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Entognatha

Entognatha is a class of small, wingless arthropods belonging to the subphylum Hexapoda, alongside the class Insecta, and is characterized primarily by its entognathous mouthparts, which are retracted into a pouch-like cavity within the head capsule rather than being exposed externally.^[1] These hexapods, totaling approximately 11,000 described species (as of 2024), undergo ametabolous development—lacking distinct larval or pupal stages—and are adapted to moist terrestrial habitats such as soil, leaf litter, and decaying organic matter, where they contribute significantly to decomposition and nutrient cycling.^[2] Unlike insects, Entognathans lack wings, a tracheal respiratory system in some groups, and compound eyes, with gas exchange often occurring through the thin body wall or cuticle.^[3] The class Entognatha encompasses three extant orders: Collembola (springtails), Diplura (two-pronged bristletails), and Protura (coneheads).^[1] Collembola, the most diverse order with about 9,600 species worldwide (as of 2024), are notable for their furcula—a tail-like appendage that enables explosive jumping—and collophore, which aids in moisture regulation; they are ubiquitous in soils and can reach densities of thousands per square meter in favorable conditions.^[4] Diplura, comprising around 1,000 species (as of 2021), feature elongated cerci that function in sensory perception and defense, with many species exhibiting autotomy (self-amputation) of these appendages; they are primarily predatory or scavenging soil dwellers.^[5] Protura, the smallest order with about 850 species (as of 2025), are highly specialized, lacking eyes and antennae altogether, and relying on forelegs modified as feelers; their styliform mouthparts are suited for piercing and sucking, and they inhabit similar humid microhabitats.^[6] Entognathans exhibit several primitive traits relative to insects, including fully muscled antennae with multiple segments and indirect sperm transfer via spermatophores, reflecting their basal position in hexapod evolution.^[3] While generally beneficial in ecosystems for breaking down organic material and serving as prey for larger invertebrates, some Collembola species can become agricultural pests by damaging seedlings or crops in high densities.^[1] Their diversity and abundance underscore their ecological importance, particularly in forest and grassland soils, though they remain understudied compared to insects.^[2]

Taxonomy and Phylogeny

Classification

Entognatha is recognized as a class within the subphylum Hexapoda of the phylum Arthropoda, comprising the three orders Collembola (springtails), Diplura (two-pronged bristletails), and Protura (coneheads).^[1] These wingless hexapods are distinguished from the class Insecta (Ectognatha) primarily by the structure of their mouthparts.^[3] The taxonomic grouping of Entognatha was historically established based on the shared feature of entognathous mouthparts, with the name proposed by R. von Stummer-Traunfels in 1891 to unite certain wingless hexapods.^[7] This classification emphasized the internalization of the mouthparts as a defining characteristic, contrasting with the external mouthparts of true insects.^[8] Early 20th-century contributions, including those by Henri Janvier, further refined the recognition of this clade through detailed morphological studies of apterygote hexapods.^[7] Collembola accounts for the vast majority of Entognatha diversity, underscoring its dominance within the class.^[9] Key synapomorphies supporting the recognition of Entognatha include the entognathous condition, where mouthparts are retracted into a ventral gnathal pouch within the head capsule; the absence of wings; and the primitive hexapod body plan with three tagmatal divisions (head, thorax, abdomen).^[8] These morphological traits provide a strong basis for the clade's coherence, particularly the internalized mouthparts that facilitate a pouch-like feeding apparatus.^[10] The monophyly of Entognatha is well-supported by morphological evidence, such as the shared entognathy and other head structures, but molecular phylogenetic studies have challenged this, suggesting potential paraphyly, with some placing Protura as sister to all other hexapods.^[10] Recent phylogenomic analyses, including a 2024 study using 1,013 single-copy orthologous genes, confirm this paraphyly, positioning Protura as the earliest-diverging hexapod lineage and Collembola + Diplura as a clade, though the traditional classification persists in many taxonomic frameworks due to robust morphological synapomorphies.^[11]^[12]

Evolutionary Relationships

Entognatha is traditionally recognized as the sister group to Ectognatha (Insecta) within the subphylum Hexapoda, with both lineages sharing a common ancestor that diverged early in hexapod evolution. This relationship unites them under the broader clade Hexapoda, characterized by six-legged body plans and other arthropod features adapted for terrestrial life.^[13] Hexapoda, including Entognatha, is embedded within the Pancrustacea clade, which also encompasses Crustacea, as robustly supported by molecular evidence from 18S rRNA genes, mitochondrial genomes, and multi-locus datasets that highlight shared genetic signatures such as specific ribosomal RNA structures and nuclear protein-coding genes.^[14]^[12] While earlier phylogenomic analyses supported Entognatha monophyly, recent investigations employing large-scale genomic datasets and advanced models, such as a 2024 study with high node support, favor paraphyly by proposing Protura as basal to other hexapods, with Collembola sister to (Diplura + Ectognatha).^[11]^[10]^[15] Morphological synapomorphies, including the entognathous condition, reduced or absent compound eyes, and conserved abdominal segmentation with 11 somites, continue to underpin the traditional grouping despite these molecular challenges. The estimated divergence between Entognatha and Ectognatha occurred around 450–480 million years ago, during the Ordovician to Silurian periods, based on molecular clock calibrations integrated with fossil constraints from early hexapod-like arthropods.^[13]

Morphology

External Features

Entognatha are small hexapods, typically measuring 0.1 to 5 mm in length, though some Diplura can reach up to 50 mm, with an elongate, soft-bodied form divided into three tagmata: head, thorax, and abdomen.^[16]^[17] The thorax consists of three segments but often appears indistinctly segmented due to the soft cuticle and lack of sclerotization.^[16] They are primitively wingless, possessing six ambulatory legs on the thorax for walking.^[18]^[19] The head is characterized by entognathous mouthparts, where the mandibles, maxillae, and labium are retracted into a pouch formed by lateral folds of the cranium, distinguishing Entognatha from ectognathous insects.^[16] Antennae are present in Collembola (short, typically 4- to 6-segmented) and Diplura (long, multi-segmented), but absent in Protura, where the forelegs serve a sensory function.^[16]^[20] Eyes are reduced or absent across the group: Collembola may have ocelli (up to 8 per side), while Protura and Diplura lack eyes entirely.^[16]^[18]^[19] The thorax bears three pairs of legs, each with five articles (coxa, trochanter, femur, tibia, tarsus), adapted for terrestrial locomotion; in Protura, the forelegs are elongated and project forward as sensory organs.^[20]^[18] Diplura have one-segmented tarsi.^[19] No wings are present in any Entognatha.^[16] The abdomen typically comprises 11-12 segments, though appearing fewer in Collembola (6 visible).^[16] Cerci are well-developed in Diplura as forceps-like (Japygidae) or filiform (Campodeidae) structures, but absent or reduced in Protura and Collembola.^[16]^[19] Collembola possess unique abdominal appendages: the collophore on segment 1 for adhesion and water uptake, the tenaculum (retinaculum) on segment 3 to secure the furcula, and the furcula on segment 4 as a springing organ for jumping.^[20] Protura and Diplura have styli on the first few abdominal segments (1-3 in Protura, up to 7 in Diplura) and eversible vesicles for osmoregulation.^[16]^[18]^[19] The cuticle is thin, flexible, and unpigmented, often appearing white or translucent, providing limited protection but allowing cutaneous respiration.^[16] No external tracheal openings (spiracles) are visible, as the respiratory system, when present, is internal.^[16]

Internal Structures

The internal mouthparts of Entognatha are characteristically internalized within a gnathal pouch formed by folds of the head capsule, enclosing the mandibles, maxillae, and labium, which distinguishes them from the externally visible ectognathous mouthparts of insects.^[21] This enclosure facilitates a range of feeding adaptations, including chewing types in Diplura for processing detritus and piercing-sucking mechanisms in some Collembola, while Protura exhibit styliform mouthparts adapted for liquid ingestion.^[2] The gnathal pouch structure supports these variations by protecting the appendages and allowing precise manipulation in soil microhabitats.^[22] The digestive system in Entognatha comprises a tubular foregut for initial food intake, a midgut for enzymatic digestion and nutrient absorption, and a hindgut for water reabsorption and waste elimination, reflecting adaptations to detritivorous diets rich in recalcitrant organic matter.^[23] Symbiotic microbes, particularly bacteria in the midgut of Collembola, play a crucial role in breaking down complex substrates like cellulose and lignins, enhancing nutrient extraction from decomposed plant material. These microbial associations vary by host species and environmental conditions but consistently aid in the decomposition process central to their ecological niche. Collembola and Protura lack tracheae and rely on cutaneous respiration through a thin, permeable cuticle that allows oxygen diffusion directly into the hemolymph, an adaptation suited to their small size and humid terrestrial or soil environments, whereas Diplura possess a tracheal system.^[23]^[16] In Collembola, the eversible vesicles of the collophore contribute to this process by facilitating epidermal gas diffusion when extended, supplementing the cuticle's role in oxygen uptake.^[24] This respiratory strategy limits activity in dry conditions but supports efficient gas exchange in moist microhabitats. The circulatory system is open, featuring a dorsal heart positioned along the midline that pumps colorless hemolymph into the hemocoel, the body cavity where it bathes organs and facilitates nutrient distribution without enclosed vessels.^[25] In Diplura, accessory pulsatile organs associated with appendages enhance hemolymph flow to extremities, maintaining circulation in elongated body forms.^[26] The hemolymph's low viscosity and lack of respiratory pigments align with the reliance on cutaneous oxygen uptake.^[27] The nervous system consists of a dorsal brain connected to a ventral nerve cord with segmental ganglia, exhibiting reduction relative to insects through fused or fewer ganglia, which streamlines neural control for their simplified lifestyles.^[28] Order-specific sensilla, such as mechanoreceptive and chemosensory types on antennae and tarsi, integrate environmental cues directly into the cord, with Protura showing specialized foretarsal sensilla for substrate exploration.^[29] This configuration supports rapid sensory-motor responses essential for navigating litter and soil.^[30]

Biology

Reproduction

Entognatha exhibit predominantly sexual reproduction, characterized by indirect sperm transfer in most species. In Collembola and Diplura, males deposit stalked spermatophores on the substrate, which females locate and uptake through their genital openings for internal fertilization.^[31] In Protura, reproduction involves indirect sperm transfer via spermatophores, either actively passed or deposited on pedicels and located by the females.^[32] Parthenogenesis is a key reproductive strategy in Entognatha, particularly common in Collembola where it occurs in many species, often resulting in all-female populations through thelytokous mechanisms that produce diploid females from unfertilized eggs.^[33] This asexual mode contributes to female-biased sex ratios in Collembola populations, with sexual species showing ratios from balanced to strongly female-skewed.^[33] Parthenogenesis occurs in some Protura species and is rare or undocumented in Diplura, where sexual reproduction predominates.^[32] Mating behaviors in Entognatha are adapted to their soil-dwelling lifestyles and emphasize chemical and physical cues. In Collembola, such as springtails, pheromones associated with spermatophores attract females to male deposits, facilitating indirect transfer without direct copulation.^[34] Diplura exhibit similar indirect strategies, with males placing spermatophores in crevices for females to collect, though specific courtship rituals remain poorly documented.^[19] Following fertilization or parthenogenetic development, oviposition occurs in moist soil environments typical of Entognatha habitats. Females lay eggs in clusters or groups within soil, leaf litter, or humus, with hatching dependent on humidity; no complex parental care is provided, as adults do not guard or provision offspring.^[32]^[35]

Development and Physiology

Entognatha undergo ametabolous development, featuring little to no metamorphosis and direct hatching as miniature adults without distinct larval stages. In the order Protura, development is anamorphic, with abdominal segments added progressively during molts; newly hatched individuals possess nine abdominal segments, and successive molts add segments until the adult complement of twelve is achieved.^[3]^[36] This gradual segment addition distinguishes Protura from other entognathans, such as Collembola and Diplura, which exhibit strictly ametabolous growth without segment addition.^[37] Growth in Entognatha occurs via repeated molting throughout their lifespan, allowing for size increase without major morphological changes.^[38] Ecdysis, the molting process, is regulated by hormones analogous to ecdysteroids in insects, which trigger the shedding of the exoskeleton.^[39] Individuals typically pass through multiple instars, with the exact number varying by species but often reaching 10 or more in soil-dwelling forms. Unlike insects, Entognatha lack Malpighian tubules for excretion and osmoregulation, relying instead on specialized rectal glands to reabsorb water and ions from the hindgut.^[40] In Collembola, desiccation tolerance is facilitated by antifreeze proteins that complement cryoprotective dehydration, enabling survival in arid or cold environments by maintaining cellular integrity during water loss.^[41] Sensory physiology emphasizes chemoreception for detecting chemical cues in soil, supplemented by mechanoreceptors on the antennae that aid navigation through substrate vibrations and tactile stimuli.^[42] Entognatha generally exhibit a lifespan of 1-2 years, with active species like jumping springtails displaying elevated metabolic rates to support locomotion and environmental responsiveness.^[43]

Ecology and Distribution

Habitats

Entognatha primarily inhabit terrestrial environments, with the majority of species favoring moist microhabitats such as soil, leaf litter, and moss, where organic matter provides shelter and sustenance. Collembola, the most diverse order, are commonly found in these substrates across forests and grasslands, while Diplura occupy similar damp soils, humus, and rotting wood. Protura are similarly restricted to humid soil layers rich in decaying material, often in forest humus or under bark. Although predominantly terrestrial, some Collembola exhibit semi-aquatic behaviors, residing on the surface films of freshwater bodies or in wet mosses, where they exploit thin water layers without submerging.^[3]^[32]^[44]^[45] The group displays a cosmopolitan distribution, occurring from Arctic tundras to tropical rainforests, with species adapted to a wide range of climates. Highest species diversity is observed in temperate forest ecosystems, where stable moisture and moderate temperatures support complex communities, as evidenced by record-high richness in undisturbed old-growth stands. Protura show a more limited range, confined to humid temperate and subtropical soils, avoiding arid conditions. Entognatha preferentially occupy the upper soil layers (0-10 cm), particularly the organic horizon, where humidity is higher and resources abundant; deeper migration occurs seasonally but is less common. These microhabitats are typically shaded, minimizing exposure to direct sunlight that could exacerbate desiccation risks due to their thin cuticles and high surface-to-volume ratio.^[46]^[47]^[32]^[44]^[48] Adaptations enable Entognatha to endure environmental extremes, including cryophilic species in polar regions that tolerate subzero temperatures through antifreeze compounds and behavioral thermoregulation. In arid deserts, thermotolerant Collembola survive via anhydrobiosis or diapause, entering dormant states during dry periods to withstand heat and dehydration. Biogeographic patterns reveal ancient origins for certain lineages; for instance, some Collembola in southern continents trace to Gondwanan vicariance, with molecular evidence supporting divergence around 21-11 million years ago in Antarctic and sub-Antarctic assemblages. In Collembola, traits like the furcula facilitate rapid evasion in these dynamic litter habitats.^[49]^[50]^[51]^[52]

Ecological Roles

Entognatha, encompassing orders such as Collembola, Diplura, and Protura, serve as primary decomposers in terrestrial ecosystems, particularly in soils where they consume organic detritus, fungi, and microbes to facilitate nutrient cycling. Collembola, the dominant group, play a key role in breaking down leaf litter and promoting the mineralization of essential nutrients like nitrogen and phosphorus, thereby enhancing soil fertility and supporting plant growth in forests and grasslands.^[53] Diplura and Protura contribute similarly by feeding on decaying organic matter in humid microhabitats, aiding the fragmentation and decomposition processes that sustain ecosystem productivity.^[19]^[18] Within soil food webs, Entognatha occupy a foundational trophic position as abundant prey for predatory arthropods, amphibians, reptiles, and birds, thereby channeling energy to higher levels and maintaining biodiversity. Their densities can reach up to 100,000 individuals per square meter in productive soils, amplifying their availability as a food resource and stabilizing predator populations.^[32]^[54] Symbiotic associations further highlight their ecological integration; Collembola act as dispersers of arbuscular mycorrhizal fungi, transporting spores and propagules to new sites, which benefits plant-fungal symbioses and soil microbial networks.^[55] In contrast, certain Diplura species prey on nematodes, exerting top-down control that regulates pest populations and prevents overabundance in soil communities.^[56] Entognatha are valued as indicator species due to their sensitivity to environmental stressors, with population declines signaling soil degradation from pollution or habitat alteration; they are routinely employed in bioassays to detect heavy metal contamination and assess overall soil health.^[48] Their burrowing and foraging behaviors improve soil aeration by creating pores and channels, which enhances oxygen diffusion and microbial decomposition rates. In rare instances, Collembola facilitate spore dispersal for fungi, performing a function akin to pollination that supports fungal reproduction and ecosystem resilience.^[57]^[58]

Diversity and Fossil Record

Orders and Species Diversity

Entognatha encompasses three extant orders: Collembola, Diplura, and Protura, each exhibiting distinct morphological adaptations suited to soil and litter microhabitats. These orders collectively represent a basal hexapod lineage characterized by entognathous mouthparts, with diversity concentrated in terrestrial environments worldwide.^[59] The order Collembola, commonly known as springtails, is the most species-rich within Entognatha, comprising approximately 9,600 described species distributed across over 30 families.^[60] These apterous hexapods are distinguished by the furcula, a tail-like appendage enabling saltatorial locomotion through explosive jumps, which aids in predator evasion and dispersal in humid soils.^[46] Among the families, Isotomidae stands out as the largest, encompassing over 1,400 species globally and playing a key role in soil decomposition processes.^[61] Diplura, or two-pronged bristletails, includes about 1,000 described species organized into 10 families and 141 genera, with a campodeiform body plan featuring elongated, cylindrical forms adapted for navigating subsurface litter.^[62] A hallmark trait is the forceps-like cerci at the abdominal apex, used for prey capture and defense, varying in form across taxa. The order is divided into two suborders: Dicellurata, with robust, pincer-like cerci (e.g., family Ricinidae), and Rhabdura, featuring more slender, sensory cerci (e.g., family Anajapygidae), reflecting adaptive divergence in foraging strategies within moist, organic-rich habitats.^[63] Protura, or coneheads, is the smallest order with around 800 described species assigned to seven families, such as Acerentomidae, which dominates with numerous genera adapted to interstitial soil spaces.^[64] Lacking eyes and antennae, these hexapods rely on foreleg chemoreception for navigation, and they exhibit anamorphic development, progressively adding abdominal segments through successive molts until maturity.^[36] This developmental mode supports their cryptic lifestyle in upper soil layers, where they contribute to microbial decomposition. Overall, Entognatha harbors approximately 11,400 described species, though estimates suggest over 50,000 undescribed forms, primarily due to the underrepresentation of Collembola in tropical inventories.^[59]^[65] Biodiversity hotspots occur in tropical regions and forest soils, where high humidity and organic matter foster elevated abundances, often exceeding 100,000 individuals per square meter.^[46] Endemism is particularly pronounced in isolated subterranean habitats like caves, where troglobitic species—such as specialized Diplura in the Dinarides—evolve unique adaptations like elongated appendages and depigmentation, highlighting vulnerability to habitat disturbance.^[66]

Paleontology

The fossil record of Entognatha is sparse due to the soft-bodied nature of these hexapods, which rarely preserve well outside of exceptional lagerstätten such as cherts and ambers; most evidence comes from impressions in sedimentary rocks or inclusions in resin, limiting insights into their early history.^[67]^[68] The oldest traces of entognathans are attributed to collembolans from the Lower Devonian Rhynie Chert in Scotland, dating to approximately 407 million years ago (Ma), where specimens like Rhyniella praecursor represent the earliest known hexapods and demonstrate their presence in early terrestrial ecosystems.^[69] More definitive fossils appear in the Carboniferous period (about 350–300 Ma), including collembolans and diplurans such as Testajapyx thomasi, which provide evidence of their diversification alongside the emergence of vascular plants and early soils.^[70] Key fossil specimens highlight the persistence of entognathans through the Mesozoic and Cenozoic. In Cretaceous amber deposits, such as those from Spain (Late Albian, ~100 Ma), numerous collembolans—including genera like Proisotoma—are preserved, offering detailed views of their morphology and phoretic behaviors with other arthropods.^[71] Diplurans are rarer but documented in Eocene Baltic amber (e.g., campodeids from ~44 Ma) and Miocene Dominican amber, revealing adaptations like elongated cerci in soil-dwelling forms.^[72] Proturan fossils are exceptionally scarce, with no confirmed pre-Cenozoic records and only fragmentary Holocene remains, underscoring significant gaps in their documentation despite molecular evidence suggesting ancient origins predating the Devonian.^[73]^[74] These fossils provide critical evolutionary insights, indicating that Entognatha diverged early from other arthropods, well before the evolution of insect flight in the late Carboniferous (~350 Ma), and played a foundational role in Paleozoic terrestrialization by contributing to soil formation through detritivory and bioturbation in nascent ecosystems like the Rhynie Chert community.^[75]^[76] The absence of pre-Devonian entognathan fossils, despite phylogenetic estimates placing their origins in the Ordovician or earlier, highlights preservational biases and the challenges of reconstructing their deep history from an incomplete record.^[3]^[77]

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Tullgren funnels are a well-established technique for extracting microarthropods due to their sensitivity to desiccation and avoidance of heat and light sources ...
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The Resilience of Polar Collembola (Springtails) in a Changing ...
All Antarctic (and most Arctic) Collembola appear to be freeze-avoidant, keeping their body fluids liquid at sub-freezing temperatures via ice-binding (i.e. ...
[47]
Adaptation of grassland springtails (Collembola) to dry and hot ...
Jun 1, 2021 · Some springtails (Collembola) are known to be tolerant to drought. They adapt to extreme environmental conditions by going into diapause or ...Missing: thermotolerant | Show results with:thermotolerant
[48]
Phylogeography of Antarctic soil invertebrate fauna reveals ancient ...
Jan 15, 2025 · Molecular dating supports ancient origins for most indigenous taxa, including Acari (up to 100 million years ago; Ma), Collembola (21–11 Ma), ...
[49]
Biogeography of circum-Antarctic springtails - ScienceDirect.com
In addition to the ancient 'Gondwanan' landmasses (continental-Antarctica, Australia, New Zealand, South America), sub-Antarctic Îles Crozet (∼8.7 Myr) and ...
[50]
Collembola - Soil Ecology Wiki
Mar 31, 2023 · Habitat & Distribution ... Collembola can be found in almost all regions of the world, from the coldest of and hottest places that can support ...
[51]
Entognatha common in vineyard soils from the Douro Demarcated ...
... Their functions include pollination, organic matter decomposition and serving as prey for higher trophic levels (McIntyre et al., 2001;Cross et al., 2015 ...
[52]
Collembola (Insecta) disperse the arbuscular mycorrhizal fungi in ...
Aug 7, 2025 · ABSTRACT: Collembola often play an important controlling role in the interrelationship between arbuscular mycorrhizal fungi (AMF) and host ...
[53]
Japygidae - an overview | ScienceDirect Topics
Diplurans occur under rotting leaf litter, logs, bark, stones and similar damp microhabitats, especially in forests. There are about 924 extant species in 125 ...
[54]
Functional role of microarthropods in soil aggregation | Request PDF
Aug 7, 2025 · The microarthropods also alter the formation of humus (Cakir and Makineci, 2013) and the soil structure (Maaß et al., 2015) . Because of their ...
[55]
Spore feeding and coexistence on dead trees - ScienceDirect.com
There are reports that Collembola disperses entomopathogenic bacteria [12], arbuscular mycorrhizal fungus [13], and mushrooms [14,15]. They also disperse ...
[56]
Revisiting the four Hexapoda classes: Protura as the sister group to ...
We herein propose to return Entognatha to its original conception by removing Protura and returning it to a clade with only Collembola and Diplura. This ...
[57]
Checklist of the Collembola of the World
Oct 31, 2024 · There are ca 9600 published species worldwide. Collembolan fossils ... But in many cases, the Collembola are just annoying 'guests', a ...
[58]
Family Isotomidae - BugGuide.Net
Isotomidae is a family of springtails, with over 200 species in ~55 genera in our area, and about 1,400 worldwide. Isotoma has macrosetae on all body segments.
[59]
Diversity, ecology, distribution and biogeography of Diplura - Sendra
Mar 18, 2021 · The order is divided into 10 families, which include 1008 species in 141 genera, with a high proportion of monotypic genera. They are ubiquitous ...
[60]
JULY 2025 - ZSI Fauna of India Checklist
Jul 1, 2025 · Global Diversity: The global diversity of the class Diplura comprises 1008 species belonging to 141 genera (Sendra et al., 2021). Diversity ...
[61]
Genera of the Protura of the World: diagnosis, distribution, and key
Jul 6, 2018 · Protura are known all over the world with more than 800 described species belonging to three different orders (Acerentomata, Sinentomata, ...
[62]
Checklist of the Collembola : Taxonomic speciation rate
Oct 31, 2024 · Taking into account that the global estimated number of Collembola species is about 50,000 (Hopkin 1998:118) to 65,000 (Porco & al. 2013:1) ...<|separator|>
[63]
Cave-adapted campodeids (Hexapoda, Diplura, Campodeidae ...
Apr 23, 2021 · Phylogeny, habitat and distribution: Diplurans are represented by 28 species of Campodeidae (one of the two dipluran families with troglobites ...<|separator|>
[64]
Some remarks on the Devonian fossil insects from the Rhynie chert ...
The latter, in particular, are of note, being the oldest record of Hexapoda in the fossil record . Rhyniella praecursor, a springtail (collembolan hexapod) ...
[65]
Fossil evidence for key innovations in the evolution of insect diversity
Explaining the taxonomic richness of the insects, comprising over half of all described species, is a major challenge in evolutionary biology.
[66]
A new assessment of Rhyniella, the earliest known insect ... - Nature
May 28, 1981 · In 1926, four head capsules of an insect, named Rhyniella praecursor, were discovered in Lower Devonian chert from Rhynie, Aberdeenshire1 by ...
[67]
New Carboniferous Diplura, Monura, and Thysanura, the hexapod ...
A new Upper Carboniferous japygid, Testajapyx thomasi n. gen. et n. sp., shows that only Diplura of Entognatha shared an ancestral ground plan with Insecta– ...
[68]
Springtails from the Early Cretaceous Amber of Spain (Collembola
Jun 30, 2016 · Here we provide a revision of the Spanish amber springtail fauna, Early Cretaceous (Late Albian) in age, based on 93 specimens sufficiently well preserved.<|control11|><|separator|>
[69]
'Dawn' hexapods in Cenozoic ambers (Diplura: Campodeoidea)
Sep 30, 2023 · We document five very rare fossil specimens of the family Campodeidae in amber from the Miocene of the Dominican Republic and the Eocene of the Baltic region.
[70]
8.2.1. The insect fossil record - Энтомология
Taxa that contain only fossils are indicated by the symbol †. The fossil record of Protura, Phthiraptera, and Zoraptera dates from only the Holocene, presumably ...
[71]
Introduction to the Parainsecta
Collembolans have the honor of being the oldest known hexapods (six-legged uniramians) in the fossil record, predating the oldest true insects. The Rhynie Chert ...<|separator|>
[72]
New light shed on the oldest insect - PubMed
Feb 12, 2004 · For true insects (Ectognatha), the oldest records are two apparent wingless insects from later in the Devonian period of North America. Here we ...
[73]
The ecology of Paleozoic terrestrial arthropods: the fossil evidence
The available fossil evidence for the ecology of terrestrial arthropods in the Paleozoic is reviewed and reinterpreted. Some original data are provided, ...
[74]
Phylogenomic Insights into the Cambrian Explosion, the ...
Our results provide insights into the 3 independent colonizations of land by arthropods and suggest that evolution of insect wings happened much earlier.