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Archosauromorpha

February 16, 2024

Archosauromorpha (Greek for "ruling lizard forms") is a clade of diapsid reptiles containing all reptiles more closely related to archosaurs (such as crocodilians and dinosaurs, including birds) rather than lepidosaurs (such as tuataras, lizards, and snakes).[1] Archosauromorphs first appeared during the late Middle Permian or Late Permian,[2] though they became much more common and diverse during the Triassic period.[3]

Archosauromorphs
Temporal range: 260–0 Ma Possible Middle Permian records
Row 1: Sharovipteryx mirabilis and Crocodylus porosus
Row 2: Pardalotus punctatus and Hyperodapedon fischeri
Row 3: Tanystropheus longobardicus
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Clade: Archelosauria
Clade: Archosauromorpha
von Huene, 1946
Subgroups

Although Archosauromorpha was first named in 1946, its membership did not become well-established until the 1980s. Currently Archosauromorpha encompasses four main groups of reptiles: the stocky, herbivorous allokotosaurs and rhynchosaurs, the hugely diverse Archosauriformes, and a polyphyletic grouping of various long-necked reptiles including Protorosaurus, tanystropheids, and Prolacerta. Other groups including pantestudines (turtles and their extinct relatives) and the semiaquatic choristoderes have also been placed in Archosauromorpha by some authors.

Archosauromorpha is one of the most diverse groups of reptiles, but its members can be united by several shared skeletal characteristics. These include laminae on the vertebrae, a posterodorsal process of the premaxilla, a lack of notochordal canals, and the loss of the entepicondylar foramen of the humerus.[1]

History and definition edit

The term Archosauromorpha was first used by Friedrich von Huene in 1946 to refer to reptiles more closely related to archosaurs than to lepidosaurs. However, there was little consensus on ancient reptile relationships prior to the late 20th century, so the term Archosauromorpha was seldom used until many years after its creation.

The advent of cladistics helped to sort out at least some of the relationships within Reptilia, and it became clear that there was a split between the archosaur lineage and the lepidosaur lineage somewhere within the Permian, with certain reptiles clearly closer to archosaurs and others allied with lepidosaurs. Jacques Gauthier reused the term Archosauromorpha for the archosaur lineage at the 1982 annual meeting of the American Society of Zoologists, and later used it within his 1984 Ph.D. thesis.[4] Archosauromorpha, as formulated by Gauthier, included four main groups of reptiles: Rhynchosauria, "Prolacertiformes", "Trilophosauria", and Archosauria (now equivalent to the group Archosauriformes). Cladistic analyses created during the 1980s by Gauthier, Michael J. Benton, and Susan E. Evans implemented Gauthier's classification scheme within large studies of reptile relations.[5][4][6]

Michel Laurin (1991) defined Archosauromorpha as the clade containing the most recent common ancestor of Prolacerta, Trilophosaurus, Hyperodapedon and all of its descendants.[7] David Dilkes (1998) formulated a more inclusive (and currently more popular) definition of Archosauromorpha, defining it as the clade containing Protorosaurus and all other saurians that are more closely related to Protorosaurus than to Lepidosauria.[8]

In 2016, Martin Ezcurra named a subgroup of Archosauromorpha, Crocopoda ("crocodile feet"). Crocopoda is defined as all archosauromorphs more closely related to allokotosaurs (specifically Azendohsaurus and Trilophosaurus), rhynchosaurs (specifically Rhynchosaurus), or archosauriforms (specifically Proterosuchus) rather than Protorosaurus or tanystropheids (specifically Tanystropheus). This group roughly corresponds to Laurin's definition of Archosauromorpha.[1]

Members edit

Unambiguous members edit

 
An interaction between two archosauromorphs: Ornithosuchus ( a member of Archosauriformes) scavenging on Hyperodapedon (a rhynchosaur)

Since the seminal studies of the 1980s, Archosauromorpha has consistently been found to contain four specific reptile groups, although the definitions and validity of the groups themselves have been questioned. The least controversial group is Rhynchosauria ("beak reptiles"), a monophyletic clade of stocky herbivores. Many rhynchosaurs had highly modified skulls, with beak-like premaxillary bones and wide heads.

 
Shringasaurus, a horned allokotosaurian from the family Azendohsauridae.

Another group of archosauromorphs has traditionally been represented by Trilophosaurus, an unusual iguana-like herbivorous reptile quite different from the rhynchosaurs. Gauthier used the name "Trilophosauria" for this group, but a 2015 study offered an alternative name. This study found that Azendohsauridae, Triassic reptiles previously mistaken for "prosauropod" dinosaurs, were in fact close relatives of Trilophosaurus and the rest of Trilophosauridae. Trilophosaurids and azendohsaurids are now united under the group Allokotosauria ("strange reptiles").[9] These two groups did not survive the end of the Triassic period, but the most famous group of archosauromorphs not only survived, but have continued to diversify and dominate beyond the Triassic-Jurassic extinction. These were the Archosauriformes, a diverse assortment of animals including the famous dinosaurs and pterosaurs. Two subclades of Archosauriformes survive to the present day: the semiaquatic crocodilians and the last of the feathered dinosaurs: birds. Gauthier used the name Archosauria to refer to what is now called the Archosauriformes; in modern studies, the name Archosauria has a more restricted definition that only includes the ancestors of crocodilians (i.e. Pseudosuchia) and birds (i.e. Avemetatarsalia).

 
The skeleton of Protorosaurus, one of the oldest archosauromorphs and namesake of the problematic group "Protorosauria"

The final unambiguous members of Archosauromorpha represent the most controversial group. These were the first archosauromorphs to appear, and can be characterized by their long necks, sprawling posture, and carnivorous habits. One name for the group, Protorosauria, is named after Protorosaurus, the oldest archosauromorph known from good remains. Another name, Prolacertiformes, is in reference to a different member, Prolacerta. Protorosauria/Prolacertiformes has had a complicated history, and many taxa have entered and left the group as paleontologists discover and re-evaluate reptiles of the Triassic. By far the most famous of these are tanystropheids such as Tanystropheus, known for having necks longer than their entire body. Other notable genera include Boreopricea, Pamelaria, and Macrocnemus, as well as strange gliding reptiles such as Sharovipteryx and Mecistotrachelos. A landmark 1998 study by David Dilkes completely deconstructed the concept of Prolacertiformes as a traditional monophyletic group (i.e. one whose members have a single common ancestor). He argued that Prolacerta was much closer to Archosauriformes than to other "prolacertiforms", invalidating the name.[8] Likewise, Pamelaria is now considered an allokotosaur, Macrocnemus is a tanystropheid, and Protorosaurus may be too basal ("primitive") to form a clade with any of its supposed close relatives.[1] As such, this final group of Archosauromorpha is generally considered paraphyletic or polyphyletic, and few modern studies use it.

Disputed members edit

 
Champsosaurus, a gharial-like choristodere which survived the Cretaceous-Paleocene extinction event. Choristoderes may represent the fifth group of archosauromorphs, but their origin is obscured.

Apart from these four groups, Archosauromorpha is sometimes considered to encompass several additional groups of reptiles. One of the most common additions is Choristodera, a group of semiaquatic reptiles with mysterious origins. Although choristodere fossils are only known from the Jurassic through the Miocene, it is theorized that they first appeared during the Permian alongside the earliest archosauromorphs. Choristoderes share numerous otherwise unique traits with archosauromorphs, but they share an equal or greater number of unique traits with lepidosauromorphs as well, so there is still some debate over their inclusion within either group.[6][1] The chameleon- or tamandua-like drepanosaurs are also semi-regularly placed within Archosauromorpha,[8] although some studies have considered them to be part of a much more basal lineage of reptiles.[10] The aquatic thalattosaurs[6] and gliding kuehneosaurids[6][10] are also irregularly considered archosauromorphs.

Genetic studies have found evidence that modern testudines (turtles and tortoises) are more closely related to crocodilians than to lizards.[11][12] If this evidence is accurate, then turtles are part of basal Archosauromorpha. Likewise, extinct turtle relatives known as Pantestudines would also fall within Archosauromorpha. Some geneticists have proposed a name to refer to reptiles within the group formed by relatives of turtles and archosaurs. This name is the clade Archelosauria. Since Pantestudines may encompass the entire aquatic reptile order Sauropterygia, this means that Archosauromorpha (as Archelosauria) may be a much wider group than commonly believed.[13] However, anatomical data disagrees with this genetic evidence, instead placing Pantestudines within Lepidosauromorpha[14] but many modern studies have supported Archelosauria. Several recent studies place sauropterygians within Archosauromorpha group, forming a large clade including Ichthyosauromorpha and Thalattosauria as opposed to the Pantestudine relations.[15][16][17]

Anatomy edit

Although the most diverse clade of living archosauromorphs are birds, early members of the group were evidently reptilian, superficially similar to modern lizards. When archosauromorphs first appeared in the fossil record in the Permian, they were represented by long-necked, lightly built sprawling reptiles with moderately long, tapering snouts. This body plan, similar to that of modern monitor lizards, is also shared by Triassic archosauromorphs such as tanystropheids and Prolacerta. Other early groups such as trilohpsaurids, azendohsaurids, and rhynchosaurs deviate from this body plan by evolving into stockier forms with semi-erect postures and higher metabolisms. The archosauriforms went to further extremes of diversity, encompassing giant sauropod dinosaurs, flying pterosaurs and birds, semiaquatic crocodilians, phytosaurs, and proterochampsians, and apex predators such as erythrosuchids, pseudosuchians, and theropod dinosaurs. Despite the staggering diversity of archosauromorphs, they can still be united as a clade thanks to several subtle skeletal features.[1]

Skull edit

 
The skull of Proterosuchus, an early archosauriform. Note the long rear branch of the downturned premaxilla and the L-shaped quadratojugal near the jaw joint.

Most archosauromorphs more "advanced" than Protorosaurus possessed an adaptation of the premaxilla (tooth-bearing bone at the tip of the snout) known as a posterodorsal or postnarial process. This was a rear-facing branch of bone that stretched up below and behind the external nares (nostril holes) to contact the nasal bones on the upper edge of the snout. A few advanced archosauriforms reacquired the plesiomorphic ("primitive") state present in other reptiles, that being a short or absent posterodorsal process of the premaxilla, with the rear edge of the nares formed primarily by the maxilla bones instead. As for the nares themselves, they were generally large and oval-shaped, positioned high and close to the midline of the skull.[4]

Many early archosauromorphs, including Protorosaurus, tanystropheids, Trilophosaurus, and derived rhynchosaurs, have a blade-like sagittal crest on the parietal bones at the rear part of the skull roof, between a pair of holes known as the supratemporal (or upper temporal) fenestrae. However, in other allokotosaurs, the basal rhynchosaur Mesosuchus, and more crownward archosauromorphs, the sagittal crest is weakly differentiated, although the inner edge of each supratemporal fenestra still possessed a depressed basin of bone known as a supratemporal fossa. Ezcurra (2016) argued that presence of supratemporal fossae and an absence or poor development of the sagittal crest could be used to characterize Crocopoda. He also noted that in almost all early archosauromorphs (and some choristoderes), the parietal bones have an additional lowered area which extends transversely (from left to right) behind the supratemporal fenestrae and sagittal crest (when applicable).[1]

The lower temporal fenestra is not fully enclosed in early archosauromorphs (and choristoderes) due to alterations to the structure of the quadratojugal bone at the rear lower corner of the skull. This bone is roughly L-shaped in these taxa, with a tall dorsal process (vertical branch), a short anterior process (forward branch), and a tiny or absent posterior process (rear branch). The bones surrounding the quadratojugal also reconfigure to offset the changes to the quadratojugal. For example, the lower branch of the squamosal bone is shortened to offset the tall dorsal process of quadratojugal which connects to it. On the other hand, the rear branch jugal bone lengthens to fill some of the space left by the shortening of the anterior process of the quadratojugal.[6] In archosauriforms, the jugal even re-encloses the lower temporal fenestra. The stapes are long, thin, and solid, without a perforating hole (stapedial foramen) present in the more robust stapes of other reptiles.[6]

Vertebrae edit

 
Cervical vertebrae from Diplodocus, a sauropod dinosaur (Archosauriformes). As with other long-necked archosauromorphs, sauropods had a complex system of laminae on their vertebrae.

In conjunction with their long, S-shaped necks, early archosauromorphs had several adaptations of the cervical (neck) vertebrae, and usually the first few dorsal (back) vertebrae as well. The centrum (main body) of each vertebra is parallelogram-shaped, with a front surface typically positioned higher than the rear surface.[1] The transverse processes (rib facets) of these vertebrae extend outwards to a greater extent than in other early reptiles. In many long-necked archosauromorphs, the rib facets are slanted, connecting to cervical ribs that are often long, thin, and dichocephalous (two-headed).[18]

Thin, plate-like ridges known as laminae develop to connect the vertebral components, sloping down from the elongated transverse processes to the centra. Laminae are practically unique to archosauromorphs, being present even in the earliest Permian genera such as Aenigmastropheus and Eorasaurus. However, they are also known to occur in the bizarre semiaquatic reptile Helveticosaurus,[3] as well as the biarmosuchian synapsid Hipposaurus.[19] In all adult archosauromorphs with the exception of Aenigmastropheus, the vertebrae lack notochordal canals, holes which perforate the centra. This also sets the archosauromorphs apart from most other Permian and Triassic reptiles.[7][3]

Forelimbs edit

The humerus (upper arm bone) is solid in archosauromorphs, completely lacking a hole near the elbow known as the entepicondylar foramen. This hole, present in most other tetrapods, is also absent in choristoderes yet not fully enclosed in some proterosuchids. In many advanced archosauromorphs, the capitulum and trochlea (elbow joints) of the humerus are poorly developed. Early archosauromorphs retain well-developed elbow joints, but all archosauromorphs apart from Aenigmastropheus have a trochlea (ulna joint) which is shifted towards the outer surface of the humerus, rather than the midpoint of the elbow as in other reptiles. In conjunction with this shift, the olecranon process of the ulna is poorly developed in archosauromorphs apart from Aenigmastropheus and Protorosaurus.[1]

Hindlimbs edit

The ankle bones of archosauromorphs tend to acquire complex structures and interactions with each other, and this is particularly the case with the large proximal tarsal bones: the astragalus and calcaneum. The calcaneum, for example, has a tube-like outer extension known as a calcaneal tuber in certain archosauromorphs. This tuber is particularly prominent in the ancient relatives of crocodylians, but it first appeared earlier at the last common ancestor of allokotosaurs, rhynchosaurs, and archosauriforms. The presence of a calcaneal tuber (sometimes known as a lateral tuber of the calcaneum) is a synapomorphy of the group Crocopoda, and is also responsible for its name.[1]

Relationships edit

The cladogram shown below follows the most likely result found by an analysis of turtle relationships using both fossil and genetic evidence by M.S. Lee, in 2013.[20]

The following cladogram is based on a large analysis of archosauriforms published by M.D. Ezcurra in 2016.[1]

See also edit

References edit

  1. ^ a b c d e f g h i j k Ezcurra, Martín D. (2016-04-28). "The phylogenetic relationships of basal archosauromorphs, with an emphasis on the systematics of proterosuchian archosauriforms". PeerJ. 4: e1778. doi:10.7717/peerj.1778. ISSN 2167-8359. PMC 4860341. PMID 27162705.
  2. ^ Martinelli, Agustín G.; Francischini, Heitor; Dentzien-Dias, Paula C.; Soares, Marina B.; Schultz, Cesar L. (2017-01-02). "The oldest archosauromorph from South America: postcranial remains from the Guadalupian (mid-Permian) Rio do Rasto Formation (Paraná Basin), southern Brazil". Historical Biology. 29 (1): 76–84. Bibcode:2017HBio...29...76M. doi:10.1080/08912963.2015.1125897. ISSN 0891-2963. S2CID 86151472.
  3. ^ a b c Butler, Richard J.; Scheyer, Torsten M.; Ezcurra, Martín D. (2014-02-27). "The Origin and Early Evolution of Sauria: Reassessing the Permian Saurian Fossil Record and the Timing of the Crocodile-Lizard Divergence". PLOS ONE. 9 (2): e89165. Bibcode:2014PLoSO...989165E. doi:10.1371/journal.pone.0089165. ISSN 1932-6203. PMC 3937355. PMID 24586565.
  4. ^ a b c Jacques Gauthier; Arnold G. Kluge; Timothy Rowe (1988). "Amniote phylogeny and the importance of fossils" (PDF). Cladistics. 4 (2): 105–209. doi:10.1111/j.1096-0031.1988.tb00514.x. hdl:2027.42/73857. PMID 34949076. S2CID 83502693.
  5. ^ Benton, Michael J. (1985-06-01). "Classification and phylogeny of the diapsid reptiles". Zoological Journal of the Linnean Society. 84 (2): 97–164. doi:10.1111/j.1096-3642.1985.tb01796.x. ISSN 0024-4082.
  6. ^ a b c d e f Evans, Susan E. (1988). "The early history and relationships of the Diapsida". In Benton, M. J. (ed.). The Phylogeny and Classification of the Tetrapods, Volume 1: Amphibians, Reptiles, Birds. Oxford: Clarendon Press. pp. 221–260.
  7. ^ a b Michel Laurin (1991). "The osteology of a Lower Permian eosuchian from Texas and a review of diapsid phylogeny". Zoological Journal of the Linnean Society. 101 (1): 59–95. doi:10.1111/j.1096-3642.1991.tb00886.x.
  8. ^ a b c David M. Dilkes (1998). "The Early Triassic rhynchosaur Mesosuchus browni and the interrelationships of basal archosauromorph reptiles". Philosophical Transactions of the Royal Society of London, Series B. 353 (1368): 501–541. doi:10.1098/rstb.1998.0225. PMC 1692244.
  9. ^ Nesbitt, Sterling J.; Flynn, John J.; Pritchard, Adam C.; Parrish, J. Michael; Ranivoharimanana, Lovasoa; Wyss, André R. (2015-12-07). "Postcranial Osteology of Azendohsaurus madagaskarensis (?Middle to Upper Triassic, Isalo Group, Madagascar) and its Systematic Position Among Stem Archosaur Reptiles" (PDF). Bulletin of the American Museum of Natural History. 398: 1–126. doi:10.5531/sd.sp.15. hdl:2246/6624. ISSN 0003-0090.
  10. ^ a b Pritchard, Adam C.; Nesbitt, Sterling J. (2017-10-01). "A bird-like skull in a Triassic diapsid reptile increases heterogeneity of the morphological and phylogenetic radiation of Diapsida". Royal Society Open Science. 4 (10): 170499. Bibcode:2017RSOS....470499P. doi:10.1098/rsos.170499. ISSN 2054-5703. PMC 5666248. PMID 29134065.
  11. ^ Bhart-Anjan S. Bhullar; Gabe S. Bever (2009). "An archosaur-like laterosphenoid in early turtles (Reptilia: Pantestudines)" (PDF). Breviora. 518: 1–11. doi:10.3099/0006-9698-518.1.1. S2CID 42333056.
  12. ^ Sean Modesto; Robert Reisz; Diane Scott (2011). "A neodiapsid reptile from the Lower Permian of Oklahoma". Society of Vertebrate Paleontology 71st Annual Meeting Program and Abstracts: 160.
  13. ^ John W. Merck (1997). "A phylogenetic analysis of the euryapsid reptiles". Journal of Vertebrate Paleontology. 17 (Supplement to 3): 1–93. doi:10.1080/02724634.1997.10011028.
  14. ^ Rieppel, Olivier (1999-02-12). "Turtle Origins". Science. 283 (5404): 945–946. doi:10.1126/science.283.5404.945. ISSN 1095-9203. PMID 10075558. S2CID 42475241.
  15. ^ Neenan, J. M.; Klein, N.; Scheyer, T. M. (2013). "European origin of placodont marine reptiles and the evolution of crushing dentition in Placodontia". Nature Communications. 4: 1621. Bibcode:2013NatCo...4.1621N. doi:10.1038/ncomms2633. PMID 23535642.
  16. ^ Simões, T.; Kammerer, C. (August 2022). "Successive climate crises in the deep past drove the early evolution and radiation of reptiles". ScienceAdvances. 08 (33): eabq1898. Bibcode:2022SciA....8.1898S. doi:10.1126/sciadv.abq1898. PMC 9390993. PMID 35984885. S2CID 251694019.
  17. ^ Wang, W.; Shang, Q. (December 2022). "Ancestral body plan and adaptive radiation of sauropterygian marine reptiles". iScience. 25 (12). Bibcode:2022iSci...25j5635W. doi:10.1016/j.isci.2022.105635. PMC 9722468. PMID 36483013.
  18. ^ Pritchard, Adam C.; Turner, Alan H.; Nesbitt, Sterling J.; Irmis, Randall B.; Smith, Nathan D. (2015-03-04). "Late Triassic tanystropheids (Reptilia, Archosauromorpha) from northern New Mexico (Petrified Forest Member, Chinle Formation) and the biogeography, functional morphology, and evolution of Tanystropheidae". Journal of Vertebrate Paleontology. 35 (2): e911186. Bibcode:2015JVPal..35E1186P. doi:10.1080/02724634.2014.911186. ISSN 0272-4634. S2CID 130089407.
  19. ^ Peecook; et al. (2018). . SVP 2018. Archived from the original on 2018-10-22. Retrieved 2018-12-13.
  20. ^ Lee, M. S. Y. (2013). "Turtle origins: Insights from phylogenetic retrofitting and molecular scaffolds". Journal of Evolutionary Biology. 26 (12): 2729–38. doi:10.1111/jeb.12268. PMID 24256520. S2CID 2106400.

February 16, 2024
archosauromorpha, greek, ruling, lizard, forms, clade, diapsid, reptiles, containing, reptiles, more, closely, related, archosaurs, such, crocodilians, dinosaurs, including, birds, rather, than, lepidosaurs, such, tuataras, lizards, snakes, archosauromorphs, f. Archosauromorpha Greek for ruling lizard forms is a clade of diapsid reptiles containing all reptiles more closely related to archosaurs such as crocodilians and dinosaurs including birds rather than lepidosaurs such as tuataras lizards and snakes 1 Archosauromorphs first appeared during the late Middle Permian or Late Permian 2 though they became much more common and diverse during the Triassic period 3 ArchosauromorphsTemporal range 260 0 Ma PreꞒ Ꞓ O S D C P T J K Pg N Possible Middle Permian recordsRow 1 Sharovipteryx mirabilis and Crocodylus porosusRow 2 Pardalotus punctatus and Hyperodapedon fischeriRow 3 Tanystropheus longobardicusScientific classificationDomain EukaryotaKingdom AnimaliaPhylum ChordataClass ReptiliaClade ArchelosauriaClade Archosauromorphavon Huene 1946Subgroups Aenigmastropheus Elachistosuchus Prolacertoides Choristodera Kuehneosauridae Drepanosauridae Helveticosauridae Ichthyosauromorpha Protorosauria likely paraphyletic Sauropterygia Thalattosauria Crocopoda Ezcurra 2016 Elessaurus Allokotosauria Rhynchosauria Boreopricea Prolacertidae Teyujagua Tasmaniosaurus ArchosauriformesAlthough Archosauromorpha was first named in 1946 its membership did not become well established until the 1980s Currently Archosauromorpha encompasses four main groups of reptiles the stocky herbivorous allokotosaurs and rhynchosaurs the hugely diverse Archosauriformes and a polyphyletic grouping of various long necked reptiles including Protorosaurus tanystropheids and Prolacerta Other groups including pantestudines turtles and their extinct relatives and the semiaquatic choristoderes have also been placed in Archosauromorpha by some authors Archosauromorpha is one of the most diverse groups of reptiles but its members can be united by several shared skeletal characteristics These include laminae on the vertebrae a posterodorsal process of the premaxilla a lack of notochordal canals and the loss of the entepicondylar foramen of the humerus 1 Contents 1 History and definition 2 Members 2 1 Unambiguous members 2 2 Disputed members 3 Anatomy 3 1 Skull 3 2 Vertebrae 3 3 Forelimbs 3 4 Hindlimbs 4 Relationships 5 See also 6 ReferencesHistory and definition editThe term Archosauromorpha was first used by Friedrich von Huene in 1946 to refer to reptiles more closely related to archosaurs than to lepidosaurs However there was little consensus on ancient reptile relationships prior to the late 20th century so the term Archosauromorpha was seldom used until many years after its creation The advent of cladistics helped to sort out at least some of the relationships within Reptilia and it became clear that there was a split between the archosaur lineage and the lepidosaur lineage somewhere within the Permian with certain reptiles clearly closer to archosaurs and others allied with lepidosaurs Jacques Gauthier reused the term Archosauromorpha for the archosaur lineage at the 1982 annual meeting of the American Society of Zoologists and later used it within his 1984 Ph D thesis 4 Archosauromorpha as formulated by Gauthier included four main groups of reptiles Rhynchosauria Prolacertiformes Trilophosauria and Archosauria now equivalent to the group Archosauriformes Cladistic analyses created during the 1980s by Gauthier Michael J Benton and Susan E Evans implemented Gauthier s classification scheme within large studies of reptile relations 5 4 6 Michel Laurin 1991 defined Archosauromorpha as the clade containing the most recent common ancestor of Prolacerta Trilophosaurus Hyperodapedon and all of its descendants 7 David Dilkes 1998 formulated a more inclusive and currently more popular definition of Archosauromorpha defining it as the clade containing Protorosaurus and all other saurians that are more closely related to Protorosaurus than to Lepidosauria 8 In 2016 Martin Ezcurra named a subgroup of Archosauromorpha Crocopoda crocodile feet Crocopoda is defined as all archosauromorphs more closely related to allokotosaurs specifically Azendohsaurus and Trilophosaurus rhynchosaurs specifically Rhynchosaurus or archosauriforms specifically Proterosuchus rather than Protorosaurus or tanystropheids specifically Tanystropheus This group roughly corresponds to Laurin s definition of Archosauromorpha 1 Members editUnambiguous members edit nbsp An interaction between two archosauromorphs Ornithosuchus a member of Archosauriformes scavenging on Hyperodapedon a rhynchosaur Since the seminal studies of the 1980s Archosauromorpha has consistently been found to contain four specific reptile groups although the definitions and validity of the groups themselves have been questioned The least controversial group is Rhynchosauria beak reptiles a monophyletic clade of stocky herbivores Many rhynchosaurs had highly modified skulls with beak like premaxillary bones and wide heads nbsp Shringasaurus a horned allokotosaurian from the family Azendohsauridae Another group of archosauromorphs has traditionally been represented by Trilophosaurus an unusual iguana like herbivorous reptile quite different from the rhynchosaurs Gauthier used the name Trilophosauria for this group but a 2015 study offered an alternative name This study found that Azendohsauridae Triassic reptiles previously mistaken for prosauropod dinosaurs were in fact close relatives of Trilophosaurus and the rest of Trilophosauridae Trilophosaurids and azendohsaurids are now united under the group Allokotosauria strange reptiles 9 These two groups did not survive the end of the Triassic period but the most famous group of archosauromorphs not only survived but have continued to diversify and dominate beyond the Triassic Jurassic extinction These were the Archosauriformes a diverse assortment of animals including the famous dinosaurs and pterosaurs Two subclades of Archosauriformes survive to the present day the semiaquatic crocodilians and the last of the feathered dinosaurs birds Gauthier used the name Archosauria to refer to what is now called the Archosauriformes in modern studies the name Archosauria has a more restricted definition that only includes the ancestors of crocodilians i e Pseudosuchia and birds i e Avemetatarsalia nbsp The skeleton of Protorosaurus one of the oldest archosauromorphs and namesake of the problematic group Protorosauria The final unambiguous members of Archosauromorpha represent the most controversial group These were the first archosauromorphs to appear and can be characterized by their long necks sprawling posture and carnivorous habits One name for the group Protorosauria is named after Protorosaurus the oldest archosauromorph known from good remains Another name Prolacertiformes is in reference to a different member Prolacerta Protorosauria Prolacertiformes has had a complicated history and many taxa have entered and left the group as paleontologists discover and re evaluate reptiles of the Triassic By far the most famous of these are tanystropheids such as Tanystropheus known for having necks longer than their entire body Other notable genera include Boreopricea Pamelaria and Macrocnemus as well as strange gliding reptiles such as Sharovipteryx and Mecistotrachelos A landmark 1998 study by David Dilkes completely deconstructed the concept of Prolacertiformes as a traditional monophyletic group i e one whose members have a single common ancestor He argued that Prolacerta was much closer to Archosauriformes than to other prolacertiforms invalidating the name 8 Likewise Pamelaria is now considered an allokotosaur Macrocnemus is a tanystropheid and Protorosaurus may be too basal primitive to form a clade with any of its supposed close relatives 1 As such this final group of Archosauromorpha is generally considered paraphyletic or polyphyletic and few modern studies use it Disputed members edit nbsp Champsosaurus a gharial like choristodere which survived the Cretaceous Paleocene extinction event Choristoderes may represent the fifth group of archosauromorphs but their origin is obscured Apart from these four groups Archosauromorpha is sometimes considered to encompass several additional groups of reptiles One of the most common additions is Choristodera a group of semiaquatic reptiles with mysterious origins Although choristodere fossils are only known from the Jurassic through the Miocene it is theorized that they first appeared during the Permian alongside the earliest archosauromorphs Choristoderes share numerous otherwise unique traits with archosauromorphs but they share an equal or greater number of unique traits with lepidosauromorphs as well so there is still some debate over their inclusion within either group 6 1 The chameleon or tamandua like drepanosaurs are also semi regularly placed within Archosauromorpha 8 although some studies have considered them to be part of a much more basal lineage of reptiles 10 The aquatic thalattosaurs 6 and gliding kuehneosaurids 6 10 are also irregularly considered archosauromorphs Genetic studies have found evidence that modern testudines turtles and tortoises are more closely related to crocodilians than to lizards 11 12 If this evidence is accurate then turtles are part of basal Archosauromorpha Likewise extinct turtle relatives known as Pantestudines would also fall within Archosauromorpha Some geneticists have proposed a name to refer to reptiles within the group formed by relatives of turtles and archosaurs This name is the clade Archelosauria Since Pantestudines may encompass the entire aquatic reptile order Sauropterygia this means that Archosauromorpha as Archelosauria may be a much wider group than commonly believed 13 However anatomical data disagrees with this genetic evidence instead placing Pantestudines within Lepidosauromorpha 14 but many modern studies have supported Archelosauria Several recent studies place sauropterygians within Archosauromorpha group forming a large clade including Ichthyosauromorpha and Thalattosauria as opposed to the Pantestudine relations 15 16 17 Anatomy editAlthough the most diverse clade of living archosauromorphs are birds early members of the group were evidently reptilian superficially similar to modern lizards When archosauromorphs first appeared in the fossil record in the Permian they were represented by long necked lightly built sprawling reptiles with moderately long tapering snouts This body plan similar to that of modern monitor lizards is also shared by Triassic archosauromorphs such as tanystropheids and Prolacerta Other early groups such as trilohpsaurids azendohsaurids and rhynchosaurs deviate from this body plan by evolving into stockier forms with semi erect postures and higher metabolisms The archosauriforms went to further extremes of diversity encompassing giant sauropod dinosaurs flying pterosaurs and birds semiaquatic crocodilians phytosaurs and proterochampsians and apex predators such as erythrosuchids pseudosuchians and theropod dinosaurs Despite the staggering diversity of archosauromorphs they can still be united as a clade thanks to several subtle skeletal features 1 Skull edit nbsp The skull of Proterosuchus an early archosauriform Note the long rear branch of the downturned premaxilla and the L shaped quadratojugal near the jaw joint Most archosauromorphs more advanced than Protorosaurus possessed an adaptation of the premaxilla tooth bearing bone at the tip of the snout known as a posterodorsal or postnarial process This was a rear facing branch of bone that stretched up below and behind the external nares nostril holes to contact the nasal bones on the upper edge of the snout A few advanced archosauriforms reacquired the plesiomorphic primitive state present in other reptiles that being a short or absent posterodorsal process of the premaxilla with the rear edge of the nares formed primarily by the maxilla bones instead As for the nares themselves they were generally large and oval shaped positioned high and close to the midline of the skull 4 Many early archosauromorphs including Protorosaurus tanystropheids Trilophosaurus and derived rhynchosaurs have a blade like sagittal crest on the parietal bones at the rear part of the skull roof between a pair of holes known as the supratemporal or upper temporal fenestrae However in other allokotosaurs the basal rhynchosaur Mesosuchus and more crownward archosauromorphs the sagittal crest is weakly differentiated although the inner edge of each supratemporal fenestra still possessed a depressed basin of bone known as a supratemporal fossa Ezcurra 2016 argued that presence of supratemporal fossae and an absence or poor development of the sagittal crest could be used to characterize Crocopoda He also noted that in almost all early archosauromorphs and some choristoderes the parietal bones have an additional lowered area which extends transversely from left to right behind the supratemporal fenestrae and sagittal crest when applicable 1 The lower temporal fenestra is not fully enclosed in early archosauromorphs and choristoderes due to alterations to the structure of the quadratojugal bone at the rear lower corner of the skull This bone is roughly L shaped in these taxa with a tall dorsal process vertical branch a short anterior process forward branch and a tiny or absent posterior process rear branch The bones surrounding the quadratojugal also reconfigure to offset the changes to the quadratojugal For example the lower branch of the squamosal bone is shortened to offset the tall dorsal process of quadratojugal which connects to it On the other hand the rear branch jugal bone lengthens to fill some of the space left by the shortening of the anterior process of the quadratojugal 6 In archosauriforms the jugal even re encloses the lower temporal fenestra The stapes are long thin and solid without a perforating hole stapedial foramen present in the more robust stapes of other reptiles 6 Vertebrae edit nbsp Cervical vertebrae from Diplodocus a sauropod dinosaur Archosauriformes As with other long necked archosauromorphs sauropods had a complex system of laminae on their vertebrae In conjunction with their long S shaped necks early archosauromorphs had several adaptations of the cervical neck vertebrae and usually the first few dorsal back vertebrae as well The centrum main body of each vertebra is parallelogram shaped with a front surface typically positioned higher than the rear surface 1 The transverse processes rib facets of these vertebrae extend outwards to a greater extent than in other early reptiles In many long necked archosauromorphs the rib facets are slanted connecting to cervical ribs that are often long thin and dichocephalous two headed 18 Thin plate like ridges known as laminae develop to connect the vertebral components sloping down from the elongated transverse processes to the centra Laminae are practically unique to archosauromorphs being present even in the earliest Permian genera such as Aenigmastropheus and Eorasaurus However they are also known to occur in the bizarre semiaquatic reptile Helveticosaurus 3 as well as the biarmosuchian synapsid Hipposaurus 19 In all adult archosauromorphs with the exception of Aenigmastropheus the vertebrae lack notochordal canals holes which perforate the centra This also sets the archosauromorphs apart from most other Permian and Triassic reptiles 7 3 Forelimbs edit The humerus upper arm bone is solid in archosauromorphs completely lacking a hole near the elbow known as the entepicondylar foramen This hole present in most other tetrapods is also absent in choristoderes yet not fully enclosed in some proterosuchids In many advanced archosauromorphs the capitulum and trochlea elbow joints of the humerus are poorly developed Early archosauromorphs retain well developed elbow joints but all archosauromorphs apart from Aenigmastropheus have a trochlea ulna joint which is shifted towards the outer surface of the humerus rather than the midpoint of the elbow as in other reptiles In conjunction with this shift the olecranon process of the ulna is poorly developed in archosauromorphs apart from Aenigmastropheus and Protorosaurus 1 Hindlimbs edit The ankle bones of archosauromorphs tend to acquire complex structures and interactions with each other and this is particularly the case with the large proximal tarsal bones the astragalus and calcaneum The calcaneum for example has a tube like outer extension known as a calcaneal tuber in certain archosauromorphs This tuber is particularly prominent in the ancient relatives of crocodylians but it first appeared earlier at the last common ancestor of allokotosaurs rhynchosaurs and archosauriforms The presence of a calcaneal tuber sometimes known as a lateral tuber of the calcaneum is a synapomorphy of the group Crocopoda and is also responsible for its name 1 Relationships editThe cladogram shown below follows the most likely result found by an analysis of turtle relationships using both fossil and genetic evidence by M S Lee in 2013 20 Crown Reptilia Pan Lepidosauria Lepidosauromorpha nbsp Archelosauria Pan Testudines Eosauropterygia nbsp Placodontia nbsp Sinosaurosphargis Odontochelys Testudinata ProganochelysTestudines nbsp PantestudinesPan Archosauria Choristodera nbsp Archosauromorpha s s Prolacertiformes nbsp Trilophosaurus nbsp Rhynchosauria nbsp Archosauriformes nbsp Archosauromorpha s l SauriaThe following cladogram is based on a large analysis of archosauriforms published by M D Ezcurra in 2016 1 Sauria Lepidosauromorpha nbsp Choristodera nbsp Archosauromorpha Aenigmastropheus Protorosaurus nbsp Tanystropheidae nbsp Crocopoda Allokotosauria Pamelaria Azendohsaurus Trilophosaurus nbsp Rhynchosauria nbsp Boreopricea Prolacertidae nbsp TasmaniosaurusArchosauriformes nbsp See also edit nbsp Reptiles portalReferences edit a b c d e f g h i j k Ezcurra Martin D 2016 04 28 The phylogenetic relationships of basal archosauromorphs with an emphasis on the systematics of proterosuchian archosauriforms PeerJ 4 e1778 doi 10 7717 peerj 1778 ISSN 2167 8359 PMC 4860341 PMID 27162705 Martinelli Agustin G Francischini Heitor Dentzien Dias Paula C Soares Marina B Schultz Cesar L 2017 01 02 The oldest archosauromorph from South America postcranial remains from the Guadalupian mid Permian Rio do Rasto Formation Parana Basin southern Brazil Historical Biology 29 1 76 84 Bibcode 2017HBio 29 76M doi 10 1080 08912963 2015 1125897 ISSN 0891 2963 S2CID 86151472 a b c Butler Richard J Scheyer Torsten M Ezcurra Martin D 2014 02 27 The Origin and Early Evolution of Sauria Reassessing the Permian Saurian Fossil Record and the Timing of the Crocodile Lizard Divergence PLOS ONE 9 2 e89165 Bibcode 2014PLoSO 989165E doi 10 1371 journal pone 0089165 ISSN 1932 6203 PMC 3937355 PMID 24586565 a b c Jacques Gauthier Arnold G Kluge Timothy Rowe 1988 Amniote phylogeny and the importance of fossils PDF Cladistics 4 2 105 209 doi 10 1111 j 1096 0031 1988 tb00514 x hdl 2027 42 73857 PMID 34949076 S2CID 83502693 Benton Michael J 1985 06 01 Classification and phylogeny of the diapsid reptiles Zoological Journal of the Linnean Society 84 2 97 164 doi 10 1111 j 1096 3642 1985 tb01796 x ISSN 0024 4082 a b c d e f Evans Susan E 1988 The early history and relationships of the Diapsida In Benton M J ed The Phylogeny and Classification of the Tetrapods Volume 1 Amphibians Reptiles Birds Oxford Clarendon Press pp 221 260 a b Michel Laurin 1991 The osteology of a Lower Permian eosuchian from Texas and a review of diapsid phylogeny Zoological Journal of the Linnean Society 101 1 59 95 doi 10 1111 j 1096 3642 1991 tb00886 x a b c David M Dilkes 1998 The Early Triassic rhynchosaur Mesosuchus browni and the interrelationships of basal archosauromorph reptiles Philosophical Transactions of the Royal Society of London Series B 353 1368 501 541 doi 10 1098 rstb 1998 0225 PMC 1692244 Nesbitt Sterling J Flynn John J Pritchard Adam C Parrish J Michael Ranivoharimanana Lovasoa Wyss Andre R 2015 12 07 Postcranial Osteology of Azendohsaurus madagaskarensis Middle to Upper Triassic Isalo Group Madagascar and its Systematic Position Among Stem Archosaur Reptiles PDF Bulletin of the American Museum of Natural History 398 1 126 doi 10 5531 sd sp 15 hdl 2246 6624 ISSN 0003 0090 a b Pritchard Adam C Nesbitt Sterling J 2017 10 01 A bird like skull in a Triassic diapsid reptile increases heterogeneity of the morphological and phylogenetic radiation of Diapsida Royal Society Open Science 4 10 170499 Bibcode 2017RSOS 470499P doi 10 1098 rsos 170499 ISSN 2054 5703 PMC 5666248 PMID 29134065 Bhart Anjan S Bhullar Gabe S Bever 2009 An archosaur like laterosphenoid in early turtles Reptilia Pantestudines PDF Breviora 518 1 11 doi 10 3099 0006 9698 518 1 1 S2CID 42333056 Sean Modesto Robert Reisz Diane Scott 2011 A neodiapsid reptile from the Lower Permian of Oklahoma Society of Vertebrate Paleontology 71st Annual Meeting Program and Abstracts 160 John W Merck 1997 A phylogenetic analysis of the euryapsid reptiles Journal of Vertebrate Paleontology 17 Supplement to 3 1 93 doi 10 1080 02724634 1997 10011028 Rieppel Olivier 1999 02 12 Turtle Origins Science 283 5404 945 946 doi 10 1126 science 283 5404 945 ISSN 1095 9203 PMID 10075558 S2CID 42475241 Neenan J M Klein N Scheyer T M 2013 European origin of placodont marine reptiles and the evolution of crushing dentition in Placodontia Nature Communications 4 1621 Bibcode 2013NatCo 4 1621N doi 10 1038 ncomms2633 PMID 23535642 Simoes T Kammerer C August 2022 Successive climate crises in the deep past drove the early evolution and radiation of reptiles ScienceAdvances 08 33 eabq1898 Bibcode 2022SciA 8 1898S doi 10 1126 sciadv abq1898 PMC 9390993 PMID 35984885 S2CID 251694019 Wang W Shang Q December 2022 Ancestral body plan and adaptive radiation of sauropterygian marine reptiles iScience 25 12 Bibcode 2022iSci 25j5635W doi 10 1016 j isci 2022 105635 PMC 9722468 PMID 36483013 Pritchard Adam C Turner Alan H Nesbitt Sterling J Irmis Randall B Smith Nathan D 2015 03 04 Late Triassic tanystropheids Reptilia Archosauromorpha from northern New Mexico Petrified Forest Member Chinle Formation and the biogeography functional morphology and evolution of Tanystropheidae Journal of Vertebrate Paleontology 35 2 e911186 Bibcode 2015JVPal 35E1186P doi 10 1080 02724634 2014 911186 ISSN 0272 4634 S2CID 130089407 Peecook et al 2018 VERTEBRAL OSTEOLOGY OF HIPPOSAURUS BOONSTRAI THERAPSIDA BIARMOSUCHIA FROM THE MIDDLE PERMIAN OF SOUTH AFRICA WITH IMPLICATIONS FOR THE EVOLUTION OF ARCHOSAUROMORPHA SVP 2018 Archived from the original on 2018 10 22 Retrieved 2018 12 13 Lee M S Y 2013 Turtle origins Insights from phylogenetic retrofitting and molecular scaffolds Journal of Evolutionary Biology 26 12 2729 38 doi 10 1111 jeb 12268 PMID 24256520 S2CID 2106400 Retrieved from https en wikipedia org w index php title Archosauromorpha amp oldid 1193699829, wikipedia, wiki, book, books, library,

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