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Springtail

March 06, 2023

Springtails (Collembola) form the largest of the three lineages of modern hexapods that are no longer considered insects (the other two are the Protura and Diplura). Although the three orders are sometimes grouped together in a class called Entognatha because they have internal mouthparts, they do not appear to be any more closely related to one another than they are to all insects, which have external mouthparts.

Springtails
Temporal range: Early Devonian – present
Orchesella cincta
Scientific classification
Kingdom: Animalia
Phylum: Arthropoda
Class: Entognatha (?)
Subclass: Collembola
Lubbock, 1871
Orders
Synonyms [1]
  • Oligentoma
  • Oligoentoma

Collembolans are omnivorous, free-living organisms that prefer moist conditions. They do not directly engage in the decomposition of organic matter, but contribute to it indirectly through the fragmentation of organic matter[2] and the control of soil microbial communities.[3] The word Collembola is from the ancient Greek κόλλα kólla "glue" and ἔμβολος émbolos "peg"; this name was given due to the existence of the collophore, which was previously thought to stick to surfaces to stabilize the creature.[4]

Some DNA sequence studies[5][6][7] suggest that Collembola represent a separate evolutionary line from the other Hexapoda, but others disagree;[8] this seems to be caused by widely divergent patterns of molecular evolution among the arthropods.[9] The adjustments of traditional taxonomic rank for springtails reflects the occasional incompatibility of traditional groupings with modern cladistics: when they were included with the insects, they were ranked as an order; as part of the Entognatha, they are ranked as a subclass. If they are considered a basal lineage of Hexapoda, they are elevated to full class status.

Morphology

 
Isotoma with visible furcula

Members of the Collembola are normally less than 6 mm (0.24 in) long, have six or fewer abdominal segments, and possess a tubular appendage (the collophore or ventral tube) with reversible, sticky vesicles, projecting ventrally from the first abdominal segment.[10] It is believed to be associated with fluid uptake and balance, excretion, and orientation of the organism itself.[11] Most species have an abdominal, tail-like appendage known as a furcula. It is located on the fourth abdominal segment of collembolans and is folded beneath the body, held under tension by a small structure called the retinaculum (or tenaculum). When released, it snaps against the substrate, flinging the springtail into the air and allowing for rapid evasion and travel. All of this takes place in as little as 18 milliseconds.[12][11]

Springtails also possess the ability to reduce their body size by as much as 30% through subsequent ecdyses (molting) if temperatures rise high enough. The shrinkage is genetically controlled. Since warmer conditions increase metabolic rates and energy requirements in organisms, the reduction in body size is advantageous to their survival.[13]

The Poduromorpha and Entomobryomorpha have an elongated body, while the Symphypleona and Neelipleona have a globular body. Collembola lack a tracheal respiration system, which forces them to respire through a porous cuticle, except for the two families Sminthuridae and Actaletidae, which exhibit a single pair of spiracles between the head and the thorax, leading to a rudimentary, although fully functional, tracheal system.[14][10] The anatomical variance present between different species partially depends on soil morphology and composition. Surface-dwellers are generally larger, have darker pigments, have longer antennae and functioning furcula. Sub-surface-dwellers are usually unpigmented, have elongated bodies, and reduced furcula. They can be categorized into four main forms according to soil composition and depth: atmobiotic, epedaphic, hemiedaphic, and euedaphic. Atmobiotic species inhabit macrophytes and litter surfaces. They are generally 8-10 millimeters in length, pigmented, have long limbs, and a full set of ocelli (photoreceptors). Epedaphic species inhabit upper litter layers and fallen logs. They are slightly smaller and have less pronounced pigments, as well as less developed limbs and ocelli than the atmobiotic species. Hemiedaphic species inhabit the lower litter layers of decomposing organic material. They are 1-2 millimeters in length, have dispersed pigmentation, shortened limbs, and a reduced number of ocelli. Euedaphic species inhabit upper mineral layers known as the humus horizon. They are smaller than hemiedaphic species; have soft, elongated bodies; lack pigmentation and ocelli; and have reduced or absent furca.[15][16][17]

Poduromorphs inhabit the epedaphic, hemiedaphic, and euedaphic layers and are characterized by their elongated bodies and conspicuous segmentation – three thoracic segments, six abdominal segments, and a prothorax.[17]

The digestive tract of collembolan species consists of three main components: the foregut, midgut, and hindgut. The midgut is surrounded by a network of muscles and lined with a monolayer of columnar or cuboidal cells. Its function is to mix and transport food from the lumen into the hindgut through contraction. Many species of syntrophic bacteria, archaea, and fungi are present in the lumen. These different digestive regions have varying pH to support specific enzymatic activities and microbial populations. The anterior portion of the midgut and hindgut is slightly acidic (with a pH of approximately 6.0) while the posterior midgut portion is slightly alkaline (with a pH of approximately 8.0). Between the midgut and hindgut is an alimentary canal called the pyloric region, which is a muscular sphincter.[11]

Systematics and evolution

Allacma fusca (Symphypleona) on rotting wood

Traditionally, the springtails were divided into the orders Arthropleona, Symphypleona, and occasionally also Neelipleona. The Arthropleona were divided into two superfamilies, the Entomobryoidea and the Poduroidea. However, recent phylogenetic studies show Arthropleona is paraphyletic.[18][19][20] Thus, the Arthropleona are abolished in modern classifications, and their superfamilies are raised in rank accordingly, being now orders Entomobryomorpha and the Poduromorpha. Technically, the Arthropleona are thus a partial junior synonym of the Collembola.[21]

The term "Neopleona" is essentially synonymous with Symphypleona + Neelipleona.[22] The Neelipleona was originally seen as a particularly advanced lineage of Symphypleona, based on the shared global body shape, but the global body of the Neelipleona is realized in a completely different way than in Symphypleona. Subsequently, the Neelipleona were considered as being derived from the Entomobryomorpha. Analysis of 18S and 28S rRNA sequence data, though, suggests that they form the most ancient lineage of springtails, which would explain their peculiar apomorphies.[8] This phylogenetic relationship was also confirmed using a phylogeny based on mtDNA[19] and whole-genome data.[20]

The latest whole-genome phylogeny supporting four orders of collembola:[20]

Springtails are attested to since the Early Devonian.[23] The fossil from 400 million years ago, Rhyniella praecursor, is the oldest terrestrial arthropod, and was found in the famous Rhynie chert of Scotland. Given its morphology resembles extant species quite closely, the radiation of the Hexapoda can be situated in the Silurian, 420 million years ago or more.[24] Additional research concerning the coprolites (fossilized feces) of ancient collembolans allowed researchers to track their lineages back some 412 million years.[11]

Fossil Collembola are rare. Instead, most are found in amber.[25] Even these are rare and many amber deposits carry few or no collembola. The best deposits are from the early Eocene of Canada and Europe,[26] Miocene of Central America,[27] and the mid-Cretaceous of Burma and Canada.[28] They display some unexplained characteristics: first, all but one of the fossils from the Cretaceous belong to extinct genera, whereas none of the specimens from the Eocene or the Miocene are of extinct genera; second, the species from Burma are more similar to the modern fauna of Canada than are the Canadian Cretaceous specimens.

There are about 3,600 different species.[29]

Ecology

Eating behavior

Specific feeding strategies and mechanisms are employed to match specific niches.[30] Herbivorous and detritivorous species fragment biological material present in soil and leaf litter, supporting decomposition and increasing the availability of nutrients for various species of microbes and fungi.[31] Carnivorous species maintain populations of small invertebrates such as nematodes, rotifers, and other collembolan species.[11][15] Springtails commonly consume fungal hyphae and spores, but also have been found to consume plant material and pollen, animal remains, colloidal materials, minerals and bacteria.[32]

Predators

Springtails are consumed by mesostigmatan mites in various families, including Ascidae, Laelapidae, Parasitidae, Rhodacaridae and Veigaiidae.[33]

Cave-dwelling springtails are a food source for spiders and harvestmen in the same environment, such as the endangered harvestman Texella reyesi.[34]

Distribution

Springtails are cryptozoa frequently found in leaf litter and other decaying material,[35] where they are primarily detritivores and microbivores, and one of the main biological agents responsible for the control and the dissemination of soil microorganisms.[36] In a mature deciduous woodland in temperate climate, leaf litter and vegetation typically support 30 to 40 species of springtails, and in the tropics the number may be over 100.[37]

 
"Snow flea"
 
A species of Sminthurinae (Symphypleona: Sminthuridae)

In sheer numbers, they are reputed to be one of the most abundant of all macroscopic animals, with estimates of 100,000 individuals per square meter of ground,[38] essentially everywhere on Earth where soil and related habitats (moss cushions, fallen wood, grass tufts, ant and termite nests) occur.[39] Only nematodes, crustaceans, and mites are likely to have global populations of similar magnitude, and each of those groups except mites is more inclusive: though taxonomic rank cannot be used for absolute comparisons, it is notable that nematodes are a phylum and crustaceans a subphylum. Most springtails are small and difficult to see by casual observation, but one springtail, the so-called snow flea (Hypogastrura nivicola), is readily observed on warm winter days when it is active and its dark color contrasts sharply with a background of snow.[40]

In addition, a few species routinely climb trees and form a dominant component of canopy faunas, where they may be collected by beating or insecticide fogging.[41][42] These tend to be the larger (>2 mm) species, mainly in the genera Entomobrya and Orchesella, though the densities on a per square meter basis are typically 1–2 orders of magnitude lower than soil populations of the same species. In temperate regions, a few species (e.g. Anurophorus spp., Entomobrya albocincta, Xenylla xavieri, Hypogastrura arborea) are almost exclusively arboreal.[39] In tropical regions a single square meter of canopy habitat can support many species of Collembola.[12]

The main ecological factor driving the local distribution of species is the vertical stratification of the environment: in woodland a continuous change in species assemblages can be observed from tree canopies to ground vegetation then to plant litter down to deeper soil horizons.[39] This is a complex factor embracing both nutritional and physiological requirements, together with behavioural trends,[43] dispersal limitation[44] and probable species interactions. Some species have been shown to exhibit negative[45] or positive[43] gravitropism, which adds a behavioural dimension to this still poorly understood vertical segregation. Experiments with peat samples turned upside down showed two types of responses to disturbance of this vertical gradient, called "stayers" and "movers".[46]

 
Dicyrtomina sp. on leaf

As a group, springtails are highly sensitive to desiccation, because of their tegumentary respiration,[47] although some species with thin, permeable cuticles have been shown to resist severe drought by regulating the osmotic pressure of their body fluid.[48] The gregarious behaviour of Collembola, mostly driven by the attractive power of pheromones excreted by adults,[49] gives more chance to every juvenile or adult individual to find suitable, better protected places, where desiccation could be avoided and reproduction and survival rates (thereby fitness) could be kept at an optimum.[50] Sensitivity to drought varies from species to species[51] and increases during ecdysis.[52] Given that springtails moult repeatedly during their entire life (an ancestral character in Hexapoda) they spend much time in concealed micro-sites where they can find protection against desiccation and predation during ecdysis, an advantage reinforced by synchronized moulting.[53] The high humidity environment of many caves also favours springtails and there are numerous cave adapted species,[54][55] including one, Plutomurus ortobalaganensis living 1,980 metres (6,500 ft) down the Krubera Cave.[56]

 
Anurida maritima on water

The horizontal distribution of springtail species is affected by environmental factors which act at the landscape scale, such as soil acidity, moisture and light.[39] Requirements for pH can be reconstructed experimentally.[57] Altitudinal changes in species distribution can be at least partly explained by increased acidity at higher elevation.[58] Moisture requirements, among other ecological and behavioural factors, explain why some species cannot live aboveground,[59] or retreat in the soil during dry seasons,[60] but also why some epigeal springtails are always found in the vicinity of ponds and lakes, such as the hygrophilous Isotomurus palustris.[61] Adaptive features, such as the presence of a fan-like wettable mucro, allow some species to move at the surface of water (Sminthurides aquaticus, Sminthurides malmgreni). Podura aquatica, a unique representative of the family Poduridae (and one of the first springtails to have been described by Carl Linnaeus), spends its entire life at the surface of water, its wettable eggs dropping in water until the non-wettable first instar hatches then surfaces.[62]

In a variegated landscape, made of a patchwork of closed (woodland) and open (meadows, cereal crops) environments, most soil-dwelling species are not specialized and can be found everywhere, but most epigeal and litter-dwelling species are attracted to a particular environment, either forested or not.[39][63] As a consequence of dispersal limitation, landuse change, when too rapid, may cause the local disappearance of slow-moving, specialist species,[64] a phenomenon the measure of which has been called colonisation credit.[65][66]

Relationship with humans

 
Tomocerus sp. from Germany

Springtails are well known as pests of some agricultural crops. Sminthurus viridis, the lucerne flea, has been shown to cause severe damage to agricultural crops,[67] and is considered as a pest in Australia.[68][69] Onychiuridae are also known to feed on tubers and to damage them to some extent.[70] However, by their capacity to carry spores of mycorrhizal fungi and mycorrhiza helper bacteria on their tegument, soil springtails play a positive role in the establishment of plant-fungal symbioses and thus are beneficial to agriculture.[71] They also contribute to controlling plant fungal diseases through their active consumption of mycelia and spores of damping-off and pathogenic fungi.[72][73] It has been suggested that they could be reared to be used for the control of pathogenic fungi in greenhouses and other indoor cultures.[74][75]

Various sources and publications have suggested that some springtails may parasitize humans, but this is entirely inconsistent with their biology, and no such phenomenon has ever been scientifically confirmed, though it has been documented that the scales or hairs from collembolans can cause irritation when rubbed onto the skin.[76] They may sometimes be abundant indoors in damp places such as bathrooms and basements, and incidentally found on one's person. More often, claims of persistent human skin infection by springtails may indicate a neurological problem, such as delusional parasitosis, a psychological rather than entomological problem. Researchers themselves may be subject to psychological phenomena. For example, a publication in 2004 claiming that springtails had been found in skin samples was later determined to be a case of pareidolia; that is, no springtail specimens were actually recovered, but the researchers had digitally enhanced photos of sample debris to create images resembling small arthropod heads, which then were claimed to be springtail remnants.[76][77][78][79][80] However, Steve Hopkin reports one instance of an entomologist aspirating an Isotoma species and in the process accidentally inhaling some of their eggs, which hatched in his nasal cavity and made him quite ill until they were flushed out.[37]

In 1952, China accused the United States military of spreading bacteria-laden insects and other objects during the Korean War by dropping them from P-51 fighters above rebel villages over North Korea. In all, the U.S. was accused of dropping ants, beetles, crickets, fleas, flies, grasshoppers, lice, springtails, and stoneflies as part of a biological warfare effort. The alleged associated diseases included anthrax, cholera, dysentery, fowl septicemia, paratyphoid, plague, scrub typhus, small pox, and typhoid. China created an international scientific commission for investigating possible bacterial warfare, eventually ruling that the United States probably did engage in limited biological warfare in Korea. The US government denied all the allegations, and instead proposed that the United Nations send a formal inquiry committee to China and Korea, but China and Korea refused to cooperate. U.S. and Canadian entomologists further claimed that the accusations were ridiculous and argued that anomalous appearances of insects could be explained through natural phenomena.[81] Springtail species cited in allegations of biological warfare in the Korean War were Isotoma (Desoria) negishina (a local species) and the "white rat springtail" Folsomia candida.[82]

Captive springtails are often kept in a terrarium as part of a clean-up crew.[83]

Ecotoxicology laboratory animals

Springtails are currently used in laboratory tests for the early detection of soil pollution. Acute and chronic toxicity tests have been performed by researchers, mostly using the parthenogenetic isotomid Folsomia candida.[84] These tests have been standardized.[85] Details on a ringtest, on the biology and ecotoxicology of Folsomia candida and comparison with the sexual nearby species Folsomia fimetaria (sometimes preferred to Folsomia candida) are given in a document written by Paul Henning Krogh.[86] Care should be taken that different strains of the same species may be conducive to different results. Avoidance tests have been also performed.[87] They have been standardized, too.[88] Avoidance tests are complementary to toxicity tests, but they also offer several advantages: they are more rapid (thus cheaper), more sensitive and they are environmentally more reliable, because in the real world Collembola move actively far from pollution spots.[89] It may be hypothesized that the soil could become locally depauperated in animals (and thus improper to normal use) while below thresholds of toxicity. Contrary to earthworms, and like many insects and molluscs, Collembola are very sensitive to herbicides and thus are threatened in no-tillage agriculture, which makes a more intense use of herbicides than conventional agriculture.[90] The springtail Folsomia candida is also becoming a genomic model organism for soil toxicology.[91][92] With microarray technology the expression of thousands of genes can be measured in parallel. The gene expression profiles of Folsomia candida exposed to environmental toxicants allow fast and sensitive detection of pollution, and additionally clarifies molecular mechanisms causing toxicology.

Collembola have been found to be useful as bio-indicators of soil quality. Laboratory studies have been conducted that validated that the jumping ability of springtails can be used to evaluate the soil quality of Cu- and Ni-polluted sites.[93]

Climate warming impact

In polar regions that are expected to experience among the most rapid impact from climate warming, springtails have shown contrasting responses to warming in experimental warming studies.[94] There are negative,[95][96] positive[97][98] and neutral responses reported.[96][99] Neutral responses to experimental warming have also been reported in studies of non-polar regions.[100] The importance of soil moisture has been demonstrated in experiments using infrared heating in an alpine meadow, which had a negative effect on mesofauna biomass and diversity in drier parts and a positive effect in moist sub-areas.[101] Furthermore, a study with 20 years of experimental warming in three contrasting plant communities found that small scale heterogeneity may buffer springtails to potential climate warming.[99]

Reproduction

Sexual reproduction occurs through the clustered or scattered deposition of spermatophores by male adults. Stimulation of spermatophore deposition by female pheromones has been demonstrated in Sinella curviseta.[102] Mating behavior can be observed in Symphypleona.[103] Among Symphypleona, males of some Sminthuridae use a clasping organ located on their antenna.[35] Many collembolan species, mostly those living in deeper soil horizons, are parthenogenetic, which favors reproduction to the detriment of genetic diversity and thereby to population tolerance of environmental hazards.[104] Parthenogenesis (also called thelytoky) is under the control of symbiotic bacteria of the genus Wolbachia, which live, reproduce and are carried in female reproductive organs and eggs of Collembola.[105] Feminizing Wolbachia species are widespread in arthropods[106] and nematodes,[107] where they co-evolved with most of their lineages.

See also

References

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External links

 
Wikimedia Commons has media related to Collembola.
  • "Springtail" . Encyclopædia Britannica. Vol. 25 (11th ed.). 1911.
  • Checklist of the Collembola of the World
  • Summary information about the distribution and ecology of Collembola (springtails) in the UK and Ireland
  • General information on Collembola
  • General information on Collembola
  • A small lecture from Steve Hopkin
  • General information on Collembola, with many macrophotographs from Dutch springtails
  • Collembola species currently recorded from South Africa

March 06, 2023
springtail, collembola, form, largest, three, lineages, modern, hexapods, that, longer, considered, insects, other, protura, diplura, although, three, orders, sometimes, grouped, together, class, called, entognatha, because, they, have, internal, mouthparts, t. Springtails Collembola form the largest of the three lineages of modern hexapods that are no longer considered insects the other two are the Protura and Diplura Although the three orders are sometimes grouped together in a class called Entognatha because they have internal mouthparts they do not appear to be any more closely related to one another than they are to all insects which have external mouthparts SpringtailsTemporal range Early Devonian present PreꞒ Ꞓ O S D C P T J K Pg NOrchesella cinctaScientific classificationKingdom AnimaliaPhylum ArthropodaClass Entognatha Subclass CollembolaLubbock 1871OrdersEntomobryomorpha Poduromorpha Symphypleona Neelipleona disputed Synonyms 1 Oligentoma OligoentomaCollembolans are omnivorous free living organisms that prefer moist conditions They do not directly engage in the decomposition of organic matter but contribute to it indirectly through the fragmentation of organic matter 2 and the control of soil microbial communities 3 The word Collembola is from the ancient Greek kolla kolla glue and ἔmbolos embolos peg this name was given due to the existence of the collophore which was previously thought to stick to surfaces to stabilize the creature 4 Some DNA sequence studies 5 6 7 suggest that Collembola represent a separate evolutionary line from the other Hexapoda but others disagree 8 this seems to be caused by widely divergent patterns of molecular evolution among the arthropods 9 The adjustments of traditional taxonomic rank for springtails reflects the occasional incompatibility of traditional groupings with modern cladistics when they were included with the insects they were ranked as an order as part of the Entognatha they are ranked as a subclass If they are considered a basal lineage of Hexapoda they are elevated to full class status Contents 1 Morphology 2 Systematics and evolution 3 Ecology 3 1 Eating behavior 3 2 Predators 3 3 Distribution 3 4 Relationship with humans 3 5 Ecotoxicology laboratory animals 4 Climate warming impact 5 Reproduction 6 See also 7 References 8 External linksMorphology Edit Isotoma with visible furcula Members of the Collembola are normally less than 6 mm 0 24 in long have six or fewer abdominal segments and possess a tubular appendage the collophore or ventral tube with reversible sticky vesicles projecting ventrally from the first abdominal segment 10 It is believed to be associated with fluid uptake and balance excretion and orientation of the organism itself 11 Most species have an abdominal tail like appendage known as a furcula It is located on the fourth abdominal segment of collembolans and is folded beneath the body held under tension by a small structure called the retinaculum or tenaculum When released it snaps against the substrate flinging the springtail into the air and allowing for rapid evasion and travel All of this takes place in as little as 18 milliseconds 12 11 Springtails also possess the ability to reduce their body size by as much as 30 through subsequent ecdyses molting if temperatures rise high enough The shrinkage is genetically controlled Since warmer conditions increase metabolic rates and energy requirements in organisms the reduction in body size is advantageous to their survival 13 The Poduromorpha and Entomobryomorpha have an elongated body while the Symphypleona and Neelipleona have a globular body Collembola lack a tracheal respiration system which forces them to respire through a porous cuticle except for the two families Sminthuridae and Actaletidae which exhibit a single pair of spiracles between the head and the thorax leading to a rudimentary although fully functional tracheal system 14 10 The anatomical variance present between different species partially depends on soil morphology and composition Surface dwellers are generally larger have darker pigments have longer antennae and functioning furcula Sub surface dwellers are usually unpigmented have elongated bodies and reduced furcula They can be categorized into four main forms according to soil composition and depth atmobiotic epedaphic hemiedaphic and euedaphic Atmobiotic species inhabit macrophytes and litter surfaces They are generally 8 10 millimeters in length pigmented have long limbs and a full set of ocelli photoreceptors Epedaphic species inhabit upper litter layers and fallen logs They are slightly smaller and have less pronounced pigments as well as less developed limbs and ocelli than the atmobiotic species Hemiedaphic species inhabit the lower litter layers of decomposing organic material They are 1 2 millimeters in length have dispersed pigmentation shortened limbs and a reduced number of ocelli Euedaphic species inhabit upper mineral layers known as the humus horizon They are smaller than hemiedaphic species have soft elongated bodies lack pigmentation and ocelli and have reduced or absent furca 15 16 17 Poduromorphs inhabit the epedaphic hemiedaphic and euedaphic layers and are characterized by their elongated bodies and conspicuous segmentation three thoracic segments six abdominal segments and a prothorax 17 The digestive tract of collembolan species consists of three main components the foregut midgut and hindgut The midgut is surrounded by a network of muscles and lined with a monolayer of columnar or cuboidal cells Its function is to mix and transport food from the lumen into the hindgut through contraction Many species of syntrophic bacteria archaea and fungi are present in the lumen These different digestive regions have varying pH to support specific enzymatic activities and microbial populations The anterior portion of the midgut and hindgut is slightly acidic with a pH of approximately 6 0 while the posterior midgut portion is slightly alkaline with a pH of approximately 8 0 Between the midgut and hindgut is an alimentary canal called the pyloric region which is a muscular sphincter 11 Systematics and evolution Edit source source source source source source source source source source Allacma fusca Symphypleona on rotting wood Traditionally the springtails were divided into the orders Arthropleona Symphypleona and occasionally also Neelipleona The Arthropleona were divided into two superfamilies the Entomobryoidea and the Poduroidea However recent phylogenetic studies show Arthropleona is paraphyletic 18 19 20 Thus the Arthropleona are abolished in modern classifications and their superfamilies are raised in rank accordingly being now orders Entomobryomorpha and the Poduromorpha Technically the Arthropleona are thus a partial junior synonym of the Collembola 21 The term Neopleona is essentially synonymous with Symphypleona Neelipleona 22 The Neelipleona was originally seen as a particularly advanced lineage of Symphypleona based on the shared global body shape but the global body of the Neelipleona is realized in a completely different way than in Symphypleona Subsequently the Neelipleona were considered as being derived from the Entomobryomorpha Analysis of 18S and 28S rRNA sequence data though suggests that they form the most ancient lineage of springtails which would explain their peculiar apomorphies 8 This phylogenetic relationship was also confirmed using a phylogeny based on mtDNA 19 and whole genome data 20 The latest whole genome phylogeny supporting four orders of collembola 20 Neelipleona Poduromorpha Symphypleona Entomobryomorpha Springtails are attested to since the Early Devonian 23 The fossil from 400 million years ago Rhyniella praecursor is the oldest terrestrial arthropod and was found in the famous Rhynie chert of Scotland Given its morphology resembles extant species quite closely the radiation of the Hexapoda can be situated in the Silurian 420 million years ago or more 24 Additional research concerning the coprolites fossilized feces of ancient collembolans allowed researchers to track their lineages back some 412 million years 11 Fossil Collembola are rare Instead most are found in amber 25 Even these are rare and many amber deposits carry few or no collembola The best deposits are from the early Eocene of Canada and Europe 26 Miocene of Central America 27 and the mid Cretaceous of Burma and Canada 28 They display some unexplained characteristics first all but one of the fossils from the Cretaceous belong to extinct genera whereas none of the specimens from the Eocene or the Miocene are of extinct genera second the species from Burma are more similar to the modern fauna of Canada than are the Canadian Cretaceous specimens There are about 3 600 different species 29 Ecology EditEating behavior Edit Specific feeding strategies and mechanisms are employed to match specific niches 30 Herbivorous and detritivorous species fragment biological material present in soil and leaf litter supporting decomposition and increasing the availability of nutrients for various species of microbes and fungi 31 Carnivorous species maintain populations of small invertebrates such as nematodes rotifers and other collembolan species 11 15 Springtails commonly consume fungal hyphae and spores but also have been found to consume plant material and pollen animal remains colloidal materials minerals and bacteria 32 Predators Edit Springtails are consumed by mesostigmatan mites in various families including Ascidae Laelapidae Parasitidae Rhodacaridae and Veigaiidae 33 Cave dwelling springtails are a food source for spiders and harvestmen in the same environment such as the endangered harvestman Texella reyesi 34 Distribution Edit Springtails are cryptozoa frequently found in leaf litter and other decaying material 35 where they are primarily detritivores and microbivores and one of the main biological agents responsible for the control and the dissemination of soil microorganisms 36 In a mature deciduous woodland in temperate climate leaf litter and vegetation typically support 30 to 40 species of springtails and in the tropics the number may be over 100 37 Snow flea A species of Sminthurinae Symphypleona Sminthuridae In sheer numbers they are reputed to be one of the most abundant of all macroscopic animals with estimates of 100 000 individuals per square meter of ground 38 essentially everywhere on Earth where soil and related habitats moss cushions fallen wood grass tufts ant and termite nests occur 39 Only nematodes crustaceans and mites are likely to have global populations of similar magnitude and each of those groups except mites is more inclusive though taxonomic rank cannot be used for absolute comparisons it is notable that nematodes are a phylum and crustaceans a subphylum Most springtails are small and difficult to see by casual observation but one springtail the so called snow flea Hypogastrura nivicola is readily observed on warm winter days when it is active and its dark color contrasts sharply with a background of snow 40 In addition a few species routinely climb trees and form a dominant component of canopy faunas where they may be collected by beating or insecticide fogging 41 42 These tend to be the larger gt 2 mm species mainly in the genera Entomobrya and Orchesella though the densities on a per square meter basis are typically 1 2 orders of magnitude lower than soil populations of the same species In temperate regions a few species e g Anurophorus spp Entomobrya albocincta Xenylla xavieri Hypogastrura arborea are almost exclusively arboreal 39 In tropical regions a single square meter of canopy habitat can support many species of Collembola 12 The main ecological factor driving the local distribution of species is the vertical stratification of the environment in woodland a continuous change in species assemblages can be observed from tree canopies to ground vegetation then to plant litter down to deeper soil horizons 39 This is a complex factor embracing both nutritional and physiological requirements together with behavioural trends 43 dispersal limitation 44 and probable species interactions Some species have been shown to exhibit negative 45 or positive 43 gravitropism which adds a behavioural dimension to this still poorly understood vertical segregation Experiments with peat samples turned upside down showed two types of responses to disturbance of this vertical gradient called stayers and movers 46 Dicyrtomina sp on leaf As a group springtails are highly sensitive to desiccation because of their tegumentary respiration 47 although some species with thin permeable cuticles have been shown to resist severe drought by regulating the osmotic pressure of their body fluid 48 The gregarious behaviour of Collembola mostly driven by the attractive power of pheromones excreted by adults 49 gives more chance to every juvenile or adult individual to find suitable better protected places where desiccation could be avoided and reproduction and survival rates thereby fitness could be kept at an optimum 50 Sensitivity to drought varies from species to species 51 and increases during ecdysis 52 Given that springtails moult repeatedly during their entire life an ancestral character in Hexapoda they spend much time in concealed micro sites where they can find protection against desiccation and predation during ecdysis an advantage reinforced by synchronized moulting 53 The high humidity environment of many caves also favours springtails and there are numerous cave adapted species 54 55 including one Plutomurus ortobalaganensis living 1 980 metres 6 500 ft down the Krubera Cave 56 Anurida maritima on water The horizontal distribution of springtail species is affected by environmental factors which act at the landscape scale such as soil acidity moisture and light 39 Requirements for pH can be reconstructed experimentally 57 Altitudinal changes in species distribution can be at least partly explained by increased acidity at higher elevation 58 Moisture requirements among other ecological and behavioural factors explain why some species cannot live aboveground 59 or retreat in the soil during dry seasons 60 but also why some epigeal springtails are always found in the vicinity of ponds and lakes such as the hygrophilous Isotomurus palustris 61 Adaptive features such as the presence of a fan like wettable mucro allow some species to move at the surface of water Sminthurides aquaticus Sminthurides malmgreni Podura aquatica a unique representative of the family Poduridae and one of the first springtails to have been described by Carl Linnaeus spends its entire life at the surface of water its wettable eggs dropping in water until the non wettable first instar hatches then surfaces 62 In a variegated landscape made of a patchwork of closed woodland and open meadows cereal crops environments most soil dwelling species are not specialized and can be found everywhere but most epigeal and litter dwelling species are attracted to a particular environment either forested or not 39 63 As a consequence of dispersal limitation landuse change when too rapid may cause the local disappearance of slow moving specialist species 64 a phenomenon the measure of which has been called colonisation credit 65 66 Relationship with humans Edit Tomocerus sp from Germany Springtails are well known as pests of some agricultural crops Sminthurus viridis the lucerne flea has been shown to cause severe damage to agricultural crops 67 and is considered as a pest in Australia 68 69 Onychiuridae are also known to feed on tubers and to damage them to some extent 70 However by their capacity to carry spores of mycorrhizal fungi and mycorrhiza helper bacteria on their tegument soil springtails play a positive role in the establishment of plant fungal symbioses and thus are beneficial to agriculture 71 They also contribute to controlling plant fungal diseases through their active consumption of mycelia and spores of damping off and pathogenic fungi 72 73 It has been suggested that they could be reared to be used for the control of pathogenic fungi in greenhouses and other indoor cultures 74 75 Various sources and publications have suggested that some springtails may parasitize humans but this is entirely inconsistent with their biology and no such phenomenon has ever been scientifically confirmed though it has been documented that the scales or hairs from collembolans can cause irritation when rubbed onto the skin 76 They may sometimes be abundant indoors in damp places such as bathrooms and basements and incidentally found on one s person More often claims of persistent human skin infection by springtails may indicate a neurological problem such as delusional parasitosis a psychological rather than entomological problem Researchers themselves may be subject to psychological phenomena For example a publication in 2004 claiming that springtails had been found in skin samples was later determined to be a case of pareidolia that is no springtail specimens were actually recovered but the researchers had digitally enhanced photos of sample debris to create images resembling small arthropod heads which then were claimed to be springtail remnants 76 77 78 79 80 However Steve Hopkin reports one instance of an entomologist aspirating an Isotoma species and in the process accidentally inhaling some of their eggs which hatched in his nasal cavity and made him quite ill until they were flushed out 37 In 1952 China accused the United States military of spreading bacteria laden insects and other objects during the Korean War by dropping them from P 51 fighters above rebel villages over North Korea In all the U S was accused of dropping ants beetles crickets fleas flies grasshoppers lice springtails and stoneflies as part of a biological warfare effort The alleged associated diseases included anthrax cholera dysentery fowl septicemia paratyphoid plague scrub typhus small pox and typhoid China created an international scientific commission for investigating possible bacterial warfare eventually ruling that the United States probably did engage in limited biological warfare in Korea The US government denied all the allegations and instead proposed that the United Nations send a formal inquiry committee to China and Korea but China and Korea refused to cooperate U S and Canadian entomologists further claimed that the accusations were ridiculous and argued that anomalous appearances of insects could be explained through natural phenomena 81 Springtail species cited in allegations of biological warfare in the Korean War were Isotoma Desoria negishina a local species and the white rat springtail Folsomia candida 82 Captive springtails are often kept in a terrarium as part of a clean up crew 83 Ecotoxicology laboratory animals Edit Springtails are currently used in laboratory tests for the early detection of soil pollution Acute and chronic toxicity tests have been performed by researchers mostly using the parthenogenetic isotomid Folsomia candida 84 These tests have been standardized 85 Details on a ringtest on the biology and ecotoxicology of Folsomia candida and comparison with the sexual nearby species Folsomia fimetaria sometimes preferred to Folsomia candida are given in a document written by Paul Henning Krogh 86 Care should be taken that different strains of the same species may be conducive to different results Avoidance tests have been also performed 87 They have been standardized too 88 Avoidance tests are complementary to toxicity tests but they also offer several advantages they are more rapid thus cheaper more sensitive and they are environmentally more reliable because in the real world Collembola move actively far from pollution spots 89 It may be hypothesized that the soil could become locally depauperated in animals and thus improper to normal use while below thresholds of toxicity Contrary to earthworms and like many insects and molluscs Collembola are very sensitive to herbicides and thus are threatened in no tillage agriculture which makes a more intense use of herbicides than conventional agriculture 90 The springtail Folsomia candida is also becoming a genomic model organism for soil toxicology 91 92 With microarray technology the expression of thousands of genes can be measured in parallel The gene expression profiles of Folsomia candida exposed to environmental toxicants allow fast and sensitive detection of pollution and additionally clarifies molecular mechanisms causing toxicology Collembola have been found to be useful as bio indicators of soil quality Laboratory studies have been conducted that validated that the jumping ability of springtails can be used to evaluate the soil quality of Cu and Ni polluted sites 93 Climate warming impact EditIn polar regions that are expected to experience among the most rapid impact from climate warming springtails have shown contrasting responses to warming in experimental warming studies 94 There are negative 95 96 positive 97 98 and neutral responses reported 96 99 Neutral responses to experimental warming have also been reported in studies of non polar regions 100 The importance of soil moisture has been demonstrated in experiments using infrared heating in an alpine meadow which had a negative effect on mesofauna biomass and diversity in drier parts and a positive effect in moist sub areas 101 Furthermore a study with 20 years of experimental warming in three contrasting plant communities found that small scale heterogeneity may buffer springtails to potential climate warming 99 Reproduction EditSexual reproduction occurs through the clustered or scattered deposition of spermatophores by male adults Stimulation of spermatophore deposition by female pheromones has been demonstrated in Sinella curviseta 102 Mating behavior can be observed in Symphypleona 103 Among Symphypleona males of some Sminthuridae use a clasping organ located on their antenna 35 Many collembolan species mostly those living in deeper soil horizons are parthenogenetic which favors reproduction to the detriment of genetic diversity and thereby to population tolerance of environmental hazards 104 Parthenogenesis also called thelytoky is under the control of symbiotic bacteria of the genus Wolbachia which live reproduce and are carried in female reproductive organs and eggs of Collembola 105 Feminizing Wolbachia species are widespread in arthropods 106 and nematodes 107 where they co evolved with most of their lineages See also Edit Arthropods portalHexapodaReferences Edit Gillott Cedric 2005 Apterygote hexapods Entomology 3rd ed Berlin Springer pp 113 125 doi 10 1007 1 4020 3183 1 5 ISBN 978 0 306 44967 3 Brady Nyle C amp Weil Ray R 2009 Organisms and ecology of the soil Elements of the nature and properties of soils 3rd ed Upper Saddle River Prentice Hall ISBN 978 0 13 501433 2 OCLC 276340542 Thimm Torsten Hoffmann Andrea Borkott Heinz Munch Jean Charles amp Tebbe Christoph C 1998 The gut of the soil microarthropod Folsomia candida Collembola is a frequently changeable but selective habitat and a vector for microorganisms Applied and Environmental Microbiology 64 7 2660 2669 Bibcode 1998ApEnM 64 2660T doi 10 1128 AEM 64 7 2660 2669 1998 PMC 106441 PMID 9647845 Lubbock John 1873 Monograph of the Collembola and Thysanura London Ray Society p 36 Nardi Francesco Spinsanti Giacomo Boore Jeffrey L Carapelli Antonio Dallai Romano amp Frati Francesco 2003 Hexapod origins monophyletic or paraphyletic PDF Science 299 5614 1887 1889 Bibcode 2003Sci 299 1887N doi 10 1126 science 1078607 PMID 12649480 S2CID 38792657 Delsuc Frederic Phillips Matthew J amp Penny David 2003 Comment on Hexapod origins monophyletic or paraphyletic PDF Science 301 5639 1482 doi 10 1126 science 1086558 PMID 12970547 S2CID 43942720 Nardi Francesco Spinsanti Giacomo Boore Jeffrey L Carapelli Antonio Dallai Romano amp Frati Francesco 2003 Response to comment on Hexapod origins monophyletic or paraphyletic PDF Science 301 5639 1482 doi 10 1126 science 1087632 S2CID 82407120 a b Gao Yan Bu Yun amp Luan Yun Xia 2008 Phylogenetic relationships of basal hexapods reconstructed from nearly complete 18S and 28S rRNA gene sequences PDF Zoological Science 25 11 1139 1145 doi 10 2108 zsj 25 1139 PMID 19267625 S2CID 10783597 Hassanin Alexandre 2006 Phylogeny of Arthropoda inferred from mitochondrial sequences strategies for limiting the misleading effects of multiple changes in pattern and rates of substitution PDF Molecular Phylogenetics and Evolution 38 1 100 116 doi 10 1016 j ympev 2005 09 012 PMID 16290034 a b Davies W Maldwyn 1927 On the tracheal system of Collembola with special reference to that of Sminthurus viridis Lubb PDF Quarterly Journal of Microscopical Science 71 281 15 30 a b c d e Hopkin Stephen P 1997 Biology of the springtails Insecta Collembola Oxford Oxford University Press a b Piper Ross 2007 Extraordinary animals an encyclopedia of curious and unusual animals Santa Barbara California Greenwood Press ISBN 9780313339226 OCLC 124074839 The incredible shrinking springtail Science 341 6149 945 30 August 2013 doi 10 1126 science 341 6149 945 a Multicellular Animals Volume II The Phylogenetic System of the Metazoa a b Coleman David C Wall Diana H 2015 01 01 Paul Eldor A ed Chapter 5 Soil Fauna Occurrence Biodiversity and Roles in Ecosystem Function Soil Microbiology Ecology and Biochemistry Fourth Edition Academic Press pp 111 149 ISBN 978 0 12 415955 6 retrieved 2020 03 16 Potapov Anton A Semenina Eugenia E Korotkevich Anastasiya Yu Kuznetsova Natalia A Tiunov Alexei V 2016 10 01 Connecting taxonomy and ecology Trophic niches of collembolans as related to taxonomic identity and life forms Soil Biology and Biochemistry 101 20 31 doi 10 1016 j soilbio 2016 07 002 ISSN 0038 0717 a b Jordana Rafael Baquero Martin Enrique Ledesma Enrique Sendra Alberto Ortuno Vicente 2020 02 01 Poduromorpha Collembola from a sampling in the mesovoid shallow substratum of the Sierra de Guadarrama National Park Madrid and Segovia Spain Taxonomy and Biogeography Zoologischer Anzeiger 285 81 96 doi 10 1016 j jcz 2020 02 001 S2CID 214349457 Xiong Y Gao Y Yin W Luan Y 2008 Molecular phylogeny of Collembola inferred from ribosomal RNA genes Molecular Phylogenetics and Evolution 49 3 728 735 doi 10 1016 j ympev 2008 09 007 ISSN 1055 7903 PMID 18835455 a b Leo Chiara Carapelli Antonio Cicconardi Francesco Frati Francesco Nardi Francesco 2019 Mitochondrial Genome Diversity in Collembola Phylogeny Dating and Gene Order Diversity 11 9 169 doi 10 3390 d11090169 ISSN 1424 2818 a b c Sun Xin Ding Yinhuan Orr Michael C Zhang Feng 2020 Streamlining universal single copy orthologue and ultraconserved element design A case study in Collembola Molecular Ecology Resources 20 3 706 717 doi 10 1111 1755 0998 13146 ISSN 1755 098X PMID 32065730 S2CID 211133755 Checklist of the Collembola Retrieved January 2 2016 Sanchez Garcia Alba amp Engel Michael S 2016 Long term stasis in a diverse fauna of Early Cretaceous springtails Collembola Symphypleona PDF Journal of Systematic Palaeontology 1 25 Daly Howell V Doyen John T amp Purcell Alexander H 1998 Introduction to insect biology and diversity 2nd ed New York Oxford University Press ISBN 978 0 19 510033 4 OCLC 925231875 Hexapoda Insects springtails diplurans and proturans Tree of Life Web Project January 1 2002 Retrieved March 26 2017 Mari Mutt Jose A 1983 Collembola in amber from the Dominican Republic PDF Proceedings of the Entomological Society of Washington 85 3 575 587 Nel Andre De Ploeg Gael Milliet Jacqueline Menier Jean Jacques amp Waller Alain 2004 The French ambers a general conspectus and the Lowermost Eocene amber deposit of Le Quesnoy in the Paris Basin PDF Geologica Acta 2 1 3 8 Penney David McNeil Andrew Green David I Bradley Robert S Jepson James E Withers Philip J amp Preziosi Richard F 2012 Ancient Ephemeroptera Collembola symbiosis fossilized in amber predicts contemporary phoretic associations PLOS ONE 7 10 e47651 Bibcode 2012PLoSO 747651P doi 10 1371 journal pone 0047651 PMC 3474712 PMID 23082186 Christiansen Kenneth amp Nascimbene Paul 2006 Collembola Arthropoda Hexapoda from the mid Cretaceous of Myanmar Burma PDF Cretaceous Research 27 3 318 33 doi 10 1016 j cretres 2005 07 003 Koehler Philip G Aparicio M L amp Pfiester Margaret July 2011 Springtails PDF Gainesville Florida University of Florida IFAS Extension Retrieved March 26 2017 Sechi Valentina D Annibale Alessandra Ambus Per Sarossy Zsuzsa Krogh Paul Henning Eriksen Jorgen Holmstrup Martin 2014 07 01 Collembola feeding habits and niche specialization in agricultural grasslands of different composition Soil Biology and Biochemistry 74 31 38 doi 10 1016 j soilbio 2014 02 019 ISSN 0038 0717 Rusek Josef September 1998 Biodiversity of Collembola and their functional role in the ecosystem Biodiversity and Conservation 7 9 1207 1219 doi 10 1023 a 1008887817883 ISSN 0960 3115 S2CID 22883809 Chen Benrong Snider Richard J amp Snider Renate M 1996 Food consumption by Collembola from northern Michigan deciduous forest PDF Pedobiologia 40 2 149 161 Koehler H H 1999 Predatory mites Gamasina Mesostigmata Invertebrate Biodiversity as Bioindicators of Sustainable Landscapes Elsevier pp 395 410 doi 10 1016 b978 0 444 50019 9 50022 4 ISBN 978 0 444 50019 9 retrieved 2022 10 06 City of Austin and Travis County September 3 2020 Support for Maintaining Endangered Status For the Bone Cave Harvestman Texella reyesi Retrieved October 6 2022 a b Hopkin Stephen P 1997 The biology of the Collembola springtails the most abundant insects in the world PDF Natural History Museum Retrieved January 2 2016 Ponge Jean Francois 1991 Food resources and diets of soil animals in a small area of Scots pine litter PDF Geoderma 49 1 2 33 62 Bibcode 1991Geode 49 33P CiteSeerX 10 1 1 635 8529 doi 10 1016 0016 7061 91 90090 G a b Hopkin Stephen P 1997 Biology of the Springtails Insecta Collembola OUP Oxford p 127 ISBN 978 0 19 158925 6 Ponge Jean Francois Arpin Pierre Sondag Francis amp Delecour Ferdinand 1997 Soil fauna and site assessment in beech stands of the Belgian Ardennes PDF Canadian Journal of Forest Research 27 12 2053 2064 doi 10 1139 cjfr 27 12 2053 a b c d e Ponge Jean Francois 1993 Biocenoses of Collembola in atlantic temperate grass woodland ecosystems PDF Pedobiologia 37 4 223 244 Lyford Walter H 1975 Overland migration of Collembola Hypogastrura nivicola Fitch colonies PDF American Midland Naturalist 94 1 205 209 doi 10 2307 2424550 JSTOR 2424550 Shaw Peter Ozanne Claire Speight Martin amp Palmer Imogen 2007 Edge effects and arboreal Collembola in coniferous plantations PDF Pedobiologia 51 4 287 293 doi 10 1016 j pedobi 2007 04 010 Zettel Jurg Zettel Ursula amp Egger Beatrice 2000 Jumping technique and climbing behaviour of the collembolan Ceratophysella sigillata Collembola Hypogastruridae PDF European Journal of Entomology 97 1 41 45 doi 10 14411 eje 2000 010 a b Didden Wim A M 1987 Reactions of Onychiurus fimatus Collembola to loose and compact soil methods and first results PDF Pedobiologia 30 2 93 100 Rodgers Denis J amp Kitching Rodger L 1998 Vertical stratification of rainforest collembolan Collembola Insecta assemblages description of ecological patterns and hypotheses concerning their generation Ecography 21 4 392 400 CiteSeerX 10 1 1 476 6663 doi 10 1111 j 1600 0587 1998 tb00404 x S2CID 85133291 Bowden John Haines Ian H amp Mercer D 1976 Climbing Collembola Pedobiologia 16 4 298 312 Krab Eveline J Oorsprong Hilde Berg Matty P amp Cornelissen Johannes H C 2010 Turning northern peatlands upside down disentangling microclimate and substrate quality effects on vertical distribution of Collembola PDF Functional Ecology 24 6 1362 1369 doi 10 1111 j 1365 2435 2010 01754 x Nickerl Julia Helbig Ralf Schulz Hans Jurgen Werner Carsten amp Neinhuis Christoph 2013 Diversity and potential correlations to the function of Collembola cuticle structures PDF Zoomorphology 132 2 183 195 doi 10 1007 s00435 012 0181 0 S2CID 14442664 Holmstrup Martin amp Bayley Mark 2013 Protaphorura tricampata a euedaphic and highly permeable springtail that can sustain activity by osmoregulation during extreme drought Journal of Insect Physiology 59 11 1104 1110 doi 10 1016 j jinsphys 2013 08 015 PMID 24035747 Verhoef Herman A 1984 Releaser and primer pheromones in Collembola PDF Journal of Insect Physiology 30 8 665 670 doi 10 1016 0022 1910 84 90052 0 Benoit Joshua B Elnitsky Michael A Schulte Glen G Lee Richard E Jr amp Denlinger David L 2009 Antarctic Collembolans use chemical signals to promote aggregation and egg laying PDF Journal of Insect Behavior 22 2 121 133 doi 10 1007 s10905 008 9159 7 S2CID 914560 Prinzing Andreas D Haese Cyrille A Pavoine Sandrine amp Ponge Jean Francois 2014 Species living in harsh environments have low clade rank and are localized on former Laurasian continents a case study of Willemia Collembola PDF Journal of Biogeography 41 2 353 365 doi 10 1111 jbi 12188 S2CID 86619537 Verhoef Herman A 1981 Water balance in Collembola and its relation to habitat selection water content haemolymph osmotic pressure and transpiration during an instar Journal of Insect Physiology 27 11 755 760 doi 10 1016 0022 1910 81 90065 2 Leinaas Hans Petter 1983 Synchronized moulting controlled by communication in group living Collembola Science 219 4581 193 195 Bibcode 1983Sci 219 193P doi 10 1126 science 219 4581 193 PMID 17841689 S2CID 41604935 Wilson Jane M 1982 A review of world Troglopedetini Insecta Collembola Paronellidae including an identification table and descriptions of new species PDF Cave Science Transactions of the British Cave Research Association 9 3 210 226 Palacios Vargas Jose G amp Wilson Jane 1990 Troglobius coprophagus a new genus and species of cave collembolan from Madagascar with notes on its ecology PDF International Journal of Speleology 19 1 4 67 73 doi 10 5038 1827 806x 19 1 6 Jordana Rafael Baquero Enrique Reboleira Sofia amp Sendra Alberto 2012 Reviews of the genera Schaefferia Absolon 1900 Deuteraphorura Absolon 1901 Plutomurus Yosii 1956 and the Anurida Laboulbene 1865 species group without eyes with the description of four new species of cave springtails Collembola from Krubera Voronya cave Arabika Massif Abkhazia PDF Terrestrial Arthropod Reviews 5 1 35 85 doi 10 1163 187498312X622430 hdl 10171 27607 Salmon Sandrine Ponge Jean Francois amp Van Straalen Nico 2002 Ionic identity of pore water influences pH preference in Collembola PDF Soil Biology and Biochemistry 34 11 1663 1667 doi 10 1016 S0038 0717 02 00150 5 Loranger Gladys Bandyopadhyaya Ipsa Razaka Barbara amp Ponge Jean Francois 2001 Does soil acidity explain altitudinal sequences in collembolan communities PDF Soil Biology and Biochemistry 33 3 381 393 doi 10 1016 S0038 0717 00 00153 X S2CID 84523833 Faber Jack H amp Joosse Els N G 1993 Vertical distribution of Collembola in a Pinus nigra organic soil Pedobiologia 37 6 336 350 Detsis Vassilis 2000 Vertical distribution of Collembola in deciduous forests under Mediterranean climatic conditions PDF Belgian Journal of Zoology 130 Supplement 1 57 61 Isotomurus palustris Muller 1776 Retrieved April 2 2017 Pichard Sylvain 1973 Contribution a l etude de la biologie de Podura aquatica Linne Collembole Bulletin Biologique de la France et de la Belgique in French 107 4 291 299 Ponge Jean Francois Gillet Servane Dubs Florence Fedoroff Eric Haese Lucienne Sousa Jose Paulo amp Lavelle Patrick 2003 Collembolan communities as bioindicators of land use intensification PDF Soil Biology and Biochemistry 35 6 813 826 doi 10 1016 S0038 0717 03 00108 1 hdl 10316 3875 S2CID 86289373 Ponge Jean Francois Dubs Florence Gillet Servane Sousa Jose Paulo amp Lavelle Patrick 2006 Decreased biodiversity in soil springtail communities the importance of dispersal and landuse history in heterogeneous landscapes PDF Soil Biology and Biochemistry 38 5 1158 1161 doi 10 1016 j soilbio 2005 09 004 Cristofoli Sara amp Mahy Gregory 2010 Colonisation credit in recent wet heathland butterfly communities Insect Conservation and Diversity 3 2 83 91 doi 10 1111 j 1752 4598 2009 00075 x S2CID 86558143 Heiniger Charlene Barot Sebastien Ponge Jean Francois Salmon Sandrine Botton Divet Leo Carmignac David amp Dubs Florence 2014 Effect of habitat spatiotemporal structure on collembolan diversity PDF Pedobiologia 57 2 103 117 doi 10 1016 j pedobi 2014 01 006 Shaw Michael W amp Haughs G M 1983 Damage to potato foliage by Sminthurus viridis L PDF Plant Pathology 32 4 465 466 doi 10 1111 j 1365 3059 1983 tb02864 x Bishop Alan L Harris Anne M amp McKenzie Harry J 2001 Distribution and ecology of the lucerne flea Sminthurus viridis L Collembola Sminthuridae in irrigated lucerne in the Hunter dairying region of New South Wales PDF Australian Journal of Entomology 40 1 49 55 doi 10 1046 j 1440 6055 2001 00202 x Lucerne Flea State of Victoria 2017 Retrieved June 2 2018 Baker A N amp Dunning Andrew R 1975 Association of populations of onychiurid Collembola with damage to sugar beet seedlings PDF Plant Pathology 24 3 150 154 doi 10 1111 j 1365 3059 1975 tb01882 x Klironomos John N amp Moutoglis Peter 1999 Colonization of nonmycorrhizal plants by mycorrhizal neighbours as influenced by the collembolan Folsomia candida PDF Biology and Fertility of Soils 29 3 277 281 doi 10 1007 s003740050553 S2CID 11014525 Sabatini Maria Agnese amp Innocenti Gloria 2001 Effects of Collembola on plant pathogenic fungus interactions in simple experimental systems PDF Biology and Fertility of Soils 33 1 62 66 doi 10 1007 s003740000290 S2CID 9273050 Shiraishi Hiroyoshi Enami Yoshinari amp Okano Seigo 2003 Folsomia hidakana Collembola prevents damping off disease in cabbage and Chinese cabbage by Rhizoctonia solani PDF Pedobiologia 47 1 33 38 doi 10 1078 0031 4056 00167 Ponge Jean Francois amp Charpentie Marie Jose 1981 Etude des relations microflore microfaune experiences sur Pseudosinella alba Packard Collembole mycophage PDF Revue d Ecologie et de Biologie du Sol in French 18 291 303 Lartey Robert T Curl Elroy A Peterson Curt M amp Harper James D 1989 Mycophagous grazing and food preference of Proisotoma minuta Collembola Isotomidae and Onychiurus encarpatus Collembola Onychiuridae Environmental Entomology 18 2 334 337 doi 10 1093 ee 18 2 334 a b Janssens Frans amp Christiansen Kenneth A November 22 2007 Synanthropic Collembola springtails in association with Man Checklist of the Collembola Retrieved April 9 2017 Berenbaum May 2005 Face time PDF American Entomologist 51 2 68 69 doi 10 1093 ae 51 2 68 Christiansen Kenneth amp Bernard Ernest C 2008 Critique of the article Collembola Springtails Arthropoda Hexapoda Entognatha found in scrapings from individuals diagnosed with delusory parasitosis Entomological News 119 5 537 540 doi 10 3157 0013 872x 119 5 537 S2CID 83870937 Lim Christopher Seng Hong Lim Scott L Chew Fook Tim amp Deharveng Louis 2009 Collembola are unlikely to cause human dermatitis Journal of Insect Science 9 3 1 5 doi 10 1673 031 009 0301 PMC 3011850 PMID 19611235 Shelomi Matan 2013 Evidence of photo manipulation in a delusional parasitosis paper PDF Journal of Parasitology 99 3 583 585 doi 10 1645 12 12 1 PMID 23198757 S2CID 6473251 Retrieved 29 January 2019 Insects as Biological Weapons Insects Disease and History Montana State University www montana edu Retrieved 2022 10 06 Lockwood Jeffrey A 2009 Six legged soldiers using insects as weapons of war 1st ed Oxford UK Oxford University Press ISBN 978 0 19 533305 3 The Top 5 Bioactive Clean Up Crew Northampton Reptile Centre 16 December 2015 Retrieved 6 July 2021 a href Template Cite web html title Template Cite web cite web a CS1 maint url status link Fountain Michelle T amp Hopkin Steve P 2001 Continuous monitoring of Folsomia candida Insecta Collembola in a metal exposure test PDF Ecotoxicology and Environmental Safety 48 3 275 286 doi 10 1006 eesa 2000 2007 PMID 11222037 ISO 11267 2014 Soil quality Inhibition of reproduction of Collembola Folsomia candida by soil contaminants Geneva International Organization for Standardization Krogh Paul Henning August 1 2008 Toxicity testing with the collembolans Folsomia fimetaria and Folsomia candida and the results of a ringtest PDF Retrieved April 17 2017 Lors Christine Martinez Aldaya Maite Salmon Sandrine amp Ponge Jean Francois 2006 Use of an avoidance test for the assessment of microbial degradation of PAHs PDF Soil Biology and Biochemistry 38 8 2199 2204 doi 10 1016 j soilbio 2006 01 026 ISO 17512 2 2011 Soil quality Avoidance test for determining the quality of soils and effects of chemicals on behaviour Part 2 Test with collembolans Folsomia candida Geneva International Organization for Standardization Chauvat Matthieu amp Ponge Jean Francois 2002 Colonization of heavy metal polluted soils by collembola preliminary experiments in compartmented boxes PDF Applied Soil Ecology 21 2 91 106 doi 10 1016 S0929 1393 02 00087 2 Ponge Jean Francois Bandyopadhyaya Ipsa amp Marchetti Valerie 2002 Interaction between humus form and herbicide toxicity to Collembola Hexapoda PDF Applied Soil Ecology 20 3 239 253 doi 10 1016 S0929 1393 02 00026 4 Nota Benjamin Timmermans Martijn J T N Franken Oscar Montagne Wajer Kora Marien Janine De Boer Muriel E De Boer Tjalf E Ylstra Bauke Van Straalen Nico M amp Roelofs Dick 2008 Gene expression analysis of Collembola in cadmium containing soil PDF Environmental Science and Technology 42 21 8152 8157 Bibcode 2008EnST 42 8152N doi 10 1021 es801472r PMID 19031917 Nota Benjamin Bosse Mirte Ylstra Bauke Van Straalen Nico M amp Roelofs Dick 2009 Transcriptomics reveals extensive inducible biotransformation in the soil dwelling invertebrate Folsomia candida exposed to phenanthrene BMC Genomics 10 236 doi 10 1186 1471 2164 10 236 PMC 2688526 PMID 19457238 Kim Shin Woong amp An Youn Joo 2014 Jumping behavior of the springtail Folsomia candida as a novel soil quality indicator in metal contaminated soils Ecological Indicators 38 67 71 doi 10 1016 j ecolind 2013 10 033 Nielsen Uffe N amp Wall Diana H 2013 The future of soil invertebrate communities in polar regions different climate change responses in the Arctic and Antarctic Ecology Letters 16 3 409 419 doi 10 1111 ele 12058 PMID 23278945 Coulson Stephen James Hodkinson Ian D Woolley Christopher Webb Nigel R Block William Worland M Rodger Bale Jeff S amp Strathdee Andrew T 1996 Effects of experimental temperature elevation on high arctic soil microarthropod populations PDF Polar Biology 16 2 147 153 doi 10 1007 BF02390435 S2CID 13826340 a b Sjursen Heidi Michelsen Anders amp Jonasson Sven 2005 Effects of long term soil warming and fertilisation on microarthropod abundances in three sub arctic ecosystems PDF Applied Soil Ecology 30 3 148 161 doi 10 1016 j apsoil 2005 02 013 Dollery Rebecca Hodkinson Ian D amp Jonsdottir Ingibjorg S 2006 Impact of warming and timing of snow melt on soil microarthropod assemblages associated with Dryas dominated plant communities on Svalbard PDF Ecography 29 1 111 119 doi 10 1111 j 2006 0906 7590 04366 x Hagvar Sigmund amp Klanderud Kari 2009 Effect of simulated environmental change on alpine soil arthropods PDF Global Change Biology 15 12 2972 2980 Bibcode 2009GCBio 15 2972H CiteSeerX 10 1 1 658 1606 doi 10 1111 j 1365 2486 2009 01926 x S2CID 36287733 a b Alatalo Juha M Jagerbrand Annika K amp Cuchta Peter 2015 Collembola in three alpine subarctic sites resistant to twenty years of experimental warming Scientific Reports 5 18161 18161 Bibcode 2015NatSR 518161A doi 10 1038 srep18161 PMC 4680968 PMID 26670681 Kardol Paul Reynolds W Nicholas Norby Richard J amp Classen Aimee T 2011 Climate change effects on soil microarthropod abundance and community structure PDF Applied Soil Ecology 47 1 37 44 doi 10 1016 j apsoil 2010 11 001 Harte John Rawa Agnieszka amp Price Vanessa 1996 Effects of manipulated soil microclimate on mesofaunal biomass and diversity PDF Soil Biology and Biochemistry 28 3 313 322 doi 10 1016 0038 0717 95 00139 5 Waldorf Elizabeth S 1974 Sex pheromone in the springtail Sinella curviseta Environmental Entomology 3 6 916 918 doi 10 1093 ee 3 6 916 Kozlowski Marek Wojciech amp Aoxiang Shi 2006 Ritual behaviors associated with spermatophore transfer in Deuterosminthurus bicinctus Collembola Bourletiellidae Journal of Ethology 24 2 103 110 doi 10 1007 s10164 005 0162 6 S2CID 12056710 Simon Jean Christophe Delmote Francois Rispe Claude amp Crease Teresa 2003 Phylogenetic relationships between parthenogens and their sexual relatives the possible routes to parthenogenesis in animals PDF Biological Journal of the Linnean Society 79 1 151 153 doi 10 1046 j 1095 8312 2003 00175 x Czarnetzki Alice B amp Tebbe Christoph C 2004 Detection and phylogenetic analysis of Wolbachia in Collembola PDF Environmental Microbiology 6 1 35 44 doi 10 1046 j 1462 2920 2003 00537 x PMID 14686939 Werren John H Zhang Wan amp Guo Li Rong 1995 Evolution and phylogeny of Wolbachia reproductive parasites of arthropods PDF Proceedings of the Royal Society B 261 1360 55 63 Bibcode 1995RSPSB 261 55W doi 10 1098 rspb 1995 0117 JSTOR 50047 PMID 7644549 S2CID 8585323 Fenn Katelyn amp Blaxter Mark 2004 Are filarial nematode Wolbachia obligate mutualist symbionts PDF Trends in Ecology and Evolution 19 4 163 166 doi 10 1016 j tree 2004 01 002 PMID 16701248 External links Edit Wikimedia Commons has media related to Collembola Springtail Encyclopaedia Britannica Vol 25 11th ed 1911 Checklist of the Collembola of the World Summary information about the distribution and ecology of Collembola springtails in the UK and Ireland General information on Collembola General information on Collembola A small lecture from Steve Hopkin General information on Collembola with many macrophotographs from Dutch springtails Collembola species currently recorded from South Africa Retrieved from https en wikipedia org w index php title Springtail amp oldid 1131121796, wikipedia, wiki, book, books, library,

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