Diplocaulus

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Diplocaulus
Temporal range: Pennsylvanian to Lopingian (Kasimovian to Wuchiapingian), 306–255  Ma
Diplocaulus - skeleton and model.jpg
Reconstructed skeleton and life restoration model of Diplocaulus at the Denver Museum of Nature and Science
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Clade: Sarcopterygii
Clade: Tetrapodomorpha
Order: Nectridea
Family: Diplocaulidae
Genus: Diplocaulus
Cope, 1877
Species
  • D. salamandroidesCope, 1877(type)
  • D. magnicornisCope, 1882
  • D. brevirostrisOlson, 1951
  • D. recurvatus? Olson, 1952
  • D. minimus? Dutuit, 1988
Synonyms

Genus-level:

  • PermoplatyopsCase, 1946

Species-level:

  • Diplocaulus limbatusCope, 1895
  • Diplocaulus copeiBroili, 1904
  • Diplocaulus pusillus? Broili, 1904
  • Permoplatyops parvus(Williston, 1918 [originally Platyops parvus])
  • Diplocaulus primigeniusMehl, 1921
  • Diplocaulus parvusOlson, 1972

Diplocaulus (meaning "double stalk") is an extinct genus of lepospondyl amphibians which lived from the Late Carboniferous to the Late Permian of North America and Africa. Diplocaulus is by far the largest and best-known of the lepospondyls, characterized by a distinctive boomerang-shaped skull. Remains attributed to Diplocaulus have been found from the Late Permian of Morocco and represent the youngest-known occurrence of a lepospondyl.

Contents

Description

Artist's reconstruction of D. magnicornis with conservative skin flaps attached to its tabular horns Diplocaulus recon.png
Artist's reconstruction of D. magnicornis with conservative skin flaps attached to its tabular horns

Diplocaulus had a stocky, salamander-like body, but was relatively large, reaching up to 1 m (3.3 ft) in length. Although a complete tail is unknown for the genus, a nearly complete articulated skeleton described in 1917 preserved a row of tail vertebrae near the head. This was construed as circumstantial evidence for a long, thin tail capable of reaching the head if the animal was curled up. [1] Most studies since this discovery have argued that anguiliform (eel-like) tail movement was the main force of locomotion utilized by Diplocaulus and its relatives. [2] [3]

Horns

A skull diagram of D. magnicornis by Douthitt (1917), whose identifications of skull bones closely matches those of modern sources Douthitt Diplocaulus skull diagram.png
A skull diagram of D. magnicornis by Douthitt (1917), whose identifications of skull bones closely matches those of modern sources

The most distinctive features of this genus and its closest relatives were a pair of long protrusions or horns at the rear of the skull, giving the head a boomerang-like shape. Most of the outer/front edge of each horn was formed by the elongated, blade-like squamosal bone. The rear edge of the skull and horns, on the other hand, was formed by the postparietal bones, also known as dermosupraoccipitals in older publications. However, the primary component of each horn (including the tips) is a long bone with a historically controversial identification. Many early sources considered the bone to be a tabular, which in other early tetrapods is a small bone lying at the rear edge of the skull. [4] [1] However, Olson (1951) doubted this, arguing that the bone's contact with the parietals excluded the possibility of it being a tabular. He argued that the bone was the supratemporal bone, which had enlarged and shifted towards the rear tip of the skull. [5] Beerbower (1963) countered Olson's reasoning by pointing out that Urocordylus , a newt-like relative of Diplocaulus, retained both a supratemporal bone and a tabular bone. In Urocordylus, the tabular lies closer to the back of the skull and even contacts the parietals, invalidating Olson's main point. [2] Based on this observation, it is more likely that the primary bone of the horns in Diplocaulus is a tabular. Many studies (even a later publication by Olson) now refer to Diplocaulus horns as tabular horns based on Beerbower's argument. [6] [3] [7]

Species

D. salamandroides

D. salamandroides was the first species of Diplocaulus to be discovered. Remains from this species were discovered near Danville, Illinois by William Gurley and J.C. Winslow, a pair of local geologists. The fossils were later described by renowned paleontologist Edward Drinker Cope in 1877. This species is only known from a small number of vertebrae sent to Cope by Gurley and Winslow. These vertebrae were noted for their similarities to those of salamanders (hence the specific name salamandroides), although Cope was reluctant to refer them to any known group. A large jaw bone with labyrinthodont teeth was associated with some of these vertebrae, but it was much larger than expected for the vertebrae and likely belonged to Eryops or some other larger amphibian. [8] D. salamandroides could be distinguished from D. magnicornis by its small size (from a fifth to a sixth the size of the latter) and less pronounced accessory articular processes (at the time identified as zygosphene-zygantrum articulations). [9]

The rocks in which these fossils were discovered had been informally referred to as the " Clepsydrops shales", named after a local genus of early synapsid by Cope in 1865. The shales were initially believed to be from either the Permian or Triassic periods in age based on the purported presence of reptile and lungfish fossils. By 1878, Cope had decided that the site was Permian. In 1908, E.C. Case noted that the shales also contain remains from fish which were from the late Carboniferous and early Permian periods. He argued that, while the Clepsydrops shales of Illinois and the similar red beds of Texas were evidently formed after the major Carboniferous coal deposits, there was not sufficient evidence to exclude them from the Carboniferous period itself. [10] Nowadays the Clepsydrops shales are typically assigned to the McLeansboro or Mattoon Formations. D. salamandroides fossils have also been found in Pennsylvania. These formations are now believed to be Missourian (late Carboniferous) in age. [7]

A skeletal diagram of Diplocaulus magnicornis by Douthitt (1917), with barred parts restored Douthitt Diplocaulus skeletal.png
A skeletal diagram of Diplocaulus magnicornis by Douthitt (1917), with barred parts restored

D. magnicornis

This species, described by Cope in 1882, is by far the most common and well-described member of the genus. D. magnicornis was the first species known from more than vertebrae, and it allowed Cope and other paleontologists to realize the nature of Diplocaulus as a bizarre long-horned "batrachian" (amphibian). [11] Much of modern knowledge on the genus is based on this species, as it outnumbers any other Diplocaulus remains by hundreds of specimens. D. magnicornis had a wide temporal distribution throughout the red beds of Texas and Oklahoma.

D. brevirostris

D. brevirostris was similar to D. magnicornis, although it was significantly more rare. It is represented by a small number of specimens found in an early strata of the Texas red beds, specifically the Arroyo Formation of the Clear Fork Group. This species can be differentiated from D. magnicornis by the much shorter and blunter snout compared to the length of the skull as a whole. In addition, the horns are more elongated, the parietals have a convex upper surface, and the rear edge of the skull is more strongly and smoothly curved. While juvenile members of D. magnicornis also have a smoothly curved rear edge of the skull, all known D. brevirostris specimens are clearly adults as shown by their robust skull ornamentation, long horns, and large size. Therefore, this trait is a legitimate distinguishing feature of adult specimens of this species. The only specimen known from more than a skull is the type specimen, AM 4470, which preserves some vertebrae similar to those of "D. primigenius". E.C. Olson, the original describer of the species, suggested that it occupied different habitats than D. magnicornis such as mountain streams, accounting for its comparative rarity. [5] However, other studies have suggested that D. magnicornis would have lived in similar environments, invalidating Olson's hypothesis. [3]

D. recurvatus

This species, from the Vale Formation of the Texas red beds, was very similar to D. magnicornis, and partially coexisted alongside that species in younger strata. Olson hypothesized that D. recurvatus may have been descended from an early stock of D. magnicornis. [12] D. recurvatus differs from D. magnicornis in one specific trait: the tips of the tabular horns are "crooked". The tips are bent relative to the rest of the horns, and abruptly taper. [13] Comparison to a growth series of D. magnicornis indicates that D. recurvatus specimens had developmental pathways which significantly differed from D. magnicornis. For example, skull length and width seem to be inversely correlated in D. recurvatus and directly correlated in D. magnicornis. [12] In addition, the restriction in the horns of D. recurvatus develops in an area which would otherwise expand in adult D. magnicornis. [6]

D. minimus

Diplocaulus minimus is a species known from the Ikakern Formation of Morocco. It had an unusually asymmetrical skull, with the left prong being long and tapering as in other species but the right prong being much shorter and more rounded. This feature was present in multiple skulls referred to this species, so it is very unlikely to be a result of crushing or distortion. Some studies have suggested that this species is more closely related to Diploceraspis than to Diplocaulus magnicornus. This may suggest that either Diplocaulus is not a true monophyletic genus, that Diploceraspis is a junior synonym of the genus, or that "Diplocaulus" minimus represents a distinct genus. [14]

Dubious species

Paleobiology

Function of the tabular horns

Various hypotheses have been put forth to the purpose of these horns. One of the earliest suggestions, provided by S.W. Williston in 1909, was that they protected external gills, [17] but in 1911 E.C. Case pointed out that there was slim evidence for this idea. [4] Another hypothesis was provided in a dissertation, published by University of Kansas professor Herman Douthitt in 1917, which focused entirely on the anatomy of Diplocaulus. Douthitt argued that the most undisputed function was that the horns acted as a counterweight to offset the heavily-built forward part of the head which would have been difficult to lift otherwise. However, he also noted that this was probably not their primary function, and that they may have been maladaptive developments "as the result of some internal metabolic derangement". [1]

In 1951, E.C. Olson suggested that the horns could have supported skin flaps capable of assisting the animal in skate- or stingray-like locomotion. However, he admitted that his suggestion was entirely conjectural considering a lack of soft tissue evidence. He also briefly proposed other possible functions, such as the use of the broad head as a burrowing tool to escape predators or survive droughts. [5] J.R. Beerbower revived the hypothesis that the horns were involved in respiration during his 1963 description of Diploceraspis , which was a close relative of Diplocaulus. His argument relied on the possibility that the horns supported operculum-like vertical pouches protecting external or internal gills. [2] One possibility is that the shape was defensive, since even a large predator would have a hard time trying to swallow a creature with such a wide head. [20]

Lift

A new hypothesis for the function of the horns was presented by South African paleontologist Arthur Cruickshank & fluid dynamicist B.W. Skews in a 1980 paper. They proposed that the tabular horns acted as a hydrofoil, allowing the animal to more easily control how water flows over its head. In the process of their investigation, Cruickshank & Skews developed a full-scale model of the head and a portion of the body of a Diplocaulus, constructed from balsa wood and modelling clay. The model was placed in a wind tunnel, and subjected to several tests to determine drag, lift, and other forces experienced by the head in different situations. [3]

The results showed that the horns generated significant lift, which would have allowed the animal to rise in the water column of a river or stream quite quickly and easily. Lift was present when the head was parallel to the flow of water (modeled by air), with lift increasing at a higher attack angle (angle above the horizontal) and only dropping once the head reached a high stall angle of 22 degrees. Lift and pitching moment was minimized at 1.5 degrees below the horizontal, which may have been the natural resting angle of the head. [3]

When the "mouth" of the model was opened, lift was barely affected, the pitching moment decreased, and drag only slightly increased. This indicates that Diplocaulus would not have been seriously disadvantaged if they chose to attack prey items while rising through the water. Cruickshank & Skews also glued numerous small spheres to the model in order to test how an irregular texture would affect the mechanics of the head. The highly irregular spheres drastically reduced lift and increased drag, but when they were rubbed off (leaving only the slightly irregular glue layer), the only major reduction in aerodynamic quality (compared to the smooth model) was that the stall angle decreased to 16 degrees. The study also inquired about the hydrodynamics of Diploceraspis, which lacked a flange on the underside of the horns which was present in Diplocaulus. When the flange was removed from the smooth model, the resulting lift forces started being generated at a lower angle, 6 degrees below the horizontal rather than 1.5. This may indicate that Diploceraspis was better adapted for slower streams, where immediate lift was prioritized over the more gradual lift created by the Diplocaulus model, which would have been able to take advantage of a swifter current. [3]

Paleoecology

A trio of three juvenile Diplocaulus in a burrow of eight (plus one juvenile Eryops ) were found to have been partially eaten by the sail-backed synapsid Dimetrodon , which likely unearthed the amphibians during a drought. One of the three was killed with a bite to the head, taking part of its skull and portions of the brain, a fatal injury that the animal could not defend against. [21]

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References

  1. 1 2 3 4 5 Douthitt, Herman (September 1917). "The Structure and Relationships of Diplocaulus" (PDF). Contributions from Walker Museum. 2 (1): 1–42.
  2. 1 2 3 Beerbower, J.R. (November 1963). "Morphology, paleoecology, and phylogeny of the Permo-Pennsylvania amphibian Diploceraspis". Bulletin of the Museum of Comparative Zoology. 130 (2): 31–108.
  3. 1 2 3 4 5 6 Cruickshank, A. R. I.; Skews, B. W. (1980). "The Functional Significance of Nectridean Tabular Horns (Amphibia: Lepospondyli)". Proceedings of the Royal Society B: Biological Sciences. 209 (1177): 513–537. doi:10.1098/rspb.1980.0110. S2CID   110443064.
  4. 1 2 3 4 5 Case, E.C. (1911). "Revision of the Amphibia and Pisces of the Permian of North America". Carnegie Institution of Washington Publication. 146: 15–91.
  5. 1 2 3 4 5 6 7 Olson, E.C. (12 January 1951). "Diplocaulus: A study in growth and variation". Fieldiana: Geology. 11 (2): 59–149.
  6. 1 2 3 Olson, Everett C. (September 1972). "Diplocaulus parvus n. sp. (Amphibia: Nectridea) from the Chickasha Formation (Permian: Guadalupian) of Oklahoma". Journal of Paleontology. 46 (5): 656–659.
  7. 1 2 Harris, Susan K.; Lucas, Spencer G.; Berman, David S.; Henrici, Amy C. (2005). "Diplocaulus cranial material from the lower Abo Formation (Wolfcampian) of New Mexico and the stratigraphic distribution of the genus". New Mexico Museum of Natural History and Science Bulletin. 30: 101–103.
  8. Cope, E.D. (2 November 1877). "Descriptions of Extinct Vertebrata from the Permian and Triassic Formations of the United States". Proceedings of the American Philosophical Society. 17 (1): 182–193.
  9. Case, E.C. (1900). "Contributions from Walker Museum. I: The Vertebrates from the Permian Bone Bed of Vermilion County, Illinois". The Journal of Geology. 8 (8): 698–729. doi:10.1086/620866.
  10. Case, E.C. (1908). "On the Value of the Evidence Furnished by Vertebrate Fossils of Age of Certain So-Called Permian Beds in America". The Journal of Geology. 16 (6): 572–580. doi:10.1086/621555. S2CID   128947959.
  11. Cope, E.D. (15 September 1882). "Third Contribution to the History of the Vertebrata of the Permian Formation of Texas". Proceedings of the American Philosophical Society. 20 (112): 447–461.
  12. 1 2 Olson, Everret C. (November 1953). "Integrating Factors in Amphibian Skulls". The Journal of Geology. 61 (6): 557–568. doi:10.1086/626128. S2CID   128813415.
  13. Olson, E.C. (27 June 1952). "Fauna of the upper Vale and Choza: 6, Diplocaulus". Fieldiana: Geology. 10 (14): 147–166.
  14. 1 2 Germain, Damien (27 May 2010). "The Moroccan diplocaulid: the last lepospondyl, the single one on Gondwana". Historical Biology. 22 (1–3): 4–39. doi:10.1080/08912961003779678. S2CID   128605530.
  15. Cope, E.D. (15 November 1895). "Some New Batrachia from the Permian of Texas". Proceedings of the American Philosophical Society. 34: 452–457.
  16. Broili, Ferdinand (14 June 1904). "Permische Stegocephalen un Reptilien aus Texas". Palaeontographica. 51: 1–120.
  17. 1 2 Williston, S.W. (1909). "The Skull and Extremities of Diplocaulus". Transactions of the Kansas Academy of Science. 22: 122–132. doi:10.2307/3624731. JSTOR   3624731.
  18. Case, E.C. (September 1946). "A Census of the Determinable Genera of the Stegocephalia". Transactions of the American Philosophical Society. 35 (4): 323–420. doi:10.2307/1005567. hdl: 2027/mdp.39015071637537 . JSTOR   1005567.
  19. Mehl, M.G. (1921). "A New form of Diplocaulus". Journal of Geology. 29 (1): 48–56. doi:10.1086/622753.
  20. Palmer, D., ed. (1999). The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals. London: Marshall Editions. p. 55. ISBN   978-1-84028-152-1.
  21. Zoehfeld, Weidner K.; Bakker, Robert T.; Flis, Chris J.; Pettersson, Carl B.; Bell, Troy H. (2013). "Abstract: BURROWS AND BREAK-INS ON THE TEXAS PERMIAN DELTA: STACKED AESTIVATING AMPHIBIANS AND ATTACKS BY DIMETRODON (2013 GSA Annual Meeting in Denver: 125th Anniversary of GSA (27-30 October 2013))". gsa.confex.com.
  22. Cf.