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Therocephalia

January 01, 1970

Therocephalia is an extinct clade of eutheriodont therapsids (mammals and their close relatives) from the Permian and Triassic periods. The therocephalians ("beast-heads") are named after their large skulls, which, along with the structure of their teeth, suggest that they were carnivores. Like other non-mammalian synapsids, therocephalians were once described as "mammal-like reptiles". Therocephalia is the group most closely related to the cynodonts, which gave rise to the mammals, and this relationship takes evidence in a variety of skeletal features. Indeed, it had been proposed that cynodonts may have evolved from therocephalians and so that therocephalians as recognised are paraphyletic in relation to cynodonts.

Therocephalians
Temporal range: Middle PermianMiddle Triassic 266–242 Ma Possible descendant taxon Cynodontia survives to present
Life restoration of two representatives of the early therocephalian genus Alopecognathus
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Clade: Synapsida
Clade: Therapsida
Clade: Eutheriodontia
Clade: Therocephalia
Broom, 1903
Subtaxa

The fossils of therocephalians are numerous in the Karoo of South Africa, but have also been found in Russia, China, Tanzania, Zambia, and Antarctica. Early therocephalian fossils discovered in Middle Permian deposits of South Africa support a Gondwanan origin for the group, which seems to have spread quickly across Earth. Although almost every therocephalian lineage ended during the great Permian–Triassic extinction event, a few representatives of the subgroup called Eutherocephalia survived into the Early Triassic. Some genera belonging to this group are believed to have possessed venom, which would make them the oldest tetrapods known to have such characteristics. However, the last therocephalians became extinct by the early Middle Triassic, possibly due to climate change, along with competition with cynodonts and various groups of reptiles — mostly archosaurs and their close relatives, including archosauromorphs and archosauriforms.

Anatomy and physiology edit

 
Head reconstruction of Lycosuchus, an early therocephalian

Like the Gorgonopsia and many cynodonts, most therocephalians were presumably carnivores. The earlier therocephalians were, in many respects, as primitive as the gorgonopsians, but they did show certain advanced features. There is an enlargement of the temporal opening for broader jaw adductor muscle attachment and a reduction of the phalanges (finger and toe bones) to the mammalian phalangeal formula. The presence of an incipient secondary palate in advanced therocephalians is another feature shared with mammals. The discovery of maxilloturbinal ridges in forms such as the primitive therocephalian Glanosuchus, suggests that at least some therocephalians may have been warm-blooded.[1]

The later therocephalians included the advanced Baurioidea, which carried some theriodont characteristics to a high degree of specialization. For instance, small baurioids and the herbivorous Bauria did not have an ossified postorbital bar separating the orbit from the temporal opening—a condition typical of primitive mammals. These and other advanced features led to the long-held opinion, now rejected, that the ictidosaurs and even some early mammals arose from a baurioid therocephalian stem. Mammalian characteristics such as this seem to have evolved in parallel among a number of different therapsid groups, even within Therocephalia.[1]

 
Skeleton of a lycosuchid on display in the University of California Museum of Paleontology, Berkeley

Several more specialized lifestyles have been suggested for some therocephalians. Many small forms, like ictidosuchids, have been interpreted as aquatic animals. Evidence for aquatic lifestyles includes sclerotic rings that may have stabilized the eye under the pressure of water and strongly developed cranial joints, which may have supported the skull when consuming large fish and aquatic invertebrates. One therocephalian, Nothogomphodon, had large sabre-like canine teeth and may have fed on large animals, including other therocephalians. Other therocephalians such as bauriids and nanictidopids have wide teeth with many ridges similar to those of mammals, and may have been herbivores.[2]

Many small therocephalians have small pits on their snouts that probably supported vibrissae (whiskers). In 1994, the Russian paleontologist Leonid Tatarinov proposed that these pits were part of an electroreception system in aquatic therocephalians.[3] However, it is more likely that these pits are enlarged versions of the ones thought to support whiskers, or holes for blood vessels in a fleshy lip.[2] The genera Euchambersia and Ichibengops, dating from the Lopingian, particularly attract the attention of paleontologists, because the fossil skulls attributed to them have some structures which suggests that these two animals had organs for distributing venom.[4][5]

Classification edit

 
Fossilized skull of Gorynychus, one of the most basal therocephalians identified to date

The therocephalians evolved as one of several lines of non-mammalian therapsids, and have a close relationship to the cynodonts, which includes mammals and their ancestors. They are broadly regarded as the sister group to cynodonts by most modern researchers, united together as the clade Eutheriodontia. However, some researchers have proposed that therocephalians are themselves ancestral to cynodonts, which would render therocephalians cladistically paraphyletic relative to cynodonts. Historically, cynodonts are often proposed to descend from (or are closest to) the therocephalian family Whaitsiidae under this hypothesis, however a 2024 study instead found support for a sister relationship between cynodonts and Eutherocephalia.[6] The oldest known therocephalians first appear in the fossil record at the same time as other major therapsid groups, including the Gorgonopsia, which they resemble in many primitive features. For example, many early therocephalians possess long canine teeth similar to those of gorgonopsians. The therocephalians, however, outlasted the gorgonopsians, persisting into the early-Middle Triassic period as small weasel-like carnivores and cynodont-like herbivores.[7]

While common ancestry with cynodonts (and, thus, mammals) accounts for many similarities between these groups, some scientists believe that other similarities may be better attributed to convergent evolution, such as the loss of the postorbital bar in some forms, a mammalian phalangeal formula, and some form of a secondary palate in most taxa. Therocephalians and cynodonts both survived the Permian-Triassic mass extinction; but, while therocephalians soon became extinct, cynodonts underwent rapid diversification. Therocephalians experienced a decreased rate of cladogenesis, meaning that few new groups appeared after the extinction. Most Triassic therocephalian lineages originated in the Late Permian, and lasted for only a short period of time in the Triassic,[8] going extinct during the late Anisian.[9]

Taxonomy edit

 
Moschorhinus life restoration, an akidnognathid

Therocephalia was first named and conceived of by Robert Broom in 1903 as an order to include what he regarded as primitive theriodonts, based primarily on Scylacosaurus and Ictidosaurus. However, his original concept of Therocephalia differed strongly from the modern classification by also including various genera of gorgonopsians (including Gorgonops) and dinocephalians. From 1903 to 1907 Broom added more therocephalian genera, as well as some non-therocephalians, to this group, including the anomodont Galechirus. The latter's inclusion highlighted Broom's view of therocephalians as 'primitive' and ancestral to other therapsids, believing anomodonts to be descended from a therocephalian-like ancestor such as Galechirus. However, by 1908 he considered its and some other non-therocephalian's inclusions to the group to be doubtful. In 1913, Broom reinstated Gorgonopsia as distinct from Therocephalia, but for many decades after there was still confusion from him and other researchers over wich genera beloned to which group. The group's rank also varied from order, suborder and infraorder depending on authors' preferred therapsid systematics.[10]

At the same time, the small 'advanced' therocephalians now classified under Baurioidea were often regarded as belonging to their own subgroup of therapsids distinct from therocephalians, the Bauriamorpha.[11] Bauriamorphs were classified separately from therocephalians for many decades, though were often inferred to have evolved from therocephalians in parallel with cynodonts, each typically from different therocephalian stock.[10] The inclusion of baurioids under Therocephalia was only firmly established in the 1980s, namely by Kemp (1982) and Hopson and Barghusen (1986).[12][13]

 
Megawhaitsia head restoration, a whaitsiid

Various therocephalian subgroups and clades have been proposed since the group was named, although their contents and nomenclature have often been highly unstable and some previously recognized therocephalian clades have turned out to be artificial or based upon dubious taxa. This has led to some prevelant names in therocephalian literature, sometimes in use for decades, being replaced by lesser-known names that hold priority. For example, the Scaloposauridae was based on fossils with mostly juvenile characteristics and is likely represented by immature specimens from other disparate therocephalian families.

In another example, the name 'Pristerognathidae' was extensively used for a group of basal therocephalians for much of the 20th century, but it has since been recognised that the name Scylacosauridae holds precedent for this group. Furthermore, the scope of 'Pristerognathidae' was unstable and variably was limited to an individual subgroup of early therocephalians (alongside others such as Lycosuchidae, Alopecodontidae, and Ictidosauridae) to encompassing the entirety of early therocephalians.[10] Similarly, various names have been used for therocephalians corresponding to the family Adkidnognathidae in 20th century literature, including Annatherapsididae, Euchambersiidae (the oldest available name) and Moschorhinidae, and members have often had a confused relationship to whaitsiids. Consensus on the name and contents of Akidnognathidae was only achieved in the 21st century, asserting that a family-level group is established on the oldest referable genus and thus Akidnognathidae takes precedent for this group of non-whaitsioid eutherocephalians.[11]

On the other hand, some groups previously thought to be artificial have turned out to be valid. The aberrant therocephalian family Lycosuchidae, once identified by the presence of multiple functional caniniform teeth, was proposed to represent an unnatural group based on a study of canine replacement in early therocephalians by van den Heever in 1980.[14] However, subsequent analysis has exposed additional synapomorphies supporting the monophyly of this group (including delayed caniniform replacement), and Lycosuchidae is currently considered a valid basal clade within Therocephalia.[15] However, most genera included in the group have since been declared dubious, and it now only includes Lycosuchus and Simorhinella.[16]

 
Regisaurus life restoration, a baurioid

Modern therocephalian taxonomy is instead based upon phylogenetic analyses of therocephalian species, which consistently recognises two groups of early therocephalians (the Lycosuchidae and Scylacosauridae) while more derived therocephalians form the clade Eutherocephalia. Some analyses have found scylacosaurids to be closer to eutherocephalians than to lycosuchids, and so have been united as the clade Scylacosauria, while others have suggested they are each other's sister taxa. Within Eutherocephalia, major clades corresponding to the families Akidnognathidae, Chthonosauridae, Hofmeyriidae, Whaitsiidae are recognised, along with various subclades grouped under Baurioidea. However, while individual groups of therocephalians are broadly recognised as valid, the interrelationships between them are often poorly supported.[17][18][19] As such, there are few higher-level named clades uniting the multiple subclades, with the exceptions of Whaitsiioidea (uniting Hofmeyriidae and Whaitsiidae) and Baurioidea.

Phylogeny edit

Early phylogenetic analyses of therocephalians, such as that of Hopson and Barghusen (1986) and van den Heever (1994), recovered and validated many of the therocephalian subtaxa mentioned above in a phylogenetic context. However, the higher-level relationships were difficult to resolve, particularly between the subclades of Eutherocephalia (i.e. Hofmeyriidae, Akidnognathidae, Whaitsiidae and Baurioidea). For example, Hopson and Barghusen (1986) could only recover Eutherocephalia as an unresolved polytomy.[13] Despite these shortcomings, subsequent discussions of therocephalian relationships relied almost exclusively on these analyses.[11] Later analyses focused on the relationships of early cynodonts, namely Abdala (2007) and Botha et al. (2007), included some therocephalian taxa and supported the existence of Eutherocephalia, but also found cynodonts to be the sister taxon to the whaitsiid therocephalian Theriognathus and thus rendering Therocephalia paraphyletic.[20][21]

Later phylogenetic analyses of therocephalians, initiated by Huttenlocker (2009), emphasise using a broader selection of therocephalian taxa and characters. Such analyses have reinforced Therocephalia as a sister clade to cynodonts, and the monophyly of Therocephalia has been supported by subsequent researchers.[11][7]

Below is a cladogram modified from an analysis published by Christian A. Sidor, Zoe. T Kulik and Adam K. Huttenlocker in 2022, simplified to illustrate the relationships of the major recognised therocephalian subclades.[22] It is based on the data matrix first published by Huttenlocker et al. (2011),[8] and represents the broad topologies found by other iterations of this dataset, such as Sigurdsen et al. (2012), Huttenlocker et al. (2014), and Liu and Abdala (2022).[23][24][17] An example of the lability of these relationships is demonstrated by Liu and Abdala (2023), who recovered an alternative topology with Chthonosauridae nested deeply within Akidnognathidae.[25]

Below is a cladogram modified from Pusch et al. (2024) analysing the relationships of therocephalians and early cynodonts. Their analysis focused on including endocranial characteristics to help resolve the relations of therocephalians and cynodonts to supplement previous analyses that relied almost entirely on superficial cranial and dental characteristics that are subject to convergent evolution, and as such only includes taxa with available applicable data. Of these, only four therocephalians could be included. However, they each represent four major groups within therocephalian phylogeny: the two 'basal therocephalians' Lycosuchus (Lycosuchidae) and Alopecognathus (Scylacosauridae) and two derived members of Eutherocephalia, Olivierosuchus (Akidnognathidae) and Theriognathus (Whaitsiidae).[6]

Notably, their analyses consistently found cynodonts and eutherocephalians to be sister taxa, with the basal therocephalians Lycosuchus and scylacosaurids in a more basal position, rendering therocephalians as they are traditionally conceived paraphyletic. This differs from previous proposals of a paraphyletic Therocephalia which typically regarded cynodonts as being closest to derived whaitsiid therocephalians.[6]

See also edit

References edit

  1. ^ a b Rubidge, B.S.; Sidor, C.A. (2001). (PDF). Annual Review of Ecology, Evolution, and Systematics. 32: 449–480. doi:10.1146/annurev.ecolsys.32.081501.114113. Archived from the original (PDF) on 2012-03-21.
  2. ^ a b Ivakhnenko, M.F. (2011). "Permian and Triassic therocephals (Eutherapsida) of Eastern Europe". Paleontological Journal. 45 (9): 981–1144. doi:10.1134/S0031030111090012. S2CID 128958135.
  3. ^ Tatarinov, L.P. (1994). "On the preservation of rudimentary rostral tubular complex of crossopterygians in theriodonts and on possible development of the electroreceptor systems in some members of this group". Doklady Akademii Nauk. 338 (2): 278–281.
  4. ^ Benoit, J.; Norton, L.A.; Manger, P.R.; Rubidge, B.S. (2017). "Reappraisal of the envenoming capacity of Euchambersia mirabilis (Therapsida, Therocephalia) using μCT-scanning techniques". PLOS ONE. 12 (2): e0172047. Bibcode:2017PLoSO..1272047B. doi:10.1371/journal.pone.0172047. PMC 5302418. PMID 28187210.
  5. ^ Field Museum (August 13, 2015). "Prehistoric carnivore dubbed 'scarface' discovered in Zambia" (Press release). Science Daily.
  6. ^ a b c Pusch, L. C.; Kammerer, C. F.; Fröbisch, J. (2024). "The origin and evolution of Cynodontia (Synapsida, Therapsida): Reassessment of the phylogeny and systematics of the earliest members of this clade using 3D-imaging technologies". The Anatomical Record. doi:10.1002/ar.25394. PMID 38444024.
  7. ^ a b Angielczyk, Kenneth D.; Kammerer, Christian F. (2018). "Non-Mammalian synapsids: the deep roots of the mammalian family tree". In Zachos, Frank E.; Asher, Robert J. (eds.). Mammalian Evolution, Diversity and Systematics. Berlin: De Gruyter. pp. 160–162. ISBN 9783110275902.
  8. ^ a b Huttenlocker, A.K.; Sidor, C.A.; Smith, R.M.H. (2011). "A new specimen of Promoschorhynchus (Therapsida: Therocephalia: Akidnognathidae) from the Lower Triassic of South Africa and its implications for theriodont survivorship across the Permo-Triassic boundary". Journal of Vertebrate Paleontology. 31 (2): 405–421. doi:10.1080/02724634.2011.546720. S2CID 129242450.
  9. ^ Grunert, Henrik Richard; Brocklehurst, Neil; Fröbisch, Jörg (25 March 2019). "Diversity and Disparity of Therocephalia: Macroevolutionary Patterns through Two Mass Extinctions". Scientific Reports. 9 (5063): 5063. Bibcode:2019NatSR...9.5063G. doi:10.1038/s41598-019-41628-w. PMC 6433905. PMID 30911058.
  10. ^ a b c Van den Heever, J. (1987). The comparative and functional cranial morphology of the early Therocephalia (Amniota: Therapsida) (Ph.D. thesis). University of Stellenbosch.
  11. ^ a b c d Huttenlocker, A. (2009). "An investigation into the cladistic relationships and monophyly of therocephalian therapsids (Amniota: Synapsida)". Zoological Journal of the Linnean Society. 157 (4): 865–891. doi:10.1111/j.1096-3642.2009.00538.x.
  12. ^ Kemp, T. S. (1982). Mammal-like reptiles and the origin of mammals. London: Academic Press. ISBN 9780124041202.
  13. ^ a b Hopson, J. A.; Barghusen, H (1986). "An analysis of therapsid relationships". In Hotton, N.; MacLean, P. D.; Roth, J. J.; Roth, E. C. (eds.). The ecology and biology of mammal-like reptiles. Washington: Smithsonian Institution Press. pp. 83–106.
  14. ^ van den Heever, J. A. (1980). "On the validity of the therocephalian family Lycosuchidae (Reptilia, Therapsida)". Annals of the South African Museum. 81: 111–125.
  15. ^ van den Heever, J. A. (1994). "The Cranial Anatomy of the Early Therocephalia (Amniota: Therapsida)". Annals of the University of Stellenbosch. 1. ISBN 978-0-7972-0498-0.
  16. ^ Abdala, F.; Kammerer, C. F.; Day, M. O.; Jirah, S.; Rubidge, B. S. (2014). "Adult morphology of the therocephalian Simorhinella baini from the middle Permian of South Africa and the taxonomy, paleobiogeography, and temporal distribution of the Lycosuchidae". Journal of Paleontology. 88 (6): 1139–1153. doi:10.1666/13-186. ISSN 0022-3360. S2CID 129323281.
  17. ^ a b Liu, J.; Abdala, F. (2022). "The emblematic South African therocephalian Euchambersia in China: a new link in the dispersal of late Permian vertebrates across Pangea". Biology Letters. 18 (7): 20220222. doi:10.1098/rsbl.2022.0222. PMC 9278400. PMID 35857894.
  18. ^ Kammerer, C. F.; Masyutin, V. (2018). "A new therocephalian (Gorynychus masyutinae gen. et sp. nov.) from the Permian Kotelnich locality, Kirov Region, Russia". PeerJ. 6. e4933. doi:10.7717/peerj.4933. PMC 5995100. PMID 29900076.
  19. ^ Liu, J.; Abdala, F. (2019). "The tetrapod fauna of the upper Permian Naobaogou Formation of China: 3. Jiufengia jiai gen. et sp. nov., a large akidnognathid therocephalian". PeerJ. 7. e6463. doi:10.7717/peerj.6463. ISSN 2167-8359. PMC 6388668. PMID 30809450.
  20. ^ Abdala, F. (2007). "Redescription of Platycraniellus elegans (Therapsida, Cynodontia) from the Lower Triassic of South Africa, and the Cladistic Relationships of Eutheriodonts". Palaeontology. 50 (3): 591–618. Bibcode:2007Palgy..50..591A. doi:10.1111/j.1475-4983.2007.00646.x. S2CID 83999660.
  21. ^ Botha, J.; Abdala, F.; Smith, R. M. H. (2007). "The oldest cynodont: new clues on the origin and diversification of the Cynodontia". Zoological Journal of the Linnean Society. 149: 477–492. doi:10.1111/j.1096-3642.2007.00268.x.
  22. ^ Sidor, C. A.; Kulik, Z. T.; Huttenlocker, A. K. (2022). "A new bauriamorph therocephalian adds a novel component to the Lower Triassic tetrapod assemblage of the Fremouw Formation (Transantarctic Basin) of Antarctica". Journal of Vertebrate Paleontology. 41 (6): e2081510. doi:10.1080/02724634.2021.2081510. S2CID 250663346.
  23. ^ Sigurdsen, T.; Huttenlocker, A. K.; Modesto, S. P.; Rowe, T. B.; Damiani, R. (2012). "Reassessment of the morphology and paleobiology of the therocephalian Tetracynodon darti (Therapsida), and the phylogenetic relationships of Baurioidea". Journal of Vertebrate Paleontology. 32 (5): 1113–1134. doi:10.1080/02724634.2012.688693. S2CID 84457790.
  24. ^ Huttenlocker, A. K. (2014). "Body Size Reductions in Nonmammalian Eutheriodont Therapsids (Synapsida) during the End-Permian Mass Extinction". PLOS ONE. 9 (2). e87553. Bibcode:2014PLoSO...987553H. doi:10.1371/journal.pone.0087553. PMC 3911975. PMID 24498335.
  25. ^ Liu, J.; Abdala, F. (2023). "Late Permian terrestrial faunal connections invigorated: the first whaitsioid therocephalian from China". Palaeontologia africana. 56: 16–35. hdl:10539/35706.

External links edit

  •   Media related to Therocephalia at Wikimedia Commons
  •   Data related to Therocephalia at Wikispecies

January 01, 1970
therocephalia, extinct, clade, eutheriodont, therapsids, mammals, their, close, relatives, from, permian, triassic, periods, therocephalians, beast, heads, named, after, their, large, skulls, which, along, with, structure, their, teeth, suggest, that, they, we. Therocephalia is an extinct clade of eutheriodont therapsids mammals and their close relatives from the Permian and Triassic periods The therocephalians beast heads are named after their large skulls which along with the structure of their teeth suggest that they were carnivores Like other non mammalian synapsids therocephalians were once described as mammal like reptiles Therocephalia is the group most closely related to the cynodonts which gave rise to the mammals and this relationship takes evidence in a variety of skeletal features Indeed it had been proposed that cynodonts may have evolved from therocephalians and so that therocephalians as recognised are paraphyletic in relation to cynodonts TherocephaliansTemporal range Middle Permian Middle Triassic 266 242 Ma PreꞒ Ꞓ O S D C P T J K Pg N Possible descendant taxon Cynodontia survives to present Life restoration of two representatives of the early therocephalian genus Alopecognathus Scientific classification Domain Eukaryota Kingdom Animalia Phylum Chordata Clade Synapsida Clade Therapsida Clade Eutheriodontia Clade TherocephaliaBroom 1903 Subtaxa Gorynychus Porosteognathus Lycosuchidae Scylacosauridae Eutherocephalia Cynodontia The fossils of therocephalians are numerous in the Karoo of South Africa but have also been found in Russia China Tanzania Zambia and Antarctica Early therocephalian fossils discovered in Middle Permian deposits of South Africa support a Gondwanan origin for the group which seems to have spread quickly across Earth Although almost every therocephalian lineage ended during the great Permian Triassic extinction event a few representatives of the subgroup called Eutherocephalia survived into the Early Triassic Some genera belonging to this group are believed to have possessed venom which would make them the oldest tetrapods known to have such characteristics However the last therocephalians became extinct by the early Middle Triassic possibly due to climate change along with competition with cynodonts and various groups of reptiles mostly archosaurs and their close relatives including archosauromorphs and archosauriforms Contents 1 Anatomy and physiology 2 Classification 2 1 Taxonomy 2 2 Phylogeny 3 See also 4 References 5 External linksAnatomy and physiology edit nbsp Head reconstruction of Lycosuchus an early therocephalian Like the Gorgonopsia and many cynodonts most therocephalians were presumably carnivores The earlier therocephalians were in many respects as primitive as the gorgonopsians but they did show certain advanced features There is an enlargement of the temporal opening for broader jaw adductor muscle attachment and a reduction of the phalanges finger and toe bones to the mammalian phalangeal formula The presence of an incipient secondary palate in advanced therocephalians is another feature shared with mammals The discovery of maxilloturbinal ridges in forms such as the primitive therocephalian Glanosuchus suggests that at least some therocephalians may have been warm blooded 1 The later therocephalians included the advanced Baurioidea which carried some theriodont characteristics to a high degree of specialization For instance small baurioids and the herbivorous Bauria did not have an ossified postorbital bar separating the orbit from the temporal opening a condition typical of primitive mammals These and other advanced features led to the long held opinion now rejected that the ictidosaurs and even some early mammals arose from a baurioid therocephalian stem Mammalian characteristics such as this seem to have evolved in parallel among a number of different therapsid groups even within Therocephalia 1 nbsp Skeleton of a lycosuchid on display in the University of California Museum of Paleontology Berkeley Several more specialized lifestyles have been suggested for some therocephalians Many small forms like ictidosuchids have been interpreted as aquatic animals Evidence for aquatic lifestyles includes sclerotic rings that may have stabilized the eye under the pressure of water and strongly developed cranial joints which may have supported the skull when consuming large fish and aquatic invertebrates One therocephalian Nothogomphodon had large sabre like canine teeth and may have fed on large animals including other therocephalians Other therocephalians such as bauriids and nanictidopids have wide teeth with many ridges similar to those of mammals and may have been herbivores 2 Many small therocephalians have small pits on their snouts that probably supported vibrissae whiskers In 1994 the Russian paleontologist Leonid Tatarinov proposed that these pits were part of an electroreception system in aquatic therocephalians 3 However it is more likely that these pits are enlarged versions of the ones thought to support whiskers or holes for blood vessels in a fleshy lip 2 The genera Euchambersia and Ichibengops dating from the Lopingian particularly attract the attention of paleontologists because the fossil skulls attributed to them have some structures which suggests that these two animals had organs for distributing venom 4 5 Classification edit nbsp Fossilized skull of Gorynychus one of the most basal therocephalians identified to date The therocephalians evolved as one of several lines of non mammalian therapsids and have a close relationship to the cynodonts which includes mammals and their ancestors They are broadly regarded as the sister group to cynodonts by most modern researchers united together as the clade Eutheriodontia However some researchers have proposed that therocephalians are themselves ancestral to cynodonts which would render therocephalians cladistically paraphyletic relative to cynodonts Historically cynodonts are often proposed to descend from or are closest to the therocephalian family Whaitsiidae under this hypothesis however a 2024 study instead found support for a sister relationship between cynodonts and Eutherocephalia 6 The oldest known therocephalians first appear in the fossil record at the same time as other major therapsid groups including the Gorgonopsia which they resemble in many primitive features For example many early therocephalians possess long canine teeth similar to those of gorgonopsians The therocephalians however outlasted the gorgonopsians persisting into the early Middle Triassic period as small weasel like carnivores and cynodont like herbivores 7 While common ancestry with cynodonts and thus mammals accounts for many similarities between these groups some scientists believe that other similarities may be better attributed to convergent evolution such as the loss of the postorbital bar in some forms a mammalian phalangeal formula and some form of a secondary palate in most taxa Therocephalians and cynodonts both survived the Permian Triassic mass extinction but while therocephalians soon became extinct cynodonts underwent rapid diversification Therocephalians experienced a decreased rate of cladogenesis meaning that few new groups appeared after the extinction Most Triassic therocephalian lineages originated in the Late Permian and lasted for only a short period of time in the Triassic 8 going extinct during the late Anisian 9 Taxonomy edit nbsp Moschorhinus life restoration an akidnognathid Therocephalia was first named and conceived of by Robert Broom in 1903 as an order to include what he regarded as primitive theriodonts based primarily on Scylacosaurus and Ictidosaurus However his original concept of Therocephalia differed strongly from the modern classification by also including various genera of gorgonopsians including Gorgonops and dinocephalians From 1903 to 1907 Broom added more therocephalian genera as well as some non therocephalians to this group including the anomodont Galechirus The latter s inclusion highlighted Broom s view of therocephalians as primitive and ancestral to other therapsids believing anomodonts to be descended from a therocephalian like ancestor such as Galechirus However by 1908 he considered its and some other non therocephalian s inclusions to the group to be doubtful In 1913 Broom reinstated Gorgonopsia as distinct from Therocephalia but for many decades after there was still confusion from him and other researchers over wich genera beloned to which group The group s rank also varied from order suborder and infraorder depending on authors preferred therapsid systematics 10 At the same time the small advanced therocephalians now classified under Baurioidea were often regarded as belonging to their own subgroup of therapsids distinct from therocephalians the Bauriamorpha 11 Bauriamorphs were classified separately from therocephalians for many decades though were often inferred to have evolved from therocephalians in parallel with cynodonts each typically from different therocephalian stock 10 The inclusion of baurioids under Therocephalia was only firmly established in the 1980s namely by Kemp 1982 and Hopson and Barghusen 1986 12 13 nbsp Megawhaitsia head restoration a whaitsiid Various therocephalian subgroups and clades have been proposed since the group was named although their contents and nomenclature have often been highly unstable and some previously recognized therocephalian clades have turned out to be artificial or based upon dubious taxa This has led to some prevelant names in therocephalian literature sometimes in use for decades being replaced by lesser known names that hold priority For example the Scaloposauridae was based on fossils with mostly juvenile characteristics and is likely represented by immature specimens from other disparate therocephalian families In another example the name Pristerognathidae was extensively used for a group of basal therocephalians for much of the 20th century but it has since been recognised that the name Scylacosauridae holds precedent for this group Furthermore the scope of Pristerognathidae was unstable and variably was limited to an individual subgroup of early therocephalians alongside others such as Lycosuchidae Alopecodontidae and Ictidosauridae to encompassing the entirety of early therocephalians 10 Similarly various names have been used for therocephalians corresponding to the family Adkidnognathidae in 20th century literature including Annatherapsididae Euchambersiidae the oldest available name and Moschorhinidae and members have often had a confused relationship to whaitsiids Consensus on the name and contents of Akidnognathidae was only achieved in the 21st century asserting that a family level group is established on the oldest referable genus and thus Akidnognathidae takes precedent for this group of non whaitsioid eutherocephalians 11 On the other hand some groups previously thought to be artificial have turned out to be valid The aberrant therocephalian family Lycosuchidae once identified by the presence of multiple functional caniniform teeth was proposed to represent an unnatural group based on a study of canine replacement in early therocephalians by van den Heever in 1980 14 However subsequent analysis has exposed additional synapomorphies supporting the monophyly of this group including delayed caniniform replacement and Lycosuchidae is currently considered a valid basal clade within Therocephalia 15 However most genera included in the group have since been declared dubious and it now only includes Lycosuchus and Simorhinella 16 nbsp Regisaurus life restoration a baurioid Modern therocephalian taxonomy is instead based upon phylogenetic analyses of therocephalian species which consistently recognises two groups of early therocephalians the Lycosuchidae and Scylacosauridae while more derived therocephalians form the clade Eutherocephalia Some analyses have found scylacosaurids to be closer to eutherocephalians than to lycosuchids and so have been united as the clade Scylacosauria while others have suggested they are each other s sister taxa Within Eutherocephalia major clades corresponding to the families Akidnognathidae Chthonosauridae Hofmeyriidae Whaitsiidae are recognised along with various subclades grouped under Baurioidea However while individual groups of therocephalians are broadly recognised as valid the interrelationships between them are often poorly supported 17 18 19 As such there are few higher level named clades uniting the multiple subclades with the exceptions of Whaitsiioidea uniting Hofmeyriidae and Whaitsiidae and Baurioidea Phylogeny edit Early phylogenetic analyses of therocephalians such as that of Hopson and Barghusen 1986 and van den Heever 1994 recovered and validated many of the therocephalian subtaxa mentioned above in a phylogenetic context However the higher level relationships were difficult to resolve particularly between the subclades of Eutherocephalia i e Hofmeyriidae Akidnognathidae Whaitsiidae and Baurioidea For example Hopson and Barghusen 1986 could only recover Eutherocephalia as an unresolved polytomy 13 Despite these shortcomings subsequent discussions of therocephalian relationships relied almost exclusively on these analyses 11 Later analyses focused on the relationships of early cynodonts namely Abdala 2007 and Botha et al 2007 included some therocephalian taxa and supported the existence of Eutherocephalia but also found cynodonts to be the sister taxon to the whaitsiid therocephalian Theriognathus and thus rendering Therocephalia paraphyletic 20 21 Later phylogenetic analyses of therocephalians initiated by Huttenlocker 2009 emphasise using a broader selection of therocephalian taxa and characters Such analyses have reinforced Therocephalia as a sister clade to cynodonts and the monophyly of Therocephalia has been supported by subsequent researchers 11 7 Below is a cladogram modified from an analysis published by Christian A Sidor Zoe T Kulik and Adam K Huttenlocker in 2022 simplified to illustrate the relationships of the major recognised therocephalian subclades 22 It is based on the data matrix first published by Huttenlocker et al 2011 8 and represents the broad topologies found by other iterations of this dataset such as Sigurdsen et al 2012 Huttenlocker et al 2014 and Liu and Abdala 2022 23 24 17 An example of the lability of these relationships is demonstrated by Liu and Abdala 2023 who recovered an alternative topology with Chthonosauridae nested deeply within Akidnognathidae 25 Therapsida Biarmosuchus tener Titanophoneus potens Gorgonopsia Anomodontia Eutheriodontia Cynodontia Charassognathus Dvinia Procynosuchus Therocephalia Lycosuchus Scylacosauria Scylacosauridae Eutherocephalia Scylacosuchus Perplexisaurus Chthonosauridae Akidnognathidae Whaitsioidea Ophidostoma Hofmeyriidae Whaitsiidae Baurioidea Ictidosuchus Ictidosuchoides Ictidosuchops Regisaurus Urumchia Karenitidae Lycideops Choerosaurus Tetracynodon Scaloposaurus Bauriamorpha Ericiolacertidae Notictoides Nothogomphodon danilovi Ordosiodon Hazhenia Bauriidae Below is a cladogram modified from Pusch et al 2024 analysing the relationships of therocephalians and early cynodonts Their analysis focused on including endocranial characteristics to help resolve the relations of therocephalians and cynodonts to supplement previous analyses that relied almost entirely on superficial cranial and dental characteristics that are subject to convergent evolution and as such only includes taxa with available applicable data Of these only four therocephalians could be included However they each represent four major groups within therocephalian phylogeny the two basal therocephalians Lycosuchus Lycosuchidae and Alopecognathus Scylacosauridae and two derived members of Eutherocephalia Olivierosuchus Akidnognathidae and Theriognathus Whaitsiidae 6 Notably their analyses consistently found cynodonts and eutherocephalians to be sister taxa with the basal therocephalians Lycosuchus and scylacosaurids in a more basal position rendering therocephalians as they are traditionally conceived paraphyletic This differs from previous proposals of a paraphyletic Therocephalia which typically regarded cynodonts as being closest to derived whaitsiid therocephalians 6 Theriodontia Cynariops Therocephalia Eutheriodontia Lycosuchus Alopecognathus Eutherocephalia Olivierosuchus Theriognathus Cynodontia Charassognathidae Charassognathus Abdalodon Dvinia Procynosuchus Epicynodontia Galesauridae Galesaurus Progalesaurus Vetusodon Cynosaurus Nanictosaurus Platycraniellus Thrinaxodon Eucynodontia Probainognathus Lumkuia Boreogomphodon Trirachodon Traditional therocephaliansSee also editEvolution of mammals List of synapsidsReferences edit a b Rubidge B S Sidor C A 2001 Evolutionary patterns among Permo Triassic therapsids PDF Annual Review of Ecology Evolution and Systematics 32 449 480 doi 10 1146 annurev ecolsys 32 081501 114113 Archived from the original PDF on 2012 03 21 a b Ivakhnenko M F 2011 Permian and Triassic therocephals Eutherapsida of Eastern Europe Paleontological Journal 45 9 981 1144 doi 10 1134 S0031030111090012 S2CID 128958135 Tatarinov L P 1994 On the preservation of rudimentary rostral tubular complex of crossopterygians in theriodonts and on possible development of the electroreceptor systems in some members of this group Doklady Akademii Nauk 338 2 278 281 Benoit J Norton L A Manger P R Rubidge B S 2017 Reappraisal of the envenoming capacity of Euchambersia mirabilis Therapsida Therocephalia using mCT scanning techniques PLOS ONE 12 2 e0172047 Bibcode 2017PLoSO 1272047B doi 10 1371 journal pone 0172047 PMC 5302418 PMID 28187210 Field Museum August 13 2015 Prehistoric carnivore dubbed scarface discovered in Zambia Press release Science Daily a b c Pusch L C Kammerer C F Frobisch J 2024 The origin and evolution of Cynodontia Synapsida Therapsida Reassessment of the phylogeny and systematics of the earliest members of this clade using 3D imaging technologies The Anatomical Record doi 10 1002 ar 25394 PMID 38444024 a b Angielczyk Kenneth D Kammerer Christian F 2018 Non Mammalian synapsids the deep roots of the mammalian family tree In Zachos Frank E Asher Robert J eds Mammalian Evolution Diversity and Systematics Berlin De Gruyter pp 160 162 ISBN 9783110275902 a b Huttenlocker A K Sidor C A Smith R M H 2011 A new specimen of Promoschorhynchus Therapsida Therocephalia Akidnognathidae from the Lower Triassic of South Africa and its implications for theriodont survivorship across the Permo Triassic boundary Journal of Vertebrate Paleontology 31 2 405 421 doi 10 1080 02724634 2011 546720 S2CID 129242450 Grunert Henrik Richard Brocklehurst Neil Frobisch Jorg 25 March 2019 Diversity and Disparity of Therocephalia Macroevolutionary Patterns through Two Mass Extinctions Scientific Reports 9 5063 5063 Bibcode 2019NatSR 9 5063G doi 10 1038 s41598 019 41628 w PMC 6433905 PMID 30911058 a b c Van den Heever J 1987 The comparative and functional cranial morphology of the early Therocephalia Amniota Therapsida Ph D thesis University of Stellenbosch a b c d Huttenlocker A 2009 An investigation into the cladistic relationships and monophyly of therocephalian therapsids Amniota Synapsida Zoological Journal of the Linnean Society 157 4 865 891 doi 10 1111 j 1096 3642 2009 00538 x Kemp T S 1982 Mammal like reptiles and the origin of mammals London Academic Press ISBN 9780124041202 a b Hopson J A Barghusen H 1986 An analysis of therapsid relationships In Hotton N MacLean P D Roth J J Roth E C eds The ecology and biology of mammal like reptiles Washington Smithsonian Institution Press pp 83 106 van den Heever J A 1980 On the validity of the therocephalian family Lycosuchidae Reptilia Therapsida Annals of the South African Museum 81 111 125 van den Heever J A 1994 The Cranial Anatomy of the Early Therocephalia Amniota Therapsida Annals of the University of Stellenbosch 1 ISBN 978 0 7972 0498 0 Abdala F Kammerer C F Day M O Jirah S Rubidge B S 2014 Adult morphology of the therocephalian Simorhinella baini from the middle Permian of South Africa and the taxonomy paleobiogeography and temporal distribution of the Lycosuchidae Journal of Paleontology 88 6 1139 1153 doi 10 1666 13 186 ISSN 0022 3360 S2CID 129323281 a b Liu J Abdala F 2022 The emblematic South African therocephalian Euchambersia in China a new link in the dispersal of late Permian vertebrates across Pangea Biology Letters 18 7 20220222 doi 10 1098 rsbl 2022 0222 PMC 9278400 PMID 35857894 Kammerer C F Masyutin V 2018 A new therocephalian Gorynychus masyutinae gen et sp nov from the Permian Kotelnich locality Kirov Region Russia PeerJ 6 e4933 doi 10 7717 peerj 4933 PMC 5995100 PMID 29900076 Liu J Abdala F 2019 The tetrapod fauna of the upper Permian Naobaogou Formation of China 3 Jiufengia jiai gen et sp nov a large akidnognathid therocephalian PeerJ 7 e6463 doi 10 7717 peerj 6463 ISSN 2167 8359 PMC 6388668 PMID 30809450 Abdala F 2007 Redescription of Platycraniellus elegans Therapsida Cynodontia from the Lower Triassic of South Africa and the Cladistic Relationships of Eutheriodonts Palaeontology 50 3 591 618 Bibcode 2007Palgy 50 591A doi 10 1111 j 1475 4983 2007 00646 x S2CID 83999660 Botha J Abdala F Smith R M H 2007 The oldest cynodont new clues on the origin and diversification of the Cynodontia Zoological Journal of the Linnean Society 149 477 492 doi 10 1111 j 1096 3642 2007 00268 x Sidor C A Kulik Z T Huttenlocker A K 2022 A new bauriamorph therocephalian adds a novel component to the Lower Triassic tetrapod assemblage of the Fremouw Formation Transantarctic Basin of Antarctica Journal of Vertebrate Paleontology 41 6 e2081510 doi 10 1080 02724634 2021 2081510 S2CID 250663346 Sigurdsen T Huttenlocker A K Modesto S P Rowe T B Damiani R 2012 Reassessment of the morphology and paleobiology of the therocephalian Tetracynodon darti Therapsida and the phylogenetic relationships of Baurioidea Journal of Vertebrate Paleontology 32 5 1113 1134 doi 10 1080 02724634 2012 688693 S2CID 84457790 Huttenlocker A K 2014 Body Size Reductions in Nonmammalian Eutheriodont Therapsids Synapsida during the End Permian Mass Extinction PLOS ONE 9 2 e87553 Bibcode 2014PLoSO 987553H doi 10 1371 journal pone 0087553 PMC 3911975 PMID 24498335 Liu J Abdala F 2023 Late Permian terrestrial faunal connections invigorated the first whaitsioid therocephalian from China Palaeontologia africana 56 16 35 hdl 10539 35706 External links edit nbsp Media related to Therocephalia at Wikimedia Commons nbsp Data related to Therocephalia at Wikispecies Portal nbsp Paleontology Retrieved from https en wikipedia org w index php title Therocephalia amp oldid 1217152414, wikipedia, wiki, book, books, library,

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