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Venus flytrap

February 15, 2024

This article is about the plant. For other uses, see Venus Flytrap (disambiguation).

The Venus flytrap (Dionaea muscipula) is a carnivorous plant native to the temperate and subtropical wetlands of North Carolina and South Carolina, on the East Coast of the United States.[4] Although various modern hybrids have been created in cultivation, D. muscipula is the only species of the monotypic genus Dionaea. It is closely related to the waterwheel plant (Aldrovanda vesiculosa) and the cosmopolitan sundews (Drosera), all of which belong to the family Droseraceae.[5] Dionaea catches its prey—chiefly insects and arachnids—with a "jaw"-like clamping structure, which is formed by the terminal portion of each of the plant's leaves; when an insect makes contact with the open leaves, vibrations from the prey's movements ultimately trigger the "jaws" to shut via tiny hairs (called "trigger hairs" or "sensitive hairs") on their inner surfaces. Additionally, when an insect or spider touches one of these hairs, the trap prepares to close, only fully enclosing the prey if a second hair is contacted within (approximately) twenty seconds of the first contact. Triggers may occur as quickly as 110 of a second from initial contact.[6]

Venus flytrap
Leaf
CITES Appendix II (CITES)[2][note 1]
Scientific classification
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Eudicots
Order: Caryophyllales
Family: Droseraceae
Genus: Dionaea
Sol. ex J.Ellis 1768
Species:
D. muscipula
Binomial name
Dionaea muscipula
J.Ellis
Distribution
Synonyms[3]
  • Dionea Raf., spelling variant
  • Dionaea corymbosa
    (Raf.) Steud. (1840)
  • Dionaea crinita
    Sol. (1990) as synonym
  • Dionaea dentata
    D'Amato (1998) name published without description
  • Dionaea heterodoxa
    D'Amato (1998) nom.nud.
  • Dionaea muscicapa
    St.Hil. (1824) sphalm.typogr.
  • Dionaea sensitiva
    Salisb. (1796)
  • Dionaea sessiliflora
    (Raf.) Steud. (1840)
  • Dionaea uniflora
    (Raf.) Steud. (1840)
  • Drosera corymbosa
    Raf. (1833)
  • Drosera sessiliflora
    Raf. (1833)
  • Drosera uniflora
    Raf. (1833)

The requirement of repeated, seemingly redundant triggering in this mechanism serves as a safeguard against energy loss and to avoid trapping objects with no nutritional value; the plant will only begin digestion after five more stimuli are activated, ensuring that it has caught a live prey animal worthy of consumption. These hairs also possess a heat sensor. A forest fire, for example, causes them to snap shut, making the plant more resilient to periods of summer fires.[7]

Although widely cultivated for sale, the population of the Venus flytrap has been rapidly declining in its native range.[8] The species is currently under Endangered Species Act review by the U.S. Fish & Wildlife Service.[9]

Etymology

The plant's common name (originally "Venus's flytrap") refers to Venus, the Roman goddess of love. The genus name, Dionaea ("daughter of Dione"), refers to the Greek goddess Aphrodite,[further explanation needed] while the species name, muscipula, is Latin for both "mousetrap" and "flytrap".[10][11] The Latin word muscipula ("mousetrap") is derived from mus ("mouse") and decipula ("trap"), while the homonym word muscipula ("flytrap") is derived from musca ("fly") and decipula.[12][13][11]

Historically, the plant was also known by the slang term "tipitiwitchet" or "tippity twitchet", possibly an oblique reference to the plant's resemblance to human female genitalia.[10][14] The term is similar to the term tippet-de-witchet which derives from tippet and witchet (archaic term for vagina).[15][16] In contrast, the English botanist John Ellis, who gave the plant its scientific name in 1768, wrote that the plant name tippitywichit was an indigenous word from either Cherokee or Catawba.[11][17] The plant name according to the Handbook of American Indians derives from the Renape word titipiwitshik ("they (leaves) which wind around (or involve)").[18][19]

Discovery by Europeans

On 2 April 1759, the North Carolina colonial governor, Arthur Dobbs, penned the first written description of the plant in a letter to English botanist Peter Collinson.[20] In the letter he wrote: "We have a kind of Catch Fly Sensitive which closes upon anything that touches it. It grows in Latitude 34 but not in 35. I will try to save the seed here."[17][21] A year later, Dobbs went into greater detail about the plant in a letter to Collinson dated Brunswick, 24 January 1760.[22][23][24]

The great wonder of the vegetable kingdom is a very curious unknown species of Sensitive. It is a dwarf plant. The leaves are like a narrow segment of a sphere, consisting of two parts, like the cap of a spring purse, the concave part outwards, each of which falls back with indented edges (like an iron spring fox-trap); upon anything touching the leaves, or falling between them, they instantly close like a spring trap, and confine any insect or anything that falls between them. It bears a white flower. To this surprising plant I have given the name of Fly trap Sensitive.

— Arthur Dobbs

This was the first detailed recorded notice of the plant by Europeans. The description was before John Ellis' letter to The London Magazine on 1 September 1768,[11] and his letter to Carl Linnaeus on 23 September 1768,[25] in which he described the plant and proposed its English name Venus's Flytrap and scientific name Dionaea muscipula.[26]

Description

The Venus flytrap is a small plant whose structure can be described as a rosette of four to seven leaves, which arise from a short subterranean stem that is actually a bulb-like object. Each stem reaches a maximum size of about three to ten centimeters, depending on the time of year;[27] longer leaves with robust traps are usually formed after flowering. Flytraps that have more than seven leaves are colonies formed by rosettes that have divided beneath the ground.

 
Illustration from Curtis's Botanical Magazine by William Curtis (1746–1799)

Fly trap leaves

The leaf blade is divided into two regions: a flat, heart-shaped photosynthesis-capable petiole, and a pair of terminal lobes hinged at the midrib, forming the trap which is the true leaf. The upper surface of these lobes contains red anthocyanin pigments and its edges secrete mucilage. The lobes exhibit rapid plant movements, snapping shut when stimulated by prey. The trapping mechanism is tripped when prey contacts one of the three hair-like trichomes that are found on the upper surface of each of the lobes. The mechanism is so highly specialized that it can distinguish between living prey and non-prey stimuli, such as falling raindrops;[28] two trigger hairs must be touched in succession within 20 seconds of each other or one hair touched twice in rapid succession,[28] whereupon the lobes of the trap will snap shut, typically in about one-tenth of a second.[29] The edges of the lobes are fringed by stiff hair-like protrusions or cilia, which mesh together and prevent large prey from escaping. These protrusions, and the trigger hairs (also known as sensitive hairs) are likely homologous with the tentacles found in this plant's close relatives, the sundews. Scientists have concluded that the snap trap evolved from a fly-paper trap similar to that of Drosera.[30]

The holes in the meshwork allow small prey to escape, presumably because the benefit that would be obtained from them would be less than the cost of digesting them. If the prey is too small and escapes, the trap will usually reopen within 12 hours. If the prey moves around in the trap, it tightens and digestion begins more quickly.

Speed of closing can vary depending on the amount of humidity, light, size of prey, and general growing conditions. The speed with which traps close can be used as an indicator of a plant's general health. Venus flytraps are not as humidity-dependent as are some other carnivorous plants, such as Nepenthes, Cephalotus, most Heliamphora, and some Drosera.

The Venus flytrap exhibits variations in petiole shape and length and whether the leaf lies flat on the ground or extends up at an angle of about 40–60 degrees. The four major forms are: 'typica', the most common, with broad decumbent petioles; 'erecta', with leaves at a 45-degree angle; 'linearis', with narrow petioles and leaves at 45 degrees; and 'filiformis', with extremely narrow or linear petioles. Except for 'filiformis', all of these can be stages in leaf production of any plant depending on season (decumbent in summer versus short versus semi-erect in spring), length of photoperiod (long petioles in spring versus short in summer), and intensity of light (wide petioles in low light intensity versus narrow in brighter light).[citation needed]

Other parts

The plant also has a flower on top of a long stem, about 6 inches long. The flower is pollinated from various flying insects such as sweat bees, longhorn beetles and checkered beetles.[31]

  •  
    Venus flytrap flower bud
  •  
    Flowering Venus flytrap showing its long flower stem
  •  
    Closeup of flower (c. 20 mm in diameter)
  •  
    The species produces small, shiny black seeds

Habitat and distribution

Habitat

 
Map of the original distribution of the Venus flytrap

The Venus flytrap is found in nitrogen- and phosphorus-poor environments, such as bogs, wet savannahs, and canebrakes. Small in stature and slow-growing, the Venus flytrap tolerates fire well and depends on periodic burning to suppress its competition.[32] Fire suppression threatens its future in the wild.[33] It survives in wet sandy and peaty soils. Although it has been successfully transplanted and grown in many locales around the world, it is native only to the coastal bogs of North and South Carolina in the United States, specifically within a 100-kilometer (60 mi) radius of Wilmington, North Carolina.[34] One such place is North Carolina's Green Swamp. There also appears to be a naturalized population of Venus flytraps in northern Florida as well as an introduced population in western Washington.[35][36] The nutritional poverty of the soil is the reason it relies on such elaborate traps: insect prey provide the nitrogen for protein formation that the soil cannot. They tolerate mild winters, and require a period of winter dormancy to survive freezing temperatures and low photoperiods. It is a common misconception that Venus flytraps require dormancy if kept indoors under sufficient artificial light.[37] However, most professional carnivorous plant growers recommend dormancy, and Venus fly traps grown without dormancy may require more light, water, and food to remain healthy.[38]

They are full sun plants, usually found only in areas with less than 10% canopy cover.[8] The habitats where it thrives are typically either too nutrient-poor for many noncarnivorous plants to survive, or frequently disturbed by fires which regularly clear vegetation and prevent a shady overstory from developing. It can be found living alongside herbaceous plants, grasses, sphagnum, and fire-dependent Arundinaria bamboos.[39] Regular fire disturbance is an important part of its habitat, required every 3–5 years in most places for D. muscipula to thrive. After fire, D. muscipula seeds germinate well in ash and sandy soil, with seedlings growing well in the open post-fire conditions. The seeds germinate immediately without a dormant period.[8]

Distribution

Dionaea muscipula occurs naturally only along the coastal plain of North and South Carolina in the U.S., with all known current sites within 90 km of Wilmington, North Carolina.[9] A 1958 survey of herbaria specimens and old documents found 259 sites where the historical record documented the presence of D. muscipula, within 21 counties in North and South Carolina.[40] As of 2019, it was considered extirpated in North Carolina in the inland counties of Moore, Robeson, and Lenoir, as well as the South Carolina coastal counties of Charleston and Georgetown. Remaining extant populations exist in North Carolina in Beaufort, Craven, Pamlico, Carteret, Jones, Onslow, Duplin, Pender, New Hanover, Brunswick, Columbus, Bladen, Sampson, Cumberland, and Hoke counties, and in South Carolina in Horry county.[9]

Population

A large-scale survey in 2019, conducted by the North Carolina Natural Heritage Program, counted a total of 163,951 individual Venus flytraps in North Carolina and 4,876 in South Carolina, estimating a total of 302,000 individuals remaining in the wild in its native range.[41] This represents a reduction of more than 93% from a 1979 estimate of approximately 4,500,000 individuals.[8] A 1958 study found 259 confirmed extant or historic sites.[40] As of 2016, there were 71 known sites where the plant could be found in the wild. Of these 71 sites, only 20 were classified as having excellent or good long-term viability.[9]

Carnivory

 
A closing trap

Prey selectivity

A time lapse showing Venus flytrap catching prey (see more videos here)

Most carnivorous plants selectively feed on specific prey. This selection is due to the available prey and the type of trap used by the organism. With the Venus flytrap, prey is limited to beetles, spiders and other crawling arthropods. The Dionaea diet is 33% ants, 30% spiders, 10% beetles, and 10% grasshoppers, with fewer than 5% flying insects.[42]

Given that Dionaea evolved from an ancestral form of Drosera (carnivorous plants that use a sticky trap instead of a snap trap) the reason for this evolutionary branching becomes clear. Drosera consume smaller, aerial insects, whereas Dionaea consume larger terrestrial bugs. Dionaea are able to extract more nutrients from these larger bugs. This gives Dionaea an evolutionary advantage over their ancestral sticky trap form.[43]

Mechanism of trapping

See also: Plant arithmetic
 
Stages and timing of the Venus flytrap carnivory process, Knowable Magazine[44]
 
Closeup of one of the hinged trigger hairs

The Venus flytrap is one of a very small group of plants capable of rapid movement, such as Mimosa pudica, the Telegraph plant, starfruit, sundews and bladderworts.

The mechanism by which the trap snaps shut involves a complex interaction between elasticity, turgor and growth. The trap only shuts when there have been two stimulations of the trigger hairs; this is to avoid inadvertent triggering of the mechanism by dust and other wind-borne debris. In the open, untripped state, the lobes are convex (bent outwards), but in the closed state, the lobes are concave (forming a cavity). It is the rapid flipping of this bistable state that closes the trap,[29] but the mechanism by which this occurs is still poorly understood. When the trigger hairs are stimulated, an action potential (mostly involving calcium ions—see calcium in biology) is generated, which propagates across the lobes and stimulates cells in the lobes and in the midrib between them.[45][46][47]

It is hypothesized that there is a threshold of ion buildup for the Venus flytrap to react to stimulation.[48] The acid growth theory states that individual cells in the outer layers of the lobes and midrib rapidly move 1H+ (hydrogen ions) into their cell walls, lowering the pH and loosening the extracellular components, which allows them to swell rapidly by osmosis, thus elongating and changing the shape of the trap lobe. Alternatively, cells in the inner layers of the lobes and midrib may rapidly secrete other ions, allowing water to follow by osmosis, and the cells to collapse. Both of these mechanisms may play a role and have some experimental evidence to support them.[49][50] Flytraps show an example of memory in plants; the plant knows if one of its trigger hairs have been touched, and remembers this for a few seconds. If a second touch occurs during that time frame, the flytrap closes.[51] After closing, the flytrap counts additional stimulations of the trigger hairs, to five total, to start the production of digesting enzymes.[52]

 
Muscoid fly
 
Chrysomelid beetle, Paria

Digestion

If the prey is unable to escape, it will continue to stimulate the inner surface of the lobes, and this causes a further growth response that forces the edges of the lobes together, eventually sealing the trap hermetically and forming a "stomach" in which digestion occurs. Release of the digestive enzymes is controlled by the hormone jasmonic acid, the same hormone that triggers the release of toxins as an anti-herbivore defense mechanism in non-carnivorous plants. (See Evolution below)[52][53] Once the digestive glands in the leaf lobes have been activated, digestion is catalysed by hydrolase enzymes secreted by the glands. One of these enzymes includes GH18 chitinase, which breaks down chitin-containing exoskeleton of trapped insects. Synthesis of this enzyme begins with at least five action potentials, which will stimulate transcription of chitinase.[54]

Oxidative protein modification is likely to be a pre-digestive mechanism used by Dionaea muscipula. Aqueous leaf extracts have been found to contain quinones such as the naphthoquinone plumbagin that couples to different NADH-dependent diaphorases to produce superoxide and hydrogen peroxide upon autoxidation.[55] Such oxidative modification could rupture animal cell membranes. Plumbagin is known to induce apoptosis, associated with the regulation of the Bcl-2 family of proteins.[56] When the Dionaea extracts were pre-incubated with diaphorases and NADH in the presence of serum albumin (SA), subsequent tryptic digestion of SA was facilitated.[55] Since the secretory glands of Droseraceae contain proteases and possibly other degradative enzymes, it may be that the presence of oxygen-activating redox cofactors function as extracellular pre-digestive oxidants to render membrane-bound proteins of the prey (insects) more susceptible to proteolytic attacks.[55]

Digestion takes about ten days, after which the prey is reduced to a husk of chitin. The trap then reopens, and is ready for reuse.[57]

Evolution

 
Drosera falconeri, with short, wide, sticky leaf traps

Carnivory in plants is a very specialized form of foliar feeding, and is an adaptation found in several plants that grow in nutrient-poor soil. Carnivorous traps were naturally selected to allow these organisms to compensate for the nutrient deficiencies of their harsh environments and compensate for the reduced photosynthetic benefit.[58] Phylogenetic studies have shown that carnivory in plants is a common adaptation in habitats with abundant sunlight and water but scarce nutrients.[43] Carnivory has evolved independently six times in the angiosperms based on extant species, with likely many more carnivorous plant lineages now extinct.[59]

The "snap trap" mechanism characteristic of Dionaea is shared with only one other carnivorous plant genus, Aldrovanda. For most of the 20th century, this relationship was thought to be coincidental, more precisely an example of convergent evolution. Some phylogenetic studies even suggested that the closest living relatives of Aldrovanda were the sundews.[60] It was not until 2002 that a molecular evolutionary study, by analyzing combined nuclear and chloroplast DNA sequences, indicated that Dionaea and Aldrovanda were closely related and that the snap trap mechanism evolved only once in a common ancestor of the two genera.[61][62]

A 2009 study[60] presented evidence for the evolution of snap traps of Dionaea and Aldrovanda from a flypaper trap like Drosera regia, based on molecular data. The molecular and physiological data imply that Dionaea and Aldrovanda snap traps evolved from the flypaper traps of a common ancestor with Drosera. Pre-adaptations to the evolution of snap traps were identified in several species of Drosera, such as rapid leaf and tentacle movement. The model proposes that plant carnivory by snap trap evolved from the flypaper traps, driven by increasing prey size. Bigger prey provides greater nutritional value, but large insects can easily escape the sticky mucilage of flypaper traps; the evolution of snap traps would therefore prevent escape and kleptoparasitism (theft of prey captured by the plant before it can derive benefit from it), and would also permit a more complete digestion.[60][61]

In 2016, a study of the expression of genes in the plant's leaves as they captured and digested prey was published in the journal, Genome Research. The gene activation observed in the leaves of the plants gives support to the hypothesis that the carnivorous mechanisms present in the flytrap are a specially adapted version of mechanisms used by non-carnivorous plants to defend against herbivorous insects.[53][63] In many non-carnivorous plants, jasmonic acid serves as a signaling molecule for the activation of defense mechanisms, such as the production of hydrolases, which can destroy chitin and other molecular components of insect and microbial pests.[64] In the Venus flytrap, this same molecule has been found to be responsible for the activation of the plant's digestive glands. A few hours after the capture of prey, another set of genes is activated inside the glands, the same set of genes that is active in the roots of other plants, allowing them to absorb nutrients. The use of similar biological pathways in the traps as non-carnivorous plants use for other purposes indicates that somewhere in its evolutionary history, the Venus flytrap repurposed these genes to facilitate carnivory.[44][65]

Proposed evolutionary history

Carnivorous plants are generally herbaceous, and their traps the result of primary growth. They generally do not form readily fossilizable structures such as thick bark or wood. As a result, there is no fossil evidence of the steps that might link Dionaea and Aldrovanda, or either genus with their common ancestor, Drosera. Nevertheless, it is possible to infer an evolutionary history based on phylogenetic studies of both genera. Researchers have proposed a series of steps that would ultimately result in the complex snap-trap mechanism:[60][61]

  • Larger insects usually walk over the plant, instead of flying to it,[66] and are more likely to break free from sticky glands alone. Therefore, a plant with wider leaves, like Drosera falconeri,[60] must have adapted to move the trap and its stalks in directions that maximized its chance of capturing and retaining such prey—in this particular case, longitudinally. Once adequately "wrapped", escape would be more difficult.[66]
  • Evolutionary pressure then selected for plants with shorter response time, in a manner similar to Drosera burmannii or Drosera glanduligera. The faster the closing, the less reliant on the flypaper model the plant would be.
  • As the trap became more and more active, the energy required to "wrap" the prey increased. Plants that could somehow differentiate between actual insects and random detritus/rain droplets would have an advantage, thus explaining the specialization of inner tentacles into trigger hairs.
  • Ultimately, as the plant relied more on closing around the insect rather than gluing them to the leaf surface, the tentacles so evident in Drosera would lose their original function altogether, becoming the "teeth" and trigger hairs—an example of natural selection utilizing pre-existing structures for new functions.
  • Completing the transition, the plant eventually developed the depressed digestive glands found inside the trap, rather than using the dews in the stalks, further differentiating it from genus Drosera.

Phylogenetic studies using molecular characters place the emergence of carnivory in the ancestors of Dionaea muscipula to 85.6 million years ago, and the development of the snap-trap in the ancestors of Dionaea and its sister genus Aldrovanda to approximately 48 million years ago.[67]

Cultivation

 
Dionaea muscipula 'Akai Ryu', Japanese for 'Red Dragon', in cultivation

Plants can be propagated by seed, taking around four to five years to reach maturity. More commonly, they are propagated by clonal division in spring or summer. Venus flytraps can also be propagated in vitro using plant tissue culture.[68] Most Venus flytraps found for sale in nurseries garden centers have been produced using this method, as this is the most cost-effective way to propagate them on a large scale. Regardless of the propagation method used, the plants will live for 20 to 30 years if cultivated in the right conditions.[69]

Cultivars

Main article: List of Venus flytrap cultivars

Venus flytraps are by far the most commonly recognized and cultivated carnivorous plant, and they are frequently sold as houseplants. Various cultivars (cultivated varieties) have come into the market through tissue culture of selected genetic mutations, and these plants are raised in large quantities for commercial markets. The cultivars 'Akai Ryu' and 'South West Giant' have gained the Royal Horticultural Society's Award of Garden Merit.[70]

Conservation

Although widely cultivated for sale as a houseplant, D. muscipula has suffered a significant decline in its population in the wild. The population in its native range is estimated to have decreased 93% since 1979.[8][41]

Status

The species is under Endangered Species Act review by the U.S. Fish & Wildlife Service.[71] The current review commenced in 2018, after an initial "90-day" review found that action may be warranted. A previous review in 1993 resulted in a determination that the plant was a "Potential candidate without sufficient data on vulnerability".[72] The IUCN Red List classifies the species as "vulnerable".[73] The State of North Carolina lists Dionaea muscipula as a species of "Special Concern–Vulnerable".[74] The species is protected under Appendix II of the Convention on International Trade in Endangered Species (CITES) meaning international trade (including in parts and derivatives) is regulated by the CITES permitting system.[75] NatureServe classified it as "Imperiled" (G2) in a 2018 review.[76]

The U.S. Fish and Wildlife Service has not indicated a timeline to conclude its current review of Dionaea muscipula. The Endangered Species Act specifies a two-year timeline for a species review. However, the species listing process takes 12.1 years on average.[77]

Threats

The Venus flytrap is only found in the wild in a very particular set of conditions, requiring flat land with moist, acidic, nutrient-poor soils that receive full sun and burn frequently in forest fires, and is therefore sensitive to many types of disturbance.[8] A 2011 review identified five categories of threats for the species: agriculture, road-building, biological resource use (poaching and lumber activities), natural systems modifications (drainage and fire suppression), and pollution (fertilizer).[78]

Habitat loss is a major threat to the species. The human population of the coastal Carolinas is rapidly expanding. For example, Brunswick County, North Carolina, which has the largest number of Venus flytrap populations, has seen a 27% increase in its human population from 2010 to 2018.[79] As the population grows, residential and commercial development and road building directly eliminate flytrap habitat, while site preparation that entails ditching and draining can dry out soil in surrounding areas, destroying the viability of the species.[80][76] Additionally, increased recreational use of natural areas in populated areas directly destroys the plants by crushing or uprooting them.[8]

Fire suppression is another threat to the Venus flytrap. In the absence of regular fires, shrubs and trees encroach, outcompeting the species and leading to local extirpations.[32][81] D. muscipula requires fire every 3–5 years, and best thrives with annual brush fires.[82] Although flytraps and their seeds are typically killed alongside their competition in fires, seeds from flytraps adjacent to the burnt zone propagate quickly in the ash and full sun conditions that occur after a fire disturbance.[83] Because the mature plants and new seedlings are typically destroyed in the regular fires that are necessary to maintain their habitat, D. muscipula's survival relies upon adequate seed production and dispersal from outside the burnt patches back into the burnt habitat, requiring a critical mass of populations, and exposing the success of any one population to metapopulation dynamics. These dynamics make small, isolated populations particularly vulnerable to extirpation, for if there are no mature plants adjacent to the fire zone, there is no source of seeds post-fire.[8]

Poaching has been another cause of population decline. Harvesting Venus flytraps on public land became illegal in North Carolina in 1958, and since then a legal cultivation industry has formed, growing tens of thousands of flytraps in commercial greenhouses for sale as household plants. Yet in 2016, the New York Times reported that demand for wild plants still exists, which "has led to a 'Venus flytrap crime ring.'"[84] In 2014, the state of North Carolina made Venus flytrap poaching a felony.[85] Since then, several poachers have been charged, with one man receiving 17 months in prison for poaching 970 Venus flytraps,[86] and another man charged with 73 felony counts in 2019.[87] Poachers may do greater harm to the wild populations than a simple count of individuals taken would indicate, as they may selectively harvest the largest plants at a site, which have more flowers and fruit and therefore generate more seeds than smaller plants.[8]

Additionally, the species is particularly vulnerable to catastrophic climate events. Most Venus flytrap sites are only 2–4 meters (6.5 –13 feet) above sea level and are located in a region prone to hurricanes, making storm surges and rising sea levels a long-term threat.[8]

Designations

In 2005, the Venus flytrap was designated as the state carnivorous plant of North Carolina.[88]

In alternative medicine

Venus flytrap extract is available on the market as an herbal remedy, sometimes as the prime ingredient of a patent medicine named "Carnivora". According to the American Cancer Society, these products are promoted in alternative medicine as a treatment for a variety of human ailments including HIV, Crohn's disease and skin cancer, even though available scientific evidence does not support these health claims.[89]

See also

Notes

  1. ^ Subject to CITES Annotation #4

References

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  2. ^ "Appendices". CITES. Retrieved 14 January 2022.
  3. ^ Schlauer, J. (N.d.) Dionaea muscipula 24 July 2020 at the Wayback Machine. Carnivorous Plant Database.
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  5. ^ Ellison, Aaron M.; Adamec, Lubomír, eds. (2018). "4:Systematics and evolution of Droseraceae". Carnivorous plants: physiology, ecology, and evolution (1st ed.). Oxford, England, UK: Oxford University Press. p. 45. ISBN 9780198779841.
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  7. ^ doi: https://doi.org/10.1038/d41586-023-02654-x
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  9. ^ a b c d (PDF). U.S. Fish & Wildlife Service. June 2017. Archived from the original (PDF) on 6 October 2019. Retrieved 15 December 2019.
  10. ^ a b . FlyTrapCare.com. 4 April 2008. Archived from the original on 17 December 2008.
  11. ^ a b c d Ellis, John (1768). The London Magazine, Or, Gentleman's Monthly Intelligencer. Vol. October 1768. R. Baldwin. p. 523.
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  14. ^ Rice, Barry (January 2007). "How did the Venus flytrap get its name?". The Carnivorous Plant FAQ.
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External links

 
Wikimedia Commons has media related to Dionaea muscipula.
 
Wikispecies has information related to Venus flytrap.
  • at ARKive
  • Venus Flytrap Growing Guide and Distribution Map
  • The Carnivorous Plant FAQ: Flytraps
  • Venus flytrap origins uncovered – BBC
  • The CP Photo Finder: "Dionaea"
  • Criminal Podcast Episode Five: Dropping Like Flies

February 15, 2024
venus, flytrap, this, article, about, plant, other, uses, venus, flytrap, disambiguation, dionaea, muscipula, carnivorous, plant, native, temperate, subtropical, wetlands, north, carolina, south, carolina, east, coast, united, states, although, various, modern. This article is about the plant For other uses see Venus Flytrap disambiguation The Venus flytrap Dionaea muscipula is a carnivorous plant native to the temperate and subtropical wetlands of North Carolina and South Carolina on the East Coast of the United States 4 Although various modern hybrids have been created in cultivation D muscipula is the only species of the monotypic genus Dionaea It is closely related to the waterwheel plant Aldrovanda vesiculosa and the cosmopolitan sundews Drosera all of which belong to the family Droseraceae 5 Dionaea catches its prey chiefly insects and arachnids with a jaw like clamping structure which is formed by the terminal portion of each of the plant s leaves when an insect makes contact with the open leaves vibrations from the prey s movements ultimately trigger the jaws to shut via tiny hairs called trigger hairs or sensitive hairs on their inner surfaces Additionally when an insect or spider touches one of these hairs the trap prepares to close only fully enclosing the prey if a second hair is contacted within approximately twenty seconds of the first contact Triggers may occur as quickly as 1 10 of a second from initial contact 6 Venus flytrapLeafConservation statusVulnerable IUCN 2 3 1 CITES Appendix II CITES 2 note 1 Scientific classificationKingdom PlantaeClade TracheophytesClade AngiospermsClade EudicotsOrder CaryophyllalesFamily DroseraceaeGenus DionaeaSol ex J Ellis 1768Species D muscipulaBinomial nameDionaea muscipulaJ EllisDistributionSynonyms 3 Dionea Raf spelling variant Dionaea corymbosa Raf Steud 1840 Dionaea crinitaSol 1990 as synonym Dionaea dentataD Amato 1998 name published without description Dionaea heterodoxaD Amato 1998 nom nud Dionaea muscicapaSt Hil 1824 sphalm typogr Dionaea sensitivaSalisb 1796 Dionaea sessiliflora Raf Steud 1840 Dionaea uniflora Raf Steud 1840 Drosera corymbosaRaf 1833 Drosera sessilifloraRaf 1833 Drosera unifloraRaf 1833 The requirement of repeated seemingly redundant triggering in this mechanism serves as a safeguard against energy loss and to avoid trapping objects with no nutritional value the plant will only begin digestion after five more stimuli are activated ensuring that it has caught a live prey animal worthy of consumption These hairs also possess a heat sensor A forest fire for example causes them to snap shut making the plant more resilient to periods of summer fires 7 Although widely cultivated for sale the population of the Venus flytrap has been rapidly declining in its native range 8 The species is currently under Endangered Species Act review by the U S Fish amp Wildlife Service 9 Contents 1 Etymology 2 Discovery by Europeans 3 Description 3 1 Fly trap leaves 3 2 Other parts 4 Habitat and distribution 4 1 Habitat 4 2 Distribution 4 3 Population 5 Carnivory 5 1 Prey selectivity 5 2 Mechanism of trapping 5 3 Digestion 6 Evolution 6 1 Proposed evolutionary history 7 Cultivation 7 1 Cultivars 8 Conservation 8 1 Status 8 2 Threats 9 Designations 10 In alternative medicine 11 See also 12 Notes 13 References 14 External linksEtymologyThe plant s common name originally Venus s flytrap refers to Venus the Roman goddess of love The genus name Dionaea daughter of Dione refers to the Greek goddess Aphrodite further explanation needed while the species name muscipula is Latin for both mousetrap and flytrap 10 11 The Latin word muscipula mousetrap is derived from mus mouse and decipula trap while the homonym word muscipula flytrap is derived from musca fly and decipula 12 13 11 Historically the plant was also known by the slang term tipitiwitchet or tippity twitchet possibly an oblique reference to the plant s resemblance to human female genitalia 10 14 The term is similar to the term tippet de witchet which derives from tippet and witchet archaic term for vagina 15 16 In contrast the English botanist John Ellis who gave the plant its scientific name in 1768 wrote that the plant name tippitywichit was an indigenous word from either Cherokee or Catawba 11 17 The plant name according to the Handbook of American Indians derives from the Renape word titipiwitshik they leaves which wind around or involve 18 19 Discovery by EuropeansOn 2 April 1759 the North Carolina colonial governor Arthur Dobbs penned the first written description of the plant in a letter to English botanist Peter Collinson 20 In the letter he wrote We have a kind of Catch Fly Sensitive which closes upon anything that touches it It grows in Latitude 34 but not in 35 I will try to save the seed here 17 21 A year later Dobbs went into greater detail about the plant in a letter to Collinson dated Brunswick 24 January 1760 22 23 24 The great wonder of the vegetable kingdom is a very curious unknown species of Sensitive It is a dwarf plant The leaves are like a narrow segment of a sphere consisting of two parts like the cap of a spring purse the concave part outwards each of which falls back with indented edges like an iron spring fox trap upon anything touching the leaves or falling between them they instantly close like a spring trap and confine any insect or anything that falls between them It bears a white flower To this surprising plant I have given the name of Fly trap Sensitive Arthur Dobbs This was the first detailed recorded notice of the plant by Europeans The description was before John Ellis letter to The London Magazine on 1 September 1768 11 and his letter to Carl Linnaeus on 23 September 1768 25 in which he described the plant and proposed its English name Venus s Flytrap and scientific name Dionaea muscipula 26 DescriptionThe Venus flytrap is a small plant whose structure can be described as a rosette of four to seven leaves which arise from a short subterranean stem that is actually a bulb like object Each stem reaches a maximum size of about three to ten centimeters depending on the time of year 27 longer leaves with robust traps are usually formed after flowering Flytraps that have more than seven leaves are colonies formed by rosettes that have divided beneath the ground nbsp Illustration from Curtis s Botanical Magazine by William Curtis 1746 1799 Fly trap leaves The leaf blade is divided into two regions a flat heart shaped photosynthesis capable petiole and a pair of terminal lobes hinged at the midrib forming the trap which is the true leaf The upper surface of these lobes contains red anthocyanin pigments and its edges secrete mucilage The lobes exhibit rapid plant movements snapping shut when stimulated by prey The trapping mechanism is tripped when prey contacts one of the three hair like trichomes that are found on the upper surface of each of the lobes The mechanism is so highly specialized that it can distinguish between living prey and non prey stimuli such as falling raindrops 28 two trigger hairs must be touched in succession within 20 seconds of each other or one hair touched twice in rapid succession 28 whereupon the lobes of the trap will snap shut typically in about one tenth of a second 29 The edges of the lobes are fringed by stiff hair like protrusions or cilia which mesh together and prevent large prey from escaping These protrusions and the trigger hairs also known as sensitive hairs are likely homologous with the tentacles found in this plant s close relatives the sundews Scientists have concluded that the snap trap evolved from a fly paper trap similar to that of Drosera 30 The holes in the meshwork allow small prey to escape presumably because the benefit that would be obtained from them would be less than the cost of digesting them If the prey is too small and escapes the trap will usually reopen within 12 hours If the prey moves around in the trap it tightens and digestion begins more quickly Speed of closing can vary depending on the amount of humidity light size of prey and general growing conditions The speed with which traps close can be used as an indicator of a plant s general health Venus flytraps are not as humidity dependent as are some other carnivorous plants such as Nepenthes Cephalotus most Heliamphora and some Drosera The Venus flytrap exhibits variations in petiole shape and length and whether the leaf lies flat on the ground or extends up at an angle of about 40 60 degrees The four major forms are typica the most common with broad decumbent petioles erecta with leaves at a 45 degree angle linearis with narrow petioles and leaves at 45 degrees and filiformis with extremely narrow or linear petioles Except for filiformis all of these can be stages in leaf production of any plant depending on season decumbent in summer versus short versus semi erect in spring length of photoperiod long petioles in spring versus short in summer and intensity of light wide petioles in low light intensity versus narrow in brighter light citation needed Other parts The plant also has a flower on top of a long stem about 6 inches long The flower is pollinated from various flying insects such as sweat bees longhorn beetles and checkered beetles 31 nbsp Venus flytrap flower bud nbsp Flowering Venus flytrap showing its long flower stem nbsp Closeup of flower c 20 mm in diameter nbsp The species produces small shiny black seedsHabitat and distributionHabitat nbsp Map of the original distribution of the Venus flytrapThe Venus flytrap is found in nitrogen and phosphorus poor environments such as bogs wet savannahs and canebrakes Small in stature and slow growing the Venus flytrap tolerates fire well and depends on periodic burning to suppress its competition 32 Fire suppression threatens its future in the wild 33 It survives in wet sandy and peaty soils Although it has been successfully transplanted and grown in many locales around the world it is native only to the coastal bogs of North and South Carolina in the United States specifically within a 100 kilometer 60 mi radius of Wilmington North Carolina 34 One such place is North Carolina s Green Swamp There also appears to be a naturalized population of Venus flytraps in northern Florida as well as an introduced population in western Washington 35 36 The nutritional poverty of the soil is the reason it relies on such elaborate traps insect prey provide the nitrogen for protein formation that the soil cannot They tolerate mild winters and require a period of winter dormancy to survive freezing temperatures and low photoperiods It is a common misconception that Venus flytraps require dormancy if kept indoors under sufficient artificial light 37 However most professional carnivorous plant growers recommend dormancy and Venus fly traps grown without dormancy may require more light water and food to remain healthy 38 They are full sun plants usually found only in areas with less than 10 canopy cover 8 The habitats where it thrives are typically either too nutrient poor for many noncarnivorous plants to survive or frequently disturbed by fires which regularly clear vegetation and prevent a shady overstory from developing It can be found living alongside herbaceous plants grasses sphagnum and fire dependent Arundinaria bamboos 39 Regular fire disturbance is an important part of its habitat required every 3 5 years in most places for D muscipula to thrive After fire D muscipula seeds germinate well in ash and sandy soil with seedlings growing well in the open post fire conditions The seeds germinate immediately without a dormant period 8 Distribution Dionaea muscipula occurs naturally only along the coastal plain of North and South Carolina in the U S with all known current sites within 90 km of Wilmington North Carolina 9 A 1958 survey of herbaria specimens and old documents found 259 sites where the historical record documented the presence of D muscipula within 21 counties in North and South Carolina 40 As of 2019 it was considered extirpated in North Carolina in the inland counties of Moore Robeson and Lenoir as well as the South Carolina coastal counties of Charleston and Georgetown Remaining extant populations exist in North Carolina in Beaufort Craven Pamlico Carteret Jones Onslow Duplin Pender New Hanover Brunswick Columbus Bladen Sampson Cumberland and Hoke counties and in South Carolina in Horry county 9 Population A large scale survey in 2019 conducted by the North Carolina Natural Heritage Program counted a total of 163 951 individual Venus flytraps in North Carolina and 4 876 in South Carolina estimating a total of 302 000 individuals remaining in the wild in its native range 41 This represents a reduction of more than 93 from a 1979 estimate of approximately 4 500 000 individuals 8 A 1958 study found 259 confirmed extant or historic sites 40 As of 2016 there were 71 known sites where the plant could be found in the wild Of these 71 sites only 20 were classified as having excellent or good long term viability 9 Carnivory nbsp A closing trapPrey selectivity source source source source source source source source A time lapse showing Venus flytrap catching prey see more videos here Most carnivorous plants selectively feed on specific prey This selection is due to the available prey and the type of trap used by the organism With the Venus flytrap prey is limited to beetles spiders and other crawling arthropods The Dionaea diet is 33 ants 30 spiders 10 beetles and 10 grasshoppers with fewer than 5 flying insects 42 Given that Dionaea evolved from an ancestral form of Drosera carnivorous plants that use a sticky trap instead of a snap trap the reason for this evolutionary branching becomes clear Drosera consume smaller aerial insects whereas Dionaea consume larger terrestrial bugs Dionaea are able to extract more nutrients from these larger bugs This gives Dionaea an evolutionary advantage over their ancestral sticky trap form 43 Mechanism of trapping See also Plant arithmetic nbsp Stages and timing of the Venus flytrap carnivory process Knowable Magazine 44 nbsp Closeup of one of the hinged trigger hairsThe Venus flytrap is one of a very small group of plants capable of rapid movement such as Mimosa pudica the Telegraph plant starfruit sundews and bladderworts The mechanism by which the trap snaps shut involves a complex interaction between elasticity turgor and growth The trap only shuts when there have been two stimulations of the trigger hairs this is to avoid inadvertent triggering of the mechanism by dust and other wind borne debris In the open untripped state the lobes are convex bent outwards but in the closed state the lobes are concave forming a cavity It is the rapid flipping of this bistable state that closes the trap 29 but the mechanism by which this occurs is still poorly understood When the trigger hairs are stimulated an action potential mostly involving calcium ions see calcium in biology is generated which propagates across the lobes and stimulates cells in the lobes and in the midrib between them 45 46 47 It is hypothesized that there is a threshold of ion buildup for the Venus flytrap to react to stimulation 48 The acid growth theory states that individual cells in the outer layers of the lobes and midrib rapidly move 1H hydrogen ions into their cell walls lowering the pH and loosening the extracellular components which allows them to swell rapidly by osmosis thus elongating and changing the shape of the trap lobe Alternatively cells in the inner layers of the lobes and midrib may rapidly secrete other ions allowing water to follow by osmosis and the cells to collapse Both of these mechanisms may play a role and have some experimental evidence to support them 49 50 Flytraps show an example of memory in plants the plant knows if one of its trigger hairs have been touched and remembers this for a few seconds If a second touch occurs during that time frame the flytrap closes 51 After closing the flytrap counts additional stimulations of the trigger hairs to five total to start the production of digesting enzymes 52 nbsp Muscoid fly nbsp Chrysomelid beetle PariaDigestion If the prey is unable to escape it will continue to stimulate the inner surface of the lobes and this causes a further growth response that forces the edges of the lobes together eventually sealing the trap hermetically and forming a stomach in which digestion occurs Release of the digestive enzymes is controlled by the hormone jasmonic acid the same hormone that triggers the release of toxins as an anti herbivore defense mechanism in non carnivorous plants See Evolution below 52 53 Once the digestive glands in the leaf lobes have been activated digestion is catalysed by hydrolase enzymes secreted by the glands One of these enzymes includes GH18 chitinase which breaks down chitin containing exoskeleton of trapped insects Synthesis of this enzyme begins with at least five action potentials which will stimulate transcription of chitinase 54 Oxidative protein modification is likely to be a pre digestive mechanism used by Dionaea muscipula Aqueous leaf extracts have been found to contain quinones such as the naphthoquinone plumbagin that couples to different NADH dependent diaphorases to produce superoxide and hydrogen peroxide upon autoxidation 55 Such oxidative modification could rupture animal cell membranes Plumbagin is known to induce apoptosis associated with the regulation of the Bcl 2 family of proteins 56 When the Dionaea extracts were pre incubated with diaphorases and NADH in the presence of serum albumin SA subsequent tryptic digestion of SA was facilitated 55 Since the secretory glands of Droseraceae contain proteases and possibly other degradative enzymes it may be that the presence of oxygen activating redox cofactors function as extracellular pre digestive oxidants to render membrane bound proteins of the prey insects more susceptible to proteolytic attacks 55 Digestion takes about ten days after which the prey is reduced to a husk of chitin The trap then reopens and is ready for reuse 57 Evolution nbsp Drosera falconeri with short wide sticky leaf trapsCarnivory in plants is a very specialized form of foliar feeding and is an adaptation found in several plants that grow in nutrient poor soil Carnivorous traps were naturally selected to allow these organisms to compensate for the nutrient deficiencies of their harsh environments and compensate for the reduced photosynthetic benefit 58 Phylogenetic studies have shown that carnivory in plants is a common adaptation in habitats with abundant sunlight and water but scarce nutrients 43 Carnivory has evolved independently six times in the angiosperms based on extant species with likely many more carnivorous plant lineages now extinct 59 The snap trap mechanism characteristic of Dionaea is shared with only one other carnivorous plant genus Aldrovanda For most of the 20th century this relationship was thought to be coincidental more precisely an example of convergent evolution Some phylogenetic studies even suggested that the closest living relatives of Aldrovanda were the sundews 60 It was not until 2002 that a molecular evolutionary study by analyzing combined nuclear and chloroplast DNA sequences indicated that Dionaea and Aldrovanda were closely related and that the snap trap mechanism evolved only once in a common ancestor of the two genera 61 62 A 2009 study 60 presented evidence for the evolution of snap traps of Dionaea and Aldrovanda from a flypaper trap like Drosera regia based on molecular data The molecular and physiological data imply that Dionaea and Aldrovanda snap traps evolved from the flypaper traps of a common ancestor with Drosera Pre adaptations to the evolution of snap traps were identified in several species of Drosera such as rapid leaf and tentacle movement The model proposes that plant carnivory by snap trap evolved from the flypaper traps driven by increasing prey size Bigger prey provides greater nutritional value but large insects can easily escape the sticky mucilage of flypaper traps the evolution of snap traps would therefore prevent escape and kleptoparasitism theft of prey captured by the plant before it can derive benefit from it and would also permit a more complete digestion 60 61 In 2016 a study of the expression of genes in the plant s leaves as they captured and digested prey was published in the journal Genome Research The gene activation observed in the leaves of the plants gives support to the hypothesis that the carnivorous mechanisms present in the flytrap are a specially adapted version of mechanisms used by non carnivorous plants to defend against herbivorous insects 53 63 In many non carnivorous plants jasmonic acid serves as a signaling molecule for the activation of defense mechanisms such as the production of hydrolases which can destroy chitin and other molecular components of insect and microbial pests 64 In the Venus flytrap this same molecule has been found to be responsible for the activation of the plant s digestive glands A few hours after the capture of prey another set of genes is activated inside the glands the same set of genes that is active in the roots of other plants allowing them to absorb nutrients The use of similar biological pathways in the traps as non carnivorous plants use for other purposes indicates that somewhere in its evolutionary history the Venus flytrap repurposed these genes to facilitate carnivory 44 65 Proposed evolutionary history Carnivorous plants are generally herbaceous and their traps the result of primary growth They generally do not form readily fossilizable structures such as thick bark or wood As a result there is no fossil evidence of the steps that might link Dionaea and Aldrovanda or either genus with their common ancestor Drosera Nevertheless it is possible to infer an evolutionary history based on phylogenetic studies of both genera Researchers have proposed a series of steps that would ultimately result in the complex snap trap mechanism 60 61 Larger insects usually walk over the plant instead of flying to it 66 and are more likely to break free from sticky glands alone Therefore a plant with wider leaves like Drosera falconeri 60 must have adapted to move the trap and its stalks in directions that maximized its chance of capturing and retaining such prey in this particular case longitudinally Once adequately wrapped escape would be more difficult 66 Evolutionary pressure then selected for plants with shorter response time in a manner similar to Drosera burmannii or Drosera glanduligera The faster the closing the less reliant on the flypaper model the plant would be As the trap became more and more active the energy required to wrap the prey increased Plants that could somehow differentiate between actual insects and random detritus rain droplets would have an advantage thus explaining the specialization of inner tentacles into trigger hairs Ultimately as the plant relied more on closing around the insect rather than gluing them to the leaf surface the tentacles so evident in Drosera would lose their original function altogether becoming the teeth and trigger hairs an example of natural selection utilizing pre existing structures for new functions Completing the transition the plant eventually developed the depressed digestive glands found inside the trap rather than using the dews in the stalks further differentiating it from genus Drosera Phylogenetic studies using molecular characters place the emergence of carnivory in the ancestors of Dionaea muscipula to 85 6 million years ago and the development of the snap trap in the ancestors of Dionaea and its sister genus Aldrovanda to approximately 48 million years ago 67 Cultivation nbsp Dionaea muscipula Akai Ryu Japanese for Red Dragon in cultivationPlants can be propagated by seed taking around four to five years to reach maturity More commonly they are propagated by clonal division in spring or summer Venus flytraps can also be propagated in vitro using plant tissue culture 68 Most Venus flytraps found for sale in nurseries garden centers have been produced using this method as this is the most cost effective way to propagate them on a large scale Regardless of the propagation method used the plants will live for 20 to 30 years if cultivated in the right conditions 69 Cultivars Main article List of Venus flytrap cultivars Venus flytraps are by far the most commonly recognized and cultivated carnivorous plant and they are frequently sold as houseplants Various cultivars cultivated varieties have come into the market through tissue culture of selected genetic mutations and these plants are raised in large quantities for commercial markets The cultivars Akai Ryu and South West Giant have gained the Royal Horticultural Society s Award of Garden Merit 70 ConservationAlthough widely cultivated for sale as a houseplant D muscipula has suffered a significant decline in its population in the wild The population in its native range is estimated to have decreased 93 since 1979 8 41 Status The species is under Endangered Species Act review by the U S Fish amp Wildlife Service 71 The current review commenced in 2018 after an initial 90 day review found that action may be warranted A previous review in 1993 resulted in a determination that the plant was a Potential candidate without sufficient data on vulnerability 72 The IUCN Red List classifies the species as vulnerable 73 The State of North Carolina lists Dionaea muscipula as a species of Special Concern Vulnerable 74 The species is protected under Appendix II of the Convention on International Trade in Endangered Species CITES meaning international trade including in parts and derivatives is regulated by the CITES permitting system 75 NatureServe classified it as Imperiled G2 in a 2018 review 76 The U S Fish and Wildlife Service has not indicated a timeline to conclude its current review of Dionaea muscipula The Endangered Species Act specifies a two year timeline for a species review However the species listing process takes 12 1 years on average 77 Threats The Venus flytrap is only found in the wild in a very particular set of conditions requiring flat land with moist acidic nutrient poor soils that receive full sun and burn frequently in forest fires and is therefore sensitive to many types of disturbance 8 A 2011 review identified five categories of threats for the species agriculture road building biological resource use poaching and lumber activities natural systems modifications drainage and fire suppression and pollution fertilizer 78 Habitat loss is a major threat to the species The human population of the coastal Carolinas is rapidly expanding For example Brunswick County North Carolina which has the largest number of Venus flytrap populations has seen a 27 increase in its human population from 2010 to 2018 79 As the population grows residential and commercial development and road building directly eliminate flytrap habitat while site preparation that entails ditching and draining can dry out soil in surrounding areas destroying the viability of the species 80 76 Additionally increased recreational use of natural areas in populated areas directly destroys the plants by crushing or uprooting them 8 Fire suppression is another threat to the Venus flytrap In the absence of regular fires shrubs and trees encroach outcompeting the species and leading to local extirpations 32 81 D muscipula requires fire every 3 5 years and best thrives with annual brush fires 82 Although flytraps and their seeds are typically killed alongside their competition in fires seeds from flytraps adjacent to the burnt zone propagate quickly in the ash and full sun conditions that occur after a fire disturbance 83 Because the mature plants and new seedlings are typically destroyed in the regular fires that are necessary to maintain their habitat D muscipula s survival relies upon adequate seed production and dispersal from outside the burnt patches back into the burnt habitat requiring a critical mass of populations and exposing the success of any one population to metapopulation dynamics These dynamics make small isolated populations particularly vulnerable to extirpation for if there are no mature plants adjacent to the fire zone there is no source of seeds post fire 8 Poaching has been another cause of population decline Harvesting Venus flytraps on public land became illegal in North Carolina in 1958 and since then a legal cultivation industry has formed growing tens of thousands of flytraps in commercial greenhouses for sale as household plants Yet in 2016 the New York Times reported that demand for wild plants still exists which has led to a Venus flytrap crime ring 84 In 2014 the state of North Carolina made Venus flytrap poaching a felony 85 Since then several poachers have been charged with one man receiving 17 months in prison for poaching 970 Venus flytraps 86 and another man charged with 73 felony counts in 2019 87 Poachers may do greater harm to the wild populations than a simple count of individuals taken would indicate as they may selectively harvest the largest plants at a site which have more flowers and fruit and therefore generate more seeds than smaller plants 8 Additionally the species is particularly vulnerable to catastrophic climate events Most Venus flytrap sites are only 2 4 meters 6 5 13 feet above sea level and are located in a region prone to hurricanes making storm surges and rising sea levels a long term threat 8 DesignationsIn 2005 the Venus flytrap was designated as the state carnivorous plant of North Carolina 88 In alternative medicineVenus flytrap extract is available on the market as an herbal remedy sometimes as the prime ingredient of a patent medicine named Carnivora According to the American Cancer Society these products are promoted in alternative medicine as a treatment for a variety of human ailments including HIV Crohn s disease and skin cancer even though available scientific evidence does not support these health claims 89 See alsoCarnivorous plants of North America List of ineffective cancer treatmentsNotes Subject to CITES Annotation 4References Schnell D Catling P Folkerts G Frost C Gardner R et al 2000 Dionaea muscipula IUCN Red List of Threatened Species 2000 e T39636A10253384 doi 10 2305 IUCN UK 2000 RLTS T39636A10253384 en Retrieved 19 November 2021 Appendices CITES Retrieved 14 January 2022 Schlauer J N d Dionaea muscipula Archived 24 July 2020 at the Wayback Machine Carnivorous Plant Database Dionaea muscipula J Ellis Plants of the World Online Royal Botanic Gardens Kew 2023 Retrieved 30 October 2023 Ellison Aaron M Adamec Lubomir eds 2018 4 Systematics and evolution of Droseraceae Carnivorous plants physiology ecology and evolution 1st ed Oxford England UK Oxford University Press p 45 ISBN 9780198779841 Sumner Thomas 20 November 2012 Investigating the Venus Flytrap insidescience com Retrieved 18 March 2018 doi https doi org 10 1038 d41586 023 02654 x a b c d e f g h i j Waller Donald 21 October 2016 Petition to list the Venus flytrap Dionaea muscipula Ellis as Endangered under the 1973 Endangered Species Act USFWS Retrieved 14 December 2019 a b c d Venus Flytrap Under Endangered Species Act review PDF U S Fish amp Wildlife Service June 2017 Archived from the original PDF on 6 October 2019 Retrieved 15 December 2019 a b Background Information on Venus Fly Traps Venus Fly Trap naming and history FlyTrapCare com 4 April 2008 Archived from the original on 17 December 2008 a b c d Ellis John 1768 The London Magazine Or Gentleman s Monthly Intelligencer Vol October 1768 R Baldwin p 523 Donaldson John William 1852 Varronianus A Critical and Historical Introduction to the Ethnography of Ancient Italy and to the Philological Study of the Latin Language J W Parker amp Son pp 431 cipula Wase Christopher 1662 Dictionarium Minus A Compendious Dictionary English Latin and Latin English Maxwell Rice Barry January 2007 How did the Venus flytrap get its name The Carnivorous Plant FAQ tippet de witchet n Green s Dictionary of Slang greensdictofslang com Retrieved 21 January 2020 Williams Gordon 2001 wicket A Dictionary of Sexual Language and Imagery in Shakespearean and Stuart Literature Three Volume Set Volume I A F Volume II G P Volume III Q Z A amp C Black p 1533 ISBN 978 0 485 11393 8 a b Mabey Richard 2016 The Challenge of Carnivorous Plants The Tipitiwitchet Chapter 16 The Cabaret of Plants Forty Thousand Years of Plant Life and the Human Imagination W W Norton amp Company ISBN 978 0 393 24877 7 Mabey Richard 2016 The Cabaret of Plants Forty Thousand Years of Plant Life and the Human Imagination W W Norton amp Company ISBN 978 0 393 24877 7 Hodge Frederick Webb 1912 Handbook of American Indians North of Mexico N Z U S Government Printing Office pp 759 titipiwitshik Irmscher Christoph 1999 The Poetics of Natural History From John Bartram to William James Rutgers University Press p 31 ISBN 978 0 8135 2615 7 Bartram John 1942 Diary of a journey through the Carolinas Georgia and Florida From July 1 1765 to April 10 1766 Transactions of the American Philosophical Society v 33 pt L American Philosophical Society p 104 hdl 2027 uc1 32106020417272 Lewis Weston Dillwyn Peter Collinson 1843 Hortus Collinsonianus An account of the plants cultivated by the late Peter Collinson W C Murray amp D Rees p 18 Gardeners Chronicle amp New Horticulturist Vol 3 4 Haymarket Publishing 1875 p 306 The Nature Conservancy Archived 29 August 2017 at the Wayback Machine Venus Flytrap Ellis John 23 September 1768 Letter 23 September 1768 London to Carl Linnaeus Directions for Bringing over Seeds and Plants from the East Indies and Other Distant Countries in a State of Vegetation Together with a Catalogue of Such Foreign Plants as Are Worthy of Being Encouraged in Our American Colonies for the Purposes of Medicine Agriculture and Commerce To Which is Added the Figure and Botanical Description of a New Sensitive Plant Called Dionaea muscipula or Venus s Fly trap London printed and sold by L Davis 1770 Venus flytraps The Carnivorous Plant FAQ Retrieved 13 June 2005 a b Raven Peter H Evert Ray Franklin Eichhorn Susan E 2005 Biology of Plants 7th ed W H Freeman and Company ISBN 978 0 7167 1007 3 a b Forterre Yoel Skotheim Jan M Dumais Jacques Mahadevan L 27 January 2005 How the Venus flytrap snaps PDF Nature 433 7024 421 425 Bibcode 2005Natur 433 421F doi 10 1038 nature03185 PMID 15674293 S2CID 4340043 Archived from the original PDF on 2 December 2007 Cameron Kenneth M Wurdack Kenneth J Jobson Richard W 2002 Molecular evidence for the common origin of snap traps among carnivorous plants American Journal of Botany 89 9 1503 1509 doi 10 3732 ajb 89 9 1503 PMID 21665752 Guarino Ben 7 February 2018 Venus flytraps give insects that pollinate their flowers a break They don t eat them Washington Post Retrieved 2 August 2020 a b W Schulze E D Schulze I Schulze amp R Oren 2001 Quantification of insect nitrogen utilization by the Venus flytrap Dionaea muscipula catching prey with highly variable isotope signatures Journal of Experimental Botany 52 358 1041 1049 doi 10 1093 jexbot 52 358 1041 PMID 11432920 Leege Lissa How does the Venus flytrap digest flies Scientific American Retrieved 20 August 2008 Darwin C R 1875 Insectivorous Plants Schnell D E 2002 Carnivorous Plants of the United States and Canada 2nd ed Timber Press ISBN 978 0 88192 540 1 Giblin D Nd Dionaea muscipula Burke Museum of Natural History and Culture Grow Venus Flytraps Indoors PDF International Carnivorous Plant Society Retrieved 2 June 2023 Venus Flytraps Dionaea Brian s Carnivorous Retrieved 21 September 2023 Gray Janet Bracey Sorrie Bruce A Wall Wade 2016 Canebrakes of the Sandhills Region of the Carolinas and Georgia Fire History Canebrake Area and Species Frequency Castanea 81 4 280 291 doi 10 2179 16 112 S2CID 89603409 a b Roberts Patricia R Oosting H J 1958 Responses of Venus Fly Trap Dionaea muscipula to Factors Involved in Its Endemism Ecological Monographs 28 2 193 218 Bibcode 1958EcoM 28 193R doi 10 2307 1942208 ISSN 1557 7015 JSTOR 1942208 a b Biodiversity Day Venus Flytrap Preservation NC DNCR www ncdcr gov 21 May 2019 Retrieved 14 December 2019 Ellison DM Gotelli NJ 2009 Energetics and the evolution of carnivorous plants Darwin s Most Wonderful plants in the world Journal of Experimental Botany 60 1 19 42 doi 10 1093 jxb ern179 PMID 19213724 a b Gibson TC Waller DM 2009 Evolving Darwin s most wonderful plant ecological steps to a snap trap New Phytologist 183 1 575 587 doi 10 1111 j 1469 8137 2009 02935 x PMID 19573135 a b Pain Stephanie 2 March 2022 How plants turned predator Knowable Magazine doi 10 1146 knowable 030122 1 Retrieved 11 March 2022 Hodick Dieter Sievers Andreas 1989 The action potential of Dionaea muscipula Ellis Planta 174 1 8 18 doi 10 1007 BF00394867 PMID 24221411 S2CID 3114033 Suda Hiraku Mano Hiroaki Toyota Masatsugu Fukushima Kenji Mimura Tetsuro Tsutsui Izuo Hedrich Rainer Tamada Yosuke Hasebe Mitsuyasu 2020 Calcium dynamics during trap closure visualized in transgenic Venus flytrap 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Action Potentials to Induce Sodium Uptake Current Biology 26 3 286 295 doi 10 1016 j cub 2015 11 057 ISSN 0960 9822 PMC 4751343 PMID 26804557 a b Bemm Felix Becker Dirk Larisch Christina Kreuzer Ines Escalante Perez Maria Schulze Waltraud X Ankenbrand Markus Weyer Anna Lena Van de Krol Elzbieta Al Rasheid Khaled A Mithofer Axel Weber Andreas P Schultz Jorg Hedrich Rainer 4 May 2016 Venus flytrap carnivorous lifestyle builds on herbivore defense strategies Genome Research 26 6 812 825 doi 10 1101 gr 202200 115 ISSN 1088 9051 PMC 4889972 PMID 27197216 Retrieved 26 May 2016 Hedrich Rainer Fukushima Kenji 17 June 2021 On the Origin of Carnivory Molecular Physiology and Evolution of Plants on an Animal Diet Annual Review of Plant Biology 72 1 133 153 doi 10 1146 annurev arplant 080620 010429 ISSN 1543 5008 PMID 33434053 S2CID 231595236 a b c Galek H Osswald WF Elstner EF 1990 Oxidative protein modification as predigestive mechanism of the carnivorous plant Dionaea muscipula an hypothesis based on in vitro experiments Free Radic Biol Med 9 5 427 434 doi 10 1016 0891 5849 90 90020 J PMID 2292436 Hsu YL Cho CY Kuo PL Huang YT Lin CC August 2006 Plumbagin 5 Hydroxy 2 methyl 1 4 naphthoquinone Induces Apoptosis and Cell Cycle Arrest in A549 Cells through p53 Accumulation via c Jun NH2 Terminal Kinase Mediated Phosphorylation at Serine 15 in Vitro and in Vivo J Pharmacol Exp Ther 318 2 484 494 doi 10 1124 jpet 105 098863 PMID 16632641 S2CID 6880736 Produced by Neil Lucas 7 December 2009 Plants Life BBC One AM Ellison 2006 Nutrient limitation and stoichiometry of carnivorous plants PDF Plant Biology 8 6 740 747 Bibcode 2006PlBio 8 740E doi 10 1055 s 2006 923956 PMID 17203429 S2CID 260253121 Albert V A Williams S E Chase M W 11 September 1992 Carnivorous plants phylogeny and structural evolution Science 257 5076 1491 1495 Bibcode 1992Sci 257 1491A doi 10 1126 science 1523408 ISSN 0036 8075 PMID 1523408 a b c d e Gibson T C Waller D M 2009 Evolving Darwin s most wonderful plant ecological steps to a snap trap New Phytologist 183 3 575 587 doi 10 1111 j 1469 8137 2009 02935 x PMID 19573135 a b c Cameron K M Wurdack K J Jobson R W 2002 Molecular evidence for the common origin of snap traps among carnivorous plants American Journal of Botany 89 9 1503 1509 doi 10 3732 ajb 89 9 1503 PMID 21665752 Rivadavia F K Kondo M Kato amp M Hasebe 2003 Phylogeny of the sundews Drosera Droseraceae based on chloroplast rbcL and nuclear 18S ribosomal DNA Sequences American Journal of Botany 90 1 123 130 doi 10 3732 ajb 90 1 123 PMID 21659087 Stokstad E 12 May 2016 How the Venus flytrap acquired its taste for meat Science 352 6287 756 Bibcode 2016Sci 352 756S doi 10 1126 science 352 6287 756 PMID 27174967 Turner John G Ellis Christine Devoto Alessandra 1 May 2002 The Jasmonate Signal Pathway The Plant Cell 14 suppl 1 S153 S164 doi 10 1105 tpc 000679 ISSN 1532 298X PMC 151253 PMID 12045275 Hedrich Rainer Fukushima Kenji 17 June 2021 On the Origin of Carnivory Molecular Physiology and Evolution of Plants on an Animal Diet Annual Review of Plant Biology 72 1 133 153 doi 10 1146 annurev arplant 080620 010429 ISSN 1543 5008 PMID 33434053 S2CID 231595236 a b Venus flytrap origins uncovered BBC News 2009 Ellison Aaron M Adamec Lubomir 2018 Carnivorous Plants Physiology Ecology and Evolution Oxford University Press ISBN 978 0 19 877984 1 Jang Gi Won Kim Kwang Soo Park Ro Dong 2003 Micropropagation of Venus fly trap by shoot culture Plant Cell Tissue and Organ Culture 72 1 95 98 doi 10 1023 A 1021203811457 S2CID 40976899 D Amato Peter 1998 The Savage Garden Cultivating Carnivorous Plants Berkeley California Ten Speed Press ISBN 978 0 89815 915 8 AGM Plants March 2020 RHS ORNAMENTAL PDF rhs org uk The Royal Horticultural Society March 2020 Retrieved 11 September 2020 Federal Register Vol 82 December 20 2017 Proposed Rules PDF Government Publishing Office US 20 December 2017 Retrieved 14 December 2019 Federal Register Vol 58 No 188 PDF cdn loc gov 30 September 1993 Retrieved 14 December 2019 The IUCN Red List of Threatened Species IUCN Red List of Threatened Species Retrieved 15 December 2019 Threatened Search Results plants usda gov Retrieved 15 December 2019 Appendices CITES cites org Retrieved 14 January 2022 a b Comprehensive Report Species Dionaea muscipula explorer natureserve org Retrieved 15 December 2019 Many endangered species face long waits for protection Scientists concerned about decreasing global diversity as a result ScienceDaily Retrieved 15 December 2019 Jennings David E Rohr Jason R 1 May 2011 A review of the conservation threats to carnivorous plants Biological Conservation Ecoregional scale monitoring within conservation areas in a rapidly changing climate 144 5 1356 1363 doi 10 1016 j biocon 2011 03 013 ISSN 0006 3207 U S Census Bureau QuickFacts Brunswick County North Carolina www census gov Retrieved 15 December 2019 Luken James O 2012 Long Term Outcomes of Venus Flytrap Dionaea muscipula Establishment Restoration Ecology 20 6 669 670 Bibcode 2012ResEc 20 669L doi 10 1111 j 1526 100X 2012 00888 x ISSN 1526 100X S2CID 84408526 Luken James 2007 Performance of Dionaea muscipula as influenced by developing vegetation The Journal of the Torrey Botanical Society 134 1 45 52 doi 10 3159 1095 5674 2007 134 45 PODMAI 2 0 CO 2 S2CID 14022318 via bioone org Yearsley Connor May 2017 The Venus Flytrap Conserving the Carnivorous Curiosity Journal of the American Botanical Council 14 5 Venus Flytraps in Peril Why Everyone s Favorite Carnivorous Houseplant Is Under Threat www mentalfloss com 30 September 2019 Retrieved 15 December 2019 Mele Christopher 28 November 2016 Venus Flytraps Need Protection From Poachers in North Carolina The New York Times ISSN 0362 4331 Retrieved 15 December 2019 Evans Jon 18 September 2014 Stealing Venus Flytrap plants now a felony www wect com Retrieved 21 July 2017 Love Shayla 28 July 2016 A poacher who stole 970 venus flytraps in N C is sentenced to prison Washington Post Archived from the original on 29 July 2016 Retrieved 15 December 2019 Still Johanna F 18 March 2019 Man charged with 73 counts of poaching Venus Flytrap bond at 750 000 Port City Daily Retrieved 15 December 2019 Venus Flytrap State Carnivorous Plant State Symbols USA statesymbolsusa org 26 September 2014 Retrieved 17 October 2019 Venus Flytrap American Cancer Society November 2008 Archived from the original on 18 February 2015 Retrieved 22 September 2013 External links nbsp Wikimedia Commons has media related to Dionaea muscipula nbsp Wikispecies has information related to Venus flytrap Images and movies of the Venus flytrap Dionaea muscipula at ARKive Venus Flytrap Growing Guide and Distribution Map The Carnivorous Plant FAQ Flytraps Venus flytrap origins uncovered BBC The CP Photo Finder Dionaea Criminal Podcast Episode Five Dropping Like Flies Retrieved from https en wikipedia org w index php title Venus flytrap amp oldid 1195565811, wikipedia, wiki, book, books, library,

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