Temnospondyli

Temnospondyli
Temnospondyls
Temporal range: Early Carboniferous - Early Cretaceous, 330–120 Ma
Possible descendant taxon Lissamphibia survives to present.
Skeleton of Eryops in the Muséum national d'histoire naturelle, Paris.
Scientific classification e
Kingdom: Animalia
Phylum: Chordata
Class: Amphibia
Subclass: "Labyrinthodontia"
Order: Temnospondyli
Zittel, 1888
Subgroups

See below

Temnospondyli (from Greek τέμνειν (temnein, "to cut") and σπόνδυλος (spondylos, "vertebra")) is a diverse order of small to giant tetrapods—often considered primitive amphibians—that flourished worldwide during the Carboniferous, Permian, and Triassic periods. A few species continued into the Cretaceous. Fossils have been found on every continent. During approximately 210 million years of evolutionary history they adapted to a wide range of habitats including fresh water, terrestrial, and even coastal marine environments. Their life history is well understood with fossils known from the larval stage, metamorphosis, and maturity. Most temnospondyls were semiaquatic, although some were almost fully terrestrial, returning to the water only to breed. These temnospondyls were some of the first vertebrates fully adapted to life on land. Although temnospondyls are considered amphibians, many had characteristics such as scales, claws, and armor-like bony plates that distinguish them from modern amphibians.

Temnospondyls have been known since the early nineteenth century and were initially thought to be reptiles. They were described at various times as batrachians, stegocephalians, and labyrinthodonts, although these names are now rarely used. Animals now grouped in Temnospondyli were spread out among several amphibian groups until the early twentieth century, when they were found to belong to a distinct taxon based on the structure of their vertebrae. Temnosondyli means "cut vertebrae" as each vertebra is divided into several parts.

Authorities disagree over whether temnospondyls were ancestral to modern amphibians (frogs, salamanders, and caecilians), or whether the whole group died out without leaving any descendants. Different hypotheses have placed modern amphibians as the descendants of temnospondyls, another group of early tetrapods called lepospondyls, or even as descendants of both groups (with caecilians evolving from lepospondyls and frogs and salamanders evolving from temnospondyls). Recent studies place a family of temnosondyls called the amphibamids as the closest relatives of modern amphibians. Similarities in teeth, skulls, and hearing structures link the two groups.

Contents

Description

Dorsal (left), ventral (center), and posterior (right) views of the skull of Metoposaurus

Many temnospondyls are much larger than living amphibians and superficially resemble crocodiles. Others are smaller and resembled salamanders.[1] Most have broad, flat heads that are either blunt (brevirostrine) or elongated (longirostrine). The skulls are rounded or triangular in shape when viewed from above, and are usually covered in pits and ridges. Many temnospondyls have canal-like groves in their skulls called sensory sulci. The sulci, which usually run around the nostrils and eye sockets, are part of a lateral line system used to detect vibrations in water.[1] As semi-aquatic animals, most temnospondyls have small limbs with four toes on each front foot and five on each hind foot. Terrestrial temnospondyls have larger, thicker limbs, and some even have claws.[2] One temnospondyl called Fayella is unusual in that it has relatively long limbs for its body and probably lived as an active runner able to chase prey.[3]

Diagram of the skull of Xenotosaurus africanus, showing the skull roof bones common in all temnospondyls.

Most of the bones of temnospondyls are also seen in other early tetrapods, although a few other bones in the skull such as interfrontals, internasals, and interparietals have developed in some taxa.[1] Most temnospondyls have tabular horns in the back of the skull, rounded projections of bone separated from the rest of the skull by indentations called otic notches. In some temnospondyls like Zatrachys, they are pointed and very prominent. Among the most distinguishing features of temnospondyls are the interpterygoid vacuities, two large holes in the back of the palate. Another pair of holes called choanae are present in front of these vacuities, and connect the nasal passage with the mouth. Temnospondyls often have teeth on their palate as well as in their jaws. Some of these teeth are so large that they are referred to as tusks. In some temnospondyls like Nigerpeton, tusks in the lower jaw pierce the palate and emerge through openings in the top of the skull.[4]

Very little is known of the soft tissue of temnospondyls. A block of sandstone was described in 2007 from the Early Carboniferous Mauch Chunk Formation of Pennsylvania that included impressions of the bodies of three temnospondyls. These impressions show that when alive they had smooth skin, robust limbs with webbed feet, and a ridge of skin on their undersides.[5] Trackways referrable to small temnospondyls have also been found in Carboniferous and Permian rocks. The trackways are called Batrachichnus and are usually found in strata that were deposited around freshwater environments, suggesting that the animals had some ties to the water.[6]

A fossil of Sclerocephalus showing a large pectoral girdle and ventral plates.

Unlike modern amphibians, many temnospondyls are covered in small, closely packed scales. The undersides of most temnospondyls are covered in rows of large ventral plates. During early stages of development, temnospondyls first have only small, rounded scales. Fossils show that as the animals grew, the scales on the underside of the body developed into large, wide ventral plates. The plates overlap each other in a way that allows a wide range of flexibility. Later semiaquatic temnospondyls like trematosaurs and capitosaurs have no evidence of scales. They may have lost scales to make movement easier underwater or to allow cutaneous respiration, the absorption of oxygen through the skin.[7]

Several groups of temnospondyls have large bony plates on their backs. One temnospondyl called Peltobatrachus has armor-like plating that covers both its back and underside.[8] The temnospondyl Laidleria also has extensive plating on its back. Most members of the family Dissorophidae also have armor, although it only covers the mid-line of the back with two narrow rows of plates.[9] Other temnospondyls like Eryops have been found with small disc-like bony scutes that were in life probably embedded in the skin. All of these temnospondyls were adapted to a terrestrial lifestyle. Armor may have offered protection from predators in the case of Peltobatrachus.[8] The scutes may have provided stability for the spine, as they would have limited flexibility and may have been connected by strong ligaments.[10] Temnospondyls such as Sclerothorax and Eryops that may have been at least partly terrestrial also have long neural spines on top of their vertebrae that would have stabilized the spine.[11] Bony scutes are also seen in plagiosaurs, but unlike Peltobatrachus, Laidleria, Eryops, and dissorophids, these animals are thought to have been fully aquatic. Plagiosaurs may have inherited their armor from a terrestrial ancestor, as both Peltobatrachus and Laidleria have been considered close relatives of the group.[8]

Temnospondyls have vertebrae that are divided into several segments. In living tetrapods, the main body of the vertebra is a single piece of bone called the centrum, but in temnospondyls this region was divided into a pleurocentrum and intercentrum. Two types of vertebrae are recognized in temnospondyls: stereospondylous and rhachitomous vertebrae. In rhachitomous vertebrae the intercentra are large and wedge-shaped, and the pleurocentra are relatively small blocks that fit between them. Both elements support a spine-like neural arch, and well-developed interlocking projections called zygapophyses strengthen the connections between vertebrae. The strong backbone and strong limbs of many ratchitomous temnospondyls allowed them to be partially, and in some cases fully, terrestrial. In stereospondylous vertebrae the pleurocentra have been lost entirely, with the intercentra enlarged as the main body of the vertebrae. This weaker type of backbone indicates that stereospondylous temnospondyls spent more time in water.[12]

History of study

Temnospondyli was named by German paleontologist Karl Alfred von Zittel in his second edition of Handbuch der Palaeontologie, published in 1888. Temnospondyl remains were known since the early part of the nineteenth century, however. The earliest described temnospondyl was Mastodonsaurus, named by Georg Friedrich Jaeger in 1828. Jaeger named Mastodonsaurus from a single tooth and considered it a reptile. Mastodonsaurus means "breast tooth lizard" after the nipple-like shape of the tip of the tooth.[13]

An early restoration of Mastodonsaurus, the first known temnospondyl.

The naming of this first specimens were disputed, however. Leopold Fitzinger named the animal Batrachosaurus in 1837. In 1841, English paleontologist Richard Owen referred to the genus as Labyrinthodon to describe its highly folded or labyrinthine teeth. Owen thought that the name Mastodonsaurus "ought not to be retained, because it recalls unavoidably the idea of the mammalian genus Mastodon, or else a mammilloid form of the tooth... and because the second element of the word, saurus, indicates a false affinity, the remains belonging, not to the Saurian, but to the Batrachian order of Reptiles."[14] Owen recognized that the animal was not a "saurian" reptile,[a] yet he also referred Jaeger's Phytosaurus to the genus. Although the two genera both have similarly sized conical teeth, Phytosaurus was later found to be a crocodile-like reptile. Additional material, including skulls, firmly placed Labyrinthodon as an amphibian. Jaeger also named Salamandroides giganteus in 1828, basing it on partial occiput, or back portion of the skull. In 1833 he described a complete skull of S. giganteus that had the same teeth as his Mastodonsaurus, making it the first known complete skull of a temnospondyl. Because Mastodonsaurus was named first, it has precedence over the other names as a senior subjective synonym.[15] Batrachosaurus is still used as the name of an unrelated brachyopid temnospondyl.

Mastodonsaurus and other similar animals were referred to as labyrinthodonts, named like Labyrinthodon for teeth that were highly folded in cross section. Owen's "Labyrinthodon Jaegeri" was later found at Guy's Cliffe, England by paleontologist William Buckland. Other specimens were found in the red sandstone of Warwickshire. As more fossils were uncovered in England, Owen depicted these labyrinthodonts as the "highest" form of batrachian and compared them to crocodiles, which he considered the highest form of reptiles. He also noted that large labyrinthodonts of the Keuper (a unit of rocks that dates to the Late Triassic) were younger than more advanced reptiles in the Magnesian and Zechstein, which are Late Permian in age. Owen used these fossils to counter the notion that reptiles evolved from a sequential progression from early amphibians (what he called "metamorphosed fishes").[16]

In addition to Mastodonsaurus, some of the earliest named genera included Metopias and Rhombopholis in 1842, Zygosaurus in 1848, Trematosaurus in 1849, Baphetes and Dendrerpeton in 1853, Capitosaurus in 1858, and Dasyceps in 1859.[17] Baphetes is now placed as an early tetrapod outside Temnospondyli, and Rhombopholis is now considered a prolacertiform reptile.[18][19]

Later in the nineteenth century, temnospondyls were classified as various members of Stegocephalia, a name coined by American paleontologist Edward Drinker Cope in 1868. Cope placed stegocephalians in the class Batrachia, the name then used for Amphibia. Stegocephalia means "roof-headed" in Greek, a reference to the wide, flat heads of temnospondyls and other early tetrapods. During this time, paleontologists considered temnospondyls to be amphibians because they possessed three main features: gill arches in juvenile skeletons, indicating they were amphibious for at least the first part of their lives; ribs that do not connect at the underside of the rib cage; and deep pits in the skull that were interpreted as space for mucous glands.[20]

Several suborders of stegocephalians were recognized in the late nineteenth and early twentieth centuries. Animals now regarded as temnospondyls were primarily labyrinthodonts, but some were classified in the Branchiosauria. Branchiosaurs were small-bodied and had simple conical teeth, while labyrinthodonts were larger and had complex, folded dentin and enamel in their teeth. Branchiosauria included only a few forms such as Branchiosaurus from Europe and Amphibamus from North America that had poorly developed bones, external gills, and no ribs. Some skeletons of Amphibamus were later found with long ribs, prompting its reassignment to Microsauria (although more detailed studies found it to be a temnospondyl).[21] Soft tissue such as scales and external gills were found in many well preserved branchiosaur fossils from Germany. In the early twentieth century, branchiosaurs would be recognized as larval forms of temnospondyls lacking many of the typical features that define the group.

Other animals that would later be classified as temnospondyls were placed in a group called Ganocephala, characterized by plate-like skull bones, small limbs, fish-like scales, and branchial arches. Unlike labyrinthodonts, they did not have a parietal foramen, a small hole in the skull behind the eye sockets. Archegosaurus, Dendrerpeton, Eryops and Trimerorhachis were placed in this group and were considered to be the most primitive members of Reptilia. Their rhachitomous vertebrae, notochord, and lack of occipital condyles (which attached the head to the neck) were features that were also shared with fishes. Thus, they were considered a link between early fishes and more advanced forms like stegocephalians.[22]

Another group called Microsauria was named by Cope in 1868. Cope classified Microsauria as a subgroup of Labyrinthodontia, placing many small amphibian-like animals within it. Among them were Dendrerpeton, once placed in Ganocephala. Dendrerpeton was later placed as a labyrinthodont with other temnospondyls, but confusion existed for many years over the classification of small amphibians.[23]

By the end of the nineteenth century, most of what are today regarded as temnospondyls were placed in the suborder Labyrinthodonta. American paleontologist Ermine Cowles Case called it Labyrinthodonta vera or "true labyrinthodonts."[24] The names Stegocephalia and Labyrinthodontia were used interchangeably to refer to the order in which it belonged belonged. The labyrinthodontian suborders Microsauria and Branchiosauria, both of which contain temnospondyls, were distinct from Labyrinthodonta. Within Labyrinthodonta were the groups Rhachitomi, Labyrinthodonti, and Embolerimi. Members of Rhachitomi like Archegosaurus and Eryops had rhachitomous vertebrae with an enlarged intercentrum that displaced the pleurocentrum. Labyrinthodonti such as Mastodonsaurus, Trematosaurus, and Micropholis had lost their pleurocentra and the intercentra made up the entire body of the vertebrae. Embolerimi had intercentra and pleurocentra that were of equal size. Embolomeres are now identified as reptiliomorphs distantly related to temnospondyls.

In 1888, von Zittel divided stegocephalians among three taxa: Lepospondyli, Temnospondyli, and Stereospondyli. He placed microsaurs in Lepospondyli, a group which he characterized as having simple, spool-shaped vertebral centra. Temnospondyli included forms with the centra divided into pleurocentra and intercentra. All members of Stereospondyli had amphicoelous centra composed only of the intercentra. Cope objected to von Zittel's classification, considering the vertebrae of lepospondyls and stereospondyls indistinguishable because each had a simple spool shape. He continued to use Ganocephala and Labyrinthodonta (which he alternatively referred to as Rhachitomi) to distinguish animals based on the absence or presence of occipital condyles.[25]

Temnospondyli became a commonly used name at the turn of the century.[26] Paleontologists included both embolomeres and rhachitomes in the group. Cope's Ganocephala and Labyrinthodonta fell out of use. In 1919, British paleontologist D. M. S. Watson proposed that the evolutionary history of these large amphibians could be seen through changes in their vertebrae. Embolomerous forms in the Carboniferous graded into rhachitomous forms in the Permian, and finally into stereospondyls in the Triassic. More importantly, Watson began using the term Labyrinthodontia to refer to these groups.[27] The name Temnospondyli was rarely used in the decades that followed. Swedish paleontologist Gunnar Säve-Söderbergh removed embolomeres from the group, narrowing its scope to rhachitomes and stereospondyls. His classification of labyrinthodonts was based heavily on characteristics of the skull rather than the vertebrae.[26]

American paleontologist Alfred Romer brought the name Temnospondyli back into use in the later twentieth century. Säve-Söderbergh used the name Labyrinthodontia in a strict sense (sensu stricto) to refer to Rhachitomi and Stereospondyli, excluding Embolomeri. Romer agreed with this classification, but used the name Temnospondyli to avoid confusion with Labyrinthodontia in its wider sense (sensu lato). Unlike modern temnospondyl classification, however, Romer included the primitive Ichthyostegalia in the group.[26]

Evolutionary history

Carboniferous and Early Permian

Capetus, a basal temnospondyl.

Temnospondyls first appeared in the Early Carboniferous around 330 million years ago (Ma). During the Carboniferous, temnospondyls included basal medium-sized forms like Dendrerpeton or large semi-aquatic forms like Cochleosaurus. Other, more derived temnospondyls such as the amphibamids were smaller and more terrestrial. They resembled salamanders, and some taxa, such as the genus Branchiosaurus, even retained external gills like the modern-day axolotl. During the latest Carboniferous and Early Permian around 300 million years ago (Ma) several groups like the dissorophids and trematopids evolved strong, robust limbs and vertebrae and became adapted to life on land while others such as the eryopids developed into large semi-aquatic predators. The dvinosaurs, a group of small aquatic temnospondyls, evolved from terrestrial ancestors in the Late Carboniferous.[28]

Late Permian

Prionosuchus from the Permian, the largest amphibian ever described.

During the Late Permian, increasing aridity and the diversification of reptiles contributed into a decline in terrestrial temnospondyls, but semi-aquatic and fully aquatic temnospondyls continued to flourish, including the large Melosaurus of Eastern Europe. Other temnospondyls such as archegosaurids developed long snouts and a close similarity to crocodiles, although they lacked the armour characteristic of the latter group. These temnospondyls included the largest known amphibian, the 9 metres (30 ft) long Prionosuchus of Brazil.[29]

Mesozoic

As temnospondyls continued to flourish and diversify in the Late Permian (260.4 - 251.0 Ma), a major group called Stereospondyli became more dependent on life in the water. The vertebrae became weak, the limbs small, and the skull large and flat, with the eyes facing upwards. During the Triassic period these animals dominated the fresh-water ecosystems, evolving in a range of both small and large forms. During the Early Triassic (251.0 - 245.0 Ma) one group of successful long-snouted fish eaters, the trematosauroids, even adapted to a life in the sea, the only known amphibians to do so with the exception of the modern Crab-eating frog. Another group, the capitosauroids, included medium and large sized animals 2.3 to 4 metres (7.5 to 13 ft) in length, with large and flat skulls that could be over a meter long in the largest forms like Mastodonsaurus. These animals spent most or all their entire lives in water as aquatic predators, catching their prey by a sudden opening of the upper jaw and sucking in fish or other small animals.[30]

Siderops, a Jurassic temnospondyl.

In the Carnian stage of the Late Triassic (228.0 - 216.5 Ma) capitosauroids were joined by the superficially very similar Metoposauridae. Metoposaurids are distinguished from capitosauroids by the positioning of their eye sockets near the front of the skull. Another group of stereospondyls called plagiosaurs had wide heads with external gills, and adapted to life at the bottom of lakes and rivers. By this time temnospondyls had become a common and widespread component of semiaquatic ecosystems. Some temnospondyls like Cryobatrachus and Kryostega even inhabited Antarctica, which was covered in temperate forests at the time.[31][32]

Triassic temnospondyls were often the dominant semiaquatic animals in their environment. Large assemblages of metoposaurs with hundreds of individuals preserved together have been found in the southwestern United States. They have often been interpreted as mass death events caused by droughts in floodplain environment. Recent studies show that these dense assemblages were instead probably the result of currents accumulating dead individuals in certain areas. These environments seem to have had little diversity, as they were inhabited almost exclusively by metoposaurs.[33]

The Triassic-Jurassic extinction event around 199.6 Ma led to the extinction of most Mesozoic temnospondyls. The brachyopoids survived, as well as a few capitosauroids and trematosauroids. While the latter two groups soon became extinct, brachyopoids persisted and grew to large sizes during the Jurassic. Among brachyopoids, the brachyopids flourished in China and the chigutisaurids became common in Gondwana. The most recent known temnospondyl was the giant chigutisaurid Koolasuchus, known from the Early Cretaceous of Australia. It survived in rift valleys that were too cold in the winter for crocodiles that normally would have competed with them. Koolasuchus was one of the largest of the brachyopoids, with an estimated weight of 500 kilograms (1,100 lb).[34]

Classification

Originally, temnospondyls were classified according to the structure of their vertebrae. Early forms, with complex vertebrae consisting of a number of separate elements, were placed in the suborder Rachitomi, and large Triassic aquatic forms with simpler vertebrae were placed in the suborder Stereospondyli. With the recent growth of phylogenetics, this classification is no longer viable. The basic rhachitomous condition is found in many primitive tetrapods, and is not unique to one group of temnospondyls. Moreover, the distinction between rhachitomous and stereospondylous vertebrae is not entirely clear. Some temnospondyls have rhachitomous, semi-rhachitomous, and sterospondylous vertebrae at different points in the same vertebral column. Other taxa have intermediate morphologies that do not fit into any category. Rachitomi is no longer recognized as a group, but Stereospondyli is still considered valid.[35][36] Below is a simplified taxonomy of temnospondyls showing currently recognized groups:

Edops, a basal edopoid.
Sclerothorax, a basal limnarchian.
Cyclotosaurus, a stereospondyl.

Class Amphibia

Phylogeny

In one of the earliest phylogenetic analyses of the group, Gardiner (1983) recognized five characteristics that made Temnospondyli a clade: a bone at the back of the skull called the parasphenoid is connected to another bone on the underside of the skull called the pterygoid; large openings called interpterygoid vacuities are present between the pterygoids; the stapes (a bone involved in hearing) is connected to the parasphenoid and projects upward; the cleithrum, a bone in the pectoral girdle, is thin; and part of the vertebra called the interdorsal attaches to the neural arch.[37] Additional features were given by Godfrey et al. (1987), including the contact between the postparietal and exoccipital at the back of the skull, small projections called uncinate processes on the ribs, and a pelvic girdle with each side having a single iliac blade.[38] These shared characteristics are called synapomorphies.

Temnospondyls are placed as basal tetrapods in phylogenetic analyses, with their exact positioning varying between studies.[39] Depending on the classification of modern amphibians, they are either included in the crown group Tetrapoda or the stem of Tetrapoda. Crown-group tetrapods are decendents of the most recent common ancestor of all living tetrapods and stem tetrapods are forms that are outside the crown group. Modern amphibians have recently been suggested as descendants of temnospondyls, which would place them within crown Tetrapoda. Below is a cladogram from Ruta et al. (2003) placing Temnospondyli within crown Tetrapoda:[40]

Tetrapoda


Acanthostega Acanthostega BW.jpg



Ichthyostega Ichthyostega BW.jpg





Tulerpeton Tulerpeton12DB.jpg





Crassigyrinus Crassigyrinus BW.jpg



Baphetidae





Colosteidae Greererpeton BW.jpg




Temnospondyli CyclotosaurusDB2 White background.jpg





Gephyrostegidae Gefyrostegus22DB.jpg



Embolomeri Diplovertebron BW.jpg





Seymouriamorpha Seymouria BW.jpg




Westlothiana Westlothiana BW.jpg


Crown Tetrapoda
Lepospondyli


Adelospondyli



Aïstopoda Phlegethontia.jpg





Nectridea Diplocaulus BW.jpg




Tuditanomorpha Tuditanus1DB.jpg




Brachystelechidae




Lysorophidae Lysorophus.jpg



Lissamphibia Prosalirus BW.jpg









Solenodonsaurus Solenodonsaurus1DB.jpg




Diadectomorpha Diadectes1DB.jpg



Amniota Gracilisuchus BW.jpg













Other studies place modern amphibians as the descendants of lepospondyls and place temnospondyls in a more basal position within the stem of Tetrapoda. Below is a cladogram from Laurin and Reisz (1999) placing Temnospondyli outside crown Tetrapoda:[41]

Tetrapoda

Acanthostega Acanthostega BW.jpg




Ichthyostega Ichthyostega BW.jpg




Tulerpeton Tulerpeton12DB.jpg




Colosteidae Greererpeton BW.jpg




Crassigyrinus Crassigyrinus BW.jpg




Whatcheeriidae Pederpes22small.jpg




Baphetidae


Crown Tetrapoda


Eucritta Eucritta1DB.jpg




"Temnospondyli" CyclotosaurusDB2 White background.jpg



Lissamphibia Prosalirus BW.jpg






Caerorhachis CaerorhahisDBsmall.jpg





Eoherpeton



Embolomeri Diplovertebron BW.jpg





Gephyrostegidae Gefyrostegus22DB.jpg




Solenodonsaurus Solenodonsaurus1DB.jpg




Seymouriamorpha Seymouria BW.jpg





Diadectomorpha Diadectes1DB.jpg



Amniota Gracilisuchus BW.jpg





Westlothiana Westlothiana BW.jpg



Lepospondyli Tuditanus1DB.jpg

















Most phylogenetic analyses of temnospondyl interrelationships focus on individual families. One of the first broad-scale studies of temnospondyl phylogeny was conducted by paleontologist Andrew Milner in 1990.[42] A 2007 study made a "supertree" of all temnospondyl families, combining the family-level trees of previous studies. The following cladogram is modified from Ruta et al. (2007):[43]

1
2

Edops



Cochleosauridae





Dendrerpetontidae



3

Trimerorhachis




Neldasaurus




Dvinosaurus




Eobrachyopidae




Brachyops



Tupilakosauridae









Saharastega




Iberospondylus




Palatinerpeton



4
5

Parioxeidae



Eryopidae





Zatracheidae


6

Trematopidae




Dissorophidae




Amphibamidae




Stegops




Eimerisaurus



Branchiosauridae










7-14









7

Lysipterygium



8

Actinodontidae




Intasuchidae




Melosauridae



Archegosauridae





9


Plagiosauridae



Peltobatrachidae





Lapillopsidae




Rhinesuchidae



10

Lydekkerinidae




Indobrachyopidae




Rhytidosteidae


11

Brachiopidae



Chigutisauridae







12

Mastodonsauroidea



13

Benthosuchus




Thoosuchidae



14

Almasauridae



Metoposauridae




Trematosauridae












1 Temnospondyli, 2 Edopoidea, 3 Dvinosauria, 4 Euskelia, 5 Eryopoidea, 6 Dissorophoidea, 7 Limnarchia, 8 Archegosauroidea, 9 Stereospondyli, 10 Rhytidostea, 11 Brachyopoidea, 12 Capitosauria, 13 Trematosauria, 14 Metoposauroidea

The most basal group of temnospondyls is the superfamily Edopoidea. Edopoids have several primitive or plesiomorphic features, including a single occipital condyle and a bone called the intertemporal that is absent in other temnospondyls. Edopoids include the Late Carboniferous genus Edops and the family Cochleosauridae. Dendrerpetontidae has also been included in Edopoidea, and is the oldest known temnospondyl family. Balanerpeton woodi is the oldest species, having been present over 330 million years ago during the Viséan stage of the Early Carboniferous. Recent analyses place Dendrerpetontidae outside Edopoidea in a more derived position.[44][45] Other primitive temnospondyls include Capetus and Iberospondylus. Saharastega and Nigerpeton, both described in 2005 from Niger, are also primitive yet come from the Late Permian. They are almost 40 million years younger than other basal temnospondyls, implying a long ghost lineage of species that are not yet known in the fossil record.[46]

In 2000, paleontologists Adam Yates and Anne Warren produced a revised phylogeny of more derived temnospondyls, naming several new clades.[36] Two major clades were Euskelia and Limnarchia. Euskelia includes the temnospondyls that were once called rhachitomes and includes two subfamilies, the Dissorophoidea and the Eryopoidea. Dissorophoids include small, mostly terrestrial temnospondyls that may be the ancestors of modern amphibians. Eryopoids include larger temnosondyls like Eryops. The second major clade, Limnarchia, includes most Mesozoic temnospondyls, as well as some Permian groups. Within Limnarchia are the superfamily Archegosauroidea and the most derived temnospondyls, the stereospondyls.

Yates and Warren also named Dvinosauria, a clade of small aquatic temnospondyls from the Carboniferous, Permian, and Triassic.[36] They placed Dvinosauria within Limnarchia, but more recent studies disagree on their position. For example, a 2007 study places them even more basal than Euskelians, while a 2008 study keeps them as basal limnarchians.[43][47]

Within Stereospondyli, Yates and Warren erected two major clades: Capitosauria and Trematosauria. Capitosaurs include large semiaquatic temnospondyls like Mastodonsaurus with flat heads and eyes near the back of the skull. Trematosaurs include a diversity of temnospondyls, including large marine trematosauroids, aquatic plagiosaurs, brachyopoids that survived into the Cretaceous, and metoposauroids with eyes near the front of their heads. In 2000, paleontologists Rainer Schoch and Andrew Milner named a third major clade of stereospondyls, the Rhytidostea.[48] This group included more primitive stereospondyls that could not be placed in either Capitosauria or Trematosauria, and included groups like Lydekkerinidae, Rhytidosteidae, and Brachyopoidea. While Capitosauria and Trematosauria are still widely used, Rhytidostea is not often supported as a true clade in recent analyses. Rhytidosteids and brachyopoids are now grouped with trematosaurians, but lydekkerinids are still considered to be a primitive family of stereospondyls.[49][50]

Relationship to modern amphibians

Life restoration of the dissorophoid Gerobatrachus, a close relative of lissamphibians.

Modern amphibians (frogs, salamanders, and caecilians) are classified in Lissamphibia. Lissamphibians appear to have arisen in the Permian. Molecular clock estimates place the first lissamphibian in the Late Carboniferous, but the first member of Batrachia (frogs and salamanders, but not caecilians) is estimated to have appeared in the Middle Permian using the same technique.[51][52] Using fossil evidence, there are three main theories for the origin of modern amphibians. One is that they evolved from lepospondyls, most likely the lysorophians.[53] Another is that they evolved from dissorophoid temnospondyls. A third hypothesis is that caecilians descended from lepospondyls and frogs and salamanders evolved from dissorophoids.[54]

Recently, the theory that temnospondyls were the ancestors of all lissamphibians has gained wide support. The skull morphology of some small temnospondyls has been compared to those of modern frogs and salamanders, but the presence of bicuspid, pedicellate teeth in small, paedomorphic or immature temnospondyls has been cited as the most convincing argument in favor of the temnospondyl origin of lissamphibians.[55] Seen in lissamphibians and many dissorophoid temnospondyls, pedicellate teeth have calcified tips and bases. During the development of most tetrapods, teeth begin to calcify at their tips. Calcification normally proceeds downward to the base of the tooth, but calcification from the tip stops abruptly in pedicellate teeth. Calcification resumes at the base, leaving an area in the center of the tooth uncalcified.[56] This pattern is seen in living amphibians and fossils.

The dissorophoid family Amphibamidae is thought to be most closely related to Lissamphibia. In 2008, an amphibamid called Gerobatrachus hottoni was named from Texas and was nicknamed the "frogamander" for its frog-like head and salamander-like body. It was thought to be the most closely related temnospondyl to lissamphibians and was placed as the sister taxon of the group in a phylogenetic analysis. Another species of amphibamid called Doleserpeton annectens is now thought to be even more closely related to lissamphibians. Unlike Gerobatrachus, Doleserpeton was known since 1969, and the presence of pedicellate teeth in its jaws has led some paleontologists to conclude soon after its naming that it was a relative of modern amphibians. It was first described as a "protolissamphibian", and the specific name annectens means "connecting" in reference to its inferred transitional position between temnospondyls and lissamphibians.[55] The structure of its tympanum, a disk-like membrane that functions like an ear drum, is similar to that of frogs and has also been used as evidence for a close relationship.[57][58] Other feature, including the shape of the palate and the back of the skull, the short ribs, and the smooth skull surface also point to it being a closer relative of lissamphibians than Gerobatrachus is. Below is a cladogram modified from Sigurdsen and Bolt (2010) showing the relationships of Gerobatrachus, Doleserpeton, and Lissamphibia:[59]

Temnospondyli

Balanerpeton




Dendrerpeton





Sclerocephalus



Eryops




 Dissorophoidea 

Ecolsonia




Micromelerpeton



 Dissorophidae 

Dissorophinae



Cacopinae



 Amphibamidae 

Eoscopus




Platyrhinops





Gerobatrachus



Apateon






Plemmyradytes




Tersomius




Micropholis



Pasawioops







Georgenthalia




Amphibamus




Doleserpeton



Lissamphibia
















Paleobiology

Feeding

Although the earliest temnospondyls were primarily semiaquatic, they had the ability to feed on land. Later, eryopoids and dissorophoids, some well adapted to terrestrial life, also fed on land. Some eryopoids became better adapted toward life in water, and shifted their diets toward aquatic organisms. The first primarily aquatic feeders were archegosaurs in the Permian. Trematosaurs and capitosaurs became independently aquatic and also returned to this type of feeding.[60]

Most aquatic stereospondyls have flattened heads. When feeding, they probably opened their mouths by lifting their skulls instead of lowering their lower jaws. The jaw mechanics of the plagiosaurid Gerrothorax is well known, and is one of the most highly adapted. Gerrothorax is thought to have lifted its skull to around 50° above horizontal through the flexing of the atlanto-occipital joint between the occipital condyles of the skull and the atlas vertebra of the neck. As the skull is raised, the quadrate bone pushes forward and causes the lower jaw to protrude outward.[61] Other stereospondyls probably also lifted their skulls, but they are not as well adapted for such movement. D.M.S. Watson was the first to suggest skull lifting as a means of feeding in temnospondyls. He envisioned that Mastodonsaurus, a much larger temnospondyl than Gerrothorax, was able to make the same movement.[62][63] Paleontologist A.L. Panchen also supported the idea in 1959, suggesting that Batrachosuchus also fed in this way.[8] At the time it was thought that these temnospondyls lifted their heads with strong jaw muscles, but it is now thought that they used larger muscles in the neck that were attached to the large pectoral girdle. Plagiosuchus, a close relative of Gerrothorax, also has a hyobranchial skeleton that muscles may have attached to. Plagiosuchus has very small teeth and a large area for muscle attachment behind the skull, suggesting that it could suction feed by rapidly opening its mouth.[30]

Unlike semiaquatic temnospondyls, terrestrial temnospondyls have skulls that are adapted for biting land-living prey. The sutures between the bones of the skull in the dissorophoid Phonerpeton are able to withstand a high degree of compression. Compressive forces would have been experienced when biting down on prey.[64] Earlier aquatic tetrapods and tetrapod ancestors differ from temnospondyls like Phonerpeton in that their skulls were also built to withstand tension. This tension would have been experienced during suction feeding underwater. Temnospondyls like Phonerpeton were among the first tetrapods that were almost exclusively terrestrial and fed by biting.[65]

Reproduction

Temnospondyls, like all amphibians, reproduced in aquatic environments. Most temnospondyls probably reproduced through external fertilization. Like most living frogs, female temnospondyls would have laid masses of eggs in water while males released sperm to fertilize them. Several fossils were described from the Early Permian of Texas in 1998 that may be egg masses of dissorophoid temnospondyls. They were the first known fossils of amphibian eggs. The fossils consist of small disks with thin membranes that are probably vitelline membranes and halo-like areas surrounding them that are most likely mucous coatings. They are attached to plant fossils, suggesting that these temnospondyls laid eggs on aquatic plants much like modern frogs. The mucous membranes show that the eggs were laid by amphibians, not fish (their eggs lack mucous), but the type of amphibian that laid them cannot be known because no body fossils are preserved with the eggs. The eggs are thought to be from dissorophoids because they are likely to be close relatives of modern amphibians, and probably had similar reproductive strategies. They are also the most common amphibians from the deposit in which the eggs were found.[66]

One temnospondyl, the dvinosaur Trimerorhachis, may have brooded young in an area between the gills called the pharyngeal pouch. Small bones belonging to younger Trimerorhachis individuals have been found in these pouches. The living Darwin's Frog is also a mouth brooder and would be the closest modern analogue to Trimerorhachis if it cared for its young in this way. An alternative possibility is that Trimerorhachis was cannibalistic, eating its young like many amphibians do today. If this was the case, the bones of these smaller individuals were originally located in the throat and were pushed into the pharyngeal pouch as the animal fossilized.[67]

Body impressions of Early Carboniferous temnospondyls from Pennsylvania suggest that some terrestrial temnospondyls mated on land like some modern amphibians. They reproduced through internal fertilization rather than mating in water. The presence of three individuals in one block of sandstone shows that the temnospondyls were gregarious. The head of one individual rests under the tail of another in what may be a courtship display.[68] Internal fertilization and similar courtship behavior are seen in modern salamanders.[5]

Growth

A larval fossil of Micromelerpeton.

While most types of temnospondyls are distinguished on the basis of features in mature specimens, several are known from juvenile and larval specimens. Metamorphosis is seen in dissorophoids, eryopids, and zatrachydids, with aquatic larvae developing into adults capable of living on land. Several types of dissorophoids do not fully metamorphose, but retain features of juveniles such as gills and small body size in what is known as neoteny.[69] Dvinosaurians and the plagiosaurid Gerrothorax were also neotenic because they retained gills, but they are only known from adult specimens.[70]

Temnospondyl larvae are often distinguished by poorly developed bones and the presence of a hyobranchial apparatus, a series of bones that gills would attach to in life. However, some fully mature temnospondyls also possess hyobranchial bones but did not have external gills.[71] A dense covering of scales is also seen in larvae and adults. Major body changes occur in metamorphosis, including the reshaping and strengthening of skull bones, the thickening of postcranial bones, and an increase in body size.

Temnospondyls like Sclerocephalus are known from both large adult specimens and small larvae, showing an extreme change in body shape. In these species, the shape and proportions of skull bones change in the early stages of development. The ornamentation on the surface of the skull roof also develops at this time. Small, regularly spaced pits are the first to form, followed by larger ridges. As development continues, the external gills disappear. Small teeth that once covered the palate are lost. The postcranial skeleton does not develop at the same rate as the skull, with ossification (the replacement of cartilage by bone) happening more slowly.[71] Vertebrae and limb bones are poorly developed, ribs and fingers are absent in the early stages, and the scapulocoracoid and ischium are entirely absent through most of development.[72] Once maturity is reached, most bones have fully formed and growth rate slows. The bones of some temnospondyls like Dutuitosaurus show growth marks, possibly an indication that growth rate varied with the change in seasons.[52] Fossils of temnospondyls like Metoposaurus and Cheliderpeton show that individuals grew larger past maturity. The oldest individuals usually have more pitting on their skulls with deeper sulci.[73]

One group of temnospondyls, the Branchiosauridae, is also known from larval specimens. Branchiosaurids like Branchiosaurus and Apateon are represented by many fossils preserving skin and external gills. An entire growth series is exhibited in the wide range of sizes among specimens, but the lack of terrestrially-adapted adult forms suggests that these temnospondyls were neotenic. Unlike other temnospondyls, their postcranial skeletons developed quickly but were still partly cartilaginous when fully mature. Adults likely had an aquatic lifestyle similar to juveniles. Recently, large specimens of Apateon gracilis were described with adaptations toward a terrestrial lifestyle, indicating that not all branchiosaurs were neotenic.[71]

While most temnospondyls are aquatic in early stages of life, most metoposaurids appear to have been terrestrial in their juvenile stage. Like other Mesozoic temnospondyls, adult metoposaurids were adapted to a semiaquatic lifestyle. Their bones are not highly developed for movement on land. The cross-sectional thickness of limb bones in adult metoposaurids shows that they could not withstand the stress of terrestrial locomotion. Juvenile individuals have bones that are thick enough to withstand this stress, and could probably move about on land. To maintain a terrestrial lifestyle, a temnospondyl's limb bones would have to thicken with positive allometry, meaning that they would grow at a greater rate than the rest of the body. This is not the case in metoposaurids, meaning that as their bodies grew larger they became less adapted toward a terrestrial lifestyle.[74]

Hearing

Temnospondyls and other early tetrapods have rounded otic notches in the back of the skull that project into the cheek region. In life, the otic notch would have been covered by a membrane called the tympanum, which is seen as a disk-like area in living frogs. The tympanum is involved in hearing, and is similar to the ear drum of more advanced tetrapods. It was traditionally thought that the tympanum developed very early in tetrapod evolution as a hearing organ and progressed to form the ear drum of amniotes. Thus, temnospondyls possessed a hearing system supposedly ancestral to that of living amphibians and reptiles.[75]

Frogs and all other living tetrapods have a rod-like bone called the stapes that aids in hearing by transferring vibrations from the ear drum —or homologous tympanum— to the inner ear. Temnospondyls also have a stapes, which projects into the otic cavity. The stapes likely evolved from the hyomandibula of lobe-finned fishes. The positioning of the stapes and the shape of the otic region suggests that the tympani of temnospondyls and frogs are homologous, but the tympani of these amphibians are no longer considered homologous with the hearing systems of reptiles, birds, and mammals. Therefore, ear structures in temnospondyls were not ancestral to those of all other tetrapods.[75]

The ability of the tympanum and stapes to effectively transmit vibrations is called impedance matching. Early tetrapods like temnospondyls have thick stapes with poor impedence matching, so it is now thought that they were not used for hearing. Instead, these thick stapes may have functioned to support the tissue that covers the otic notch.[38] Early temnospondyls like Dendrerpeton could not hear airborne sound but would have been able to detect vibration in the ground.[76] Later temnospondyls like Doleserpeton had otic regions adapted to hearing. Doleserpeton has a structure in the inner ear called the perilymphatic duct, which is also seen in frogs and is associated with hearing. Its stapes is also a better transmitter of sound. The hearing system of Doleserpeton and related temnospondyls was able to detect airborne sound and may have been ancestral to that of living amphibians.[57][58]

Notes

  1. ^ Owen placed Labyrinthodon in Batrachia, a group that includes frogs, and classified Batrachia within Reptilia. What are today classified as reptiles (lizards, snakes, crocodilians and turtles) were called saurian reptiles.

References

  1. ^ a b c Steyer, J.-S.; and Laurin, M. (2011). "Temnospondyli". Tree of Life Web Project. http://tolweb.org/Temnospondyli. Retrieved 3 August 2011. 
  2. ^ Hunt, A.P.; Lucas, S.G.; and Berman, D.S. (1996). "A new amphibamid (Amphibia: Temnospondyli) from the Late Pennsylvanian (Middle Stephanian) of central New Mexico, USA". Paläontologische Zeitschrift 70 (3-4): 555–565. doi:10.1007/BF02988092. 
  3. ^ Olson, E.C. (1972). "Fayella chickashaensis, the Dissorophoidea and the Permian terrestrial radiations". Journal of Paleontology 46 (1): 104–114. 
  4. ^ Steyer, J.S.; Damiani, R.; Sidor, C.A.; O'Keefe, F.R.; Larsson, H.C.E.; Maga, A.; and Ide, O. (2006). "The vertebrate fauna of the Upper Permian of Niger. IV. Nigerpeton ricqlesi (Temnospondyli: Cochleosauridae), and the edopoid colonization of Gondwana". Journal of Vertebrate Paleontology 26 (1):  :18–28. doi:10.1671/0272-4634(2006)26[18:TVFOTU]2.0.CO;2. http://www.washington.edu/burkemuseum/collections/paleontology/sidor/Steyer%26al2006.pdf. 
  5. ^ a b Stratton, C. (29 October 2007). "Ancient Amphibians Left Full-Body Imprints". GSA Newsroom. The Geological Society of America. http://www.geosociety.org/news/pr/07-60.htm. Retrieved 2 August 2011. 
  6. ^ Hunt, A.P.; and Lucas, S.G. (2005). "Tetrapod ichnofacies and their utility in the Paleozoic". In Buta, R.J.; Rindsberg, A.K.; and Kopaska-Merkel, D.C. (eds.). Pennsylvanian Footprints in the Black Warrior Basin of Alabama. 1. Alabama Paleontological Society. pp. 113–119. http://kudzu.astr.ua.edu/apsmono1/paper08_APS_MONO_1_Hunt_Lucas.pdf. 
  7. ^ Witzmann, F. (2007). "The evolution of the scalation pattern in temnospondyl amphibians". Zoological Journal of the Linnean Society 150 (4): 815–834. doi:10.1111/j.1096-3642.2007.00309.x. 
  8. ^ a b c d Panchen, A.L. (1959). "A new armoured amphibian from the Upper Permian of East Africa". Philosophical Transactions of the Royal Society of London B 242 (691): 207–281. doi:10.1098/rstb.1959.0005. 
  9. ^ Bolt, J.R. (1974). "Armor of dissorophids (Amphibia: Labyrinthodontia): an examination of its taxonomic use and report of a new occurrence". Journal of Paleontology 48 (1): 135-14. 
  10. ^ Dilkes, D.W. (2009). "Comparison and biomechanical interpretations of the vertebrae and osteoderms of Cacops aspidephorus and Dissorophus multicinctus (Temnospondyli, Dissorophidae)". Journal of Vertebrate Paleontology 29 (4): 1013–1021. doi:10.1671/039.029.0410. 
  11. ^ Schoch, R.R.; Fastnacht, M.; Fichter, J.; and Keller, T. (2007). "Anatomy and relationships of the Triassic temnospondyl Sclerothorax". Acta Palaeontologica Polonica 52 (1): 117–136. http://app.pan.pl/archive/published/app52/app52-117.pdf. 
  12. ^ Colbert, E.H. (1969). Evolution of the Vertebrates (2nd ed.). New York: John Wiley & Sons. 
  13. ^ Jaeger, G.F. (1828). "Reptilien aus dem Alaunschiefer". Über die fossile reptilien, welche in Würtemberg aufgefunden worden sind. Stuttgart: J.B. Metzler. pp. 34–38. http://www.biodiversitylibrary.org/item/23708#page/44/mode/1up. 
  14. ^ Jardine, W.; Selby, P.J.; Johnston, D.D.; and Taylor, R. (1842). "Proceedings of Learned Societies: Geological Society". The Annals and Magazine of Natural History 8 (48): 58–61. http://www.biodiversitylibrary.org/page/2338058#page/74/mode/1up. 
  15. ^ Moser, M.; and Schoch, R.R. (2007). "Revision of the type material and nomenclature of Mastodonsaurus giganteus (Jaeger) (Temnospondyli) from the Middle Triassic of Germany". Palaeontology 50 (5): 1245–1266. doi:10.1111/j.1475-4983.2007.00705.x. 
  16. ^ Owen, R. (1842). "Report on British fossil reptiles". Report of the Eleventh Meeting of the British Association for the Advancement of Science 11: 60–204. http://books.google.com/books?id=dy5LAAAAYAAJ&pg=PA60#v=onepage&q&f=false. 
  17. ^ Owen, R. (1861). "Order II: Labyrinthodontia". Palaeontology or A systematic summary of extinct animals and their geological relations. Edinburgh: Adam and Charles Black. pp. 206–218. http://books.google.com/books?id=mzYDAAAAQAAJ&pg=PA206#v=onepage&q&f=false. 
  18. ^ Milner, A.C.; and Lindsay, W. (1998). "Postcranial remains of Baphetes and their bearing on the relationships of the Baphetidae (= Loxommatidae)". Zoological Journal of the Linnean Society 22 (1): 211–235. doi:10.1111/j.1096-3642.1998.tb02530.x. 
  19. ^ Benton, M.J.; and Walker, A.D. (1996). "Rhombopholis, a prolacertiform reptile from the Middle Triassic of England". Palaeontology 39 (3): 763–782. http://palaeontology.palass-pubs.org/pdf/Vol%2039/Pages%20763-782.pdf. 
  20. ^ Woodward, A.S. (1898). "Class Batrachia". Outlines of vertebrate palaeontology for students of zoology. Cambridge: University Press. pp. 470. 
  21. ^ Moodie, R.J. (1909). "A contribution to a monograph of the extinct amphibia of North America. New forms from the Carboniferous". The Journal of Geology 17 (1): 38–82. 
  22. ^ Owen, R. (1860). "Order I: Ganocephala". Systematic summary of extinct animals and their geological relations. Edinburgh: Adam and Charles Black. pp. 168–183. http://books.google.com/books?id=vkMsAAAAYAAJ&printsec=frontcover&cad=0#v=onepage&q&f=false. 
  23. ^ Carroll, R. L.; and Gaskill, P. (1978). "The Order Microsauria". Memoirs of the American Philosophical Society 126: 1–211. http://books.google.com/books?id=mjcyaQw78X4C&printsec=frontcover&dq=the+order+microsauria#v=onepage&q&f=false. 
  24. ^ Case, E.C. (1898). "Studies for Students: The Development and Geological Relations of the Vertebrates". The Journal of Geology 6 (5): 500–523. 
  25. ^ Cope, E.D. (1888). "Handbuch der Palæontologie of Zittel". The American Naturalist 22 (263): 1018–1019. 
  26. ^ a b c Romer, A.S. (1947). "Review of the Labyrinthodontia". Bulletin of the Museum of Comparative Zoology 99 (1): 1–368. http://ia700303.us.archive.org/4/items/bulletinofmuseum99harv/bulletinofmuseum99harv.pdf. 
  27. ^ Watson, D.M.S. (1919). "The Structure, Evolution and Origin of the Amphibia. The "Orders" Rachitomi and Stereospondyli". Philosophical Transactions of the Royal Society of London Series B 209: 1–73. 
  28. ^ Pawley, K. (2007). "The postcranial skeleton of Trimerorhachis insignis Cope, 1878 (Temnospondyli: Trimerorhachidae): a plesiomorphic temnospondyl from the Lower Permian of North America". Journal of Paleontology 81 (5): 873–894. doi:10.1666/pleo05-131.1. 
  29. ^ Fox, C.B.; and Hutchinson, P. (1991). "Fishes and amphibians from the Late Permian Pedra de Fogo Formation of Northern Brazil". Palaeontology 34 (3): 561–573. http://palaeontology.palass-pubs.org/pdf/Vol%2034/Pages%20561-573.pdf. 
  30. ^ a b Damiani, R.; Schoch, R.R.; Hellrung, H.; Werneburg, R.; and Gastou, S. (2009). "The plagiosaurid temnospondyl Plagiosuchus pustuliferus (Amphibia: Temnospondyli) from the Middle Triassic of Germany: anatomy and functional morphology of the skull". Zoological Journal of the Linnean Society 155 (2): 348–373. doi:10.1111/j.1096-3642.2008.00444.x. 
  31. ^ Colbert, E.H.; and Cosgriff, J.W. (1974). "Labyrinthodont amphibians from Antarctica". American Museum Novitates 2552: 1–30. http://digitallibrary.amnh.org/dspace/handle/2246/2750. 
  32. ^ Sidor, C.A.; Damiani, R.; and Hammer, W.R. (2008). "A new Triassic temnospondyl from Antarctica and a review of Fremouw Formation biostratigraphy". Journal of Vertebrate Paleontology 28 (3): 656–663. doi:10.1671/0272-4634(2008)28[656:ANTTFA]2.0.CO;2. 
  33. ^ Lucas, S.G.; Rinehart, L.F.; Krainer, K.; Spielmann, J.A.; and Heckert, A.B. (2010). "Taphonomy of the Lamy amphibian quarry: A Late Triassic bonebed in New Mexico, U.S.A.". Palaeogeography, Palaeoclimatology, Palaeoecology 298 (3-4): 388–398. doi:10.1016/j.palaeo.2010.10.025. 
  34. ^ Martin, A.J. (2009). "Dinosaur burrows in the Otway Group (Albian) of Victoria, Australia, and their relation to Cretaceous polar environments". Cretaceous Research 30 (2009): 1223–1237. doi:10.1016/j.cretres.2009.06.003. http://www.envs.emory.edu/faculty/MARTIN/ResearchDocs/Dinosaur_burrows_2009.pdf. 
  35. ^ Laurin, M.; and Steyer, J.-S. (2000). "Phylogeny and Apomorphies of Temnospondyls". Tree of Life Web Project. http://tolweb.org/tree/phylogeny.html. Retrieved 18 July 2011. 
  36. ^ a b c Yates, A.M.; and Warren, A.A. (2000). "The phylogeny of the ‘higher’ temnospondyls (Vertebrata: Choanata) and its implications for the monophyly and origins of the Stereospondyli". Zoological Journal of the Linnean Society 128 (1): 77–121. doi:10.1111/j.1096-3642.2000.tb00650.x. 
  37. ^ Gardiner, B.G. (1983). "Gnathostome vertebrae and the classification of the Amphibia". Zoological Journal of the Linnean Society 79 (1): 1–59. doi:10.1111/j.1096-3642.1983.tb01160.x. 
  38. ^ a b Godfrey, S.J.; Fiorillo, A.R.; and Carroll, R.L. (1987). "A newly discovered skull of the temnospondyl amphibian Dendrerpeton acadianum Owen". Canadian Journal of Earth Sciences 24 (4): 796–805. doi:10.1139/e87-077. 
  39. ^ Ruta, M.; Jeffery, J.E.; and Coates, M.I. (2003). "A supertree of early tetrapods". Proceedings of the Royal Society B 270 (1532): 2507–2516. doi:10.1098/rspb.2003.252. http://rspb.royalsocietypublishing.org/content/270/1532/2507.full.pdf. 
  40. ^ Ruta, M.; Coates, M.I.; and Quicke, D.L.J. (2003). "Early tetrapod relationships revisited". Biological Reviews 78: 251–345. doi:10.1017/S146479310200610. http://pondside.uchicago.edu/oba/faculty/coates/5.RutCoaQuick2003.pdf. 
  41. ^ Laurin, M.; and Reisz, R.R. (1999). "A new study of Solenodonsaurus janenschi, and a reconsideration of amniote origins and stegocephalian evolution". Canadian Journal of Earth Sciences 36: 1239–1255. http://www.erin.utoronto.ca/~w3reisz/pdf/laurin_reisz1999.PDF. 
  42. ^ Milner, A.R. (1990). "The radiations of temnospondyl amphibians". In Taylor, P.D and Larwood, G.P. (eds.). Major Evolutionary Radiations. Oxford: Clarendon Press. pp. 321–349. 
  43. ^ a b Ruta, M.; Pisani, D.; Lloyd, G. T.; and Benton, M. J. (2007). "A supertree of Temnospondyli: cladogenetic patterns in the most species-rich groups of early tetrapods". Proceedings of the Royal Society B 274 (1629): 3087–3095. doi:10.1098/rspb.2007.1250. PMC 2293949. PMID 17925278. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2293949. 
  44. ^ Milner, A.R. (1980). "The temnospondyl amphibian Dendrerpeton from the Upper Carboniferous of Ireland". Palaeontology 23 (1): 125–141. http://palaeontology.palass-pubs.org/pdf/Vol%2023/Pages%20125-141.pdf. 
  45. ^ Holmes, R.B.; Carroll, R.L.; and Reisz, R.R. (1998). "The first articulated skeleton of Dendrerpeton acadianum (Temnospondyli: Dendrerpentonidae) from the Lower Pennsylvanian locality of Joggins, Nova Scotia, and a review of its relationships". Journal of Vertebrate Paleontology 18 (1): 64–79. 
  46. ^ Sidor, C.A.; O'Keefe, F.R.; Damiani, R.J.; Steyer, J.-S.; Smith, R.M.H.; Larsson, H.C.E.; Sereno, P.C.; Ide, O.; and Maga, A. (2005). "tetrapods from the Sahara show climate-controlled endemism in Pangaea". Nature 434 (7035): 886–889. doi:10.1038/nature03393. PMID 15829962. http://www.burkemuseum.org/pub/Sidor_et_al_2005.pdfPermian. 
  47. ^ Englehorn, J.; Small, B.J; and Huttenlocker, A. (2008). "A redescription of Acroplous vorax (Temnospondyli: Dvinosauria) based on new specimens from the Early Permian of Nebraska and Kansas, U.S.A.". Journal of Vertebrate Paleontology 28 (2): 291–305. doi:10.1671/0272-4634(2008)28[291:AROAVT]2.0.CO;2. 
  48. ^ Schoch, R. R.; and Milner, A. R. (2000). "Stereospondyli". In P. Wellnhofer (ed.). Handbuch der Paläoherpetologie. 3B. Munich: Verlag Dr. Friedrich Pfeil. pp. 203. 
  49. ^ Warren, A.; and Marsicano, C. (2000). "A phylogeny of the Brachyopoidea". Journal of Vertebrate Paleontology 20 (3): 462–483. doi:10.1671/0272-4634(2000)020[0462:APOTBT]2.0.CO;2. 
  50. ^ Yates, A.M. (2000). "A new tiny rhytidosteid (Temnospondyli: Stereospondyli) from the Early Triassic of Australia and the possibility of hidden temnospondyl diversity". Journal of Vertebrate Paleontology 20 (3): 484–489. doi:10.1671/0272-4634(2000)020[0484:ANTRTS]2.0.CO;2. 
  51. ^ Zhang, P.; Zhou, H.; Chen, Y.-Q.; Liu, L.-F.; and Qu, L.-H. (2005). "Mitogenomic perspectives on the origin and phylogeny of living amphibians". Systematic Biology 54 (3): 391–400. doi:10.1080/1063515059094527. http://naherpetology.org/pdf_files/264.pdf. 
  52. ^ a b San Mauro, D.; Gower, D.J.; Oommen, O.V.; Wilkinson, M.; and Zardoya, R. (2004). "Phylogeny of caecilian amphibians (Gymnophiona) based on complete mitochondrial genomes and nuclear RAG1". Molecular Phylogenetics and Evolution 33: 413–427. doi:10.1016/j.ympev.2004.05.01. http://www.bmnh.org/PDFs/SM_04_MPE.pdf. 
  53. ^ Laurin, M. (1998). "The importance of global parsimony and historical bias in understanding tetrapod evolution. Part I — systematics, middle ear evolution, and jaw suspension". Annales des Sciences Naturelles, Zoologie, Paris 13e (19): 1–42. 
  54. ^ Anderson, J.S.; Reisz, R.R.; Scott, D.; Fröbisch, N.B.; and Sumida, S.S. (2008). "A stem batrachian from the Early Permian of Texas and the origin of frogs and salamanders". Nature 453: 515–518. doi::10.1038/nature0686. http://www.cnah.org/pdf_files/988.pdf. 
  55. ^ a b Bolt, J.R. (1969). "Lissamphibian origins: possible protolissamphibian from the Lower Permian of Oklahoma". Science 166 (3907): 888–891. doi:10.1126/science.166.3907.888. 
  56. ^ Vasil'eva, A.B.; and Smirnov, S.V. (2001). "Pedicellate teeth and the problems of amphibian phylogeny". Doklady Biological Sciences 376 (5): 89–90. doi:10.1023/A:1018858917237. 
  57. ^ a b Bolt, J.R.; and Lombard, R.E. (1985). "Evolution of the amphibian tympanic ear and the origin of frogs". Biological Journal of the Linnean Society 24 (1): 83–99. doi:10.1111/j.1095-8312.1985.tb00162.x. 
  58. ^ a b Sigurdsen, T. (2008). "The otic region of Doleserpeton (Temnospondyli) and its implications for the evolutionary origin of frogs". Zoological Journal of the Linnean Society 154 (4): 738–751. doi:10.1111/j.1096-3642.2008.00459.x. 
  59. ^ Sigurdsen, T.; and Bolt, J.R. (2010). "The Lower Permian amphibamid Doleserpeton (Temnospondyli: Dissorophoidea), the interrelationships of amphibamids, and the origin of modern amphibians". Journal of Vertebrate Paleontology 30 (5): 1360–1377. doi:10.1080/02724634.2010.501445. 
  60. ^ Fortuny, J.; Marcé-Nogué, J.; de Esteban-Trivigno, S.; Gil, L.; and Galobart, À. (2011). "Temnospondyli bite club: ecomorphological patterns of the most diverse group of early tetrapods". Journal of Evolutionary Biology in press. doi:10.1111/j.1420-9101.2011.02338.x. 
  61. ^ Jenkins, F.A. Jr.; Shubin, N.H.; Gatesy, S.M.; and Warren, A. (2008). "Gerrothorax pulcherrimus from the Upper Triassic Fleming Fjord Formation of East Greenland and a reassessment of head lifting in temnospondyl feeding". Journal of Vertebrate Paleontology 28 (4): 935–950. doi:10.1671/0272-4634-28.4.935. 
  62. ^ Watson, D.M.S. (1920). "The structure, evolution and origin of the Amphibia. The "Orders" Rachitomi and Stereospondyli". Philosophical Transactions of the Royal Society of London B 209: 1–73. doi:10.1098/rstb.1920.0001. 
  63. ^ Celeskey, Matt (28 December 2008). "The flip-up skull of Gerrothorax". The Hairy Museum of Natural History. http://www.hmnh.org/archives/2008/12/28/the-flip-up-skull-of-gerrothorax/. Retrieved 2 August 2011. 
  64. ^ Markey, M.J. (2006). "Feeding shifts across the fish-amphibian transition are revealed by changes in cranial sutural morphology". Geological Society of America Abstracts with Programs 38 (7): 341. 
  65. ^ Markey, M.J.; and Marshall, C.R. (2007). "Terrestrial-style feeding in a very early aquatic tetrapod is supported by evidence from experimental analysis of suture morphology". Proceedings of the National Academy of Sciences of the United States of America 104 (17): 7134–7138. doi:10.1073/pnas.0701706104. 
  66. ^ Mamay, S.H.; Hook, R.W.; and Hotton, N. III. (1998). "Amphibian eggs from the Lower Permian of north-central Texas". Journal of Vertebrate Paleontology 18 (1): 80–84. 
  67. ^ Olson, E.C. (1979). "Aspects of the biology of Trimerorhachis (Amphibia: Temnospondyli)". Journal of Paleontology 53 (1): 1–17. 
  68. ^ Lucas, S.G.; Fillmore, D.L.; and Simpson, E.L. (2007). "Amphibian body impressions from the Mississippian Mauch Chunk Formation, eastern Pennsylvania". Geological Society of America Abstracts with Programs 39 (6): 400. 
  69. ^ Schoch, R.R. (2002). "The evolution of metamorphosis in temnospondyls". Lethaia 35 (4): 309–327. doi:10.1111/j.1502-3931.2002.tb00091.x. 
  70. ^ Reiss, J.O. (2002). "The phylogeny of amphibian metamorphosis". Zoology 105 (2): 85–96. doi:0944-2006/02/105/02-085. http://users.humboldt.edu/jreiss/Current/phylomet.pdf. 
  71. ^ a b c Schoch, R.R.; and Fröbisch, N.B. (2006). "Metamorphosis and neoteny: alternative pathways in an extinct amphibian clade". Evolution 60 (7): 1467–1475. doi:10.1111/j.0014-3820.2006.tb01225.x. 
  72. ^ Schoch, R.R. (2003). "Early larval ontogeny of the Permo-Carboniferous temnospondyl Sclerocephalus". Palaeontology 46 (5): 1055–1072. doi:10.1111/1475-4983.00333. 
  73. ^ Werneburg, R.; and Steyer, J.S. (2002). "Revision of Cheliderpeton vranyi Fritsch, 1877 (Amphibia, Temnospondyli) from the Lower Permian of Bohemia (Czech Republic)". Paläontologische Zeitschrift 76 (1): 149–162. doi:10.1007/BF02988193. 
  74. ^ Rinehart, L.F.; Lucas, S.G.; and Heckert, A.B. (2009). "Limb allometry and lateral line groove development indicates terrestrial-to-aquatic lifestyle transition in Metoposauridae (Amphibia: Temnospondyli)". Geological Society of America Abstracts with Programs 41 (7): 263. 
  75. ^ a b Lombard, R.E.; and Bolt, J.R. (1979). "Evolution of the tetrapod ear: an analysis and reinterpretation". Biological Journal of the Linnean Society 11 (1): 19–76. doi:10.1111/j.1095-8312.1979.tb00027.x. 
  76. ^ "Localities of the Carboniferous: Dendrerpeton and Joggins, Nova Scotia". UCMP. Regents of the University of California. 2006. http://www.ucmp.berkeley.edu/carboniferous/joggins.html. Retrieved 1 August 2011. 

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  • Temnospondyli — Temnospọndyli   [zu griechisch témnein »schneiden« und spondýlios »Wirbel«], Schnittwirbler, fossile Ordnung der Labyrinthodontia, vom Karbon bis zur Trias. Die teils wenige Zentimeter, teils bis 4 m langen Temnospondyli hatten aalförmige oder… …   Universal-Lexikon

  • Temnospondyli — noun formerly a suborder of Stegocephalia; large Carboniferous and Permian amphibians having vertebrae in which some elements remain separate • Syn: ↑order Temnospondyli • Hypernyms: ↑animal order • Member Holonyms: ↑Labyrinthodontia, ↑superorder …   Useful english dictionary

  • Temnospondyli (classification phylogenetique) — Temnospondyli (classification phylogénétique) Cette page a pour objet de présenter un arbre phylogénétique des Temnospondyli (ou Temnospondyles), c est à dire un cladogramme mettant en lumière les relations évolutives complexes (relations groupes …   Wikipédia en Français

  • Temnospondyli (classification phylogénétique) — Cette page a pour objet de présenter un arbre phylogénétique des Temnospondyli (Temnospondyles), c est à dire un cladogramme mettant en lumière les relations de parenté existant entre leurs différents groupes (ou taxa), telles que les dernières… …   Wikipédia en Français

  • temnospondyli — tem·no·spon·dy·li …   English syllables

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