductive organs = ovary + style + stigma) that are partially joined (connate) toward their base. The ovary is 6-12 loculed (chambered).

American Pokeweed produces somewhat unique 6-11 mm diameter berries that have 10 (9-12) cells. The berries start out green and later turn dark purple to almost black, with bright crimson-colored juice. The 3 mm lens-shaped shiny black seeds are embedded in the juicy berries and are mostly spread by birds that are able to eat the berries without toxic side effects.

Similar Species Frequently Confused With

There are no other species it can be confused within North America. The Phytolaccaceae family is a small family with only a handful of species and the unique stems and berry clusters of this species make it difficult to confuse with anything else. However, there are two varieties of Phytolacca americana. Sometimes the varieties’ properties can overlap and vary making them hard to distinguish. However, in general, the two can be distinguished as follows:

  • Phytolacca americana var americana – fruit stalks (pedicels) are usually longer than 6 mm when in fruit, and are longer than the berries. The racemes are usually drooping and are typically quite long, from 12-30 cm long (raceme only, not including the stalk). This variety is much more common and widespread throughout the species’ entire range.
  • Phytolacca americana var rigida – pedicels are shorter than the berries and less than 6 mm long when in fruit. The racemes are erect and typically much shorter, usually only 6-9 cm long. This variety is also only found in eastern coastal USA from North Carolina and Virginia south along the coast as far west as Texas.

Habitat & Growing Conditions of Phytolacca americana

In North America, it tends to be found in disturbed areas including pastures, edge habitats, roadsides, fence rows, forest openings, recently cleared areas and waste areas. It is an opportunistic species that seems able to thrive on human disturbance.

It grows in full sun to part shade. Due to its more opportunistic nature it can be found growing in a variety of soil and moisture conditions.

Growing American Pokeweed in Your Garden

Growing native species in your yard is easy, once established they require little or no maintenance. They also provide important wildlife and biodiversity values as well. These factors all make them the perfect plant for your garden.

American Pokeweed is easy to grow from seed, you can either purchase seeds or gather some from the wild. Seeds can be obtained in the Amazon Affiliates links at the bottom of the page. Plants generally cannot be transplanted as they have a long taproot. But the seeds are fairly easy to germinate and remain viable for decades. Simply spread them on a thin layer of compost and lightly cover them with soil. Keep them moist until they germinate then thin them. Once mature each plant will need approximately 1 m of space.

Pokeweed grows quite tall but can be pruned shorter if necessary. Ideally choose a location behind your flower beds and plant it in almost any soil type and condition. It is highly opportunistic that way and will tolerate almost anything. Once past the seedling stage you can simply leave it alone, it requires no fertilizer and no water once established. Just let it grow and harvest it yourself if that is your reason for growing it, or leave it be and let the wildlife feast on the berries when they come ripe.

Winter Maintenance

Even though it is a herbaceous perennial and will die back for the winter, do not cut the dead growth back until spring. If there are remaining berries on the bush the birds, rodents, deer, etc will keep returning to nibble on them all winter long. Then in the spring before it gets new shoots, cut the dead stems back to ground level.

Wildlife Values of American Pokeweed

American pokeweed feeds numerous native wildlife species from birds like robins, hummingbirds, and bluebirds to squirrels, foxes, opossums and raccoons. Most animals eat the juicy berries when ripe but white-tailed deer also feed on the leaves and stems, especially in the spring. It is also a host to the lovely leopard moths and it’s an important plant for migratory birds in eastern North America.

Distribution of American Pokeweed Phytolacca americana

In Canada, Phytolacca americana is found only in the eastern provinces of Ontario, Quebec, and New Brunswick.

In the USA American Pokeweed is found throughout all the eastern states from Minnesota south to Louisiana and all states east of there. It is also found in the southern states of Texas, New Mexico, and Arizona with scattered populations in the pacific coast states of California, Oregon and Washington. It is most widespread in the eastern USA.

In Mexico, it has been found in Baja California (norte), Nuevo Leon, Veracruz, and along the eastern edge of Oaxaca. It is likely native there due to populations on the southern border of the USA. Though its populations and status there do not appear to have been studied.

American Pokeweed was formerly a North American endemic species. Globally it has now been introduced to numerous countries in Europe as well as in Japan.

Status of Phytolacca americana

American Pokeweed is considered Globally Secure (G5). Given its weedy opportunistic tendencies, this is not surprising as it is a tough plant tolerant of various growing conditions including human disturbance.

In Canada, Phytolacca americana is considered Apparently Secure (S4). It is unranked in Quebec and New Brunswick.

However in the USA, it is only considered Secure locally (S5) in Iowa, Kentucky, Virginia, West Virginia, and Delaware. It is Apparently Secure (S4) in Illinois. As is the case with most of our native plants it is as yet unranked in most of the states that it is currently found in. The unranked states it is found in include: Maine, Vermont, New Hampshire, Massachusetts, Rhode Island, Connecticut, New York, New Jersey, Maryland, Pennsylvania, Ohio, Indiana, Michigan, Wisconsin, Minnesota, North Carolina, South Carolina, Tennessee, Georgia Florida, Alabama, Mississippi, Louisiana, Arkansas, Missouri, Nebraska, Kansas, Oklahoma, Texas, New Mexico, Arizona, California, Oregon, and Washington.

Traditional or Other Uses of American Pokeweed

American Pokeweed Use as a Vegetable

Poke salad was a common food eaten regularly as recently as the mid 1900’s. The young leaves were picked, washed, then cooked. The water was poured out, new water added, then cooked again, and rinsed out again. This process deactivated the toxins and rinsed them out of the young leaves. Only the young leaves were eaten this way as they became more toxic with maturity. Young shoots were also picked and eaten similar to asparagus. The berries were frequently used to color wine and eaten cooked in pies, usually mixed with other berries.

The Cherokee Nation of the USA has a long traditional history of the use of American Pokeweed. They too would cook and eat the greens. The later settlers no doubt learned this practice from them. The Cherokee people used to pick the young leaves and dry them for later use. They would also peel, cook and eat the young stems like asparagus. Sometimes they would even dip the stems in egg, and then cornmeal, and fry them as you would fish. They also used the berries in wines for flavor and color. The Iroquois and Malecite also occasionally used Phytolacca americana as a food source.

Phytolacca americana Medicinal Uses

Medicinally American Pokeweed was used by native North Americans for a number of ailments. Usually, the root was used medicinally, mostly externally but also internally, no doubt under strictly controlled supervision as the root is the most poisonous. The Iroquois used it for various skin conditions, rashes, bruises, etc. They also used it for rheumatism and problems with the liver or blood. The Delaware, Mahuna, and Micmac used it for similar purposes in similar ways. The Mohegan used the mashed berries as a poultice for sore breasts for nursing mothers. It was also used as a poison by the Iroquois Mohegan and Mahuna peoples. The Iroquois even used it as a love medicine where they would ‘tie in a poplar tree, then place among roots’.

More recently Phytolacca americana has been widely used by herbalists for various skin ailments, particularly hemorrhoids. It is also being studied for its known potent antiviral and antifungal properties. It is even being examined for use against HIV (Human Immunodeficiency Virus).

Ethical Wildcrafting of Phytolacca americana

If you want to wildcraft Phytolacca americana please find a nice large and healthy population to harvest from. If you find just a few plants or a single plant please leave them alone to reproduce. Even though it is a weedy species whose status is currently secure, it is a plant with a ‘bad rap’ that is often eradicated locally due to its being so misunderstood and feared. So when wildcrafting, as always, please follow the 1 in 20 rule as described in the Ethical Wildcrafting post. Also, because it tends to grow well under human disturbance, be sure the area you are wildcrafting from is free of major sources of pollution.

Wildcrafting and Processing

If you are harvesting wear gloves to minimize contact exposure. When harvesting leaves pick 1 in every 20 leaves you see and place them in a bag or basket. Then bring them home and either dry them flat on a screen or rack for later use or cook them right away if making poke salad. Please be very careful if you are ingesting them in any way, be aware of the poisonous properties, and treat the plant with the respect it deserves. If storing the greens be sure to label the bag or jar with TOXIC IF INGESTED to prevent others from accidentally ingesting enough to poison themselves.

If you are harvesting the roots then dig the root with a digging stick as described in the Ethical Wildcrafting post. Bring the root home and remove any dirt, then slice it into smaller manageable pieces before drying for later use. Once dried it can be made into a tincture or a salve. If you are not a trained herbalist please limit your use of the root to external applications only. Be sure to label TOXIC IF INGESTED on your harvesting bag, rack, and tincture bottles to prevent others from accidentally ingesting the poison.

Berries can be harvested when ripe, pick the entire cluster (only picking 1 in 20 clusters that you see), then bring them home and either use them right away or dry them on a screen or rack for later use. Again, be sure to label the storage jar with TOXIC IF INGESTED to prevent others from accidentally ingesting toxic amounts of the berries.

References and Resources

Canadensys Plant Search https://data.canadensys.net/vascan/search

Dictionary of Botanical Terms – by Lyrae’s Nature Blog https://lyraenatureblog.com/blog/dictionary-of-botanical-terms/

Eflora Plants of North America http://www.efloras.org/browse.aspx?flora_id=1

iNaturalist Plant Search https://www.inaturalist.org/home

Native American Ethnobotany http://naeb.brit.org/

Natureserve Explorer https://explorer.natureserve.org/Search

USDA Plants Database https://plants.sc.egov.usda.gov/home

Willis, Lyrae (2022).  Plant Families of North America.  Not yet published. 

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


Lilium columbianum Columbia Tiger Lily - Native Plant of the Week

Columbia Tiger Lily, Lilium columbianum photo from In-Shuck-ch FSR near Pemberton, BC, Canada
Columbia Tiger Lily, Lilium columbianum photo from In-Shuck-ch FSR near Pemberton, BC, Canada

Columbia Tiger Lily Lilium columbianum – Native Plant of the Week

Introduction

The Columbia Tiger Lily or Lilium columbianum is a beautiful true lily of the Liliaceae family. For most of my life, its familiar bloom greeted me in late spring throughout the summer in the southern half of British Columbia where I have spent most of my life. The pretty orange blossoms with their unique turban-shaped features are difficult to confuse with other species. I love seeing them on the sides of the road in late spring and early summer when they are at their peak.

But nothing breaks my heart more than watching people pick handfuls of the beautiful flowers, clearly not recognizing the damage they are doing. Anytime you pick a flower from the wild you are preventing it from reproducing. In some cases, you are dooming the entire plant and all of its future offspring. The flowers of virtually all plants give rise to the fruits and/or seeds that are the next generation. While the Columbia Tiger Lily is still somewhat common, I have noticed it becoming less common in areas where I have witnessed them being picked.

The Columbia Tiger Lily, Lilium columbianum, was an important staple food source for many native peoples in western North America. It is still sometimes gathered and eaten as food, but please follow good Ethical Wildcrafting principles if you want to try this.

In recent years Lilium columbianum has been becoming more and more available commercially. I love the idea of our beautiful native plants being made available commercially. As long as gardeners purchase their seeds or bulbs from a native plant supplier who propagates themselves and does not harvest from the wild that is. Particularly if it is native in your area, please buy some seeds and grow them in your own yard. You will not be disappointed! See the section on Growing Columbia Tiger Lily below for more information.

Description of Columbia Tiger Lily

Stem & Leaves of Lilium columbianum

A variable but usually tall plant on slender stems up to 1-2 m tall. Sometimes they may be shorter, even as low as 15 cm tall when found growing in subalpine conditions. They grow from highly variable-shaped elongated bulbs up to 5 cm in diameter.

The thin stems have anywhere from 3 – 20 whorled leaves arranged equally around the same node. As you go up the stem towards the flowers the leaves become only partially whorled then scattered. Its leaves are more or less elliptical in shape to wider near the tip (apex) and narrower at the base (oblanceolate) and are anywhere from 1.5 – 15.5 cm long. The apex (tip) is always sharply pointed to varying degrees (acute to acuminate). The leaves are always at least twice to several times longer than they are wide. Leaf margins are often smooth but may be slightly wavy (undulate).

Leaves of the Columbia Tiger Lily, Lilium columbianum photo from Carlson Lake, BC, Canada
Leaves of the Columbia Tiger Lily, Lilium columbianum photo from Carlson Lake, BC, Canada
Mature flower close-up of Lilium columbianum showing exerted stamens & reflexed petals.
Mature flower close-up of Lilium columbianum showing exerted stamens & reflexed petals.

Flowers & Fruits of Lilium columbianum

The flowers bloom anywhere from May to September, depending on elevation and latitude. They are beautiful, but not fragrant. Flowers are bright, showy, light orange nodding flowers with maroon-purple to reddish spots on their six tepals. Being a lily they have ‘tepals’ in that their sepals and petals appear virtually identical and are not easily distinguished. The tepals are characteristically reflexed, bending backward so far they often touch their tips together at the back of the flower. The shape is often referred to as Turk’s cap or turban shaped.

The anthers are yellow to orange in color and are borne on exserted filaments in that they extend out of the flower beyond the tepals. Flowers from northern populations typically have more exserted stamens (anthers + filaments) than those in the southern end of its range.

There are anywhere from 1 and up to 15 flowers per stem in favorable conditions. The flowers are pollinated by rufous hummingbirds and swallowtail butterflies. In late summer or early fall, they produce a seed capsule 2.2 – 5.5 cm long.

Similar Species Frequently Confused With

The unique flowers of this species make it difficult to confuse with other plants except similar species in the same genus of the Liliaceae family.

  • Lilium kelloggii – this plant may hybridize with Lilium columbianum in the southern part of its range which can make it hard to identify. However, L. kelloggii is not found north of Oregon. Its flowers are more fragrant than not but are also reflexed. However, the tepals are always more pink than orange, sometimes with orange stripes.
  • Lilium occidentale – this plant has a very limited range, being found only along the coast in southwestern Oregon and northwestern California. The flower tepals are reflexed but are very red in color.
  • Lilium pardalinum – this plant may hybridize with Lilium columbianum in the southern part of its range making them hard to identify. However, it is also not found north of southernmost Oregon. It is a highly variable species with many subspecies. In general, however, its tepals are always varying shades of red towards their tips, orange towards their base. While the tepals are reflexed they are typically not as reflexed as Lilium columbianum.
  • Lilium philadelphicum – this is the only other one that Lilium columbianum could be confused within eastern British Columbia, Canada as it is the only other ‘Tiger Lily’ that grows there, and the only area where it overlaps L. columbianum in range. These are easily distinguished however by the usually red or darker orange tepals that are never reflexed.

Habitat & Growing Conditions of Columbia Tiger Lily

Though its range is somewhat limited, it is common where it does grow and it adapts to a variety of different ecosystems. It can be found in clearings, meadows, forest edges, and on roadsides, particularly in the mountains where they have been less picked. They also grow in a variety of forest types including scrub, mixed or coniferous. The Columbia Tiger Lily also tolerates a wide range of elevations, being found anywhere from 0 – 1800 m above sea level.

Lilium columbianum typically grows in partial shade but can be found in full sun or full shade. In full shade they are more lanky with less flowers. They prefer rich loamy soil types as long as they are well-drained soils. They do not grow in waterlogged soils.

Growing Columbia Tiger Lily in Your Garden

Native species are fantastic additions to your garden. If you live in the Pacific Northwest, once established these will require little to no maintenance and they provide important wildlife and biodiversity values as well as their aesthetic beauty. Please purchase seeds or bulbs from a native plant supplier who propagates themselves and does not harvest from the wild that is. Seeds are a better choice if you are uncertain where the supplier is getting their bulbs from, there are some available in the Amazon Affiliates section at the bottom of this article.

When started from seed Columbia Tiger Lily takes 3 – 5 years to mature before it produces and significant bulbs and abundant flowers. If you already have bulbs you can divide them or gently remove the bulb scales to more quickly produce new plants. Share your bulbs around with your friends in the Pacific Northwest and have them grow them too!

Be sure you have a spot with rich loamy soil. If not, dig up a roughly 70 cm cubic pit of soil out of your chosen spot and fill it with rich loamy soil. Plant your seeds, bulbs or plants and amend the surface with organic compost for food and water retention. Keep it moist but not wet, wet soil can cause basal rot.

If your land is prone to waterlogging be sure to also dig out a pit of soil but add sand and gravel to the bottom of the pit and mix a little sand into your loamy soil. Then plant the bulbs or seeds in a raised mount of soil. This will help keep them drier than the surrounding land. Waterlogged plants are prone to basal rot which will kill the plant.

Winter Maintenance

Columbia Tiger Lily is a herbaceous perennial so the above-ground growth will die back each fall. Once the leaves have all died you can cut it down. If you live in a particularly cold area you could put some mulch over the bulbs in the winter to protect them. Then when spring comes you can dig them up and divide the bulbs, if desired.

Pests and Other Problems

Aphids may attack your plants as they are fond of most lilies. If this is the case spray them with diluted neem oil as a safe treatment. Neem works great on aphids and will not harm the plants.

Wildlife Values of Columbia Tiger Lily

Multiple native pollinators visit the Columbia Tiger Lily including butterflies, birds, bees (native and honeybees), and more. Though native peoples ate the bulbs on a regular basis it is not certain if wildlife ever feed on the bulbs.

Distribution of Columbia Tiger Lily Lilium columbianum

Columbia Tiger Lily is endemic to western North America, being found nowhere else in the world. In Canada, it is found throughout the southern half of British Columbia. In the USA it is found throughout most of Washington, the northern tip of Idaho, the extreme northwest corner of Montana, western Oregon, and the northwest corner of California. It is found nowhere else in North America.

Status of Lilium columbianum

Columbia Tiger Lily is considered Secure (S5). However, it is only secure in British Columbia, Canada. It is considered Imperiled (S2) in Montana, USA where it has an extremely limited distribution. In Idaho, Washington, Oregon, and California it is as yet Unranked, sadly as is the case with so many of our native US plant species. Clearly, the USA needs to do more to assess its plant populations so that they can be adequately ranked.

Traditional or Other Uses of Columbia Tiger Lily

The Columbia Tiger Lily has a long history of use as a staple food source by native peoples in western North America. The following groups of people were all noted as using it as a source of food whether eaten fresh, steamed, dried, etc. They include: Clallam, Klallam, Lummi, Nitinaht, Okanagan, Okanagan-Colville, Quileute, Quinault, Samish, Shuswap, Skagit, Swinomish, Skokomish, and Thompson.

The flavor has been described anywhere from peppery and tasty, somewhat resembling chestnuts to varying levels of bitterness. The flavor likely varies between different regions as well as harvest times. Bulbs were usually gathered in the late summer or early fall after the flowers had died off. Sometimes, however, they were also harvested in the spring. They were gathered and then steamed in pits and eaten warm, or eaten later cold with oil. The Thompson people would also boil them with salmon roe during the salmon runs and eat it as a favorite dish among their people.

Columbia Tiger Lily bulbs were also processed and stored as a winter food staple. After steaming they would be dried and made into storage cakes with dried meat or berries, especially saskatoon berries. They would then be eaten throughout the winter in cakes or added to soups.

There are no references found for using Lilium columbianum for medicinal purposes. Other closely related lily species were used in various medicinal preparations, but no medicinal uses for Columbia Tiger Lily were found. However, the Okanagan-Colville people would mix the mashed bulbs with stinkbugs to ward against ‘plhax’ in a form of witchcraft medicine.

Ethical Wildcrafting of Lilium columbianum

Ideally if you live in the Pacific Northwest try growing these beautiful flowers in your garden. See the section above for more information. If you still want to try the bulb of the Columbia Tiger Lily as a wild food, first be sure that the population is secure in your area. Then be sure to find a nice large and healthy population. If you find just a few plants or a single plant please leave them alone to reproduce.

When wildcrafting follow the 1 in 20 rule for plants as described in the Ethical Wildcrafting post. For every 20 plants you see, you can harvest one. Since you are digging the bulb you will no doubt kill the plant during harvest so please stick closely to the 1 in 20 rule. To help aid in propagation wait until the flowers have died and the seeds have formed. This way, when you harvest the bulbs you can scatter the mature seeds so that they will grow into new plants.

Wildcrafting and Processing Tips

When you dig the bulbs please do not use a shovel as it will damage the bulbs as well as the roots of surrounding plants. Instead, use a digging stick as these are far less damaging. A digging stick is any short, sturdy stick that won’t break when you dig the soil with it. You can bring your own or find one along the way. Dig into the ground just out from the base of the plant until you find the bulb(s). Once dug, brush the dirt off the bulbs and place them in a basket of some kind and bring them home to process them.

To prevent molding bulbs should be processed soon after picking. To process bulbs simply clean them and steam them or cook them in a pit in the traditional way. Some sources mention that drying them for a couple of days in the sun first may help remove some of the bitter flavors. But, as this bitterness is variable and subjective, you could try it either way.

Please, if you are trying this, do so in moderation. The days of using wild food for subsistence living in North America are for the most part long gone. This is thanks to invasive species, habitat destruction, and other harmful human practices that threaten our wild plant populations. It might be fun to try, but it is no longer a lifestyle we can choose to live if we want our native species to survive in the future.

References and Resources

Canadensys Plant Search https://data.canadensys.net/vascan/search

Dictionary of Botanical Terms – by Lyrae’s Nature Blog https://lyraenatureblog.com/blog/dictionary-of-botanical-terms/

Eflora Plants of North America http://www.efloras.org/browse.aspx?flora_id=1

iNaturalist Plant Search https://www.inaturalist.org/home

Native American Ethnobotany http://naeb.brit.org/

Natureserve Explorer https://explorer.natureserve.org/Search

USDA Plants Database https://plants.sc.egov.usda.gov/home

Willis, Lyrae (2021).  Plant Families of North America.  Not yet published. 

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


Desert Thorn Apple Datura discolor - Native Plant of the Week

Fruit of Datura discolor - photo from Mazatlan, Sinaloa, Mexico by Lyrae Willis
Fruit of Datura discolor – photo from Mazatlan, Sinaloa, Mexico by Lyrae Willis
Flower of Datura discolor - photo from Mazatlan, Sinaloa, Mexico by Lyrae Willis
Flower of Datura discolor – photo from Mazatlan, Sinaloa, Mexico by Lyrae Willis

Desert Thorn Apple, Toloache, Datura discolor – Native Plant of the Week

Introduction

Desert Thorn Apple, or commonly called Toloache in Mexico, is the species Datura discolor. The Datura genus are of the Solanaceae or Nightshade family along with tomatoes, potatoes, peppers, and eggplants. It is a beautiful, hearty plant worthy of our respect and admiration, but with extreme caution due to its toxicity.

The Desert Thorn Apple is often seen growing on roadsides as well as in semi-open natural areas in sandy soils and washes (dry creek beds in dry climates or deserts where water flows when it rains) throughout its range. Even when it is in the dry season, the Desert Thorn Apple still often appears lush and green when little else is. It has large, beautiful, delicate-looking white trumpet-shaped flowers whose throat is tinged with varying shades of purple. Its beauty and drought tolerance make it popular as a garden plant in its natural range. However, in some areas, it can be illegal to sell, buy or even grow Datura plants.

Toxicity of the Desert Thorn Apple or Toloache

Don’t let the incredible beauty of the large trumpet flowers of Datura discolor fool you. As with all other Datura species, the entire plant is potentially highly toxic. The flowers, leaves, roots, and especially the seeds all contain a potentially lethal mix of toxic alkaloids including scopolamine and atropine. Datura species have been known to poison people, livestock, and pets. Its effects have at times been fatal. Children, in particular, seem to be susceptible to the atropine alkaloids.

If ingested these alkaloids may cause symptoms ranging from dry skin, dry mouth, dilated pupils, muscle stiffness, and confusion to agitation, paralysis, delirium, amnesia, strong hallucinations, and even death. Most human cases of toxicity are from intentional ingestion of a more common closely related species known as Jimson Weed, Datura stramonium. Teenagers and young adults frequently ingest or smoke the plant for its potentially hallucinogenic effects, but often end up hospitalized, or worse, from its unintended toxic side effects.

Avoiding Toxic Effects

It is, however, easy to avoid poisoning from the Desert Thorn Apple as most poisonings are from intentional ingestion. Simply don’t ingest it. Sometimes however it can get mixed in with plant harvests and contaminate livestock feed. If there is a lot of Datura in your fields simply go and remove the plants at harvest time to prevent contamination. There was even a case of poisoning from a certain type of semi-domesticated honey wasp that caused poisoning from honey, though this method of ingestion appears to be quite rare.

Treatment for Poisonings

Most people are hospitalized due to their agitated state. The primary treatment for poisoning is activated charcoal to reduce the absorption of the toxic alkaloids by the stomach. Hospitals may also administer drugs to calm the patients down and counteract the effects. Pets and livestock are treated with activated charcoal.

Description of Datura discolor

Leaves & Stem of Datura discolor

Datura discolor plant from above showing growth habit, leaves and flower.
Datura discolor plant from above showing growth habit, leaves and flower.

Desert Thorn Apple or Toloache is an annual or short-lived perennial sub-shrub that varies considerably in height. It can be a low-growing somewhat sprawling shrub less than 50 cm tall to an upright one growing up to 1.5 m tall. Its tough stalks are green with purple stripes (striations) on them. The purple striations are often quite conspicuous and help aid in its identification to help distinguish it from other species of Datura. The widely ovate-shaped leaves are 5-18 cm long and 3-16 cm wide. The leaves may or may not be toothed (dentate) or slightly wavy-edged (undulate). The surfaces may or may not be variously hairy (pubescent).

Flowers & Fruits of Datura discolor

Datura discolor has very large, upright white funnelform (somewhat trumpet-shaped) flowers with varying shades of purple (see photo at top of page). The purple is usually in the throat of the flower but sometimes also on the edges of the flared face (corolla) of the flower. The 8-15 cm long flower tubes are surrounded by a 6-14 cm long tubular calyx. The corolla of the flower is 4-8 cm wide generally with 5 strong points or acumens (and 5 shorter acumens) that are usually short and vary from acute to acuminate on the very edges of the corolla. The flowers are short-lived, opening at night and typically withering after just one day.

It has a spiny roundish (globose) seed capsule 2.5-4 cm wide, as do most Datura species (see photo at top of page). The capsule has 200 to 300 spines that are each 1.3-2 cm long. The capsule splits or dehisces along 4 sutures releasing numerous black kidney-shaped (reniform) seeds. Its persistent round (rotate) calyx surrounds the base of the seed capsule where it attaches to the stem.

Similar Species Datura discolor is Frequently Confused With

Datura discolor is part of the Solanaceae family and could easily be confused with any of the other species of Datura. There are currently 14 accepted species and all tend to be highly variable, growing according to their environmental conditions. This can make identification challenging.

There are some key differences that will help you distinguish Desert Thorn Apple from the others. Here is a list of the other species found in the same range as Datura discolor and their differences in habitat or appearance:

  • Datura ceratocaula – native to Mexico but prefers swamps or other wet areas, unlike most other Datura species. The flowers often have a bluish tinge. Also unlike all other Datura species, the seed capsules are never spiny making them easy to distinguish.
  • Datura ferox – the long spine thorn apple once thought to be native to China actually originated in the Americas and is native to Mexico and Central America. It is known for its particularly long spines on its seed capsules. The leaves are toothed and hairy and its hairy stalks are thick and often tinged with red. It is an upright annual no more than 90 cm tall.
  • Datura innoxia – the downy or recurved thorn apple also grows in a similar range, but it is known for its downy soft leaves and stems making the plant appear soft and greyish in color. The flowers are similar in size but usually have recurved edges that bend downwards. The fruits are larger and usually egg-shaped and split irregularly instead of along 4 sutures.
  • Datura leichhardtii – grows in similar habitats and to similar heights as Datura discolor. However, this plant is covered with small hairs and has smaller inconspicuous yellowish-white flowers that set it apart from other Datura species.
  • Datura quercifolia – found in similar habitats but also survives in moist environments in full sun. It is distinguished by its oak-shaped leaves and its small pale violet funnel-shaped flowers that seldom exceed 4.5 cm long.
  • Datura stramonium – common jimsonweed is an aggressive weed throughout the range of Datura discolor. Its flowers however are more fragrant than the Desert Thorn Apple, are only 6 – 9 cm long, generally do not ever fully open, and they are usually white or cream and rarely violet in color. The seed capsules also open along 4 sutures but they are larger, up to 8 cm long, and are oval or egg-shaped, not round.
  • Datura wrightii – grows in the southwestern USA and northern Mexico but it is a herbaceous perennial growing to 1.5 m tall and wide. Its leaves are more rounded, tapering to a point and may be wavy but generally are not toothed. The flowers are also large and white (to 20 cm long) and may be tinged with purple, but are much more fragrant and generally last much longer. The similar-sized capsules have more spines (300-400) but they contain tan instead of black seeds.

Habitat & Growing Conditions of Desert Thorn Apple

Desert Thorn Apple, Datura discolor, is common in sunny, dry places throughout the Sonoran desert and surrounding areas of the southwestern USA, Mexico, and Caribbean islands in arid and semi-arid areas. Desert Thorn Apple is also frequently found on roadsides and next to buildings where the eaves protect its delicate flowers from the rains. It is generally only found at lower elevations, below 600 m.

It prefers open sunny areas in sandy soils and washes (dry creek beds) throughout its range. It can be found in part shade but not full shade. It prefers dry soil and can tolerate drought conditions. It can tolerate moist soil types but will not grow in wet soil.

Growing Desert Thorn Apple in Your Garden

If you live in the southwest of USA, Caribbean, Mexico or other nearby areas Desert Thorn Apple will be very easy to grow in your garden. Please check your are to make sure it is legal to grow however as in some states it is regulated. If you are able to grow it then fantastic, native species, once established, require little to no maintenance making them the perfect garden plant.

If given a little TLC Desert Thorn Apple will behave as a short-lived perennial, otherwise it grows as an annual. Collect the seeds each year and scatter them in your chosen spot to grow on their own, or if you prefer you could start them in pots and transfer them to your garden from there. It would be best to start them in newspaper pots, peat pots, or other biodegradable pots so that you do not have to disturb their roots when you plant them in your garden.

Find a nice sunny spot with sandy soil, but amend it with a small amount of organic compost in order to feed it so that it grows larger and produces more flowers than it would in sandy soils alone.

If your soil is too heavy or rich dig out a 50 cm x 50 cm x 50 cm pit and mix sand and/or gravel into the soil before putting it back in the pit. If the area is prone to collect moisture then try planting the seeds on top of a slight mound so that it is higher than the surrounding soil allowing it some extra drainage. When it comes to Desert Thorn Apple the soil really never can be too dry providing you water it if it does happen to look wilted.

Distribution of Datura discolor

In the USA, Desert Thorn Apple is native in California and Arizona. In North America it does not grow any further north than California and Arizona, being entirely absent from Canada.

In Mexico, it is more widespread throughout the western, central, and southern states. It is native in Sonora, Sinaloa, Nayarit, Baja California, Baja California Sur, Mexican Pacific Islands, Jalisco, Guanajuato, Colima, Michoacan, Queretaro, San Luis Potosi, Nuevo Leon, Tamaulipas, Puebla, Guerrero, Veracruz, Oaxaca, and Chiapas. It has also been found in the Caribbean, particularly in Cuba and Puerto Rico, where it is also believed to be native.

Many Datura species have now been introduced around the world. Datura discolor has been introduced to western India and different parts of northern and southern Africa.

Status of Datura discolor

Desert Thorn Apple, Toloache, or Datura discolor, is considered Globally Secure (G5). In the USA, as is the case with most native plants it seems, it is yet unranked. No other information on its status could be found. However, it is a hearty plant that is relatively common in its natural range. It has also been introduced outside of its natural range, so its actual global status is likely fairly Secure.

Traditional or Other Uses of Desert Thorn Apple

In North America Datura species were frequently used ritualistically by shamans, medicine men, and other spiritual leaders to induce hallucinations. Various species were widely used, however, not just the Desert Thorn Apple, but all Daturas in their range. It was reportedly used this way by the Pima, Navajo, Havasupai, and Southern Paiute. The Aztecs of Mexico widely used it by their medicine men, necromancers, and also in their ritualistic sacrifices. It is apparently even an ingredient of the well-known Haitian ‘Zombie Poison”.

Datura discolor the Desert Thorn Apple or Toloache was also used medicinally. Specifically the Pima peoples in North America used it as an analgesic for childbirth, on the skin for sores or to draw pus from boils, as a wash for sore eyes, as a gastrointestinal aid for ulcers, and the heated flowers as a poultice for earaches.

In the Old World, after it was introduced from the New World, it was also used both medicinally and ritualistically. Medicinally it was used in similar ways as Belladonna. Sometimes Datura was also used to poison people, in witchcraft, or as an aid to suicide.

Ethical Wildcrafting of Datura discolor

Ingestion of Desert Thorn Apple, in any form and quantity, is no longer recommended or commonly practiced. If you are however using it in a ritual and not planning to ingest it in any form then please follow standard Ethical Wildcrafting principles. Find a nice large and healthy population to harvest whichever parts of the plant you wish to harvest. Please try not to kill the entire plant when you wildcraft as it is a native species in North America. If you are wanting to grow it in your garden simply harvest the ripe seeds and plant them the following spring.

And of course, be absolutely certain that you bring a paper bag with a pen to carefully label the species and location. Once labeled add “TOXIC IF INGESTED” in large bold print on the bag so that it is never accidentally ingested. While drying keep the label with the plant parts that are drying. Once dried and ready to be stored follow the practice of carefully labeling species and severe toxicity if ingested, again to prevent anyone from accidentally ingesting it and poisoning themselves.

References and Resources

Canadensys Plant Search https://data.canadensys.net/vascan/search

Dictionary of Botanical Terms – by Lyrae’s Nature Blog https://lyraenatureblog.com/blog/dictionary-of-botanical-terms/

iNaturalist Plant Search https://www.inaturalist.org/home

Native American Ethnobotany http://naeb.brit.org/

Natureserve Explorer https://explorer.natureserve.org/

Rel de Herbarios del Noroeste de Mexico https://herbanwmex.net/portal/

USDA Plants Database https://plants.sc.egov.usda.gov/home

Wikipedia on effects of ingestion and treatment: https://en.wikipedia.org/wiki/Datura

Willis, Lyrae (2022).  Plant Families of North America.  Not yet published. 

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


Mountain Arnica Arnica latifolia - Native Plant of the Week

Mountain Arnica, Broadleaf Arnica, Arnica latifolia.  Lyrae Willis photo 2019, Strutel Creek Edgewood, BC, Canada
Mountain Arnica, Broadleaf Arnica, Arnica latifolia. Lyrae Willis photo 2019, Strutel Creek Edgewood, BC, Canada

Mountain Arnica Arnica latifolia – Native Plant of the Week

Introduction

Mountain Arnica, Broadleaf Arnica, or Arnica latifolia is a common native wildflower found in the mountains of western North America. The Arnica genus has numerous species and is well-known to herbalists, wildflower enthusiasts, and nature lovers alike.  In the summer, when you go up the mountains, you are often greeted by their abundant cheerful yellow blooms. 

There are actually numerous different species of Arnica in North America, and often, to the untrained eye, they can be difficult to tell them apart. However, with a little training on the physical characteristics of the Asteraceae flowers they can readily be identified (see Description below). Fortunately, however, if you are wanting to use them medicinally many of the Arnicas share similar medicinal properties.  However, some species are rarer than others. So if you are doing any ethical wildcrafting, please keep this in mind. Check for rare species in your area to ensure you are not picking from rare plants. 

Description of Mountain or Broadleaf Arnica

Leaves & Stem

Broadleaf Arnica or Mountain Arnica is a perennial herb 10-60 cm tall from simple stems that are sometimes branched. It grows from a sturdy rhizome and produces hairy flower stalks that rarely have more than 2-4 pairs of leaves on them. There are, however usually numerous leaves growing in a rosette around the base of the flower stalks. The 2-10 cm long leaves are usually toothed and may or may not have leaf stalks (petioles). The leaves are usually broadly lance-shaped but can vary from lance-shaped to almost heart-shaped (cordate).

Flowers & Fruit

The flowers are yellow sunflower-like flowers typical of the Asteraceae family. There are 1-5 flower heads per stalk with anywhere from 8-15 ray florets (the ‘petals’ of an Asteraceae compound flower) per flower. The ray florets surround a slightly darker yellow central disk of 20-90 disk florets (tiny little flowers in the central area of an Asteraceae compound flower). If you want to learn more about Asteraceae flowers and their unique physical characteristics, I suggest you check out the diagrams here https://cronodon.com/BioTech/asteraceae.html . You can also read the Wiki page on Asteraceae, it is very informative. However, the above link has much better diagrams showing the different physical features of the composite flowers.

The bracts surrounding the compound flower (involucres) are narrowly shaped like a spinning top (turbinate). There are from 8-20 lance-shaped or reverse lance-shaped (oblanceolate) phyllaries (the second set of bracts surrounding the base of Asteraceae flowers) below the involucre bracts. Their reduced calyx or sepals (pappus) is seen as a white and bristly tuft of hairs outside the corolla of each of the tiny little florets.

Their fruit is known as a cypsela, a small seed with a hairy tuft of a pappus that remains attached, aiding in dispersal by wind. The cypsela is dark brown, 5-9 mm long, and sparsely covered with long, soft, straight hairs (villous).

Similar Species Arnica latifolia is Frequently Confused With

As a yellow-flowered Asteraceae, of which there are so many, it could be confused with other asters of the same color.

Different species of Arnica genus are usually distinguished by their leaf shape, florets, cypsela, pappus, and their involucres. There are numerous species in North America all with a similar superficial appearance. The variability in leaf shape, and similar habitat preferences, can make Arnica latifolia easy to confuse with Arnica cordifolia in particular with its heart-shaped (cordate) leaves. In the case of Arnica cordifolia, its leaves are heart-shaped (cordate), never lance-shaped, and always have petioles. Furthermore, Arnica cordifolia typically has fewer ray florets and their involucres are broadly bell-shaped (campanulate). Finally, the cypsela of Arnica cordifolia is 5-10 mm long, dark grey, and sparsely to densely covered in coarse, long, rough hairs (hirsute) and sometimes may be covered in stalked glands (stipitate-glandular).

Habitat & Growing Conditions of Mountain Arnica

Mountain Arnica, Broadleaf Arnica, or Arnica latifolia is native to western North America. It is typically, though not exclusively, found in relatively moist montane to subalpine forests from 500-3300 m in elevation. As you increase in latitude, the elevation it is found at decreases, as with most wildflowers. It grows in both forests and open meadows. It is often seen growing along the side of logging roads and even in older clear-cuts, providing these have enough moisture.

Mountain Arnica is usually found in full sun to part shade. In hotter climates, it prefers part shade but prefers more sun as you move north. It prefers sandy well-drained, slightly alkaline soils. But it can also be found growing in a variety of soil types as long as they are well drained as it will not grow in waterlogged soils.

Growing Mountain Arnica in Your Garden

Arnica latifolia can be relatively easy to grow if the conditions are suitable. If you live in a mountainous area in western North America, you should have no problem growing it. If you live in a dry climate, it may be more challenging to grow it in your yard, but it can be done. Arnica tolerates full sun to part shade and prefers moist but well-drained soils. Be sure to amend your soil with some organic compost for food and moisture retention. Otherwise, being a native species, it will require little to no maintenance once it becomes established in your yard.

If you have heavy clay or very sandy and gravelly soils you should dig out a pit of soil and fill it with a humus-rich topsoil instead. Then plant your seeds or your plants in the pit you created. If your land tends to be waterlogged (heavy clay soil), then place the plants or seeds on a mound higher than the surrounding soil so that it can get extra drainage. If your land tends to drain too quickly after a rain (lots of gravel and sand) then place the plants or seeds in a small depression so that it collects and holds water better for longer periods of time. Again, once established, they should require little to no maintenance.

Wildlife Values of Arnica latifolia

Nothing could be found on the wildlife values of Arnica latifolia. If you know of some please Contact Me!

Distribution of Mountain or Broadleaf Arnica

In Canada, Arnica latifolia is found in the Yukon and Northwest Territories, as well as in British Columbia and Alberta.

In the USA, it is native to Washington, Oregon, California, Idaho, Montana, Colorado, Wyoming, Nevada, Utah, and New Mexico. According to iNaturalist it may also be found in Arizona, USA.

According to iNaturalist Arnica latifolia may be found in Mexico in the states of Sinaloa and Jalisco. Those reports, however, are all as of yet unconfirmed. Arnica latifolia is a highly diverse species, and there are many species of Arnica that resemble each other making positive identifications challenging for the untrained. So we could assume its southern limit maybe California and New Mexico, and the northern limit is Alaska, Yukon, and Northwest Territories.

Status of Arnica latifolia

Mountain or Broadleaf Arnica is considered Secure (G5). However, it is only Secure (G5) in British Columbia, Canada. It is considered Apparently Secure (S4) in Alberta, Canada. In the Yukon and Northwest Territories, it is considered Vulnerable (S3). It is considered Vulnerable (S3) in Utah and Wyoming in the United States. In all other states where it is located, it is as of yet Unranked, as is the case of many native plants in that region.

Traditional or Other Uses of Mountain Arnica

Arnica species have long been used in Europe in salves, tinctures, and ointments for their anti-inflammatory properties for sore muscles, stiffness, and bruises. It was also widely used for various first aid treatments as an antiseptic and antibacterial, for insect bites, and healing wounds. However, it should be noted that Arnica is no longer recommended for internal use due to possible toxic effects. Furthermore, many herbalists recommend that it be used only on unbroken skin due to the possibility of irritation in sensitive individuals. Despite these warnings, Arnica is still a widely used topical herbal medicine today.

There is less documented historical use of Arnica in North America compared to that of Europe. But native peoples in North America did sometimes use Arnica species. Poultices were made by the Thompson to reduce swellings, treat rheumatism, and for cuts and bruises. Catawba people used root decoctions internally back pain. Shuswap used an infusion externally for sore eyes.

The Okanagan-Colville used it as a love potion when mixed with the heart and tongue of a robin and red ochre.

Ethical Wildcrafting of Arnica latifolia for Medicinal Use

When wildcrafting, follow the 1 in 20 rule for flowers as described in the Ethical Wildcrafting post. For every 20 flowers you see, pick one. Do not pick all the flowers off a single plant instead, spread your harvest around. Alternatively, grow it in your garden, see the section above on Growing Arnica in Your Garden.

Find a nice large and healthy population of flowers to harvest from. If you find just a few plants or a single plant, please leave them alone to reproduce. Arnica flowers should be picked in the summer when in full bloom but before they start to go to seed. Do not pick the flowers when they are wet with dew or rain to help prevent molding. Also, do not pick in the heat of the day if the flowers look ‘droopy’. The quality will be poor and it is more damaging to the plant. The goal is to leave the plant alive and still thriving when you are done.

Wildcrafting and Processing

To pick the flowers, simply pinch them off their stalks at the base of the flower. They are easily plucked from their stems this way, but if you find them tough use a knife, scissors, or hand cutters to cut them off (See Resources below). Never pull the stalks out to harvest the flowers or you could damage the plant so that it may not survive the following year. Once the flowers are picked, they can be placed in a basket or a paper bag. I always use a paper bag for wildcrafting and I carry a sharpie with me to write the date, species, and location of harvest. I re-use my bags over and over again.

When you get them home dry them in a single layer on a drying rack or an old window screen works great. You can dry flowers on a flat surface like a table, but be sure to turn them daily to prevent molding. Once dried, your harvest can be stored in glass jars until you are ready to use it. Never pre-grind or crush your herbs before storing as this dramatically reduces their shelf life. Instead, store them whole and dried. Then you can crush or grind as needed when you are ready to use them.

References and Resources

Canadensys Plant Search https://data.canadensys.net/vascan/search

Cronodon Asteraceae Flower Diagram https://cronodon.com/BioTech/asteraceae.html .

Dictionary of Botanical Terms – by Lyrae’s Nature Blog https://lyraenatureblog.com/blog/dictionary-of-botanical-terms/

Eflora Plants of North America http://www.efloras.org/browse.aspx?flora_id=1

iNaturalist Plant Search https://www.inaturalist.org/home

Native American Ethnobotany http://naeb.brit.org/

NatureServe Explorer https://explorer.natureserve.org/Search

USDA Plants Database https://plants.sc.egov.usda.gov/home

Willis, Lyrae (2022).  Plant Families of North America.  Not yet published. 

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


The Art of Ethical Wildcrafting - Learn What It Is And How To Do It

Ethical wildcrafting under the power lines with my oldest son in Sechelt, BC, Canada back in 2005. Power lines are a great place to harvest because they get slashed down every 10 years by the power company.
My youngest son wildcrafting juniper
‘berries’ on a quiet roadside (never use
a busy highway!) earlier this year (2023).
I always like to show my kids these
useful skills.

The Art of Ethical Wildcrafting

So what is “ethical wildcrafting” anyway? I have always defined ethical wildcrafting as “the wild harvesting of plants, lichens, fungus, or other organisms from nature in a manner that reduces our impact as much as possible.” This covers both the ethical (to reduce our impact) and the wildcrafting (harvesting from nature) parts. When I used to teach a course on ethical wildcrafting 15-20 years ago, I always started with the same basic definition. The goal is to reduce, not eliminate, your impact. Your presence alone in any ecosystem has an impact. The whole ‘leave no trace’ movement, while I absolutely support it 150%, strictly speaking from an ecological perspective, is impossible. Fortunately, however, we do not need to “leave no trace”. We simply need to reduce our impact to a level that the ecosystem, population, or plant can recover in as short a time as possible.

When to Use the 1 in 10, 1 in 20, or 1 in 50 Rules of Ethical Wildcrafting

So when it comes to ethical wildcrafting, you may hear of the “1 in 10”, “1 in 20”, or “1 in 50” rules. So which one are you supposed to follow? First of all, this rule refers to the percentage of plants you can harvest from a healthy population. If there are 20 plants, then you can take one if you follow the 1 in 20 rule. So when do you follow which rule?

First and foremost, before considering ethical wildcrafting for any reason, know your plant ID! Be absolutely sure that you are harvesting the correct species. This will prevent the accidental harvest of rare or endangered species. It could also prevent you from getting very sick or even dying if you accidentally harvest and ingest a poisonous species. 

From an ethical perspective, 1 in 10 should only be used with extremely common native plants with many large, healthy populations. Alternatively, it can also be used with introduced non-invasive, non-native plants. The 1 in 20 rule works great for common native plants. If you harvest one in every 20 in a stable, healthy population, that population, in theory, should be able to recover. I say this in theory because you may not know if that population is already declining or otherwise threatened. That is why with wildcrafting, whenever it is possible, you should never harvest an entire plant. 

The 1 in 50 Rule for Rare Plants

The 1 in 50 rule was designed for the harvesting of rare plants. However, I strongly discourage anyone from ever harvesting rare plants. The only possible exceptions would be for emergency survival purposes (extremely rare) or, in some cases, if its harvesting is needed to help aid in its conservation. If it is for conservation purposes, then please leave that to the scientists who are specialists in that field and are tasked with that responsibility. I believe that 99% of the time, even for scientists, collecting rare plants is not necessary. As an Environmental Scientist myself, I strongly advocate the use of very thorough botanical descriptions, along with multiple well-done photographs showing all the floral parts, stem, and leaf features. In most cases, this will be satisfactory.

If further information is needed on a rare plant, then with the advances in molecular analysis seen today we can now take tissue samples for DNA and molecular analysis. Tissue samples generally involve the collection of a very small amount of live plant matter. There is no need to destroy the original wild plant. In fact, by doing this, we can even take those cultures to create clones of the original plant. The clones can then be analyzed in a laboratory or greenhouse setting or used to produce more plants for conservation or commercial uses, etc. This completely eliminates the need to potentially damage the entire population ‘for the sake of science’ or reproducing them for conservation or commercial purposes.

The problem is that if you harvest one rare plant, even if you think you are doing the right thing, you may be stealing the genetics that was going to allow that species to survive long-term. Especially in the face of climate change and the current extinction crisis, you literally may be dooming that rare species to extinction. That may sound dramatic, and in all likelihood, you will not be the cause of its demise, but you also may be. So why take the chance? That is why it is best to leave them alone and enjoy them in the wild or in photographs instead. I frequently return to the site of rare and endangered plants, even if they are only locally rare and common elsewhere. I would rather enjoy them in their natural setting. And even more frequently, I examine the photos of them that I took in their natural environment, whole and completely unharmed by my presence. That is my rant on rare plants; I will say no more.

Ethical Wildcrafting of Invasive Species 

And when can you ignore that rule of thumb completely? With invasive non-native species. If you are harvesting Himalayan Blackberry roots in coastal areas, for example, dig up as much as you want. Or maybe you want to harvest Japanese Knotweed – then have at it and take it all if you can. In both cases odds are pretty high that the population will still return with a vengeance the following year. Again though, know your plant ID before you do this! Be absolutely certain you know what you are harvesting.

What is The Difference Between an Introduced and Invasive Species?

There are introduced species all over the globe, and many have ‘naturalized’ and, in theory, reached a balance in our ecosystem and are not currently threatening native species. Take dandelions, for example, that mostly live in lawns that have already displaced native species. The dandelions feed our bees providing flowers that were otherwise replaced by lawns. Invasive species are aggressive and are currently outcompeting our native species for resources. Invasive species vary from region to region; check with your local Invasive Species group about the problem species in your area.

How to Ethically Wildcraft

So how exactly do you go about ethically wildcrafting for personal use? It depends on what you are looking for. Here is what I used to teach my students in my class for each situation. If you have another request I have not covered here or want further clarification, then please Contact Me, and I will add it to the list!  

General Ethical Wildcrafting Tips:

  • Know your plant identification! I cannot stress this fact enough. Use a field guide, the internet, and my new Native Plant of the Week Blog to help aid you in your identification. Never ethically wildcraft a plant if you are not 100% certain of its identification.
  • Do not harvest anything when wet. Wait until the sun has dried the rain or dew off the plant before harvesting. This helps prevent rotting and molding.
  • Do not harvest in the heat of the day – the quality of your harvest will be poor. Harvesting a plant that is heat-stressed is also much more likely to damage the plant.
  • When wildcrafting, it is best to place your harvest either in an open basket or loosely into paper bags. The paper bag method works well when you are wildcrafting multiple things so that you can keep them all separated. Leave the bag open on top. Or, if you must close it deal with them as quickly as possible to prevent molding. 
  • Be sure the area you are harvesting from is either public land or private land that you have permission to wildcraft from. Never go ethically wildcrafting in a protected area or park of any kind.
  • Be sure the area you are harvesting from is free of environmental toxins. For example, do not wildcraft from an area downslope from a garbage dump. Also, avoid any sources of industrial discharge, whether solid, liquid, or water. Finally, the side of a busy highway is not recommended due to contaminants from vehicle exhaust. I have wildcrafted from the side of a quiet paved or dirt logging road before, though, since there is much less traffic there.
  • If the plant you are wildcrafting is poisonous (for example, Datura discolor or Phytolacca americana), even mildly so, wear gloves while harvesting to prevent absorption through the skin. Also, place the harvested parts into a paper bag labeled TOXIC IF INGESTED. While drying the plant parts, place another label on the tray with them so that it is clear, and again on the jar the dried product is stored in. Even if you think you are the only one using it, you never know when someone might come along and want to try something, maybe thinking it is something else, and they end up violently ill or worse. Also, of course, keep any toxic plants well out of reach of children.

The Essential Ethical Wildcrafting and Plant Propagation Tool Kit

I put my paper bags, digging tools, cutters, knife, alcohol, gloves, containers, and Sharpies in a tool bag that I took from a drill. I just leave it in the car, so it’s always there with me anywhere I go. I use this for wildcrafting medicinal herbs as well as wild seeds for plant propagation.

Tools You Should Have: 

  • Gloves for digging or to deal with prickles, spines, and thorns. Also, you may want gloves if you plan on handling any poisonous plants.
  • Sharp knife for cutting roots, tough leave stalks, flower stems, or bark
  • Container of wood ashes to seal wounds
  • Paper bags and or baskets to put your goods in
  • Sharpie felt or pen to write on your bags what, when, and where you wildcrafted it from
  • Digging stick for roots. A digging stick is a short, sturdy, pointy stick that will not break when you start sticking it in the dirt and scraping the ground with it. I usually just pick one up along the way. Never use a shovel for digging roots. Shovels are indiscriminate and will cut through everything, including what you are harvesting and what you intend to leave behind.

Specific Ethical Wildcrafting Tips:

Ethically Wildcrafting Flowers

Arnica latifolia plant with lots of flowers on it. This was in an area with many other plants so you could easily pick a few flowers from each plant.
Arnica latifolia plant with lots of flowers on it. This was in an area with many other plants so you could easily pick a few flowers from each plant.

If you are ethically wildcrafting flower heads, then harvest using the 1 in 10 for introduced non-invasive plants and 1 in 20 rule for common native plants. However, with a modification. Instead of 1 in 20 plants, I recommend 1 in 20 flowers. If there are only a few plants or a single plant, then leave them be. If there is a field of flowers, then use the 1 in 20 rule, but spread your harvest around. Never pick all the flowers from a single plant. Instead, pick a few here and a few there until you have what you need. Please always follow the 1 in 20 rule for native flowers like Arnica latifolia, for example. If it is an introduced species such as St John’s Wort, for example, you can always pick more. And, of course, if you are picking invasive plants, then by all means, pick to your heart’s desire. But always know your plant identification!  

To harvest, pick the flowers by pinching off the heads at the base. For those attached to tough stalks, you can use a knife to sever it from its stem. Never pull out the whole flower stalk, as you may damage the rest of the plant. Place your flower heads loosely in a paper bag or a basket. As soon as you get them home, dry them on a drying rack, an old window screen, or a table surface but be sure to turn them once a day to prevent molding. Once dry, store the heads in a glass jar until they are ready to use.

Ethically Wildcrafting Leaves

Wildcrafting leaves is easy - pick them from the branches and put them in bag or basket
Leaves of Populus tremuloides; photo from Edgewood, BC, Canada. Leaves on large trees are numerous, making it easy to get what you need from 1-2 trees.

Leaves are best wildcrafted before the plant puts its energy into flowering. So, this means either spring or early summer, depending on the plant. Again use the 1 in 20 rule of ethical wildcrafting for leaves as you would flowers. Do not pick all the leaves off a single plant, or it will not be able to photosynthesize and complete its life cycle. Usually, you can simply pluck off the leaves by pinching them at the base with your fingers. Occasionally you will need a knife to cut off leaves with large or tough leaf stalks.

After picking, place the leaves loosely in a paper bag or a basket. Do not pack them in tightly. When you get them home, dry them in a single layer on a rack, screen, or table (turn daily if there is no ventilation). Once dry, store them in a glass jar. I recommend not crushing them too much until you are ready to use them. When you grind or crush them, it increases the surface area, which degrades the leaves faster than if left whole or in larger pieces.

Ethically Wildcrafting Needle-Like Leaves 

Wildcrafting of needle-like leaves - Picea engelmannii. Simply plug some off of each branch until you have enough
Harvesting of needle-like leaves – just pluck some needles from each branch until you have enough.

These are the same as regular leaves, only easier as they can be easily plucked from the branch. Using the 1 in 20 rule of ethical wildcrafting would be challenging if you had to count the needles, so there is a better way. Simply put, never strip the whole branch. Instead, take a small handful from each branch until you have enough.

Pluck your needles from the branch and place them in a paper bag. Then dry them on a rack or screen. Leave them for a couple of weeks until they are truly dry. Being tough and resinous, they may appear dry but are not until they become brittle. From there, they can be stored in a glass jar or used right away. 

Ethically Wildcrafting Aerial Parts 

Harvesting aerial parts is easy, you simply cut the entire stem at its base and hang them upside down to dry - eg - Yarrow
Harvesting aerial parts is easy – you can take the whole stem and dry them upside down in small bunches.

If you are picking the whole stem and flowers, then you can follow the same rule as for flowers and leaves. Use the 1 in 20 rule of ethical wildcrafting by picking 1 in 20 stems in the population and spreading your harvest around. These are the easiest things to harvest because you take the whole stem.

When harvesting the whole stem, always use a knife to cut it from near the base of the plant. Never pull the whole stem out, or you could damage the entire plant, and it may not return the following year or complete its annual life cycle that year.  

You can bunch your stems together and tie them with a string or elastic band to hang dry. Be sure your stem bases are not covered with leaves that will rot and mold. If they are, remove the leaves and dry them separately. Alternatively, simply reduce the number of stems in your bunch significantly. Generally speaking, never put more than 10 stems in a bunch, sometimes less.  Once dry, you can cut them into shorter sections (but not too small!) and store them in a glass jar until you are ready to use them. As with leaves, do not grind or crush them until you are ready to use them.

Ethically Wildcrafting Berries, Drupes, Nuts, or Other Fruits

Fruits of Fragaria virginiana from my yard in Edgewood, BC. We had lots of these plants so I could pick quite a few berries and still left lots for the birds and other wildlife.
Fruits of Fragaria virginiana from my yard in Edgewood, BC. We had lots of these plants so I could pick quite a few berries and still left lots for the birds and other wildlife.

These are usually easy to pick; we all know how to pick berries and fruits. Please keep in mind that wildlife often depends on these fruits for survival. So be sure to follow the 1 in 20 rule and spread your harvest around so you do not remove all the fruits from a single area.  

After picking, place your fruits in a bowl or container if they are particularly juicy. Drier fruits like nuts or juniper berries (not technically an actual berry, botanically speaking!) can be placed in a paper bag. Fruits can be frozen or dried using the drying rack or screen method. You could even use a food dehydrator if they are particularly juicy. Do not use a table or cookie sheet, as berries and fruits can mold quickly.  Once dry, store them in a glass jar.

Ethically Wildcrafting Seeds

Wildcrafting seeds - make sure your plant is full mature, then pluck the seeds, or their vessels, and put them in a bag to further dry before sorting them and storing them. This is Chilopsis linearis (Desert Willow)
Wildcrafting seeds – make sure your plant is full mature, then pluck the seeds, or their vessels, and put them in a bag to further dry before sorting them and storing them. This is Chilopsis linearis (Desert Willow)

When ethically wildcrafting seeds for medicine, be sure the plant has fully matured. This is usually in the later summer or in the fall when the leaves have started to die back a little. You want to make sure they are fully ripened before harvesting. Simply pick the seeds, again roughly following the 1 in 20 rule for seeds. Spread your harvest around, being sure to leave seeds on the plant or the ground where they would have naturally fallen.

Once picked, place the seeds into a paper bag and then dry them on a drying rack or screen at home. If they are contained in pods of some kind and the pods are easy to open, you can do this right away. Sometimes though, you may need to dry them first in order to crush the ‘container’ holding the seeds. Once dried and any pods etc., are removed, they should be stored in a glass jar.

Many already dry seeds not contained in a pod or other coating can be left in the paper bag. In the case of dry seeds, simply give the paper bag a shake once in a while to be certain they dry completely.

Ethically Wildcrafting Rose Hips

Wildcrafting Rose hips - simply pluck them off and process them before drying. Rosa nutkana; photo from Sechelt, BC, Canada.
Wildcrafting Rose hips – simply pluck them off and process them before drying. Rosa nutkana; photo from Sechelt, BC, Canada.

These must be wildcrafted in the early fall after they have matured but before the fall rains start the molding. If you wait too long, they also tend to get a lot of bugs in them. As always, follow the 1 in 20 rule of ethical wildcrafting and pluck them from the bushes by pinching them off at the base with your fingers. They can be picked and placed into a basket or a paper bag. Bring them home and process them immediately.

When processing rose hips, I always cut them in half or even quarters, as they can often be quite large. Because they are large, they dry slowly, making them prone to rotting. Also, once dry, they are very tough and almost impossible to cut, making them difficult to use later on. Once dried, store them in a glass jar until ready for use.

Ethically Wildcrafting Roots, Rhizomes & Bulbs

Roots of all kinds are generally best ethically wildcrafted in fall or spring. When digging roots from a fibrous root plant or a rhizome plant, try to harvest some of the roots without killing the whole plant. You can do this by gently digging around the base of the plant with your hands or a digging stick. Never use a shovel, or you will unintentionally damage other roots and sometimes other plants. If the plant has a taproot or a bulb, there is usually no way to save the plant, in which case, follow the 1 in 20 rule for whole plants.

Do not wash your roots unless they are already wet and muddy when harvesting, then quickly rinse them. Usually, however, simply brush the dirt off the roots. Then place them on a drying rack or a screen. If they are dirty, then wait a day or so, then brush them again to remove any remaining dirt. At this stage, you usually also want to cut your medicinal roots into more manageable pieces before allowing them to finish drying. Roots usually become incredibly tough and difficult to cut once allowed to dry fully. Once dried, store the cut pieces in a glass jar.

If harvesting bulbs or other roots for edible use, such as Lilium columbianum for example, once you bring them home and clean them off, they should usually be processed within a few days to ensure freshness and prevent mold from destroying your harvest.

Ethically Wildcrafting Root Bark

Follow the same rule when ethically wildcrafting roots in that you should not dig up the whole plant. For example, when I harvest Devil’s Club root bark, I dig gently around the base of the plant with my hand or a digging stick. Then I find a nice single root and sever it with a sharp knife, just a bit away from the base of the plant. If available, I rub ashes on the wound on the plant side to help prevent infection. Then I dig out the rest of the root and bring it home with me.  

When processing your root bark, brush the dirt off the root. Sometimes you may need to allow it to dry for a day first, if necessary, to remove all the dirt. Then before it dries out completely, take a sharp knife and scrape the bark from the woody root. Place these shreds of bark on a drying rack or screen and allow them to dry completely. Once dried, store the shredded bark in a glass jar. I like to save the twisted pale wood from the root for plant stakes in my houseplants or simply for decoration. 

Ethically Wildcrafting Bark

This Culturally Modified Tree is a very ancient Yellow Cedar (Cupressus nootkatensis) that had bark harvested long ago by the Salish people on the Sunshine Coast of BC, Canada. Bark harvesting is permanent, but notice how they only took a couple of strips and the tree is still alive.
This Culturally Modified Tree is a very ancient Yellow Cedar (Cupressus nootkatensis) that had bark harvested long ago by the Salish people on the Sunshine Coast of BC, Canada. Bark harvesting is permanent, but notice how they only took a couple of strips and the tree is still alive.

I typically do not encourage the wildcrafting of bark because of the permanent damage it does to the tree. The tree above is what you call a Culturally Modified Tree. It is a very cool ancient (over 1000 years) old-growth Yellow Cedar (Cupressus nootkatensis) that had some of its bark harvested long ago, possibly hundreds of years ago, by the Salish people on the Sunshine Coast of BC, Canada. It shows you that bark harvesting is permanent. But notice how they only took a couple of strips, and the tree is still alive. However, if it is common, short-lived, weedy, and especially if it is non-native and invasive, then by all means, please do. Sometimes, if a tree has lots of branches, you can cut off a small branch and harvest all of the bark off that branch rather than the trunk of the tree.

It is best to ethically wildcraft bark in the spring when the shrub or tree is in its active growing season. It grows new bark from spring to summer, making it easier to harvest and less damaging to the tree. The bark is easy to harvest, especially bark that peels vertically up the tree. Put a slice in the bark a little way up from the base (but never right at the base). Then grab the edge of that slice with your knife or hand and pull it up, stripping it off the tree. Never take more than 1 strip off a single tree, and use the 1 in 20 rule for the plant population. Cut your bark into manageable pieces the same day of harvest, then dry them on a drying rack or screen. 

Note that if the bark peels horizontally, be very careful, cutting each side; never strip as you would vertical bark. If you ‘ring the tree’ in that you remove a horizontal patch all around the tree, the entire tree will die. Trees are really only ‘alive’ in their inner bark. The heartwood no longer grows or transports water or nutrients. If you remove its living bark from all around the tree, it will no longer be able to transport water or nutrients. 

Ethically Wildcrafting Plant Resin

To wildcraft resin blisters pop the blisters or gently scrape them off the bark. This is Abies amabilis, photo from Spipyus Provincial Park, BC, Canada
To wildcraft resin blisters, pop the blisters or gently scrape them off the bark. This is Abies amabilis, a photo from Spipyus Provincial Park, BC, Canada

Resin usually seeps from scars in the bark, or in some cases, the trees produce blisters of resin under their outer bark, as in the Abies amibilis shown above. Sometimes, you can obtain the resin from the fresh buds of a tree in spring before they produce new leaves. In most cases, it is collected in the spring. But resin blisters under the bark can be harvested anytime.

To wildcraft resin, you can scrape it off the tree from scars already in the bark. Or you can create slits in the bark to release resin and come back a few days later to collect it. When cutting bark to release resin, this must be done in the spring. With fresh buds, simply pick them off the tree in the spring following the 1 in 20 rule. For resin blisters, do the same; pick off 1 in 20 blisters. Place your resin into a glass jar. Buds can be placed in a basket or bag. I recommend you collect resin with your bare hands because if you use gloves, you will likely never get them clean again. I use my bare hands and then clean them with vegetable oil and orange or lemon essential oil that will cut through the resin.

Storage is easy for straight resin (not buds – see below). Simply leave your resin in the glass jar until you are ready to use it. To keep it extra fresh, I store it in the fridge until I am ready to use it. It can often last a couple of years stored that way. If harvesting buds, however, these could be prone to molding or rotting. So with buds, you would want to dry these on a screen as you would flowers, bark, leaves, etc.

Ethically Wildcrafting Lichens 

Usnea spp lichens on windfall in the forest make it easy to follow the rules of ethical wildcrafting. Simply find a downed branch or tree and harvest from that. These would eventually die on the forest floor anyway, but do not take them all! Some animals use these as a source of food.
Usnea spp lichens on a windfall in the forest make it easy to follow the rules of ethical wildcrafting. Simply find a downed branch or tree and harvest from that. These would eventually die on the forest floor anyway, but do not take them all! Some animals use these as a source of food.

Most lichens can usually be harvested any time of year since they don’t really ‘go to seed’ and usually have multiple dormant cycles throughout the year. When harvesting, choose a large healthy population and follow the 1 in 20 rule of ethical wildcrafting. Whenever possible, with lichens that grow in trees, choose specimens that have already fallen to the forest floor. Alternatively, find a recent blowdown tree and ethically wildcraft from that. Because these are epiphytes with multiple dormancy cycles, they can remain healthy and viable on the floor for months or even years. Leave the tree lichens in the living trees to continue growing and spreading.

After collecting the lichens, dry them on a rack or screen. Once dry (when it becomes brittle to the touch), they can be stored in a glass jar. When ready to use, simply pulverize in a blender or a coffee grinder. The powder will separate from the hyphal threads, which can then be sifted out using a fine-mesh strainer.

Ethically Wildcrafting Mushrooms

Never harvest mushrooms unless you know EXACTLY what is is. This pretty mushroom is Galerina marginata, aka Funeral Bell. It is delay poisonous, containing the same poisons as the Deathcap mushroom.
Never harvest mushrooms unless you know EXACTLY what is is. This pretty mushroom is Galerina marginata, aka Funeral Bell. It is delay poisonous, containing the same poisons as the Deathcap mushroom.

These obviously must be harvested in the mushroom season, which is usually, but not always, in the fall. Be sure you are spot on with your identification when harvesting for human consumption; some mushrooms, like the pretty ones in the picture above, can be lethal if ingested.

Pick the mushrooms by gently snapping them off at the base. Please follow at least the 1 in 10 rule. Many unethical harvesters go in and clear out the entire patch because they believe they will just keep coming back. This is true to a point because most of the fungus by far is located beneath the ground. The mushroom is the equivalent of a flower on a large plant. However, over-harvesting repeatedly from the same patch will degrade the mycelial network beneath the soil. Also, repeated trampling on the dirt above the ground will also damage the fungus below the ground. 

After picking the mushrooms, brush any dirt or debris off and use them immediately when used for culinary purposes. When they are for medicinal purposes or long-term storage of edible mushrooms, they should be dried. Smaller mushrooms can be dried whole on a rack, screen, or on low heat in a dehydrator. Larger mushrooms should be either sliced or diced before drying to make them easier to use at a later date. Once dried, store them in a glass jar.  

Conclusion

Now you have the tools and skills that you need to go out and ethically wildcraft your own ingredients to make natural medicines. Please be ethical, be educated, and be safe. And most of all, know your plant ID! Happy ethical wildcrafting! 

If you have any questions, please do not hesitate to ask, Contact Me and I will do my best to reply within 48 hours.

References and Resources

Dictionary of Botanical Terms: Lyrae’s Nature Blog Dictionary of Botanical Terms is now online.

Eflora – for more information on plant identification for North America: http://www.efloras.org/browse.aspx?flora_id=1

Emerson, Lyrae 1998. Ethical Wildcrafting. Unpublished Booklet from a course on Ethical Wildcrafting taught by Lyrae Emerson (Willis) from 1998-2009.

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


Oplopanax horridus Devil's Club - Native Plant of the Week

Oplopanax horridus Devil's Club plant with flowers
Oplopanax horridus Devil’s Club plant with flowers

Native Plant of the Week – Devil’s Club – Oplopanax horridus

Introduction

Devil’s Club, Devil’s Walking Stick, or Oplopanax horridus, has long been one of my favorite native plants. I have spent many hours in the forest over the years admiring the leaves in the dappled sunlight reaching them through the forest canopy. It is a plant to be respected, in part because of its large size and its beautiful leaves. In part because of its powerful medicinal properties. Also, it should be respected because of its nasty, irritating spines you do not want in your skin. Once pricked it can sting for up to 48 hours or even more if they spines remain in your skin. I do not go near this gorgeous plant with a good pair of leather gloves. The ‘nastier’ and more unique a plant is, however, the more I respect it. Devil’s Club are tough, tenacious, patient, and almost magical plants. I think I understand why some native Americans used it in ceremonies.

For more than 20 years I have been ethically wildcrafting the bark of the roots to make medicines with. The medicinal properties of this plant are quite strong and the bark is very effective in treating a number of ailments. If you do harvest any of this unique and somewhat rare native plant, please do so ethically. See Traditional or Other Uses and the Ethical Wildcrafting sections below for more information. If you have any questions please feel free to Contact Me for more information.   

Description of Devil’s Club Oplopanax horridus

Leaves & Stem

Large palmate leaf of Oplopanax horridus
Large palmate leaf of Oplopanax horridus

Oplopanax horridus is commonly known as Devil’s Club or sometimes Devil’s Walking Stick. It is a member of the Araliaceae family along with ginseng and many others.  Devil’s Club is a large understory shrub 1 to 3 m tall, erect to somewhat sprawling. It frequently falls prostrate on the ground and roots from its fallen stems. It also spreads vegetatively through its spreading rhizomes, often producing clonal patches. The stems are all very densely covered with sharp spines that can be very irritating when they pierce the skin. The irritation, once pierced in the skin, can sometimes last for several days.

Devil’s Club has large palmate leaves (lobed maple-like leaves) with from 5 to 13 lobes on each leaf. The leaves may have spines along the leaf veins on both the upper and lower surfaces. The leaves have long petioles and are notched at their base where the petiole attaches. They are arranged on the stem spirally and are usually very large, anywhere from 15 – 45 cm across.   In the fall its large leaves turn yellow and drop off before winter, returning in early spring the following year.

Flowers & Fruit

In spring Devil’s Club produces 10 – 20 cm diameter dense pyramidal compound racemes of umbels of small greenish-white flowers. Each small bisexual flower has 5 greenish-white petals. 

These are followed by clusters of small round red drupes (a fleshy fruit with a hard pit) about 4 – 7 mm in diameter.  Even though it produces seeds in its drupes, more often it produces populations of clones that grow from spreading rhizomes.

Similar Species Frequently Confused With

Devil’s Club is a unique shrub of the Araliaceae family that is hard to confuse with other species. Between the large spiny leaves, the spiny stems, and the pyramidal umbels of flowers and drupes it would be difficult to misidentify. However, when the flowers and berries are not present, the leaves could superficially be mistaken for the following species:

  • Ricinus communis – the Castor Plant of the Euphorbiaceae family is an invasive species making its way into the Pacific Northwest of USA and western Canada. It has large palmate leaves and terminal pyramidal flower clusters like Devil’s Club but is entirely lacking in spines and is monoecious rather than bisexual.
  • Heracleum maximum – Giant Cow Parsnip of the Apiaceae family– an invasive species widespread throughout the range of Devil’s Club with large palmate leaves. However this is a herbaceous perennial with soft stems, not woody, and also lacks the spines. Its flowers are also large white umbels not the terminal pyramidal clusters seen in Devil’s Club.
  • Acer macrophyllum – Big Leaf Maple of the Sapindaceae family in a shrub or small tree size could at a distance look similar, but it lacks the similar flowers and has no spines at all.
  • Ribes bracteosum – while the Rosaceae family member sometimes can bear small thorns it lacks the large spines seen in Devil’s Club, its leaves are also more of a medium size palmate variety, and the flowers are completely different.

Habitat & Growing Conditions of Oplopanax horridus

Devil’s Club is an indicator species for wetlands and old growth forests as these are its preferred habitats. It can be found in damp forests, riparian areas, as well as coniferous and mixed forests throughout its range. Because it prefers moist, dense forests with little or no disturbance this makes them sensitive to logging and other human impacts. It prefers cool conditions from low to subalpine elevations.

Devil’s Club grows in rich, loamy soils that are consistently moist. It can tolerate seasonal flooding and waterlogged soils. It prefers full shade but can grow in part shade if the conditions are right. It will not grow well in full sun and patches often slowly die when exposed to the forest edge by logging or development.

Growing Devil’s Club in Your Garden

Since Devil’s Club is fond of damp forests it may be difficult to grow in your yard unless you have forested or otherwise somewhat shady spaces on your land. It will not grow in full sun. You can buy seeds online through the Amazon Affiliates link at the bottom. If you have shady damp forest then it will be easy to grow, simply plant young plants or seedlings in the damp shady forest, be sure to water them if it gets too dry and feed it lots of organic compost as it gets started. After that, leave it alone and it will do well.

If you do not have a forest or have a dry forest but still want to try growing it here are some things you could try. Be sure the location is at least in partial shade, never full sun. If it is in a drier forest what you can do is dig a depression into your chosen location and fill it with lots of organic compost. Compost holds moisture very well and the depression will collect the water you give it as well as rainwater that falls naturally. The idea is to create a spot for water to collect to create a more moist micro-climate. Then plant your plants or seedlings in the depression and check on them periodically to make sure they do not dry out too much. Do not keep them waterlogged all the time either, they just need to be moist.

If you have shade and no forest you can do the same as above, create a small depression somewhere in part shade. If the soil is poor remove about 50 cm at least of soil and fill it with humus-rich topsoil or a mix of soil with lots of organic compost. Then plant the Devil’s Club there. If there is not too much sun it will still grow outside of a forest setting. The key is to plant it and leave it alone as it does not like to be disturbed or fussed over in any way.

Wildlife Values of Devil’s Club

Bears are known to eat the berries of Devil’s Club and slugs will feed on the leaves. Otherwise due to the spines most animals leave them alone.

Distribution of Oplopanax horridus

Devil’s club is endemic to northern North America, being found nowhere else in the world. The genus Oplopanax does contain two other species but these are both found in Eastern Asia.

In Canada, the Devil’s Club is native to BC, Alberta, and the Yukon Territories with a disjunct distribution with a much smaller isolated population on two islands of Lake Superior in Ontario. 

In the USA it is native to the Pacific Northwest in Washington, Oregon, Idaho, Montana, southcentral Alaska, and also with an isolated population in Michigan on one island of Lake Superior on the USA side of the border. 

Status of Oplopanax horridus

Oplopanax horridus conservation status is considered Globally Secure (G5).

Currently, however, it is only considered Secure in British Columbia, Canada and Montana, USA. Locally in Canada in the Yukon Territories and Alberta, it is considered Vulnerable (S3). In the USA in Alaska, Washington, Oregon, and Idaho it is currently unranked.

The isolated population on the three islands in Lake Superior is considered Critically Imperilled (S1) in Ontario, Canada, and Imperilled (S2) in Michigan, USA.   

Traditional or Other Uses of Devil’s Club

The Devil’s Club has a very long history of use by First Nations peoples of the Pacific Northwest.  It was used in many ceremonial and medicinal ways. 

Devil’s Club as Food

The Oweekeno boiled the young spring buds and ate them as food.

Ceremonial Uses of Devil’s Club

The spines were used by the Bella Coola to ward off evil spirits. Gitzgan, Wet’suwet’en, and Haisla chewed the root bark as part of a pre-hunting purification ritual. The Kitasoon bathed in an infusion before hunting to remove the human smell. Haisla and Hanaksiala used it in purification ceremonies. Makah medicine men used it in their ceremonies.

The Haisla made the ashes of the wood into a ceremonial face paint for their warriors. Haisla and Hanaksiala used the ash mixed with salmon roe as a face paint for dancing. Their shamans would also use it to expel evil spirits from their patients. Nitinaht used the wood ash as a face paint to make their ceremonial dancers more powerful. The Lummi also used the ash mixed with grease as a face paint. They also used an infusion to cleanse the area where people had died.

The Haisla and Hanaksiala used the bark as a good luck charm by hunters, fishers, and shaman. Kwakiutl used it for protection and its magical powers. Tsimshian shamans, novices, and warriors used it for power.

The dried bark powder was used by the Green River Group as a deodorant. Haisla and Hanaksiala used an infusion of the bark after bathing.

Devil’s Club as Tools

The Clallam, Makah, Klallam, and Nitinaht people used the wood for fishing lures of various kinds. Hesquiat used the wood for fishing lures and for spearing octopus.

The Hesquiat used bark and berries as paint for baskets and other objects.

Medicinal Uses of Oplopanax horridus

Internal Uses of Devil’s Club

It is usually the root bark that is used medicinally, but occasionally the berries or leaves are also used. The Bella Coola, Haisla, Nitinaht, and Gitzgan used a bark decoction internally it to treat rheumatism (arthritis). The Gitzgan, Cowlitz, Haisla, Hanaksiala, Okanagan-Colville, Oweekeno, Sanpoil, Wet’suwet’en, and Green River Group took it internally for colds, coughs and bronchitis.

The Bella Coola, Gitzgan, and Carrier used the the bark as an emetic and purgative, either chewed or taken in hot water. Gitzgan, Okanagan, Oweekeno, Thompson, Wet’suwet’en, and Haisla took an infusion as a tonic or blood cleanser. The Haislan and Hanaksiala sometimes made an infusion with sea water and used that as a powerful emetic.

The Gitzgan took it internally for stomach pain and ulcers as well as flu and for gonorrhea. Haisla, Hanaksiala, Okanagan, Thompson, and Kwakiutl used a decoction internally for stomach problems and as a laxative. The Thompson also used it as a dietary aid to stimulate appetite, curb weight loss, and treat ulcers. Wet’suwet’en used the decoction to treat the flu.

The Gitzgan, Wet’suwet’en and Haisla also took it with other herbs internally to treat cancer. Gitzgan, Haisla, Wet’suwet’en, and Thompson took it with other herbs for diabetes. Kwakiutl, Skagit, Okanagan-Colville, Gitzgan, Haisla, and Wet’suwet’en took it as a decoction for tuberculosis. Gitzgan, Haisla, Wet’suwet’en, Nitinaht, and Thompson took it with other herbs broken bones or other problems related to bones. Skagit used a decoction after childbirth as a gynecological aid.

External Uses of Devil’s Club

The Carrier, Oweekeno, Coast Salish, and Kwakiutl used the bark as a poultice and took it internally as an analgesic for pain. The Cowlitz, Haisla, Hanaksiala, Makah, Nitinaht, Oweekeno, Coast Salish, Wet’suwet’en, and Gitzgan used it externally in a wash or a poultice for arthritic joints and rheumatism. The Coast Salish used the prickly spines on the skin as a counter-irritant for pain. Kwakiutl used it in a steam bath as an analgesic for pain. The Gitzgan, Wet’suwet’en, and Haisla used the bark in a poultice for wounds, sores, boils, ulcers, as a skin wash, and as an antihemorrhagic. The Okanagan, Tlingit, and Thompson used the burned stems with grease as a salve for sores and pain. Lummi used the bark poultice for nursing women to stop excessive milk flow.

Haisla and Hanaksiala used a bark infusion as an eyewash, especially for cataracts. The Oweekeno mashed the berries and used it as a treatment for head lice.

The Cheyenne and Crow people mixed the bark with tobacco and smoked it as an analgesic for headache.

Modern Uses of Devil’s Club as Medicine

Modern pharmaceutical applications include the use of it to treat tuberculosis.  Herbalists use Devil’s Club for coughs, colds, and as an analgesic. Personally, I have been making it into tinctures for respiratory infections and flu for over 20 years. I used to make a popular salve with it among other ingredients, that I sold under my own company label used for first aid, fungal and viral infections. 

Ethical Wildcrafting of Oplopanax horridus for Medicinal Use

If you do harvest the root from the wild please keep in mind it is a slow-growing plant whose range is decreasing. Alternatively grow it in your garden if you live in an area where it is native especially. See the Growing Devil’s Club in Your Garden section above.

Please always follow Ethical Wildcrafting guidelines when harvesting any plant from nature. Choose a large healthy population, not located in a protected area. Try to always only harvest from one plant near the outside of the population, and never dig up the whole plant. And always follow the 1 in 20 rule of ethical wildcrafting.

Wildcrafting and Processing

Wear gloves when working with Devil’s Club as the thorns are very irritating. I like to use leather gloves that are also waterproof (see Resources below) because the leather protects your skin and being waterproof is a benefit as Devil’s Club usually grows in wet or moist environments. Also, be sure you have a good quality, sharpened knife for cutting the roots to prevent causing unnecessary damage to the plant. I always like to bring my survival knife with me for projects like this because then it serves a dual purpose. I suggest a decent, affordable one in the links below.

Gently dig around the base of a single plant with your hands or a digging stick. Never use a shovel or you will damage other roots. Find a nice root and sever it with a clean sharp blade. Once severed it is best to seal the wound with ashes to prevent the root from getting infected.  Then take the root home, brush the dirt off (do not wash it), and scrape off all of the bark. The bark is what contains the most medicinal compounds.

Dry the bark and use it in infusions in teas or salves, or make it into long-lasting alcohol-based tinctures. I have always saved the wood from the root and put it in my plant pots to hold trailing stems or simply for decoration. I did this out of respect for the plant and not wanting to waste any part of it.  

References and Resources

Canadensys Plant Search https://data.canadensys.net/vascan/search

Dictionary of Botanical Terms – by Lyrae’s Nature Blog https://lyraenatureblog.com/blog/dictionary-of-botanical-terms/

Native American Ethnobotany http://naeb.brit.org/

Natureserve Explorer https://explorer.natureserve.org/Taxon/ELEMENT_GLOBAL.2.148842/Oplopanax_horridus 

Pojar, Jim; Andy MacKinnon (1994). Plants of Coastal British Columbia. BC Ministry of Forests and Lone Pine Publishing. p. 82

USDA Plants Database https://plants.sc.egov.usda.gov/home

Wikipedia https://en.wikipedia.org/wiki/Devil’s_club

Willis, Lyrae (2021).  Plant Families of North America.  Not yet published.

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


Are Common Cattails Typha latifolia Really an Invasive Species?

Illustration 1: Typha latifolia - Lyrae Willis photo from Michigan, USA. You can tell this is Typha latifolia because there is no space between the smaller male flowers and the larger female flowers on the inflorescence spike.
Illustration 1: Typha latifolia – Lyrae Willis photo from Michigan, USA. You can tell this is Typha latifolia because there is no space between the smaller male flowers and the larger female flowers on the inflorescence spike.

Are Common Cattails Typha latifolia Really an “Invasive Native Species?”

Summary 

If common cattails, Typha latifolia, can be used to treat wastewater and restore degraded marshes and wetlands, then human perceptions of this native invasive species should change. Although Typha spp are indeed native to North America and much of the world, they are often considered invasive due to their tendency to form large monocultures, something that has been on the increase over the last century in North America. Cattails are unique in adapting to high nutrient and metal concentrations without suffering negative effects. In fact, Typha spp has been shown to increase growth under conditions most other plants find toxic. They also remove toxins and excess nutrients, cleaning the water in the process. Humans have drained so many wetlands, more than 90% in most urbanized areas. The few wetlands that remain are almost always subjected to drastic changes in both water quality and quantity. As a result, we have created conditions for the cattail, and very few other plants, to thrive in. Perhaps instead of treating the cattail like an invasive weed, we should accept the fact that the cattail monoculture issue is simply a natural response to the unnatural degradation of our wetlands. Then we could instead focus on letting the cattails do their work of removing toxins. Simultaneously, we would need to work at restoring balance to the ecosystem. If you would like to learn more, please continue reading.   

Description and Distribution of Cattails Typha latifolia and Typha spp

Typha latifolia, the common cattail, is a native emergent aquatic species found in wetlands, marshes, ditches, ponds, and lakeshores throughout most of the world. It lives in every Canadian province and territory and south throughout the entire continental USA and Mexico. It is also found worldwide in Britain, Eurasia, Africa, India, New Zealand, and Australia. T. latifolia is a herbaceous perennial with long slender green stalks over 1 m tall topped with terminal round flower spikes. The flower spikes have male flowers on top and dense persistent female flowers beneath that are greenish when new but turn characteristically brown and fuzzy when mature. Basal leaves are thin with parallel veins that run their entire length of more than 1 m. The cattails reproduce by seeds but also readily reproduce vegetatively by clonal spreading of their thick underground roots.  

Typha angustifolia and Typha x glauca, a hybrid of T. latifolia and T. angustifolia, are two other common native cattails in North America. The other two cattails are easily separated in the field by T. latifolia’s male and female spikes that usually have no gap between them and its very robust dark brown female spike at maturity. T. angustifolia and T. xglauca’s narrower leaves and the gap between its female and male spikes differentiate them from T. latifolia. T. latifolia is also more tolerant of a wider range of conditions from tropical to cool temperate in both humid and dry climates from sea level up to 2125 m in elevation. The other two species are found at lower elevations and latitudes.

Typha x glauca has fairly broad leaves like T. latifolia cattails but it has a gap between the male and female flowers
Typha x glauca has fairly broad leaves like T. latifolia but it has a gap between the male and female flowers
Typha angustifolia has narrower leaves than other cattails and its female flowers are also smaller making a narrower spike.
Typha angustifolia has narrower leaves and its female flowers are also smaller making a narrower spike.

The Use of Emergent Aquatics like Cattails in Constructed Wetlands

Emergent aquatics, particularly Typha latifolia, have been shown in multiple studies to be effective biofilters that can help remove excess nutrients and toxins from wastewater. Emergent aquatics are important in wastewater treatment wetlands because they help stabilize the plant beds, provide filtration, surface area for microbes, slow the speed of currents, aid in sedimentation, and increase the contact time between runoff and plant surface area. Furthermore, the turnover of roots allows for better aerobic conditions and water penetration into the soil. The roots also release organic compounds that provide a food source for denitrifying microbes that are important for removing Nitrogen.

When it comes to removing toxins or excess nutrients from wetlands, laboratory studies have shown that cattails can accumulate high levels of Copper, Nickel, and Iron in their leaves and especially their roots. Those same studies found that growth was actually stimulated at moderate levels of Copper that many plants find toxic. Further studies by the same authors on Nickel and Iron showed no toxicity with concentrations five to six times higher than that of Copper. These studies show that cattails are highly tolerant of excess metals and could be a valuable tool in remediation.

The removal rates of excess nutrients and pollutants from wastewater predictably vary under the varying environmental conditions outside the laboratory. But this is useful in that constructed wetlands can be designed to optimize targeted pollutants by using a different construction design. For these reasons and its widespread native distribution, Typha latifolia is a common plant used in constructed wetlands designed to purify wastewater or as a secondary treatment for municipal sewage treatment plants. They are abundant, adaptable, provide structure, and clean the water. They truly are miraculous plants when it comes to their use in constructed wetlands.

The Invasiveness of Typha latifolia Cattails

Some people have concerns about using cattails in wetland restoration projects because they are often considered to be an invasive species. Cattails may appear invasive due to changes in water levels, wildfire suppression, excessive nutrients, or metal input which all favor cattail growth at the expense of other species. This can result in large monocultures of this native species. Typha’s ability to clone and grow rapidly also contributes to its superior competitive ability under altered environmental conditions. If, however, the wetland is a high-quality natural area, the cattails generally exist as scattered patches of plants with open water and numerous other species. This suggests that it is wetland degradation and not the cattail itself that is forming the monocultures.

Cattail marsh monoculture from Alberta, Keeler 2015 photo.
Illustration 2: Typha latifolia Cattail marsh in Alberta. Keeler, 2015.

In the case of wastewater treatment wetlands designed specifically to handle contaminated water, then the invasiveness of cattails is not an issue. Most other species would not be able to survive in the conditions of constructed wastewater wetlands anyway. Typha latifolia, on the other hand, will flourish and clean the water at the same time as providing a habitat for birds and invertebrates that use the cattails for nesting and reproduction.

This all suggests that the cattail itself is a successful opportunistic species that can adapt to a wide range of adverse conditions. While this itself does not make it invasive, it does suggest that the cattail’s inherent ability to tolerate adverse conditions is what is creating the monocultures. We are the ones who are degrading our wetlands, so we are creating the conditions in which cattails can sometimes create monocultures.

Removal of Cattail Monocultures To Restore Biodiversity

Studies of the physical removal of some of the cattails in monocultures have shown a marked increase in biological diversity in both the soil and water. These same and other studies have also shown a noticeable increase in birds, muskrats, and invertebrates. Other studies with draining and burning showed that while draining alone increased Typha cover, it also increased species diversity. If you use draining along with summer burning, it will help reduce Typha dominance while releasing nutrients and stimulating the growth of other species. This draining and burning process, because it also mobilizes nutrients, may help deal with the excess nutrient load that created the monoculture in the first place. In the case of excess metals, however, the cattails and their roots should simply be periodically removed and disposed of, removing the toxins from the system while promoting biodiversity. These methods will all work if we have eliminated or reduced the source(s) of pollutants or water changes. This may be an effective way to quickly restore the diversity that used to exist in these marshes before human disruption turned them into monocultures.

Conclusion:

In summary, Typha latifolia can be very useful both in restoration projects and in wastewater remediation. The invasiveness of cattails is not an issue if we address the disruption and pollution of our wetlands. In areas where they already are monocultures, if we correct or mitigate the source of degradation, those wetlands could easily be restored to recreate thriving and biodiverse wetlands. Furthermore, using cattail monocultures in wastewater treatment wetlands is beneficial since the cattail is very effective for wastewater treatment and few other plants will survive in those conditions. Finally, perhaps it is our perception that is what really needs to change. Instead of treating cattails like an invasive species, we should recognize why they may form monocultures. We should take responsibility for it rather than blaming this native species and trying ineffectively to control it. Instead, we should let it thrive and do its job while we work to create cleaner wetlands with less pollution and water stresses. After we have done our part either in creating cattail treatment wetlands where needed or by reducing or eliminating sources of degradation, then we can look at addressing the cattail monocultures through passive or active restoration processes.

If you want to learn more about native plants in North America, Check out my new Native Plant of the Week Blog where each week I will focus on a different native plant. You can learn how to identify it, where it is found, its conservation status, its traditional uses, and ethical wildcrafting.

And if you want to learn more about invasive species, what they are, and why we should be concerned, check out What are Invasive Species and What Should We Do About Them? Also, check out my newest blog category on Invasive Species of North America where each week, I will describe a different invasive species in North America and what we can do to help control it.

References and Resources

Ducks Unlimited. Managing your Restored Wetland. Online publication http://www.ducks.org/media/Conservation/GLARO/_documents/_library/_landowner/Freshwater_WL_Mgt.pdf

Grace, JB and JS Harrison, 1986. The Biology of Canadian Weeds. 73. Typha latifolia,Typha angustifoia and Typha xglauca. Can. J. Plant Sci. 66: 361-3’79.

Green E.K., and S.M. Galatowitsch 2001. Differences in wetland plant community establishment with additions of nitrate-N and invasive species (Phalaris arundinacea and Typha xglauca). Department of Horticultural Science, University of Minnesota. Published by NRC Research Press February 12,2001.

Keeler, Kathleen, 2015. Visiting Alberta–Cattail Marshes and Flyways. The Wandering Botanist. http://khkeeler.blogspot.ca/2015/12/visiting-alberta-cattail-marshes-and.html. December 27, 2015.

Motivans K. And S. Apfelbaum. 1987. Element Stewardship abstract for Typha spp. North American cattails. The Nature Conservancy. October 2007.

Taylor, Gregory J and A. A. Crowder, 1983. Uptake and accumulation of heavy metals by Typha latifolia in wetlands of the Sudbury, Ontario region. Canadian Journal of Botany 61: 63-73.

Taylor, Gregory J and A. A. Crowder, 1984. Copper and nickel tolerance in Typha latifolia clones from contaminated and uncontaminated environments. Canadian Journal of Botany 62: 1304- 1308.

USDA Plant Guide. Broad-Leaved Cattail Typha latifolia. USDA NRCS National Plant Data Center & Idaho Plant Material Center.

Wetlands International, 2003. The use of constructed wetlands for wastewater treatment. Wetlands International, Malaysia Office, First Edition 2003.

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!


Welcome to My Nature Blog!

Old Growth Swamp from the Coastal Mountains, British Columbia, Canada
Old Growth Swamp from the Coastal Mountains, British Columbia, Canada
Me sitting in an Old Growth Swamp in the Coastal Mountains of BC back in 2007.
Me sitting in an Old Growth Swamp in the Coastal Mountains of BC back in 2007.

Lyrae’s Nature Blog

Welcome to my first nature blog!  I created Lyrae’s Nature Blog to help me share my passion for science and nature writing.  This nature blog will cover topics such as native plants, invasive species, habitat loss, climate change, and more. I have a BSc, Honors, in Environmental Sciences, specializing first in Chemical Environmental Analysis and later in Botany and Ecology.  After my degree, I received professional certifications in Wetland Assessments, Riparian Areas Assessments, and Ecological Restoration. I have always loved science and writing scientific papers for school. Now I am venturing outside of my science bubble to try my hand at writing for a more general audience. My goal is to share some of the wonderful knowledge I have gathered along my lifelong learning journey.  

Coming soon, I will publish my first article on the use of “invasive native” cattails to help with wetland and wastewater remediation. Soon after, I will publish my first ‘Native Plant of the Week’ blog. Each week I will describe a native North American plant, provide a photo(s), its range and status, and current or traditional uses. If you have any particular requests for topics related to the environment, plants, or ecology, please feel free to contact me. 

For More Information

Please contact me if you have any questions about my articles, suggestions for specific topics, or questions about my ecological consulting and survey services. Use the contact me page to send me your information and inquiry, and I will do my best to respond within 48 hours.  

And finally, If you want to learn more about who I am, check out my Autobiography. Thank you for reading, and I look forward to sharing more soon!

Currently Seeking Funding To Continue This Non-Profit, Ad-Free Work

If you are able to donate so that I can continue this non-profit work of supplying people with scientific information on the plant families, native plants, and invasive species found throughout North America, please donate using the GoFundMe link below. Thank you!