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Anapsids
Temporal range: Late Carboniferous to Late Triassic
312–201.3 Ma
Anapsid skull
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Informal group: Anapsida
Williston, 1917
Subgroups

An anapsid is an amniote whose skull lacks one or more skull openings (fenestra, or fossae) near the temples.[1] Traditionally, the Anapsida are considered the most primitive subclass of amniotes, the ancestral stock from which Synapsida and Diapsida evolved, making anapsids paraphyletic. It is, however, doubtful that all anapsids lack temporal fenestra as a primitive trait, and that all the groups traditionally seen as anapsids truly lacked fenestra.

Anapsids and the turtles

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Anapsid skull of Caretta caretta (loggerhead sea turtle), a testudine

While "anapsid reptiles" or "Anapsida" were traditionally spoken of as if they were a monophyletic group, it has been suggested that several groups of reptiles that had anapsid skulls might be only distantly related. Scientists still debate the exact relationship between the basal (original) reptiles that first appeared in the late Carboniferous, the various Permian reptiles that had anapsid skulls, and the Testudines (turtles, tortoises, and terrapins). However, it was later suggested that the anapsid-like turtle skull is due to reversion rather than to anapsid descent. The majority of modern paleontologists believe that the Testudines are descended from diapsid reptiles that lost their temporal fenestrae. More recent morphological phylogenetic studies with this in mind placed turtles firmly within diapsids,[2][3][4][5][6] most commonly within Archelosauria.[7]

Phylogenetic position of turtles

[edit]

All molecular studies have strongly upheld the placement of turtles within diapsids; some place turtles within Archosauria,[8] or, more commonly, as a sister group to extant archosaurs.[9][10][11][12][13] One molecular study, published in 2012, suggests that turtles are lepidosauromorph diapsids, most closely related to the lepidosaurs (lizards, snakes, and tuataras).[14] However, in a later paper from the same authors, published in 2014, based on more extensive data, the archosauromorph hypothesis is supported.[7]

Reanalysis of prior phylogenies suggests that they classified turtles as anapsids both because they assumed this classification (most of them were studying what sort of anapsid turtles are) and because they did not sample fossil and extant taxa broadly enough for constructing the cladogram. Testudines is suggested to have diverged from other diapsids between 200 and 279 million years ago, though the debate is far from settled.[15][9][16] Although procolophonids managed to survive into the Triassic, most of the other reptiles with anapsid skulls, including the millerettids, nycteroleterids, and pareiasaurs, became extinct in the Late Permian period by the Permian-Triassic extinction event.

Anapsida in modern taxonomy

[edit]

Anapsida is still sporadically recognized as a valid group, but is not favoured by current workers.[17][18] Anapsids in the traditional meaning of the word are not a clade, but rather a paraphyletic group composed of all the early reptiles retaining the primitive skull morphology, grouped together by the absence of temporal openings.[17][18] Gauthier, Kluge and Rowe (1988) attempted to redefine Anapsida so it would be monophyletic, defining it as the clade containing "extant turtles and all other extinct taxa that are more closely related to them than they are to other reptiles".[19]

This definition explicitly includes turtles in Anapsida; because the phylogenetic placement of turtles within Amniota is very uncertain, it is unclear what taxa, other than turtles themselves, would be included in such defined Anapsida, and whether its content would be similar to the Anapsida of tradition. Indeed, Gauthier, Kluge and Rowe (1988) themselves included only turtles and Captorhinidae in their Anapsida, while excluding the majority of anapsids in the traditional sense of the word from it.[19]

Temporal openings in traditional anapsids

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Tsuji and Müller (2009) noted that the name Anapsida implies a morphology (lack of temporal openings) that is in fact absent in the skeletons of a number of taxa traditionally included in the group.[18] A temporal opening in the skull roof behind each eye, similar to that present in the skulls of synapsids, has been discovered in the skulls of a number of members of Parareptilia (the group containing most of reptiles traditionally referred to as anapsids), including lanthanosuchoids, millerettids, bolosaurids, some nycteroleterids, some procolophonoids and at least some mesosaurs.[18][20][21] The presence of temporal openings in the skulls of these taxa makes it uncertain whether the ancestral reptiles had an anapsid-like skull as traditionally assumed or a synapsid-like skull instead.[21]

See also

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References

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Anapsid

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from Grokipedia
Anapsids are amniotes characterized by a primitive skull condition lacking temporal fenestrae, the openings behind the orbits that accommodate jaw muscles in more derived reptiles.[1][2] This solid-roofed temporal region represents the basal sauropsid morphology, distinguishing anapsids from synapsids (with one fenestra) and diapsids (with two).[1] The group originated approximately 340 million years ago during the Carboniferous period as part of the early diversification of amniotes, though the oldest definitive fossils date to the Lower Permian around 290 million years ago, such as Acleistorhinus from Oklahoma.[1][3] Diversity peaked in the Upper Permian (~260 million years ago), with key extinct clades including the captorhinids (small, lizard-like herbivores), procolophonids (robust herbivores that survived the end-Permian mass extinction), pareiasaurs (heavily armored herbivores), and parareptiles like millerettids and lanthanosuchids, primarily known from South Africa and Russia.[3][2] Most anapsid lineages perished during the end-Permian extinction event ~252 million years ago, with only procolophonoids persisting into the Triassic before their extinction around 210 million years ago at the end-Triassic boundary.[3] Traditionally, turtles (Testudines) were classified as the sole surviving anapsids due to their solid-skulled anatomy, with the oldest known fossils like Proganochelys appearing in the Upper Triassic ~220 million years ago.[3][2] However, recent phylogenetic analyses based on molecular data and detailed osteology, including transitional forms like the Permian Eunotosaurus africanus, indicate that turtles are derived diapsids nested within Archosauromorpha as the sister group to archosaurs (birds and crocodilians), with their anapsid-like skull resulting from secondary closure of fenestrae.[2][4] This reclassification renders Anapsida a paraphyletic or grade-level grouping of basal sauropsids rather than a monophyletic clade, highlighting ongoing debates in reptile phylogeny.[2] Today, turtles comprise about 360 extant species in 14 families, adapted for aquatic, terrestrial, and semi-aquatic lifestyles with unique bony shells formed from fused ribs and dermal ossifications.[2]

Definition and Characteristics

Skull Morphology

An anapsid is defined as an amniote whose skull roof is solid, lacking temporal fenestrae—openings posterior to the orbit that characterize other amniote clades. This represents the plesiomorphic (ancestral) condition among sauropsids.[5] This condition represents the primitive state among amniotes, where the temporal region remains fully enclosed by dermal bones, providing a continuous bony armor.[6] In the temporal region, the postorbital bone extends posteriorly to meet the squamosal, while the supratemporal and tabular bones contribute to the upper portion, ensuring complete coverage without perforations for jaw adductor muscles.[7] This "anapsid condition" contrasts with the fenestrated skulls of synapsids (one opening) and diapsids (two openings), which evolved to accommodate expanded musculature.[6] While most anapsids exhibit this unfenestrated morphology, variations occur, such as slight emargination—a marginal indentation rather than a true fenestra—in groups like captorhinids, early Permian reptiles that retained an ancestrally solid temporal region despite these minor excavations.[8] For instance, in Captorhinus aguti, the skull shows no lateral openings, but subtle posterior emargination along the squamosal-quadrate suture, preserving overall integrity.[9] Primitive anapsids are distinguished by key bones in the posterior skull roof, including the tabular (lateral to the postparietal) and postparietal (midline), which form a robust supratemporal arcade and resist biomechanical stresses from feeding and locomotion.[7] The anapsid skull originated in early amniote ancestors during the Late Carboniferous, approximately 310 million years ago, evolving from early tetrapod ancestors.[10] This morphology provided structural support in the initial amniote radiation, before fenestration patterns diverged in descendant lineages around the Carboniferous-Permian boundary.[7]

General Anatomy

The postcranial skeleton of anapsid reptiles was characterized by robust vertebrae featuring amphicoelous centra, which provided flexibility while supporting efficient weight-bearing on terrestrial substrates.[11] These vertebrae, combined with strong limb girdles and pentadactyl limbs, enabled adaptations for land-based locomotion, reflecting the transition from amphibian-like forms to fully terrestrial vertebrates.[11] Unlike later diapsid reptiles, primitive anapsids lacked specialized modifications for upright postures, maintaining a more generalized structure suited to varied environments. Dentition in anapsids varied to accommodate diverse diets, with many forms exhibiting conical teeth indicative of insectivory or carnivory, while others developed leaf-shaped crowns for processing vegetation in herbivorous lineages.[12] Tooth attachment was typically thecodont in basal groups, allowing for replacement, though some advanced forms showed pleurodont implantation along the inner jaw margin.[13] This variability highlights dietary flexibility central to their ecological success on land. Fossil impressions suggest that anapsid skin was covered in lepidosis, consisting of epidermal scales that protected against desiccation and abrasion in terrestrial habitats, with primitive forms generally lacking osteoderms.[2] Anapsids exhibited a broad size range, from small individuals approximately 20 cm in length to larger specimens exceeding 2 meters, allowing occupation of multiple niches.[2] Locomotion among anapsids primarily involved a sprawling gait, similar to that of modern lizards, which facilitated maneuverability over uneven terrain but limited speed compared to more erect postures in other amniote lineages.[14]

Historical Classification

Traditional Concept of Anapsida

The term Anapsida was coined by paleontologist Samuel W. Williston in 1917 to denote a group of reptiles characterized by the absence of temporal fenestrae in the skull, distinguishing them from other amniotes with openings in the temporal region. This classification built on earlier work by Henry Fairfield Osborn in 1903, which emphasized skull morphology as a key taxonomic feature among early reptiles. Williston's framework positioned Anapsida as a basal lineage retaining the solid-skulled condition of ancestral amniotes, reflecting a primitive "lizard-like" body plan adapted for terrestrial life.[15] The concept was formalized in the mid-20th century by Alfred Sherwood Romer in his seminal monograph Osteology of the Reptiles (1956), where Anapsida was established as one of four major subclasses of reptiles alongside Synapsida, Diapsida, and Euryapsida. Romer defined Anapsida as the stem group encompassing all reptiles with an unfenestrated temporal region, serving as the foundational lineage from which turtles (Testudines) and parareptilian forms evolved, while highlighting their role as the most primitive amniotes. This subclass included a broad temporal scope, extending from the Late Carboniferous period—when the earliest known members appeared amid the diversification of tetrapods—to the present day, with turtles as the sole surviving representatives. Key proponents, such as Robert L. Carroll in Vertebrate Paleontology and Evolution (1988), reinforced this view by describing Anapsida as comprising lizard-like primitive reptiles that exemplified early amniote adaptations, including robust skulls suited for biting and ground-dwelling locomotion. Despite its widespread adoption, the traditional concept of Anapsida faced early scrutiny for its limitations, as the group's reliance on the plesiomorphic absence of fenestrae suggested a paraphyletic assemblage rather than a strictly monophyletic clade; however, this was largely overlooked in favor of the classification's morphological simplicity and utility in organizing fossil diversity.[16] Turtles were consistently placed within Anapsida as advanced members derived from this basal stock.

Role of Turtles in Early Taxonomy

Turtles (Testudines) have been traditionally assigned to the subclass Anapsida since the early 20th century, primarily due to the apparent absence of temporal fenestrae in the skulls of adult individuals. This classification stemmed from the recognition of their solid temporal skull roof as a primitive feature shared with early amniotes, distinguishing them from synapsids and diapsids that exhibit temporal openings for jaw muscle attachment.[2][17] The anatomical rationale for this placement emphasized the complete ossification of the turtle skull, particularly evident in hatchlings where the temporal region forms a solid roof without perforations, and in adults where extensive fusion of dermal bones such as the postorbital, squamosal, and supratemporal obscures any potential underlying openings. Early paleontologists linked this morphology to cotylosaurs, an obsolete group encompassing primitive reptiles like captorhinids, positing turtles as direct descendants retaining the ancestral anapsid condition. For instance, Jaekel (1915) explicitly hypothesized a cotylosaurian origin for turtles based on their shared "stegale" (roofed) skull structure.[17][18] Key debates in the mid- to late 20th century reinforced this affinity, with Gaffney (1979) arguing for close ties to procolophonians through shared cranial traits such as the configuration of the palate and temporal roofing elements, positioning turtles within a broader anapsid clade including parareptiles. This view portrayed turtles as evolutionary relics amid the extinction of other anapsid lineages by the end of the Triassic, with Testudines emerging as the sole surviving representatives and thus justifying the continued recognition of Anapsida as a valid subclass in traditional taxonomy.[19][20] This classification exerted significant cultural and educational influence, appearing in major textbooks and references well into the 1990s; for example, Benton (1985) listed Testudines under Anapsida in discussions of reptilian phylogeny, reflecting the dominance of morphological criteria over emerging molecular data.[21]

Modern Taxonomy

Cladistic Revisions

The advent of cladistic methods in the late 20th century fundamentally altered the understanding of Anapsida, shifting from a Linnaean classification based on skull fenestration to one emphasizing monophyletic clades defined by shared derived characters. Early cladistic analyses, such as those by Gauthier et al. (1988), revived the concept of Parareptilia as a monophyletic group comprising many traditional anapsids, positioned as the sister taxon to Diapsida within Sauria, thereby rendering Anapsida a paraphyletic grade of basal sauropsids characterized by primitive traits like an unfenestrated skull roof. This perspective highlighted that Anapsida lacked unique synapomorphies uniting all its members, instead representing a sequential series of stem lineages rather than a cohesive clade. Building on this foundation, Laurin and Reisz (1995) conducted a comprehensive parsimony analysis of 124 morphological characters across 13 early amniote taxa, explicitly proposing that Anapsida constitutes a grade rather than a clade, with its members forming a basal assemblage outside the monophyletic Synapsida and a redefined Reptilia (encompassing Parareptilia + Eureptilia).[22] Their phylogeny recovered three major amniote lineages—Synapsida, Parareptilia (including pareiasaurs and procolophonoids), and Eureptilia (sauropsids)—demonstrating that the absence of temporal fenestrae in anapsids is a plesiomorphic condition shared with the amniote ancestor, not a defining apomorphy.[22] Fossil-based evidence from these studies emphasized the polyphyletic distribution of former anapsid groups, such as captorhinids aligning closer to diapsids and mesosaurs as early sauropsid outliers.[22] Molecular phylogenies in the late 1990s provided corroborating evidence, with Zardoya and Meyer (1998) analyzing complete mitochondrial genomes from representative amniotes and finding that turtles—long emblematic of Anapsida—cluster robustly with archosaurs, supporting diapsid affinities and further confirming the paraphyly of Anapsida by excluding its sole surviving lineage.[23] This molecular signal aligned with fossil data showing anapsids as basal to Sauria or dispersed within Parareptilia, a clade now recognized for its diversity in Permian and Triassic forms.[23] In contemporary taxonomy, Anapsida is no longer recognized as a formal monophyletic taxon but persists informally to denote non-synapsid, non-diapsid amniotes, particularly in discussions of early sauropsid evolution.[24] Recent phylogenetic studies, including those integrating genomic data, continue to uphold this paraphyletic status, with analyses of nuclear and mitochondrial sequences reinforcing the basal positioning of parareptilian-grade taxa without resurrecting Anapsida as a clade.[25]

Phylogenetic Position of Turtles

The phylogenetic position of turtles (Testudines) has shifted dramatically in modern cladistic analyses, with a strong consensus establishing them as members of Diapsida rather than the traditional Anapsid grouping. This reclassification is supported by both molecular and developmental evidence, refuting the long-held view of turtles as primitive anapsids with secondarily closed temporal fenestrae. Instead, turtles are now recognized as derived diapsids whose adult skulls exhibit fused fenestrae, masking their underlying diapsid ancestry. Molecular phylogenies, beginning with mitochondrial DNA studies in the late 1990s, consistently place turtles within Diapsida as the sister group to Archosauria. For instance, analyses of complete mitochondrial genomes from turtles and other amniotes supported their diapsid affinities, positioning them as sister to the archosaur clade (birds and crocodilians). Subsequent nuclear genome sequencing in the 2010s and 2020s has reinforced this, with phylogenomic datasets from thousands of genes confirming turtles' divergence from other diapsids around 260 million years ago (Ma) during the late Permian. Recent phylogenomic studies as of 2024 continue to support turtles as the sister group to Archosauria.[23][26][27][28] These studies highlight shared genetic markers, such as conserved synteny and gene orthologs, that align turtles more closely with diapsid reptiles than with extinct anapsid-grade taxa.[23][26][27] Developmental and fossil evidence further corroborates this molecular consensus, particularly through embryonic studies revealing transient diapsid skull fenestrae in turtles that fuse in adulthood. Rieppel and de Braga's 1996 examination of turtle ontogeny identified upper and lower temporal fenestrae during early development, which become obscured by bone overgrowth, indicating a secondary loss rather than a primitive anapsid condition. Fossil stem-group turtles, such as Eunotosaurus africanus from ~260 Ma, exhibit diapsid-like features including incipient fenestration, supporting turtles as crown-group diapsids that diverged early within the clade. By the 2010s, integrated phylogenies combining genomic and fossil data had decisively refuted the anapsid hypothesis, with no credible support remaining for turtles outside Diapsida.[27][29] Comparative analyses underscore turtles' closer affinities to lepidosaurs than to extinct anapsids, based on shared synapomorphies like cranial kinesis facilitated by flexible suspensorial structures. Turtles retain subtle streptostylic movement of the quadrate bone, akin to that in lizards and snakes, enabling limited jaw mobility despite their rigid skulls—a trait absent in true anapsids. These morphological parallels, combined with molecular data, position turtles robustly within Diapsida, highlighting the paraphyly of the traditional Anapsida.[17][30]

Extinct Groups

Early Anapsids

Early anapsids represent the basal eureptilian lineages that emerged during the Late Carboniferous and diversified in the Early Permian, characterized by their solid, anapsid skull morphology lacking temporal fenestrae and serving as stem-group amniotes with primitive traits such as acrodont dentition and sprawling gait.[31] These groups bridged the evolutionary gap between earlier synapsids and later diapsid-dominated saurians, retaining a fully roofed temporal region that distinguished them from more derived reptiles.[32] Their fossils, primarily from fluvial and lacustrine deposits, indicate a period of initial amniote radiation before the more extensive Permian diversification. The Captorhinidae, one of the earliest and most widespread anapsid families, consisted of small, lizard-like reptiles typically measuring 20-30 cm in length, with robust triangular skulls ornamented by pitted and ridged bone surfaces. A representative genus, Captorhinus aguti, from approximately 289 million years ago in the Early Permian, exemplifies these forms with its multiple marginal tooth rows on the maxilla and dentary, adapted for grasping and crushing prey, supporting an primarily insectivorous diet.[32] This dentition, combined with slender limbs and a long tail, suggests agile terrestrial predators or opportunists in floodplain environments.[31] Millerettidae, emerging around 280 million years ago in the Kungurian stage of the Early Permian, displayed transitional features toward later parareptilian clades, including elongated snouts and more gracile builds compared to captorhinids. The genus Milleretta, known from the South African Karoo Basin, featured a narrow skull with acrodont teeth suited for insectivory and a postcranial skeleton indicating quadrupedal locomotion with some cursorial adaptations.[33] These reptiles, often under 50 cm long, bridged basal anapsids to more specialized Permian forms through subtle refinements in cranial kinesis and limb proportions. Fossils of early anapsids occur in both Laurasian (North America, Europe) and Gondwanan (South Africa, Brazil) localities, reflecting an early Pangaean dispersal facilitated by the Late Carboniferous assembly of supercontinents.[34] Key sites include the Texas Red Beds of the Clear Fork Group, where captorhinids dominate assemblages alongside amphibians and synapsids, preserving bonebeds from riverine settings around 290-280 million years ago.[35] Overall diversity remained limited, with fewer than a dozen genera documented before the mid-Permian, likely constrained by ecological niches and preceding minor extinction pulses.

Advanced Anapsid Clades

Advanced anapsid clades represent more derived parareptilian lineages that emerged during the Late Permian and persisted into the Early Triassic, exhibiting specialized morphological features adapted to terrestrial environments. These groups, including Pareiasauria and Procolophonoidea, diverged from earlier anapsid stems by developing enhanced defensive structures, dietary specializations, and variations in body size, reflecting adaptive radiations in the aftermath of Permian biotic crises.[36] Pareiasauria comprised a diverse assemblage of robust, armored herbivores that flourished across Pangaea during the middle to late Permian, approximately 260 to 250 million years ago. These reptiles, such as Pareiasaurus from the Karoo Basin of South Africa and related forms from European Russia, reached lengths of up to 3 meters and weighed several hundred kilograms, making them among the largest non-mammalian herbivores of their time. A defining feature was their thick, knobby osteoderms embedded in the skin, providing armor-like protection against predators and possibly aiding in thermoregulation. Fossils indicate a global distribution, with recent discoveries in China, including the mid-sized Yinshanosaurus angustus from the upper Permian Naobaogou Formation in Inner Mongolia, revealing phylogenetic insights into pareiasaur diversification and supporting their role as widespread mid-to-large herbivores.[37][38][39] Procolophonoidea, in contrast, consisted of smaller, more agile forms that appeared in the Late Permian and survived until the Late Triassic, approximately 259 to 201 million years ago. Exemplified by Procolophon trigoniceps from the Lystrosaurus Assemblage Zone in South Africa, these parareptiles were typically under 1 meter in length, with a robust skull featuring a beak-like snout and specialized dentition for grinding tough vegetation. Their herbivorous adaptations included palinal jaw movement and marginal teeth with bulbous cusps, enabling efficient processing of fibrous plants. Procolophonoids are known from localities in South Africa, Brazil, and Australia, demonstrating their ability to endure the end-Permian mass extinction and recolonize post-extinction ecosystems.[40][41][42] Other notable advanced clades include Lanthanosuchidae, crocodile-like parareptiles with armored bodies known primarily from the Late Permian of South Africa and Russia, and Nycteroleteridae, small lizard-like forms from European Russia. Key adaptations in advanced anapsids involved a pronounced shift toward herbivory, evidenced by dental and cranial modifications for plant processing, alongside increased body sizes in pareiasaurs that supported greater ecological dominance in terrestrial guilds. These traits likely enhanced survival in resource-variable Permian landscapes. However, most advanced anapsid lineages declined sharply by the end of the Triassic, around 201 million years ago, largely outcompeted by rising archosauromorphs that filled similar niches with superior locomotor and physiological efficiencies. Procolophonoids represent one of the last holdouts, persisting until the Late Triassic before their extinction at the end-Triassic boundary.[36][43]

Evolutionary Context

Fossil Record

The fossil record of anapsids encompasses a temporal span from approximately 290 million years ago in the Lower Permian to around 201 million years ago in the Late Triassic, marking the diversification and eventual decline of this group of early reptiles characterized by skulls lacking temporal fenestrae.[3] Earlier basal sauropsids such as Hylonomus lyelli from the Joggins Formation in Nova Scotia, Canada (~310 Ma, Westphalian stage), represent the initial radiation of amniotes in swampy, coal-forming environments and the ancestral anapsid skull condition. By the Lower Permian (Cisuralian, ~299–272 Ma), anapsid fossils become more abundant in North American localities, including the red beds of Oklahoma and Texas, yielding well-preserved captorhinid specimens from cave deposits like those at Richards Spur.[3] These early Permian sites document small, lizard-like herbivores and insectivores, with diversity increasing toward the Upper Permian (~272–252 Ma), where lanthanosuchids, millerettids, and pareiasaurs appear in Russian and South African assemblages.[3] In the Upper Permian, the Karoo Basin of South Africa emerges as a critical locality, preserving extensive pareiasaur and early procolophonoid remains in floodplain and lacustrine sediments of the Beaufort Group, reflecting a peak in anapsid diversity around 260 million years ago.[3] Procolophonoids, including forms like Procolophon trigoniceps, continued into the Early Triassic (~252–247 Ma) in the same basin, often found in burrow assemblages that suggest communal behavior in post-extinction recovery ecosystems.[44] Triassic records extend to ~201 Ma, with procolophonids documented in European and North American red beds, though non-turtle anapsids wane by the Late Triassic; separately, primitive turtles such as Proganochelys (now considered derived diapsids) appeared around 220 Ma in the Upper Triassic.[3] Gondwanan sites, including the Parnaíba Basin in Brazil's Pedra de Fogo Formation, add Lower Permian captorhinids like Captorhinikos sp., highlighting early herbivory in southern landmasses.[45] Anapsid fossils were first described in the mid-19th century, with pareiasaurs noted from South African Karoo exposures as early as 1848,[46] followed by the naming of Captorhinus in 1882 based on North American material.[47] Major 20th-century discoveries expanded the record through systematic excavations in the Karoo and North American Permian basins, while 21st-century efforts have revealed more complete assemblages, such as articulated skeletons from Richards Spur. Preservation favors disarticulated skulls and partial postcrania due to depositional environments like river channels and caves, with rare lagerstätten providing insights into soft tissues; complete skeletons are exceptional, as seen in some procolophonid burrows.[3] A notable gap exists between the Middle Pennsylvanian and Lower Permian, reflecting limited terrestrial preservation, and another in the Jurassic, where anapsid fossils are scarce beyond early turtles, signaling the group's restriction to Triassic holdovers.[3] Recent discoveries in the 2020s have enriched the record, particularly from China, where the pareiasaur Yinshanosaurus angustus from the Naobaogou Formation (latest Permian, 259–254 Ma) bridges faunal connections between Laurasian and Gondwanan assemblages, with its mid-sized, armored herbivore morphology echoing African relatives.[48] In June 2025, a fossilized colony of Procolophon trigoniceps was reported from the Karoo Basin, preserving multiple individuals (adults and juveniles) in complex underground burrows, providing direct evidence of communal living in Early Triassic post-extinction recovery ecosystems.[49] Similarly, 2020 findings of captorhinids in Brazil's Pedra de Fogo Formation underscore Gondwanan herbivore origins, filling biogeographic gaps in early Permian distributions.[45] These updates, absent from pre-2015 syntheses, emphasize ongoing revelations in understudied Asian and South American sites.[3]

Implications for Amniote Evolution

Anapsids occupy a basal position in amniote phylogeny, serving as an outgroup to the Synapsida-Diapsida clade while retaining plesiomorphic traits such as the solid temporal skull roof without fenestrae, which represents the ancestral condition for Amniota.[6] This configuration, seen in early forms like Hylonomus from the Late Carboniferous, underscores the evolutionary starting point from which temporal fenestration evolved independently in synapsids and diapsids.[50] The recognition of Anapsida as paraphyletic, rather than a monophyletic clade, is evidenced by the diverse lineages within it, including Parareptilia (such as mesosaurs and procolophonoids) and basal Eureptilia (like captorhinids), which collectively form a sequential grade of early sauropsid evolution rather than a unified group.[22] In this framework, Parareptilia emerges as the sister group to Eureptilia, which encompasses Sauria (diapsids including turtles in modern views), highlighting how anapsid-grade reptiles contributed foundational diversity to sauropsid radiation.[22] Anapsids influenced subsequent diapsid evolution by potentially serving as a sister assemblage to Sauria, with shared ancestral features such as robust limb structures appearing in parareptilian forms like pareiasaurs and persisting in derived groups including turtles and early archosaurs.[22] More broadly, anapsids were integral to the Carboniferous diversification of amniotes around 310–314 Ma, marking the initial terrestrial radiation of fully amniotic tetrapods.[50] Their near-total extinction following the end-Permian mass extinction event, which severely impacted parareptilian disparity and richness, paved the way for diapsid dominance in the Mesozoic, reshaping amniote ecological roles.[51] Persistent gaps in understanding these early divergences, estimated at approximately 310 Ma via fossil-calibrated molecular clocks, highlight the need for additional integrated molecular and paleontological data to refine timings and relationships amid uncertainties in clock calibration.[52]

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  40. (PDF) A new Triassic procolophonoid reptile and its implications for ...
  41. A procolophonid reptile from the Lower Triassic of Australia
  42. (PDF) Phylogenetic relationships of procolophonid parareptiles with ...
  43. First procolophonid (Reptilia, Parareptilia) from the Lower Triassic of ...
  44. https://doi.org/10.7717/peerj.8719
  45. Palaeos Vertebrates Eureptilia: Captorhinidae (3)
  46. The tetrapod fauna of the upper Permian Naobaogou Formation of ...
  47. The oldest parareptile and the early diversification of reptiles - PMC
  48. Species richness and disparity of parareptiles across the end ... - NIH
  49. Error in estimation of rate and time inferred from the early amniote ...
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