A New Lower Permian Trematopid (Temnospondyli ......2007; Schoch, 2009). While it may be argued that...
Transcript of A New Lower Permian Trematopid (Temnospondyli ......2007; Schoch, 2009). While it may be argued that...
A New Lower Permian Trematopid (Temnospondyli: Dissorophoidea) from Richards Spur, Oklahoma
by
Brendan Polley
A thesis submitted in conformity with the requirements for the degree of Master of Science
Department of Ecology and Evolutionary Biology University of Toronto
© Copyright by Brendan Polley 2009
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A new Lower Permian trematopid (Temnospondyli:
Dissorophoidea) from Richards Spur, Oklahoma
Brendan Polley
Master of Science
Department of Ecology and Evolutionary Biology University of Toronto
2009
Abstract
A new trematopid amphibian, Acheloma dunni, is reported based on excellently preserved cranial
and postcranial elements recovered from the Lower Permian fissure fill deposits of the Dolese
Brothers Co. limestone quarry near Richards Spur, Oklahoma. The new taxon is characterized by
distinct lateral exposures of the palatine (l.e.p.) and ectopterygoid (l.e.e.) completely enclosed
within the suborbital elements. This large, terrestrial adapted carnivore may represent the top
predator of the Richards Spur assemblage. A phylogenetic analysis including 11 ingroup taxa
and 54 cranial characters yielded a single most parsimonious tree, placing A. dunni within the
monophyletic Trematopidae as the sister taxon to Acheloma cumminsi. Furthermore, the analysis
supports including the enigmatic Ecolsonia and Actiobates within Trematopidae, forming a clade
with the Upper Pennsylvanian Anconastes and the Lower Permian Tambachia. The study is the
first to comprehensively analyze all valid and aberrant forms of Trematopidae within the context
of broader dissorophoid phylogeny.
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Acknowledgments
I am indebted to the many individuals whose support and guidance truly enriched this
challenging and rewarding year. Thank you to my supervisor, R. Reisz for being an unwavering
source of encouragement and direction. As you did for me, I will be sure to have faith in my own
students, treat them with respect, and push them to realize their potential.
I am grateful to D. Scott for her invaluable technical training, for photographing specimens, and
for, of course, her friendship. Thank you to my friends in the Reisz lab, N. Campione, J.
Fröbisch, N. Fröbisch, J. Hawthorn, D. Mazierski, and N. Wong Ken for all their advice and
support. Also, many thanks to my advisors D. Evans and D. Walsh for your guidance and
constructive feedback.
Special thanks to B. Dunn and M. Feese for their continuing efforts to collect fossils from
Richards Spur. This project, among countless others, would not have been made possible without
their generous donations to the Sam Noble Oklahoma Museum of Natural History.
I am grateful to D. Berman of the Carnegie Museum of Natural History, Pittsburgh, PA; R.
Ethington of the University of Missouri, Columbia, MO; M. Norell of the American Museum of
Natural History, New York, NY; and M. Ryan of the Cleveland Museum of Natural History,
Cleveland, OH for allowing me access to various trematopid specimens for study.
Finally, thank you to my family, friends, and especially J. Cawaling for their unconditional love
and support throughout the course of this project and beyond.
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Table of Contents
Acknowledgments.......................................................................................................................... iii
Table of Contents........................................................................................................................... iv
List of Figures ................................................................................................................................ vi
List of Appendices ....................................................................................................................... viii
1 Introduction ................................................................................................................................ 1
2 Materials..................................................................................................................................... 4
3 Abbreviations ............................................................................................................................. 6
3.1 Institutional Abbreviations.................................................................................................. 6
3.2 Anatomical Abbreviations .................................................................................................. 6
4 Systematic Paleontology ............................................................................................................ 7
4.1 Type Specimen.................................................................................................................... 7
4.2 Referred Specimens ............................................................................................................ 8
4.3 Diagnosis............................................................................................................................. 8
4.4 Occurrence .......................................................................................................................... 8
4.5 Etymology........................................................................................................................... 8
5 Description ................................................................................................................................. 8
5.1 General ................................................................................................................................ 8
5.2 Skull Roof ........................................................................................................................... 9
5.3 Palate................................................................................................................................. 13
5.4 Braincase........................................................................................................................... 15
5.5 Lower Jaw......................................................................................................................... 16
5.6 Axial Skeleton................................................................................................................... 17
5.7 Appendicular Skeleton...................................................................................................... 18
6 Discussion ................................................................................................................................ 20
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6.1 Phylogenetic Analysis....................................................................................................... 20
6.2 Habits and Lifestyle .......................................................................................................... 23
References..................................................................................................................................... 26
Figures and Captions..................................................................................................................... 35
Appendix 1.................................................................................................................................... 65
Appendix 2.................................................................................................................................... 67
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List of Figures
Figure 1. Reconstruction of skull of Acheloma dunni in A, dorsal view; B, ventral view; C, right
lateral view. Scale = 50 mm
Figure 2. Skull of Acheloma dunni, holotype (OMNH 73281) in dorsal view. Scale = 50 mm
Figure 3. Skull of Acheloma dunni, holotype (OMNH 73281) in right lateral view. Scale = 50
mm
Figure 4. Acheloma dunni, referred specimen (BMRP2007.3.4) in left lateral view. Scale = 10
mm
Figure 5. Acheloma dunni, referred specimen (BMRP2007.3.1) in right lateral view. Scale = 10
mm
Figure 6. Acheloma dunni, referred specimen (OMNH 52365). Partial right upper jaw
articulation in dorsal view. Scale = 10 mm
Figure 7. Skull of Acheloma dunni, holotype (OMNH 73281) in ventral view. Scale = 50 mm
Figure 8. Skull of Acheloma dunni, holotype (OMNH 73281) in occipital view. Scale = 50 mm
Figure 9. Partial left lower jaw of Acheloma dunni, holotype (OMNH 73281) in A, lateral view;
B, medial view; C, dorsal view; D, ventral view. Scale = 10 mm
Figure 10. Partial right lower jaw of Acheloma dunni, holotype (OMNH 73281) in A, lateral
view; B, medial view; C, dorsal view; D, ventral view. Scale = 10 mm
Figure 11. Acheloma dunni, referred specimen (OMNH 52365). Partial right lower jaw
articulation in A, lateral view; B, posterior view. Scale = 10 mm
Figure 12. Atlas-axis complex and associated cervical vertebrae of Acheloma dunni, holotype
(OMNH 73281) in A, right lateral view; B, left lateral view; C, anterior view. Scale = 10 mm
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Figure 13. Acheloma dunni, referred specimen (OMNH 52545). Right humerus in A, posterior
view; B, extensor view; C, anterior view; D, flexor view; E, proximal view; F, distal view. Scale
= 50 mm
Figure 14. Acheloma dunni, referred specimen (OMNH 73514). Partial pelvic girdle and
hindlimb. Scale = 5 mm. Illustration by Heidi Richter.
Figure 15. Single most parsimonious tree of dissorophoid relationships derived from cladistic
analysis using PAUP 4.0b10 with A, relevant synapomorphies mapped on (* indicates a
synapomorphy that supports the clade, but appears elsewhere in the tree); B, bootstrap (bold) and
Bremer decay (italics) values calculated for the analysis; TL, tree length; CI, consistency index;
RC, rescaled consistency index
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List of Appendices
Appendix 1. Data matrix used for phylogenetic analysis including 12 taxa and 54 characters. ‘a’
represents polymorophic characters (0&1)
Appendix 2. Descriptions of characters used in phylogenetic analysis. Characters 1-24 are
informative cranial characters based on Schoch and Rubridge (2005). Characters 25-38 are taken
from Ruta & Bolt (2006). Characters 39-54 are from literature as cited.
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1 Introduction The Dolese limestone quarry, situated near Richards Spur, Oklahoma is home to the most diverse
known assemblage of Paleozoic terrestrial tetrapods. Regular excavation of Ordovician Arbuckle
limestone has continually yielded fossil-rich clays and conglomerates (Olson, 1991). Although
often disarticulated, fossil material is abundant and well preserved, boasting representatives of
numerous different taxa (Reisz, 2007; Frobisch & Reisz, 2008). A significantly large proportion
of this fossil material (Daly, 1973; Olson, 1991) has been assigned to the small terrestrial
eureptile, Captorhinus aguti. Olson (1991) interpreted the relative abundance of C. aguti material
as indicative of an Early Permian age for the faunal assemblage. More specifically, he inferred
that the fauna of Richards Spur was contemporaneous with the Leonardian Arroyo Formation of
the Clear Fork Group of Texas (Olson, 1991). This assignment has been further supported by
biostratigraphic evidence based on the fauna recovered from the South Grandfield locality of
southern Oklahoma (Daly, 1973; Sullivan et al., 2000; Maddin et. al., 2006).
The Richards Spur assemblage represents a dramatic departure from contemporary Early
Permian faunas. Whereas the majority of North American localities typically yield faunal
samples consistent with aquatic, semi-aquatic, and terrestrial forms of lowland, deltaic
environments (Olson, 1952), the Richards Spur assemblage is comprised exclusively of small
and medium-sized terrestrial forms. This unique faunal composition has led to the suggestion
that the locality has preserved a predominantly arid, upland assemblage (Sullivan et al., 2000;
Anderson & Reisz, 2003; Schoch, 2009). Although rare, skeletal elements of larger taxa have
been reported from Richards Spur, corroborating the hypothesis that the distinct composition of
the fossil assemblage may have been the product of paleoecological factors, rather than
taphonomic biases (Sullivan et al., 2000). These large remains include isolated elements
assignable to a varanopid (Maddin et al., 2006), the sphenacodontid Thrausmosaurus (Evans et.
al., 2009), the dissorophid Cacops (Sullivan et al., 2000; Reisz et al., 2009), a large trematopid
suggested to be Acheloma (Bolt, 1974a; Shultze & Chorn, 1983; Sullivan et al., 2000),
Seymouria (Sullivan & Reisz, 1999), and an unidentified eryopid, possibly Eryops (Olson, 1991).
Similar to the typical smaller taxa, the large forms recovered from Richards Spur appear to
represent taxa that were primarily terrestrial. As early amniotes, there is little doubt that the
varanopid and sphenacodontid were well suited for life on land. Dissorophids and trematopids,
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collectively forming the clade Olsoniformes, are considered the most terrestrial representatives
of late Paleozoic temnospondyl amphibians (Bolt, 1969; Berman et al., 1987; Sumida et al.,
1998; Dilkes & Brown, 2007; Markey & Marshall, 2007; Schoch, 2009). Likewise, authors agree
Seymouria was principally terrestrial, dependant on an aquatic habitat only during reproduction
and very early growth stages (Sullivan & Reisz, 1999; Berman et al., 2000; Klembara et al.,
2007; Schoch, 2009). While it may be argued that eryopids may have been aquatic or semi-
aquatic, the identification of the skull fragment as Eryops is doubtfull, and the fragment is not
diagnostic. In fact, we propose that it is more appropriate to designate the skull fragment as
Temnospondyli incertae sedis.
Described here is a new large trematopid skull (OMNH 73281) collected from Richards Spur in
2006. While trematopids were previously known from Richards Spur on the basis of isolated,
fragmentary elements, the newly recovered skull is nearly complete, showing little distortion.
This material represents the largest recorded taxon of the Richards Spur assemblage, rivaling the
varanopid described by Maddin et al. (2006) in size. Trematopids form a monophyletic clade of
poorly understood temnospondyl amphibians known from the Late Pennsylvanian and Early
Permian of North America and central Germany (Berman et al., 1987; Dilkes, 1990; Sumida et
al., 1998). The taxonomic history of Trematopidae is long and convoluted and while the
monophyly of the clade has remained largely unquestioned, the group as a whole has yet to be
subject to rigorous phylogenetic analysis.
Trematopidae, as erected by Williston (1910) was originally a modest group, including only two
taxa known from Lower Permian type specimens: Acheloma cumminsi (Cope, 1882) and
Trematops milleri (Williston, 1909). In 1926, Mehl described an additional species of
Trematops, T. thomasi; however, the family remained largely unexamined until Olson’s (1941)
comprehensive study. In his review, he erected several new species of Acheloma and Trematops:
A.pricei, A.whitei, and T.willistoni. He later expanded the family by describing Trematopsis
seltini (Olson, 1956) and Trematops stonei (Olson, 1970). The type specimen of Trematopsis
was later found to be a junior synonym of Cacops (Milner, 1985b). Moreover, Olson was first to
recognize the close affinities between trematopids and the diverse group of terrestrially adapted
amphibians of the family Dissorophidae. Dissorophids span a greater temporal and geographic
range than trematopids and are distinguished from trematopids by the possession of armored
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dermal plates associated with the neural spines and the absence of an elongated external naris
(Olson, 1941; Carroll, 1964a; DeMar, 1966b; DeMar, 1968).
Subsequent authors also recognized the close relationship of trematopids and dissorophids
(Vaughn, 1969; Berman et al. 1985; 1987; Dilkes, 1990; Daly, 1994; Sumida et al., 1998;
Anderson et al., 2008). However, because ingroup relationships of both families remained
largely unresolved, several taxonomic problems arose when forms seemingly possessing a
combination of trematopid and dissorophid characters were discovered and described. Mordex
calliprepes and Parioxys ferricolus were both originally described as trematopids (Romer, 1947).
Mordex was later synonymized with Amphibamus (Carroll, 1964a) only to be resurrected as a
dissorophid with a trematopid-like elongated external naris (Milner, 1986). Presently, Mordex is
in the process of once again being reclassified as a basal trematopid (Milner, 2007). Parioxys is
still considered closely related to dissorophids, but has been removed from Trematopidae and
placed within its own family, Parioxyidae (Mustafa, 1955; Carroll, 1964b).
Longiscitula houghae (DeMar, 1966a) was originally described as possessing both a trematopid-
like external naris and the distinctive dermal armor of dissorophids. Reexamination of the type
specimen revealed the apparent elongated external naris was an artifact of preservation (Bolt,
1974c). Milner (2003) eventually synonymized L. houghae with Dissorophus multicintus. The
enigmatic Ecolsonia cutlerensis was described as sharing affinities with dissorophids but was
tentatively assigned to Trematopidae by Vaughn (1969) based on its elongated external naris and
lack of exostoses and armor. Berman et al. (1985) argued the skull proportions and structure of
the otic notch of Ecolsonia were in fact indicative of dissorophid affinities, and that its elongated
external naris evolved convergently. Daly (1994) incorporated Ecolsonia into her study of
dissorophoid relationships but was unable to resolve its assignment (Sumida et al., 1998). Eaton
(1973) described the Late Pennsylvanian Actiobates peabodyi as a dissorophid; however, he
stipulated that the distinction between trematopids and dissorophids was nonexistent and all taxa
assigned to both families should fall under Dissorophidae. Later authors that recognized both
families agree Actiobates is a trematopid possibly exhibiting an early stage of development
(Berman et al., 1985; Milner, 1985; Daly, 1994). Partly for these reasons, both Ecolsonia and
Actiobates have been excluded from most cladistic analyses of trematopid relationships (Berman
et al. 1987; Dilkes, 1990; Sumida et al. 1998).
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Currently, Trematopidae consists of five known genera. Actiobates peabodyi is at least
provisionally still a valid trematopid (Berman et al., 1987; Milner, 1985; Dilkes, 1990; Daly,
1994; Sumida et al., 1998). Anconastes vesperus (Berman et al., 1987) represents a Late
Pennsylvanian trematopid from Texas. Dilkes and Reisz (1987) found Trematops milleri to be a
junior synonym of Acheloma cumminsi, and retained the name Acheloma for the genus. Dilkes
(1990) synonymized the small Early Permian trematopid taxa erected by Olson (1941) into a new
genus, Phonerpeton pricei. Finally, the Early Permian Tambachia trogallas (Sumida et al., 1998)
recovered from central Germany represents the most recent addition to the family. Here we
describe a new species of trematopid and comprehensively revaluate the interrelationships of
trematopids using phylogenetic analysis. Furthermore, this study is the first to include the
aberrant Ecolsonia and Actiobates in an analysis of trematopid ingroup relationships in an
attempt to resolve their taxonomic positions and define Trematopidae.
2 Materials The holotype, OMNH 73281, consists of an exceptionally preserved skull measuring 164 mm
along its midline. The skull has experienced no crushing but has been slightly sheared to the
right. All other damage appears to have occurred as a result of the blasting and transport
operations of the quarry from which it was recovered. The antorbital region of the left side of the
skull is substantially damaged and remains unprepared. The rest of the skull has been prepared
and shows little sign of damage with the following exceptions: the posterior portion of the
quadratojugals and tabulars are broken, while the quadrates are missing entirely. Also, a break is
present along the roof of the skull between the frontal and nasal, extending onto a portion of the
prefrontal. The palate has been extensively prepared; leaving only a small area along the medial
edges of the right premaxilla and maxilla obscured by matrix and a tightly associated captorhinid
lower jaw. Only the most anterior portions of the lower jaws are present but remain
disarticulated. The atlas-axis complex is present along with disarticulated elements comprising
the third and fourth cervical vertebrae.
The referred specimens consist of well-preserved large postcranial elements, jaw joint, and two
small partial skulls. The pelvic girdle OMNH 73514 is nearly complete and allied with a femur,
tibia, fibula, and disarticulated elements of the pes. OMNH 52365 consists of partial elements
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comprising the jaw articulation. OMNH 52545 is a complete right humerus. BMRP2007.3.4 is a
small partial skull measuring 56 mm along its dorsal midline. It appears to have been extensively
acid prepared, leaving the dermal sculpturing severely eroded but all sutures clearly visible. The
anterior most half of the skull is absent along with the braincase, palate and most of the lower
jaw. BMRP2007.3.1 is a partial skull consisting only of the antorbital bar and its associated
cheek region.
The holotype of Acheloma cumminsi (AMNH 4205) was examined for anatomical comparison.
The material consists of a nearly complete but substantially crushed skull, a string of 22
articulated presacral vertebrae, both scapulocoracoids, and both humeri. Also examined, was the
type specimen of Acheloma stonei (CMNH 10969), represented by a distorted partial skull. The
specimen was observed for comparative purposes but left out of analysis due to its lack of
informative characters. A cast of the only specimen of Acheloma thomasi (MU 501) was also
made available for study.
Specimens of almost all other trematopid taxa were also available for study, including the
holotype (CM 41711) and paratype (CM 28590) of Anconastes vesperus; the holotype (UCLA
VP 1734) and paratypes (CM 38017; CM 41703) of Ecolsonia cutlerensis; and the holotype
(MNG 7722) of Tambachia trogallas.
Observations of Phonerpeton pricei were based on a complete skull with partial postcranial
skeleton (AMNH 7150) and published reconstructions (Dilkes, 1990).
Specimens of Actiobates peabodyi were not examined. Comparisons and character coding was
accomplished using published illustrations and descriptions (Eaton, 1973; Milner, 1985a).
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3 Abbreviations
3.1 Institutional Abbreviations
AMNH, American Museum of Natural History, New York, NY; BMRP, Burpee Museum of
Natural History, Rockford, IL; CM, Carnegie Museum of Natural History, Pittsburgh, PA;
CMNH, Cleveland Museum of Natural History, Cleveland, OH; MCZ, Museum of Comparative
Zoology, Harvard University, Cambridge, MA; MNG, Museum der Natur, Gotha, Germany;
MU, University of Missouri, Columbia, MO; OMNH, Sam Noble Oklahoma Museum of
Natural History, University of Oklahoma, Norman, OK; UCLA VP, University of California,
Los Angelas, CA.
3.2 Anatomical Abbreviations
a, angular; art, articular; at, atlas; axn, axial neural spine; axi, axial intercentrum; bo,
basioccipital; c, centrale; c3, third cervical vertebra; c4, fourth cervical vertebra; cr, cervical rib;
ct, cultriform process; d, dentary; ect, ectopterygoid; eo, exoccipital; f, frontal; fe, femur; fi,
fibula; i, intermedium; il, ilium; in.f, internarial fenestra; is, ischium; j, jugal; l, lacrimal; l.e.e.,
lateral exposure of the ectopterygoid; l.e.p., lateral exposure of the palatine; m, maxilla; n, nasal;
obt, obturator foramen; op, opisthotic; p, parietal; paf, para-articular foramen; pal, palatine; pc,
pleurocentrum; pco, precoronoid; pf, postfrontal; pm, premaxilla; po, postorbital; pp,
postparietal; pra, prearticular; prf, prefrontal; ps, parasphenoid; pt, pterygoid; ptf, post temporal
fenestra; pu, pubis; q, quadrate; qj, quadratojugal; s, stapes; sa, surangular; se, sphenethmoid;
sm, septomaxilla; so, supraocciptal; sp, splenial; sq, squamosal; st, supratemporal; t, tabular; ti,
tibia; tib, tibiale; v, vomer
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4 Systematic Palaeontology Temnospondyli Zittel, 1888
Euskelia Yates and Warren, 2000
Dissorophoidea Bolt, 1969
Olsoniformes Anderson et al., 2008
Trematopidae Williston, 1910
4.1 Revised Diagnosis
The clade consisting of Acheloma cumminsi and all other taxa that share a more recent common
ancestor with A. cumminsi than with Dissorophus.
Acheloma Cope, 1882
4.2 Revised Generic Diagnosis
Large trematopid temnospondyl characterized by the following autapomorphies: toothed, raised
crest running anteroposteriorly along the vomer, mesial to the choana; otic notch with a nearly
horizontal ventral margin.
Acheloma dunni, sp. nov.
(Fig. 1-14)
4.3 Type Specimen
OMNH 73281, nearly complete skull with associated atlas-axis complex and partial lower jaw.
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4.4 Referred Specimens
BMRP2007.3.4, small trematopid skull; BMRP2007.3.1, trematopid snout; OMNH 52365, jaw
articulation; OMNH 73514, pelvic girdle; OMNH 52545, right humerus
4.5 Diagnosis
Large trematopid temnospondyl amphibian distinguished from all other trematopids by
sculptured lateral exposures on skull roof of both palatine and ectopterygoid that are excluded
from the ventral margin orbit by the lacrimal and jugal. Differs from Acheloma cumminsi in
having a relatively narrower and less robust snout, and a proportionally smaller internarial
fenestra.
4.6 Occurrence
Dolese Brothers Co. limestone quarry, near Richards Spur, Comanche County, Oklahoma;
fissure fill deposits in Ordovician Arbuckle limestone probably equivalent to Leonardian Arroyo
Formation of Clear Fork Group, Lower Permian.
4.7 Etymology
The specific name honors Brent Dunn, who has graciously collected and donated several
specimens from the Dolese Brothers Co. limestone quarry for study.
5 Description
5.1 General
As observed in all other trematopids (Berman et al., 1987; Dilkes, 1990; Sumida et al., 1998), the
skull of Acheloma dunni is tall, box-like, and roughly triangular in shape (Fig.1 & 2). The
surface of the skull roof is covered in deep, rounded dermal pitting, about uniform in shape.
Overall, the skull most closely resembles Acheloma cumminsi in its large size, the presence of an
enlarged, elongate key-hole shaped, external narial opening, and slitlike otic notch with broad,
overhanging shelf (Dilkes & Reisz, 1987). However, while the skull roof of OMNH 73281 is
slightly larger in both overall length and width than the holotype of A. cumminsi (AMNH 4205),
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the snout of A. dunni is narrower and considerably less robust. Descriptions are based primarily
on OMNH 73281 and others specimens as cited.
5.2 Skull Roof
The premaxilla of A. dunni has a well-developed posterodorsal alary process, lapping onto the
anterolateral area of the nasal. An internarial fenestra measuring 3 mm in diameter is situated
along the midline suture between the premaxillae. The same structure is present in the type
specimen of A. cumminsi but is proportionately larger, measuring 7 mm in diameter. A
proportionately large internarial fenestra is also present in Phonerpeton (Dilkes, 1990), while the
structure appears to be completely absent in all other trematopids (Berman et al., 1985; Berman
et al., 1987; Dilkes, 1990; Sumida et al., 1998). The presence of an internarial fenestra is not
exclusive to trematopids as it is found in a variety of other taxa, including the dissorophid
Cacops (Bolt, 1977a, Reisz et al. 2009. Mehl (1926) described the partial snout of the Lower
Permian trematopid Acheloma thomasi (as Trematops thomasi) from Snyder, Oklahoma that
possessed a reduced or perhaps absent internarial fenestra. Authors have generally accepted
Olson’s (1941) suggestion that A. thomasi is a junior synonym of A. cumminsi (as T. milleri),
although the assertion was made only under the condition that the internarial fenestra was in fact
present. Mehl did not list a specimen number in his description and it appears the only record of
A. thomasi material is of a cast of the type specimen (MU 501) in the University of Missouri at
Columbia collections (Katz, 2008). The cast is in poor condition; however, it is informative
enough to indicate the internarial fenestra is absent.
Seven teeth are preserved on each premaxilla, along with another six empty alveoli. Initially,
there is a steady increase in size of teeth posteriorly, with the largest being in the ninth or tenth
tooth position. The last three teeth in the premaxillary series decrease in size posteriorly. The
preserved teeth on the maxilla exhibit a similar pattern, at first increasing in size posteriorly and
reaching their maximum size at about the seventh or eighth tooth position, beneath the posterior
margin of the external naris. The remaining teeth gradually decrease in size posteriorly. There
are 18 preserved teeth on the right maxilla with spaces for at least ten more. The maxilla is a long
slender element, stretching posteriorly past the level of the anterior border of the otic notch. The
maxilla has the greatest dorsal expansion at the level of the largest teeth, beneath the enlarged
external narial opening. Its dorsal edge makes up the majority of the ventral border of the
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external naris where the maxilla also has a well-developed medial shelf that forms the floor of
the external naris.
The conspicuous elongated external narial opening, often cited as the defining character of
trematopids (Olson, 1941; Vaughn, 1969; Olson, 1970; Eaton, 1973; Daly, 1994), is bordered by
the premaxilla, maxilla, nasal, prefrontal, and lacrimal. The increase in the height of the maxilla
in conjunction with a lateral expansion of the nasal along the margin of the external naris,
partitions the external naris into distinct anterior and posterior sections. This gives the narial
opening an overall keyhole shape (Fig. 3). The dorsal expansion of the maxilla occurs just
posterior to the area where the septomaxilla is located in the opening in all other trematopids
(Sumida et. al., 1998), including Ecolsonia, delineating the posterior extent of the functional
external naris (Bolt, 1974c; Berman et. al., 1987; Dilkes, 1993). Although the septomaxilla is not
preserved in A. dunni, it probably was in a similar position. A laterally concave, smooth lamina
known as the narial flange (Dilkes, 1990; Dilkes, 1993) descends from the ventral surface of the
skull roof and lies in close association with the external naris. Comprised of contributions of the
nasal, prefrontal, and lacrimal, the narial flange makes broad contact with the antorbital bar. This
condition is common among other trematopid taxa (Eaton, 1973; Berman et. al., 1987; Dilkes &
Reisz, 1987; Dilkes, 1990; Sumida et al., 1998). A narial flange has been found in other
dissorophoids including Doleserpeton (Bolt, 1974c; Carroll, 1964a; Reisz et. al., 2008);
however, the structure does not appear to contact the antorbital bar in any of these taxa. A narial
flange in this case is visible in the holotype of Ecolsonia in cross section; however, the
configuration of the narial flange cannot be confirmed because the area surrounding the
antorbital bar remains absent or unprepared in all specimens.
The external naris of A. dunni is floored by the vomer and palatine. The choana lies well anterior
to the posterior margin of the external naris as in A. cumminsi (Dilkes & Reisz, 1987). The
posterior border of the choana is in line with the posterior margin of the external naris in all other
trematopids (Eaton, 1973; Berman et. al., 1985; Berman et. al., 1987; Dilkes, 1993; Sumida et.
al., 1998). A partially prepared sheet of bone is exposed medial to the narial flange. It appears to
be the dorsally directed laminar process running along the midline of the rostrum, referred to as
the median vomerine septum by Dilkes (1990). This structure is present in A. cumminsi,
Phonerpeton (Dilkes, 1990), and was also revealed in Anconastes and Tambachia (Sumida et.
al. 1998). Examination of the holotype of Ecolsonia (UCLA VP 1734) indicates a median
11
vomerine septum is present. Contact between the skull roof and the median vomerine septum can
be confirmed in only A. cumminsi (Dilkes & Riesz, 1987); however, the same structure
approaches the skull roof but does not contact it in Phonerpeton (Dilkes, 1990), and in
Ecolsonia. The dorsal extent of the median vomerine septum is unknown in either specimen of
Anconastes (CM 41711; CM 28590) or Tambachia (MNG 7722). If the median vomerine septum
made even cartilaginous contact with the skull roof, the strut-like structure may have supported
compressive and shearing forces acting on the rostrum and vomers respectively during feeding.
Anteriorly, the vomerine walls bifurcate, contacting the ventrolateral surfaces of the premaxillae.
The lacrimal makes up the ventral half of the antorbital bar, contributing to both the
posteroventral margin of the external narial opening and the anteroventral margin of the orbit.
Anteriorly, the bone has a relatively short subnarial process, suturing bluntly with the dorsally
expanded portion of the maxilla (Fig. 3). A short subnarial process is also present in Tambachia
and Actiobates (Sumida et. al., 1998). In other trematopids, the lacrimal extends anteriorly to a
point about level with the subdivision of the external narial opening.
The prefrontal is a triangular shaped bone that makes up the dorsal half of the antorbital bar.
Anteriorly, it contributes to the posterodorsal margin of the external narial opening. The posterior
process of the prefrontal forms the anterodorsal margin of the orbit and makes contact with the
frontal. The prefrontal does not contact the postfrontal; instead, the frontal separates the two
elements and contributes to the dorsal border of the orbit.
The jugal is tall and broad, spanning most of the length of the cheek region. Dorsally, it
contributes to the circumorbital series by forming the ventral margin of the orbit. It extends
ventrally to meet the maxilla near the posterior limit of the latter. The posterior-most portions of
the jugal form a tall slightly curved wedge, contacting the squamosal dorsally, and the
quadratojugal posteroventrally.
The most intriguing feature of A. dunni is the presence of several distinct exposures of sculptured
bone visible on the lateral surface of the cheek region. The roughly oval shaped elements lie
adjacent to one another, bordered ventrally by the maxilla and dorsally by the lacrimal and jugal.
Three separate elements can be seen in OMNH 73281 and BMRP2007.3.4 (Fig. 4). The most
anterior element appears to be a lateral exposure of the palatine (l.e.p.). It is comprised of a
sculptured lateral expansion of a portion of the palatine lying just posterior to the palatal fang
12
and replacement pit. Posterior to the l.e.p. is a small lateral exposure of the ectopterygoid (l.e.e.),
consisting of only the most anterior portion of the ectopterygoid. The third and largest exposure
is formed by a secondary lateral expansion of the ectopterygoid associated with the lateral
margin of the socket housing the ectopterygoid fang and replacement pit. A similar pattern is
observed in BMRP2007.3.1 although it would appear that the lateral exposures of the
ectopterygoid are fused (Fig. 5).
Occurrences of an l.e.p. and l.e.e. have been reported in only dissorophoids and the
trimerorhachoids Isodectes and Saurerpeton (Godfrey et al., 1987). An l.e.p. and l.e.e. have been
recognized in the trematopid Phonerpeton, although the relationship between the two exposures
vary between specimens (Dilkes, 1990). Neither an l.e.p. nor l.e.e. are present in Actiobates,
Anconastes, Ecolsonia or Tambachia (Eaton, 1973; Berman et al., 1985; Berman et al., 1987;
Sumida et al., 1998). Although all four taxa possess relatively large orbits and narrow suborbital
bars, it is the maxilla and not the palatine or ectopterygoid that contributes to the ventral margin
of the orbit. Examination of the holotype of A. cumminsi confirms previous accounts that neither
an l.e.p. nor l.e.e. are present (Bolt, 1974b; Dilkes & Reisz, 1987).
Posteriorly, the orbit is bordered by the postfrontal and postorbital (Fig. 3). Both bones are
roughly triangular in shape. The postfrontal contacts both the frontal and parietal medially, and
the supratemporal posteriorly. The postorbital is a narrow element forming a broad, interdigitated
suture with the squamosal. Only the dorsal and ventral-most points of the postorbital make
constricted contact with the supratemporal and jugal respectively. Together, the postfrontal,
postorbital and squamosal form a narrow area of bone separating the orbit and the otic notch.
The squamosal is a large element, forming a substantial portion of the otic notch. The sculptured
lateral margin of the embayment of the squamosal appears horizontal in outline in its most
anterior portion. Medially, the squamosal has an internally directed flange that makes up the
ventral surface of the otic notch. The flange is deflected ventrally at a gradual angle, and contacts
the quadratojugal posteriorly. Together, the squamosal, supratemporal, and tabular contribute to
the dorsal margin of the otic notch. The bones form a deep posterolaterally directed
supratympanic shelf overhanging a well-defined, unsculptured supratympanic flange. Presence of
a supratympanic shelf has been confirmed in A. cumminsi and Phonerpeton; however, the
supratympanic shelf appears to be replaced by sculpturing covering the lateral area above the otic
13
notch in both Ecolsonia and Tambachia. The area above the otic notch is unpreserved and
undescribed in Anconastes and Actiobates respectively.
Dorsally, the squamosal slopes ventrally to form the majority of the anteroposteriorly directed
supratympanic flange. The slope of the squamosal constricts the otic notch dorsoventrally;
however the bone lacks the distinct semilunar curvature observed in other dissorophoids. Among
trematopids, a semilunar curvature of the squamosal has been recorded in Ecolsonia,
Phonerpeton, and Tambachia (Berman et. al., 1985; Dilkes, 1990; Sumida et. al., 1998). A
semilunar curvature of the squamosal is absent in A. cumminsi, while the area is unpreserved in
Anconastes (Berman et. al., 1987). Posteriorly, the squamosal contacts the tabular, excluding the
semilunar flange of the supratemporal (Bolt, 1974a) from the ventral margin of the
supratympanic flange. The posterior extent of the tabulars is unknown in all specimens of A.
dunni.
OMNH 52365 preserves the posterior most portion of the otic notch (Fig. 6). The posteroventral
margin of the squamosal slopes ventrally lapping onto the quadratojugal. The quadratojugal
forms the posterior end of the otic notch before curving sharply dorsally and contributing to the
lateral surface of a robust, rounded jaw articulation. A medially projecting process of the
quadratojugal contacts the quadrate. The quadrate is a narrow, unsculptured bone forming the
posterolateral corner of the skull. The dorsal surface of OMNH 52365is slightly damaged and
what would appear to be the dorsal process of the quadrate has broken off.
5.3 Palate
The vomers are densely covered with small, recurved teeth. Anteriorly, the vomers are smooth,
deflected laterally and contact the premaxillae. The dorsal extent of the bones contacts the nasals,
forming a deep internarial pit (Fig. 7). The ventral area of the internarial fenestra is visible in this
vicinity and appears laterally expanded with respect to its dorsal compliment. A prominent shelf
housing a large fang with a replacement pit on each vomer overhangs the posterior margin of the
internarial pit and is level with the anterior margin of the choana. An additional set of accessory
fang pairs are situated directly posterior to the larger fangs. A distinct toothed, raised crest runs
anteroposteriorly along the medial border of the choana. The same crest has been observed in
some primitive temnospondyls (Ruta & Bolt, 2006). The crest continues onto a posterolateral
process of the vomer that flanks the medial edge of the palatine and contacts the pterygoid.
14
The ventral surface of the palatine is mainly occupied by a massive fang and a large replacement
pit. As mentioned above, the palatine forms the posterior border of the choana. Medially, the
palatine is excluded from the interpterygoid vacuity by contact between the vomer and the
palatal ramus of the pterygoid. In most dissorophoids, contact between the vomer and pterygoid
is lost and the palatine and/or ectopterygoid contribute to the lateral margins of an expanded
interpterygoid vacuity. Retention of the vomer-pterygoid contact and a rather narrow
interpterygoid vacuity is common among trematopids but considered primitive (Berman et. al.,
1985; Berman et. al., 1987; Dilkes & Reisz, 1987; Dilkes, 1990; Sumida et. al., 1998). In most
dissorophoids, contact between the vomer and pterygoid is lost and the palatine and/or
ectopterygoid contribute to the lateral margins of an expanded interpterygoid vacuity.
Posteromedially, the palatine has a small, toothed, ridge-like swelling that contacts the pterygoid.
The ectopterygoid is a smaller palatal element than either the palatine or the pterygoid, but still
houses a large fang and replacement pit. The overall size of the ectopterygoid teeth does not
exceed that of the marginal teeth in A. cumminsi (Dilkes & Reisz, 1987). Although the tips of the
fangs are broken in OMNH 73281, the teeth of A. dunni are clearly larger than any of the
preserved marginal teeth. Posteriorly, the ectopterygoid forms the rounded anterior border of the
adductor fossa. Similar to the palatine, a raised toothed ridge runs posterolaterally along the
ectopterygoid onto the pterygoid.
The right pterygoid of OMNH 73281 is nearly complete, missing only the posteriormost portion
of the quadrate ramus. The entire palatal ramus and basipterygoid region of the pterygoid are
covered in a dense shagreen of small teeth, whereas the quadrate ramus appears smooth.
Although slightly damaged, a curved transverse flange runs along the posterior margin of the
palatal ramus into the adductor fossa. The dorsomedially directed internal process of the
basipterygoid region makes broad contact with the basipterygoid process of the parasphenoid.
The basicranial joint is firmly sutured and immobile. Examination of AMNH 4205 reveals that
the basicranial joint of A. cumminsi is also sutured, and not indistinguishably fused as described
by Dilkes & Reisz (1987). The basicranial joint is mobile in Anconastes and Tambachia (Sumida
et. al., 1998)
15
5.4 Braincase
The parasphenoid is complete and visible in ventral view of the skull (Fig. 8). The long, narrow
cultriform arches along the midline of the skull, reaching its maximum height at point about level
with the center of the orbit. While the tapered anterior end of the cultriform process undoubtedly
reached the vomers, the area remains damaged and details of attachment between the elements
are unknown. Dorsally, the cultriform process articulates with an ossified sphenethmoid. The
sphenethmoid contacts tightly the ventral surface of the frontal and postfrontal. The body of the
parasphenoid is rectangular, extending thin laterally expanding wings posteriorly. A deep
anteroposterior depression runs medially along the ventral surface. A distinct triangular patch of
tiny teeth sits on a transverse, tall ridge medial to the basipterygoid processes. The denticles
extend only onto the posterior tip of the cultriform process. The absence of parasphenoidal
dentition was used to unite Acheloma and Phonerpeton (Dilkes, 1990); however, reexamination
of AMNH 4205 indicates that small teeth are in fact present on the parasphenoid of A. cumminsi
but only the most proximal borders of the dentition have been preserved. Among dissorophoids
in which the area is known, only Broiliellus and Dissorophus lack parasphenoidal dentition
(Sumida et. al., 1998).
The basioccipital is tightly associated with the parasphenoid and only enough of the bone has
been prepared to confirm its presence. The basioccipital joins the exoccipitals to form the
occipital condyle; however, the suture between the two elements is not visible. The exoccipitals
are slightly narrow ventrally and form the lateral borders of the foramen magnum. Each
exoccipital makes contact with the posterolateral edge of the occipital flange of the postparietals.
Interestingly, dorsal to this contact, the exoccipitals appear robust, and medially expanded,
forming the majority of the dorsal margin of the foramen magnum. In the only specimen of
Acheloma stonei (CMNH 10969) and Phonerpeton, this area consists of a gap, partially
separating the exoccipitals and postparietals. The same gap is present in the aberrant
temnospondyl Platyhystrix and is interpreted as evidence of a cartilaginous supraoccipital
(Berman, 2000).
It is possible that the robust dorsal expansion of the exoccipitals of A. dunni represents an
ossified suproccipital fused to the exoccipitals. Within temnospondyls, similar ossifications
thought to be homologous to the suprocciptial have been recorded in Eryops and Edops (Berman,
16
2000). Orginally, Carroll’s (1964) description of Dissorophus angustus included an account of a
supraoccipital similar to that of A. dunni; however, according to the character coding of Laurin &
Reisz (1997), the supraoccipital is absent. The only other recorded instance of an ossified
supraoccipital within Temnospondyli is in Schoch’s (1999) description of the braincase of
Kamacops acervalis. However, the structure of the supraoccipital of Kamacops differs greatly
from that of A. dunni and other temnospondyls. Whereas, the suppraoccipital appears fused to
the exoccipitals in A. dunni, in Kamacops the bone fuses with the opisthotics, separating the
exoccipitals from the postparietals in a manner similar to its homologue in microsaurs,
lysorophids, amniotes, and diadectomorphs (Schoch, 1999; Berman, 2000
Both stapes are complete and preserved in place (Fig.1 & 8). The thin anteroposteriorly
compressed shaft is curved with its distal end fitting into an open posteroventral notch along the
supratympanic flange. A distinct stapedial foramen is visible on the posterior surface of the
footplate (Fig.7 & 8). The foramen is considered primitive in temnospondyls (Daly, 1994), but is
retained in all trematopids. The footplate is roughly tetrahedral in shape and sutures to the basal
plate of the parasphenoid ventrally. The rest of the footplate contacts the fenestra ovalis. This
configuration is common within Temnospondyli and may have been mobile in a pump-handle
fashion (Bolt & Lombard, 1984).
5.5 Lower Jaw
The lower jaw is represented by fragmentary material (OMNH 73281) consisting of the anterior
most portions of the dentary, precoronoid, and splenial (Fig. 9 & 10). The dorsal surface of the
dentary is smooth, housing a large fang and a replacement pit medially. The posterior extent of
the bone is missing, making an exact count of dentary teeth impossible. The dentary sutures with
the precoronoid along a distinct dorsal depression, where a large foramen is present posterior to
the dentary fang. A dense patch of small teeth occupies a narrow band along the dorsal surface of
the precoronoid. Ventromedially, the precoronoid contacts the splenial along a deep
anteroposteriorly directed groove. The groove continues anteriorly, deflecting dorsally and
creating a medially situated gap in the sutural surface of the symphysis. The symphysis consists
mainly of the dentary with smaller posterior contributions from the splenial and precoronoid.
OMNH 52365 preserves the posterior corner of the lower jaw (Fig. 11). The surangular and
articular are robust, forming the articulating surface of the lower jaw. Medially, a greatly
17
interdigitated suture separates the surangular from prearticular and angular. The para-articular
foramen is visible on the posteromedial surface of the prearticular.
5.6 Axial Skeleton
Slightly disarticulated anterior vertebral elements were recovered in close association with
OMNH 73281 (Fig. 12), including the atlas-axis complex and portions of the third and fourth
vertebrae. Several fragments of tall, wing-like cervical ribs flank the vertebral column on either
side. Although each structure appears to be in its correct relational position, each vertebral
element has been rotated counterclockwise. The altas-axis complex is a massive structure
exhibiting an interesting configuration. The atlantal neural arches are present but only the right
half appears to be complete. Both elements are oriented dorsally and are greatly separated from
their counterpart medially by a single robust anterior expansion of the axial neural spine.
Williston (1909) described a similar orientation of the neural arches in A. cumminsi (as
Trematops milleri). The prezygapophyses are oriented almost vertically, probably articulating
with paired proatlantal elements. The postzygapophyses are comparably more prominent and
horizontally directed. The atlantal neural arches are fused to the centrum with no distinguishable
suture, as observed in Doleserpeton (Bolt, 1969; Bolt, 1977b) and Amphibamus (Carroll, 1964;
Daly, 1994). The body of the centrum is unipartite, consisting of one or more fused elements. A
distinct laterally constricted body and ventral keel are typical features of rhachitimous intercentra
and suggest that the atlantal intercentrum is at least one of the contributing elements to the
centrum. The centrum appears subrectangular in lateral view and dorsolaterally expanded
beneath the neural arches. This expanded area may consist of the intercentrum and neural arches
fusing to the atlantal pleurocentra that are otherwise absent. Anteriorly, the bicondylar
articulating surface of the centrum aligns almost perfectly with the occipital condyle of the skull.
The tight fit between the atlas and the occipital would have likely restricted the range of
movement about this joint, if not preventing it altogether.
The axis is a tall, broad multipartite element. Stout axial neural arches contact broad
posterolaterally protruding transverse processes but remain unfused to the centrum. The
prezygapophyses are directed anterolaterally to articulate with the atlantal neural arches. The
postzygapophyses are notably elongate in comparison to the prezygapophyses and directed
posterolaterally. The axial neural arches fuse dorsally, forming the broad, rugous axial neural
18
spine. The lateral surfaces of the neural spine are concave, narrowing anteriorly to wedge
between the atlantal neural arches. Dorsally, the neural spine thickens greatly before tapering to a
pyramidal point. The wedge-like axial intercentrum is present but displaced posteriorly. As in A.
cumminsi the axial intercentrum is considerably smaller than those of the following cervical
vertebrae (Williston, 1909). No pleurocentra are visible.
The third cervical vertebra appears mostly complete but disarticulated. The slightly bulbous
dorsal tip of the neural spine is damaged. A dorsoventrally directed groove runs along the
anterior face of the spine. Ventrally, the groove bifurcates to meet the strongly anteromedially
directed prezygapohyses. The postzygapophyses remain only partially prepared, with articulating
surfaces oriented posterolaterally. A single ventrolaterally directed transverse process is visible.
Posteriorly, the distal surface of the transverse process is broad and flat, and would have
articulated with the wide cervical ribs. The intercentrum is disarticulated but lies in close
association with the rest of the third cervical vertebra. It is roughly crescentric and wedge-shaped
in lateral view. Another intercentrum, presumably belonging to the fourth cervical vertebra is
pressed against the posterior surface of the third cervical intercentrum. Only a single unpaired
and disarticulated pleurocentrum is visible. It is unclear what particular vertebra this element
contributed to.
5.7 Appendicular Skeleton
OMNH 52545 represents a complete right humerus (Fig. 13). The humerus is a massive element
with flared proximal and distal ends oriented at approximately right angles to each other. The
shaft is laterally constricted and would appear somewhat subrectangular in cross section.
Distally, a well-developed ectepicodyle and entepicondyle dominate the extensor surface. A
convex radial condyle is positioned on the anteroventral surface of the flexor side. Proximal to
this area, a prominent supinator process comes to a blunt point. A supinator process has been
observed in other trematopids where the area is preserved (Williston, 1909; Olson, 1941; Dilkes
& Reisz, 1987; Dilkes, 1990) but is also present in Eryops, seymouramorphs, and diadectimorphs
(Pawley & Warren, 2006). Moreover, the development of a supinator process has been correlated
with the degree of ossification of the humerus and is at least suggestive of a terrestrial lifestyle
(Pawley & Warren, 2006). A posteriorly directed anterior humeral keel joins the supinator
19
process to a roughtly oval attachment area for the pectoralis muscle alongside a distinct deltoid
crest. Proximally, the humeral articulating surfaces are well developed and slightly convex.
OMNH 73514 represents the pelvic girdle and extremity of A. dunni (Fig. 14). Both sides of the
pelvic girdle are partly exposed in lateral view with no discernable sutures separating the ilium,
ischium, and pubis. Most of the iliac blade is missing on the left pelvis, although the rest of the
element appears intact. The right pelvis is missing portions of the ichium and pubis and has a
large crack running along its surface. Any preserved structures dorsal to the ventral margin of the
acetabulum remain occluded by matrix housing the hindlimb. Both pelves are broad, thin bones.
The acetabulum is triangular in outline, bordered dorsally by a strongly developed transverse
pelvic ridge and posterior supra-acetabular notch. A large laterally directed obturator foramen is
present. The right femur is complete and is in articulation with the right pelvis, and resembles the
described femur of A. cumminsi (Williston, 1909; Olson, 1941). The proximal head and distal
heads are expanded, while the shaft is gently concave. The long fourth and internal trochanters of
the adductor blade are robust, with a thin intertrochanteric ridge bordering a deep oval concavity.
A deep adductor crest runs along the entire flexor surface of the femur, terminating near the
fibular condyle. The distal head is all that remains of the left femur, which sits in close
association with an articulated tibia, fibula, and elements of the pes.
The tibia (Fig.14) has a greatly expanded femoral head with a well-developed cnemial crest and
trough. The slender shaft appears circular in cross section, broadening distally to meet the
convex articular facet. The fibula is almost as long as the tibia. Its proximal and distal ends are
about equal in width. Both ends are slightly directed toward the tibia by a medially concave
curvature of the shaft. Following the description of the pes of A. cumminsi (Williston, 1909;
Schaeffer, 1941), the tibia and fibula articulate with a proximodistally elongate intermedium
(Fig.14) along the medial surfaces of their distal ends. Distal to the intermedium is the wide,
concave fourth centrale. The wedge-shaped tibiale flanks the tibia, rotated slightly out of
position. A small bone possibly representing a centrale or tarsal sits out of place, displaced by the
distal end of the right femur. Next to this bone are two broken unidentified phalangeal elements.
A single element of the pes located next to the right pelvis has suffered pyrite damage and may
represent the first centrale.
20
6 Discussion
6.1 Phylogenetic Analysis
A review of previous studies involving trematopid relationships reveals that the family has
typically been analyzed in two ways. While each approach affirms both the monophyly of
Trematopidae and its position as the sister group of Dissorophidae, subtle differences in
methodology have resulted in varying perceptions of trematopid interrelationships.
Firstly, cladistic analysis of trematopid ingroup relationships have been assessed using a single
taxon as the outgroup while also excluding aberrant forms from the analysis altogether. Dilkes
(1990) was first to show that Anconastes, Phonerpeton, and Acheloma formed a monophyletic
sister-group to Amphibamus (Amphibamus(Anconastes(Phonerpeton, Acheloma))). Ecolsonia
and Actiobates were not included in that study at the time because they were generally
considered as a dissorophid or juvenile, respectively. Sumida et al. (1998) performed a similar
cladistic analysis when describing Tambachia, heavily basing the choice of character states and
outgroups on the work of Dilkes (1990) and Daly (1994). They concluded that the monophyletic
Trematopidae consisted of two sister groups comprised of Tambachia and Anconastes in one
clade, and Acheloma and Phonerpeton in the other (Amphibamus(Tambachia,
Anconastes)(Acheloma, Phonerpeton)). As in earlier works, Sumida et al. (1998) used only
Amphibamus for outgroup comparisons and left Ecolsonia and Actiobates out of that analysis,
despite growing evidence that neither form could be considered a dissorophid (Daly, 1994).
Secondly, trematopids have been included in larger scale phylogenetic studies of dissorophoid
and temnospondyl relationships. Although, Ecolsonia and Actiobates have also been included in
most of these cases, character coding for trematopids has often been based primarily on only the
best known forms, excluding more than half of the potential members of the family from
analysis. Daly (1994) included Trematopidae in her analysis of amphibamid relationships along
with Ecolsonia. The analysis placed Ecolsonia outside Trematopidae; however, while several
different trematopid taxa were discussed, character coding for the group as a whole was based
largely on Acheloma. Subsequent authors followed this trend, coding characters for trematopids
as using only Acheloma and Phonerpeton (Ruta et al., 2003; Schoch & Rubridge, 2005;
Anderson et al., 2008; Frobisch & Reisz, 2008). The purposes of these studies were not to
examine trematopid ingroup relationships, still the approach maintained monophyly for
21
trematopids, allowing the clade to be effectively utilized for outgroup comparison. However,
resolution within the group was lost through this method and the diversity existing within
Trematopidae as highlighted by Sumida et al. (1998) remained unaccounted for. As a result,
forms such as Ecolsonia and Actiobates failed to cluster with derived trematopid taxa like
Acheloma, and fell outside the clade.
Ruta et al. (2007) included all valid trematopid taxa, as well as Ecolsonia and Actiobates into a
supertree of temnospondyl relationships. The results showed that Actiobates grouped with the
trematopids Anconastes and Tambachia, while Ecolsonia fell within Dissorophidae. Conversely,
the analysis of dissorophoid relationships conducted by Huttenlocker et al. (2007) indicated that
Ecolsonia shared a more recent common ancestor with trematopids than dissorophids. Although
the study did not resolve trematopid ingroup relationships, data from Acheloma, Phonerpeton,
Tambachia, and Actiobates were considered when coding characters for Trematopidae.
The present study undertakes the first comprehensive phylogenetic analysis of Trematopidae
examining all valid and aberrant forms of the group along with the new taxon within the broader
context of dissorophoid relationships. The data matrix used by Schoch & Rubridge (2005)
provided the framework for our phylogenetic analysis. Twenty-four informative cranial
characters were utilized from this matrix and another thirty were added from the literature
(Appendix 2). Sclerocephalus haeuseri is a well described lower tetrapod known from abundant
material (Schoch, 2003; Schoch & Rubridge, 2005) and was selected as the outgroup for this
analysis. Micromelerpeton credneri was included as a representative of basal dissorophoids.
Eoscopus lockardi (Daly, 1994) and Micropholis stowi were used to represent the two sister
clades comprising Amphibamidae (Schoch, 2005). Exquisite material of the recently described
Cacops morrisi (Reisz et al., 2009) was readily available and used to represent Dissorophidae.
The trematopids Acheloma cumminsi, Anconastes vespersus, Phonerpeton pricei, Tambachia
trogallas, Actiobates peabodyi, and Ecolsonia cutlerensis were added, essentially forming an
ingroup of 11 taxa. A total of 54 cranial characters were used in the analysis. Character coding
for Ecolsonia, all trematopid taxa except Actiobates, and Cacops was based on first hand
observations (Appendix 1). Coding for all other taxa was based primarily on the data matrices of
Schoch & Rubridge (2005), Ruta & Bolt (2006), and published descriptions as cited. A
parsimony analysis was performed using PAUP 4.0b10 (Swofford, 2003) and MacClade 4.08
(Maddison & Maddison, 1992). All analyses were performed using a branch-and-bound search
22
with all characters equally weighted and unordered. Bremer support and bootstrap values were
calculated to determine the robustness of nodes. The analysis resulted in one single most-
parsimonious tree with a tree length of 101 steps, consistency index of 0.69, and rescaled
consistency index of 0.45 (Fig. 15).
The Olsoniformes (Dissorophidae, Trematopidae) forms a clade supported by three unambiguous
synapomorphies (16, 19, 20). Two additional steps are required to collapse the node. It is
supported by a bootstrap value of 65%.
The monophyly of Trematopidae is supported by five unambiguous synapomorphies (39, 41, 42,
44, 50) and includes all previously valid trematopids along with Actiobates and Ecolsonia. The
clade is strongly supported by a Bremer value of 5 and bootstrap value of 90%. Members of
Trematopidae are defined by the presence of an elongated external naris (39) with the prefrontal
contributing to its margin (50); caniniform teeth (41); an inflection of the prearticular along the
medial rim of the adductor fossa (42); and a median vomerine septum (44).
Within Trematopidae, Actiobates, Ecolsonia, Anconastes, and Tambachia form a clade based
primarily on the contribution of the maxilla to the ventral margin of the orbit in the absence of an
l.e.p. and l.e.e. The node collapses after an additional two steps and it has a bootstrap value of
77%. Anconastes and Tambachia are strongly united by a Bremer value of 6 and bootstrap value
of 77%. Interestingly, both Ecolsonia and Actiobates share a more recent ancestor with
Anconastes and Tambachia (the two trematopids often left out of analyses) than either does with
Acheloma or Phonerpeton. This may account for instances in which Ecolsonia fell outside
Trematopidae when trematopid character coding was representative of only Acheloma or
Phonerpeton. Furthermore, replacement of the supratympanic shelf by dermal sculpturing along
the dorsal rim of the otic notch has been cited as a character uniting Dissorophidae (Daly, 1994),
and was used to argue the assignment of Ecolsonia as a dissorophid (Berman, et. al., 1985).
However, this character cannot be valid since the recently described dissorophid, Cacops morrisi
(Reisz et. al., 2009), retains a supratympanic shelf along the dorsal border of its otic notch.
The new trematopid recovered from Richards Spur clusters with Acheloma and indicates that we
can place it with that genus, but as a new species. The node uniting Acheloma dunni and
Acheloma cumminsi is supported by two unambiguous synapomorphies: vomer with raised crest
lying mesial to choana (33-0); and otic notch with nearly horizontal ventral margin (43). The
23
node has a Bremer support value of 8 and bootstrap value of 98%. A. dunni is distinguished from
all other dissorophoids based on a single autapomorphy: the presence of sculptured lateral
exposure of palatal elements that are excluded from the ventral margin of the orbit.
Phonerpeton does not form a clade with Acheloma as previous studies have suggested (Dilkes,
1990; Sumida et al., 1998; Ruta et al., 2007). This contradiction has resulted from changes in the
character coding with respect to the presence of parasphenoid dentition in Acheloma. Originally,
Acheloma and Phonerpeton were united based on the presence of an internarial fenestra and a
lack of teeth on the parasphenoid. The internarial fenestra appears in an array of other
dissorophoids. Examination of the holotype of A. cumminsi along with the fact that dentition is
present on the parasphenoid of A. dunni resulted in the collapse of the node uniting Phonerpeton
and Acheloma.
6.2 Speculations on Habits and Lifestyle
Acheloma dunni appears to represent a large, terrestrial predator within the Richards Spur
assemblage. As an olsoniform, Acheloma dunni falls within the group of Paleozoic amphibians
considered to exhibit morphological specializations for life on land (Bolt, 1969; Berman et al.,
1987; Sumida et al., 1998; Dilkes & Brown, 2007; Markey & Marshall, 2007; Schoch, 2009). Its
tall, box-like skull with laterally positioned orbits and lack of lateral line canals is comparable to
that of Early Permian terrestrial amniotes and other olsoniforms (Dilkes & Brown, 2007; Reisz et
al., 2009). Furthermore, well-ossified limb bones including a humerus with well-developed
condyles and prominent supinator process suggest A. dunni possessed large muscles capable of
holding itself up on land (Pawley & Warren, 2006; Dilkes & Brown, 2007). What is known of
the axial skeleton bears similarities to that of other olsoniforms characterized by a well-ossified
atlas-axis complex and presacral vertebrae contributing to a relatively short trunk (Williston,
1909; 1910). Although many medium to large temnospondyls similar in size to the olsoniforms
were aquatic (Schoch, 2009), their relatively short axial length and small tail would suggest
olsoniforms were more suited for an amphibious to terrestrial lifestyle (Laurin et al., 2004).
Furthermore, the atlas-axis complex observed in A. dunni, is robust like that of Diadectes
(Sumida & Lombard, 1991). The atlas would have attached firmly to the occipital condyle, and
likely would have provided support for the weight of the massive skull in terrestrial
environments.
24
The function of the posterior expansion of the trematopid external narial opening has been the
focus of limited inquiry (Olson, 1941; Bolt, 1974c; Dilkes, 1993). Bolt (1974c) proposed the
posterior portion of the external naris developed in response to the lateral expansion of a gland.
Furthermore, as the external naris expanded to accommodate the gland, the narial flange may
have developed its unique morphology to support stressors concentrated on the narrow antorbital
bar during feeding and avert the potential loss of structural integrity in the rostrum. He cited the
lateral expansion of the glandula nasalis externa (salt gland) found in living reptiles as the most
likely candidate, suggesting it may have helped the amphibians cope with the demands of living
in terrestrial environments. However, within extant taxa, salt glands are found primarily in birds
and reptiles that are either marine or feed on vegetation with high potassium content; functioning
primarily in ionic regulation rather than osmoregulation (Peaker & Linzell, 1975). Neither
condition would appear to be met by the carnivorous, terrestrial trematopids. But regardless of
whether or not the posterior expansion of the external naris was caused by the enlargement of a
salt gland, Bolt (1974c) concluded the typical trematopid elongated external naris and narial
flange could not be used as diagnostic characters for the family. He reasoned that in any
labyrinthodont, the expansion of any structure lateral to the nasal cavity could result in an
elongated external narial opening along with the subsequent development of a narial flange. The
argument was later used to support removing Ecolsonia from Trematopidae (Berman et. al.,
1985).
Conversely, Dilkes’ (1993) study of the cranial ontogeny of Phonerpton suggests that the narial
flange developed early in the postmetamorphic ontogeny of trematopids. In turn, the posterior
expansion of the external naris occurred successively, correlating with the growth of the
premaxillary and maxillary caniniform teeth and probable changes in the areas of stress
concentration in the skull. He argued the narial flange evolved as a terrestrial adaptation in
dissorophoids, enhancing water conservation and olfactory sensitivity by increasing the surface
area of the nasal capsule. Additionally, the flange may have been modified in trematopids to also
reinforce the skull. Furthermore, Dilkes (1993) stated the presence of a salt gland is equivocal
and as seen in living reptiles, an expansion of such gland would not necessarily result in the
posterior expansion of the external naris. Although, the true physiological function of the
elongated external naris and narial flange is unknown, both Bolt (1974c) and Dilkes (1993) agree
changes in forces acting on the skull during feeding played a key role in their development. The
25
advent of the use of finite-element analysis in assessing sutural stress responses to feeding forces
(Rayfield, 2005) may provide promising insight into the purpose of these unique features.
Modifications in sutural morphology in response to changes in forces associated with feeding are
also illustrated in the unique configuration of the l.e.p. and l.e.e. in A. dunni. Bolt (1974b)
proposed the l.e.p. (and likely the l.e.e.) evolved in early dissorophoids typically characterized by
small skulls with large orbits. A thickening of the palatine and its subsequent migration into the
circumorbital elements of a widening orbit would have provided mechanical support for
compressive forces acting on the narrow suborbital bar during feeding. However, unlike other
dissorophoids, A. dunni has small orbits and a tall suborbital bar comparable to that of Acheloma
cumminsi. A tall cheek region likely provided greater mechanical support than the typically thin
suborbital bars of most dissorophoids, so the development of an l.e.p. and l.e.e. in A. dunni is
surprising. In A. dunni, the ectopterygoid fang is relatively larger than that found in any other
trematopid, including A. cumminsi in which the ectopterygoid fangs are about the same size as
the largest marginal tooth (Dilkes & Reisz, 1987). Moreover, the development of large
ectopterygoid fangs in A. dunni would have undoubtedly resulted in different forces acting on the
palate and suborbital bar during feeding in comparison to A. cumminsi. If Bolt (1974b) is correct
in asserting that the evolution of an l.e.p. provided support for stressors associated with feeding
then the evolution of laterally exposed palatal elements in A. dunni may relate to forces ensued
on the skull by the enlarged ectopterygoid fangs.
Trematopids have generally been considered as terrestrial predators (Olson, 1941; Dilkes, 1990;
Markey & Marshall, 2007). Recent fossil evidence indicates large olsoniforms like A. dunni at
least scavenged on top predators and played a significant role in their ecosystems (Reisz & Tsuji,
2006; Reisz et al., 2009). A. dunni is the largest described taxon of the Richards Spur assemblage
(Maddin et al., 2006) and displays a host of complex adaptations associated with specialized
feeding habits. As such, A. dunni may represent the top predator of the Richards Spur ecosystem.
26
References
Anderson, J. S. and R. R. Reisz. 2003. A new microsaur (Tetrapoda: Lepospondyli) from
the Lower Permian of Richards Spur (Fort Sill), Oklahoma. Canadian Journal of Earth
Sciences 40:499-505.
Anderson, J. S., A. Henrici, S. S. Sumida, T. Martens, and D. S. Berman. 2008.
Georgenthalia clavinasica, a new genus and species of dissorophoid temnospondyl from
the early Permian of Germany, and the relationships of the family Amphibamidae.
Journal of Vertebrate Paleontology 28:61-75.
Berman, D. S., R. R. Reisz, and D. A. Eberth. 1985. Ecolsonia cutlerensis, an Early
Permian Dissorophid amphibian from the Cutler Formation of North-Central New
Mexico. New Mexico Bureau of Mines and Mineral Resources 191:5-31.
Berman, D. S., R. R. Reisz, and D. A. Eberth. 1987. A new genus and species of
trematopid amphibian from the late Pennsylvanian of North-Central New Mexico.
Journal of Vertebrate Paleontology 7:252-269
Berman, D. S. 2000. Origin and early evolution of the amniote occiput. Journal of
Paleontology 74:938-956.
Bolt, J. R. 1969. Lissamphibian origins: possible protolissamphibian from the Lower
Permian of Oklahoma. Science 166:888-891.
Bolt, J. R. 1974a. A trematopid skull from the Lower Permian, and analysis of some
characters of the dissorophoid (Amphibia: Labyrinthodontia) otic notch. Fieldiana,
Geology 30:67-79.
Bolt, J. R. 1974b. Evolution and functional interpretation of some suture patterns in
Paleozoic labyrinthodont amphibians and other lower tetrapods. Journal of
Paleontology 48:434-458.
27
Bolt. J. R. 1974c. Osteology, function, and evolution of the trematopsid (Amphibia:
Labyrinthodontia) nasal region. Fieldiana, Geology 33:11-30.
Bolt, J. R. 1977a. Cacops (Amphibia: Labyrinthodontia) from the Fort Sill locality, Lower
Permian of Oklahoma. Fieldiana, Geology 37:61-73.
Bolt, J. R. 1977b. Dissorophoid relationships and ontogeny, and the origin of the
Lissamphibia. Journal of Paleontology 51:235-249.
Carroll, R. L. 1964a. Early evolution of the dissorophid amphibians. Bulletin of the
Museum of Comparative Zoology 131:161-250.
Carroll, R. L. 1964b. The relationships of the rhachitomous amphibian Parioxys. American
Museum Novitates 2167:1-11.
Cope, E. D. 1882. Third contribution to the history of the Vertebrata of the Permian
Formation of Texas. Proceedings of the American Philosophical Society 20:447-461.
Daly, E. 1973. A Lower Permian vertebrate fauna from Southern Oklahoma. Journal of
Paleontology 47:562-589.
Daly, E. 1994. The Amphibamidae (Amphibia: Temnospondyli), with a description of a
new genus from the Upper Pennsylvanian of Kansas. Miscellaneous Publications of the
University of Kansas Museum of Natural History 85:1-59.
DeMar, R. E. 1966a. Longiscitula houghae, a new genus of dissorophid amphibian from
the Permian of Texas. Fieldiana: Geology 16:45-53.
DeMar, R. E. 1966b. The phylogenetic and function implications of the armor of the
Dissorophidae. Fieldiana: Geology 16:55-88.
28
DeMar, R. E. 1968. The Permian labyrinthodont amphibian Dissorophus multicinctus, and
adaptations and phylogeny of the family Dissorophidae. Journal of Paleontology
42:1210-1242.
Dilkes, D. W., and R. R. Reisz. 1987. Trematops milleri Williston, 1909 identified as a
junior synonym of Acheloma cumminsi Cope, 1882, with a revision of the
genus. American Museum Novitates 2902:1-12.
Dilkes, D. W. 1990. A New Trematopsid Amphibian (Temnospondyli: Dissorophoidea)
from the Lower Permian of Texas. Journal of Vertebrate Paleontology 10:222-
243.
Dilkes, D. W. 1991. Reinterpretation of a larval dissorophoid amphibian from the Lower
Permian of Texas. Canadian Journal of Earth Sciences 28:1488-1492.
Dilkes, D. W. 1993. Biology and evolution of the nasal region in trematopid amphibians.
Paleontology 36:839-853.
Dilkes, D. W. and L. E. Brown. 2007. Biomechanics of the vertebrae and associated
osteoderms of the Early Permian amphibian Cacops aspidephorus. Journal of Zoology
271:396-407.
Duellman, W. E. and L. Trueb. 1986. Biology of amphibians. McGraw-Hill, New York.
Eaton, T. H. 1973 A Pennsylvanian dissorophid amphibian from Kansas. Occasional
Papers of the Museum of Natural History, University of Kansas 14:1-8.
Evans, D. C., H. C. Maddin and R. R. Reisz. 2009. A re-evaluation of sphenacodontid synapsid
material from the Lower Permian fissure fills near Richards Spur, Oklahoma.
Palaeontology 52: 219-227.
29
Frobisch, N. B. and R. R. Reisz. 2008. A new Lower Permian amphibamid
(Dissorophoidea, Temnospondyli) from the fissure fill deposits near Richards Spur,
Oklahoma. Journal of Vertebrate Paleontology 28:1015-1030.
Godfrey, S. T., A. R. Fiorillo, and R. L. Carroll. 1987. A newly discovered skull of the
temnospondyl amphibian Dendrerpeton acadianum Owen. Canadian Journal of Earth
Sciences 24:796-805.
Huttenlocker, A. K., J. D. Pardo, and B. J. Small. 2007. Plemmyradytes shintoni, gen. et sp.
nov., an Early Permian amphibamid (Temnospondyli: Dissorophoidea) from the Eskridge
Formation, Nebraska. Journal of Vertebrate Paleontology 27:316-328.
Katz, S. G. 2008. Restoration of the vertebrate fossil collection of the University of
Missouri at Columbia. Journal of Paleontology 50:194-197.
Klembara, J., D. S. Berman, A. C. Henrici, A. Čerňanský, R. Werneburg, and T. Martens.
2007. First description of skull of Lower Permian Seymouria sanjuanensis
(Seymouriamorpha: Seymouriidae) at an early juvenile growth stage. Annals of Carnegie
Museum 76:53-72.
Laurin, M. and R. R. Reisz. 1997. A new perspective on tetrapod phylogeny; pp. 9-59 in
Sumida, S. S. and Martin, L. M. (eds.), Amniote Origins. Academic Press, San Diego.
Laurin, M., M. Girondot, and M. Loth. 2004. The evolution of long bone microstructure
and lifestyle in lissamphibians. Paleobiology 30:589-613.
Maddin, H. C., D. C. Evans, and R. R. Reisz. 2006. An Early Permian Varanodontine
Varanopid (Synapsida: Eupelycosauria) from the Richards Spur Locality,
Oklahoma. Journal of Vertebrate Paleontology 26:957-966.
Maddison, W. P. and D. R. Maddison. 1992. MacClade: Analysis of Phylogeny and
Character Evolution. Sinauer Associates, Sunderland, Massachusetts.
30
Markey, M. J. and C. R. Marshall. 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 17:7134-7138.
Mehl, M. G. 1926. Trematops thomasi, a new amphibian from the Permian of Oklahoma.
Journal of Geology 34:466-474.
Milner, A. R. 1985a. On the identigy of the amphibian Hesperoherpeton garnettense from
the Upper Pennsylvanian of Kansas. Paleontology 28:767-776.
Milner, A. R. 1985b. On the identity of Trematopsis seltini (Amphibia: Temnospondyli)
from the Lower Permian of Texas. Nues Jahrbuch fur Geologie und Palaontologie,
Monatshefte 1985(6):357-367.
Milner, A. R. 1986. Dissorophoid amphibians from the Upper Carboniferous of Nyranny;
pp. 671-674 in Z. Rocek (ed.), Studies in Herpetology: Proceedings of the Herpetological
Meeting (3rd Ordinary General Meeting of the Societas Europea Herpetologica). Chicago
University Press, Prague.
Milner, A. R. 2003. Longiscitula houghae DeMar, 1966 (Amphibia: Temnospondyli), a
junior synonym of Dissorophus multicinctus Cope, 1895. Journal of Vertebrate
Paleontology 23:941-944.
Milner, A. R. 2007. Mordex laticeps and the base of the Trematopidae. Journal of
Vertebrate Paleonotology 27:118A.
Mustafa, Y. S. 1955. The affinities of Parioxys ferricolus and the phylogeny of the
“eryopsoid” amphibians. Bulletin of the Institute of Egypt 36:77-104.
Olson, E. C. 1941. The Family Trematopsidae. Journal of Geology 49:149-176.
31
Olson, E. C. 1956. A new trematopsid amphibian from the Vale Formation. Fieldiana:
Geology 10:323-328.
Olson, E. C. 1970. Trematops stonei sp. nov. (Temnospondyli: Amphibia) from
Washington Formation, Dunkard Group, Ohio. Kirtlandia 8:1-12.
Olson, E. C. 1991. An Eryopid (Amphibia: Labyrinthodontia) from the Fort Sill fissures,
Lower Permian, Oklahoma. Journal of Vertebrate Paleontology 11:130-132.
Pawley, K. and Warren, A. 2006. The appendicular skeleton of Eryops megacephalus
Cope, 1877 (Temnospondyli: Eryopoidea) from the Lower Permian of North
America. Journal of Paleontology 80:561-580.
Peaker, M. and J. L. Linzell. 1975. Salt glands in birds and reptiles. Cambridge University
Press, New York.
Rayfield, E. J. 2005. Using finite-element analysis to investigate suture morphology: A
case study using large carnivorous dinosaurs. The Anatomical Record Part A:
Discoveries in Molecular, Cellular, and Evolutionary Biology 283A:349-365.
Reisz, R. R. and L. A. Tsuji. 2006. An articulated skeleton of Varanops with bite marks:
the oldest known evidence of scavenging among terrestrial vertebrates. Journal of
Vertebrate Paleontology 26:1021-1023.
Resiz, R. R. 2007. Terrestrial vertebrate fauna of the Lower Permian cave deposits near
Richards Spur Oklahoma with emphasis on dissorophoids. Journal of Vertebrate
Paleontology 27:A113
Reisz, R. R., R. R. Schoch, and J. S. Anderson. 2009. The armoured dissorophid Cacops
from the Early Permian of Oklahoma and the exploitation of the terrestrial realm by
amphibians. Naturwissenschaften 96:789-796.
32
Ruta, M., J. E. Jeffery, and M. I. Coates. 2003 A supertree of early tetrapots. Proceedings of the
Royal Society of London: Biological Sciences 270: 2507-2516.
Ruta, M and J. R. Bolt. 2006. A reassessment of the temnospondyl amphibian Perryella
olsoni from the Lower Permian of Oklahoma. Transactions of the Royal Society of
Edinburgh: Earth Science 97:113-165.
Ruta, M., D. Pisani, G. T. Lloyd, and M. J. Benton. 2007. A supertree of Temnospondyli:
cladogenetic patterns in the most species-rich group of early tetrapods. Proceedings of the
Royal Society of Edinburgh: Biological Sciences 274:3087-3095.
Schaeffer, B. 1941. The morphological and functional evolution of the tarsus in amphibians
and reptiles. Bulletin of the American Museum of Natural History 78:395-472.
Schoch, R. R. 1999. Studies on braincases of early tetrapods: Structure, homology, and
phylogeny – 2. Kamacops acervalis and other advanced temnospondyls. Neues Jahrbuch
für Geologie und Paläontologie Abhandlungen, 213:289-299.
Schoch, R. R. 2003. Early larval ontogeny of the Permo-Carboniferous temnospondyl
Sclerocephalus. Paleontology 46:1055-1072.
Schoch, R. R. and B. S. Rubidge. 2005. The amphibamid Micropholis from the
Lystrosaurus assemblabge zone of South Africa. Journal of Vertebrate Paleontology
25:502-522.
Schoch, R. R. 2009. Evolution of life cycles in early amphibians. Annual Review of Earth
and Planetary Sciences 37:135-162.
Schultze, H. P. and J. Chorn. 1983. A Labyrinthodont Palatine form the Permian of Fort
Sill, Oklahoma, Reinterpreted as a Vomer. Journal of Paleontology 57:1050-
1052.
33
Sullivan, C., and R. R. Reisz. 1999. First record of Seymouria (Vertebrata:
Seymouriamorpha) from Early Permian fissure fills at Richards Spur, Oklahoma.
Canadian Journal of Earth Sciences 36:1257-1266.
Sullivan, C., R. R. Reisz, and W. J. May. 2000. Large Dissorophoid Skeletal Elements
from the Lower Permian Richards Spur Fissures, Oklahoma, and their
Paleoecological Implications. Journal of Vertebrate Paleontology 20:456-461.
Sumida, S. S. and R. E. Lombard. 1991. The atlas-axis complex in the Late Paleozoic
genus Diadectes and the characteristics of the atlas-axis complex across the amphibian to
amniote transition. Journal of Paleontology 65:973-983.
Sumida, S. S., D. Berman, and T. Martens. 1998. A New Trematopid Amphibian from
the Lower Permian of Central Germany. Paleontology 41:605-629.
Swofford, D. 2003. PAUP*: Phylogenetic Analysis Using Parsimony (*and Other
Methods), Version 4 0b10. Sinauer Associates, Sunderland, Massachusetts.
Vaughn, P. P. 1969. Further evidence of close relationship of the trematopsid and
dissorophid labyrinthodont amphibians with a description of a new genus and species.
Bulletin of the Southern California Academy of Sciences 68(3):121-130.
Williston, S. W. 1909. New or little-known Permian vertebrates: Trematops, new genus.
Journal of Geology 17:636-658.
Williston, S. W. 1910. Cacops, Desmospondylus: new genera of Permian vertebrates.
Bulletin of the Geological Society of America 21:249–284.
Yates, A. M. and A. A. Warren. 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 128:77-121.
34
Zittel, K. A. R., von. 1887-1890. Handbuch der Paläontologie. 1. Abteilung: Paläozoologie,
Volume 3 Vertebrata (Pisces, Amphibia, Reptilia, Aves). Oldenbourg, Munich, 900 pp.
35
Figures and Captions
Figure 1. Reconstruction of skull of Acheloma dunni in A, dorsal view; B, ventral view; C, right
lateral view. Scale = 50 mm
36
37
Figure 2. Skull of Acheloma dunni, holotype (OMNH 73281) in dorsal view. Scale = 50 mm
38
39
Figure 3. Skull of Acheloma dunni, holotype (OMNH 73281) in right lateral view. Scale = 50
mm
40
41
Figure 4. Acheloma dunni, referred specimen (BMRP2007.3.4) in left lateral view. Scale = 10
mm
42
43
Figure 5. Acheloma dunni, referred specimen (BMRP2007.3.1) in right lateral view. Scale = 10
mm
44
45
Figure 6. Acheloma dunni, referred specimen (OMNH 52365). Partial right upper jaw
articulation in dorsal view. Scale = 10 mm
46
47
Figure 7. Skull of Acheloma dunni, holotype (OMNH 73281) in ventral view. Scale = 50 mm
48
49
Figure 8. Skull of Acheloma dunni, holotype (OMNH 73281) in occipital view. Scale = 50 mm
50
51
Figure 9. Partial left lower jaw of Acheloma dunni, holotype (OMNH 73281) in A, lateral view;
B, medial view; C, dorsal view; D, ventral view. Scale = 10 mm
52
53
Figure 10. Partial right lower jaw of Acheloma dunni, holotype (OMNH 73281) in A, lateral
view; B, medial view; C, dorsal view; D, ventral view. Scale = 10 mm
54
55
Figure 11. Acheloma dunni, referred specimen (OMNH 52365). Partial right lower jaw
articulation in A, lateral view; B, posterior view. Scale = 10 mm
56
57
Figure 12. Atlas-axis complex and associated cervical vertebrae of Acheloma dunni, holotype
(OMNH 73281) in A, right lateral view; B, left lateral view; C, anterior view. Scale = 10 mm
58
59
Figure 13. Acheloma dunni, referred specimen (OMNH 52545). Right humerus in A, posterior
view; B, extensor view; C, anterior view; D, flexor view; E, proximal view; F, distal view. Scale
= 50 mm
60
61
Figure 14. Acheloma dunni, referred specimen (OMNH 73514). Partial pelvic girdle and
hindlimb. Scale = 5 mm. Illustration by Heidi Richter.
62
63
Figure 15. Single most parsimonious tree of dissorophoid relationships derived from cladistic
analysis using PAUP 4.0b10 with A, relevant synapomorphies mapped on (* indicates a
synapomorphy that supports the clade, but appears elsewhere in the tree); B, bootstrap (bold) and
Bremer decay (italics) values calculated for the analysis; TL, tree length; CI, consistency index;
RC, rescaled consistency index.
64
65
Appendix 1
Data matrix used for phylogenetic analysis including 12 taxa and 54 characters. ‘a’ represents
polymorophic characters (0&1)
1
1 2 3 4 5 6 7 8 9 0 1 1 1 1 1 1 1 1 1 2
1 2 3 4 5 6 7 8 9 0 2 2 2 2 2 2 2 2 2 3
1 2 3 4 5 6 7 8 9 0
Acheloma cumminsi 0 1 1 0 0 0 0 ? 0 1 0 0 1 1 0 1 0 1 1 1 1 0 ? ? 0 0 1 0 1 1
Acheloma dunni 3 1 1 0 0 0 0 ? 0 1 0 0 1 1 0 1 0 1 1 1 1 0 ? 0 0 0 1 0 1 1
Actiobates peabodyi 2 ? ? 0 0 0 ? ? ? 0 0 ? ? ? 1 ? 1 1 1 ? 1 0 ? 0 0 1 0 1 1 1
Anconastes vesperus 2 ? ? 0 0 1 ? ? 0 ? 0 0 1 ? ? ? 0 1 1 1 1 1 ? 0 0 0 0 0 1 0
Cacops morrisi 1 1 1 1 0 0 0 0 1 1 0 1 1 1 0 1 0 1 1 1 1 1 0 0 0 0 0 0 1 1
Ecolsonia cutlerensis 2 1 1 0 0 0 1 0 0 0 0 0 1 1 0 1 0 0 1 1 1 1 0 0 0 0 0 0 1 1
Eoscopus lockardi 1 1 0 0 0 0 a a 1 1 1 1 1 1 1 0 1 1 0 a 1 0 1 1 0 0 0 0 1 1
Micromelerpeton credneri 1 ? 1 0 0 0 a a 1 a 0 0 ? 1 0 0 1 0 0 0 1 1 1 0 0 0 0 0 1 1
Micropholis stowi 1 1 1 0 1 1 1 a 1 1 1 1 1 1 0 a 0 0 0 0 1 a 1 0 0 0 0 0 1 1
Phonerpeton pricei a 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 0 1 1 1 1 0 0 0 0 0 1 0 1 1
Sclerocephalus haeuseri 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 1 0 0 0
Tambachia trogallas 2 1 ? 0 0 1 0 ? 0 ? 0 0 1 1 0 1 0 1 1 1 1 1 ? ? 0 0 0 ? 1 0
66
3 3 3 3 3 3 3 3 3 4 1 2 3 4 5 6 7 8 9 0
4 4 4 4 4 4 4 4 4 5 1 2 3 4 5 6 7 8 9 0
5 5 5 5 1 2 3 4
Acheloma cumminsi 1 1 0 0 0 0 1 0 1 1 1 1 1 1 1 1 0 0 0 1 0 0 0 2
Acheloma dunni 1 1 0 0 0 0 1 0 1 1 1 ? 1 1 ? 1 0 0 0 1 0 0 0 2
Actiobates peabodyi 0 ? ? ? ? ? ? 1 1 ? 1 ? ? ? 0 1 0 1 0 1 0 1 1 1
Anconastes vesperus 0 ? ? ? ? ? ? 0 1 0 1 1 0 1 ? 1 0 1 0 1 0 1 1 1
Cacops morrisi 0 0 1 1 0 ? ? 0 0 1 0 0 0 0 2 0 1 0 1 0 1 0 1 2
Ecolsonia cutlerensis 0 1 1 0 0 0 1 0 1 0 1 1 0 1 2 1 0 1 1 1 1 1 1 0
Eoscopus lockardi 1 0 1 1 0 0 ? 0 0 1 0 0 0 0 0 0 0 0 1 0 0 1 1 0
Micromelerpeton credneri 1 0 1 1 1 ? ? 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
Micropholis stowi 1 0 1 1 0 ? ? 0 0 0 0 0 0 0 0 0 0 0 1 0 0 2 1 0
Phonerpeton pricei 0 0 1 0 0 0 1 0 1 1 1 1 0 1 0 0 0 0 1 1 0 0 1 1
Sclerocephalus haeuseri 1 0 1 0 0 ? ? 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
Tambachia trogallas 0 ? 1 0 0 ? ? 1 1 0 1 1 0 1 0 1 0 1 0 1 0 1 1 1
67
Appendix 2
Descriptions of characters used in phylogenetic analysis. Characters 1-24 are informative cranial
characters based on Schoch and Rubridge (2005). Characters 25-38 are taken from Ruta & Bolt
(2006). Characters 39-54 are from literature as cited.
(1) Laterally exposed palatine: palatine overplated by jugal and lacrimal with no lateral exposure
(0); palatine wedging between lacrimal and jugal to make contribution to skull roof and orbital
margin (1); maxilla contributes to orbital margin in the absence of lateral exposure of palatine (2)
(based on Sumida et al., 1998); lateral exposure of palatine present and excluded from orbital
margin by jugal and lacrimal contact (3)
(2) Dorsal quadrate process: quadrate having smooth posterodorsal side in plesiomorphic state
(0); quadrate with prominent dorsoposterior outgrowth, the quadrate process (1).
(3) Vomerine depression: ventral surface of vomers flat and element divided into anterior and
posterior portion by transverse ridges that may or may not bear transverse tooth row (0); single
unpaired depression in anterior portion of vomers that may or may not house an opening (1).
(4) Parasphenoid dentition: basal plate of parasphenoid bearing shagreen of small teeth
(denticles) anteromedially (0); plate entirely smooth (1).
(5) Parasphenoid denticle field: parasphenoid denticle field well established, with triangular
outline and with apex reaching onto base of cultriform process (0); denticle field greatly
expanded anteriorly to cover most of the cultriform process (1).
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(6) Parasphenoid basal plate: basal plate roughly quadrangular, as long as wide (0); basal plate
much shorter than wide, reaching about half the width (1).
(7) Vomerine denticle field: vomer covered with more or less dense shagreen of teeth in addition
to obligatory fang pair (0); shagreen confined to juvenile stages and /or absent throughout
ontogeny (1).
(8) Vomerine fangs: vomer lacking fangs in its medial portion, outside lateral tooth arcade, but
have smaller accessory teeth in that region (0); vomer with additional fang pairs posterior to mid-
vomerine depression (1).
(9) Pterygoid-vomer: Retention of suture between pterygoid (palatine ramus) and vomer (0);
pterygoid contacting only posteriormost portion of palatine and lacking suture with vomer (1).
(10) Pterygoid flange: palatine ramus of pterygoid merging continuously into basipterygoid
ramus (0); palatine ramus broadening abruptly to form transverse flange (1).
(11) Palatine, ectopterygoid: palatine and ectopterygoid much wider than maxilla (0); palatine
and ectopterygoid reduced to narrow struts not wider than adjoining maxilla (1).
(12) Interpterygoid vacuity: interpterygoid vacuity roundish or oval in outline (0); interpterygoid
vacuity greatly expanded laterally at mid-level (1).
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(13) Narial flange: ventral (inner) side of prefrontal, lacrimal, and nasal smooth (0); inner side of
these bones forming complicated bar-like structure (narial flange), permitting contact with
antorbital bar (1).
(14) Prefrontal process: prefrontal forming simple suture with lacrimal laterally (0); prefrontal
underplating lacrimal widely by means of ventral prefrontal process contacting palatine (1).
(15) Tabular size: Tabular narrower than postparietal, but reaching almost same size as latter (0);
tabular minute and laterally constricted by unique enlargement of otic notch (1).
(16) Tabular-squamosal: Tabular and squamosal widely separated by supratemporal (0);
squamosal meeting tabular, excluding supratemporal from otic notch (1).
(17) Postparietal length: postparietal forming transversely rectangular or quadrangular element
(0); postparietal abbreviated and reduced to narrow, poorly ornamented strut at posterior margin
of skull table (1).
(18) Squamosal- supratemporal: suture between squamosal and supratemporal nearly as long as
supratemporal itself (0); foreshortened squamoso-supratemporal suture reaching only one third
or less length of supratemporal (1).
(19) Supratympanic flange (=semilunar flange in Schoch and Rubidge 2005, terminology
following Bolt (1974)): squamosal continuously ornamented around margin of otic notch (0);
squamosal having dorsally exposed and ornamented area (supratympanic flange) stepping
abruptly into steeply aligned, poorly ornamented portion (1).
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(20) Semilunar flange (=supratemporal flange of Schoch and Rubidge (2005)): supratemporal
without ventral projection into otic notch (0); supratemporal forming marked ventral flange
participating in medial bordering of otic notch (1).
(21) Prefrontal-postfrontal: prefrontal and postfrontal firmly sutured, excluding the frontal from
orbital margin (0); both elements separated by frontal, at least dorsally (1).
(22) Skull width: moderately wide skull with jugals, postorbitals, and medial skull roofing series
usually longer than wide (0); skull table and cheek overall broadened, most elements being as
wide as long or wider (1).
(23) Palpebral ossifications: ossifications in orbit restricted to sclerotic ring (0); numerous
palpebral ossicles at medial margin of sclerotic ring (1).
(24) Stapes: stapes with pronounced dorsodistal curvature directed towards dorsally located otic
notch (0); stapes abbreviated without dorsodistal curvature, directed laterally towards vertically
aligned otic notch (1).
(25) Absence (0) or presence (1) of a prefrontal-jugal contact.
(26) Maxilla extending posterior to the level of the posterior margin of the orbit (0) or
terminating at the level of such margin or anterior to it (1).
71
(27) Absence (0) or presence (1) of inward inflection of skull outline in dorsal view at the level
of the maxilla-premaxilla suture.
(28) Presence (0) or absence (1) of a maxilla-quadratojugal contact.
(29) Parietals more (0) or less (1) than two and a half times as long as wide.
(30) Postparietal less than (0) or more than (1) four times wider than long.
(31) Postorbital not narrowing (0) or narrowing (1) to an acute posterior point.
(32) Absence (0) or presence (1) of condition: vomer with posterolateral ramus that extends
posteriorly along the medial margin of the palatine.
(33) Vomer with (0) or without (1) a toothed, raised crest running anteroposteriorly and lying
mesial to the choana.
(34) Palatine excluded from (0) or contributing to (1) the interpterygoid vacuity.
(35) Absence (0) or presence (1) of condition: palatal ramus of the pterygoid forming a butt joint
with the posterior margin of the palatine, thus producing a continuous sheet of bone with the
latter.
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(36) Absence (0) or presence (1) of an exoccipital-tabular contact.
(37) Absence (0) or presence (1) of an exoccipital-postparietal contact.
(38) Jaw articulation lying posterior to (0), level with (1), or anterior to (2) the posterior facets of
the exoccipitals.
(39) External narial opening: uniform, oval shaped margin (0); posteriorly expanded with distinct
anterior and posterior regions giving external naris an overall “key-hole” shape (1) (Dilkes,
1990)
(40) Internarial fenestra: present (0); reduced (1); absent (2) (Dilkes, 1990)
(41) Marginal teeth: uniform in size (0); caniniform teeth on premaxilla and maxilla (1) (Dilkes,
1990)
(42) Inflection of the prearticular along the medial rim of the adductor fossa: absent (0); present
(1) (Dilkes, 1990)
(43) Ventral border of otic notch: slopes posteroventrally (0); nearly horizontal (1) (Dilkes &
Reisz, 1987)
(44) Median vomerine septum: absent (0); present (1); (Dilkes & Reisz, 1987; Dilkes, 1990)
73
(45) Tabular process: short or absent (0); curves gradually to meet robust quadrate process (1);
bent down sharply at approximately a right angle to the dorsal edge of the skull table and fused
to the quadrate process (2) (Dilkes & Reisz, 1987)
(46) Stapedial foramen: present (1); absent (0) (Daly, 1994)
(47) Knobby exostoses ornamenting the skull roof: absent (0); (1) present (1) (Daly
1994).
(48) Subnarial lacrimal process: long (0); short (1) (Sumida et al., 1998)
(49) Semilunar curvature of the squamosal along ventral border of the supratympanic flange:
absent (0); present (1) (Berman et al., 1985; Dilkes, 1990)
(50) Entrance of the prefrontal into the naris due to the posterior elongation of the external naris:
absent (0); present (1) (Daly, 1994)
(51) Dorsal rim of occiput: smooth (0); ornamented (1)
(52) Ratio of preorbital length to postorbital length: preorbital length greater than postorbital
length by greater than 10% (0); preorbital and postorbital lengths approximately equal (1);
postrbital length greater than pretorbital length by greater than 10%(2)
74
(53) Suborbital bar height: greater than 10% of the total midline skull length (0); less than 10%
of the total midline skull length (1)
(54) Minimum distance between otich notch and orbital margin: greater than 25% of the total
midline skull length (0); between 10% to 25% the total midline skull length (1); less than 10% of
the total midline skull length (2)