Sauropareion anoplus Modesto, Sues, and Damiani, 2001

Macdougall, Mark J., Modesto, Sean P. & Botha-Brink, Jennifer, 2013, The postcranial skeleton of the Early Triassic parareptile Sauropareion anoplus, with a discussion of possible life history, Acta Palaeontologica Polonica 58 (4), pp. 737-749 : 739-745

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https://doi.org/ 10.4202/app.2011.0099

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Sauropareion anoplus Modesto, Sues, and Damiani, 2001
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Sauropareion anoplus Modesto, Sues, and Damiani, 2001

Figs. 1–7 View Fig View Fig View Fig View Fig View Fig View Fig .

Holotype: SAM−PK−11192, a partial skeleton.

Type locality: Barendskraal, Middelburg District, Eastern Cape Province, South Africa ( Modesto et al. 2001; Modesto and Damiani 2007).

Type horizon: Uppermost strata of the Palingkloof Member of the Balfour Formation, Beaufort Group, Lower Triassic.

Referred specimens.—BP/1/5779, a partial skull from Barendskraal ( MacDougall and Modesto 2011); NMQR 3544 ( Figs. 1 View Fig , 2 View Fig ), a partial, articulated anterior half of a skeleton preserved to the 15th presacral vertebra from Vangfontein, Middelburg District, Eastern Cape Province, South Africa; NMQR 3556 ( Figs. 3 View Fig , 4 View Fig ), partial juvenile skeleton with skull and various disarticulated postcranial elements from Vangfontein; NMQR 3602 ( Figs. 5 View Fig , 6 View Fig ) near complete juvenile skeleton from Vangfontein.

Diagnosis.—From Modesto et al. (2001) and Modesto and Damiani (2007): procolophonid characterized by deep occipital shelves on parietals and supratemporals, resulting in deep median embayment in posterior margin of skull table, and absence of supinator process on humerus. The presence of a posteroventral facial process on the quadratojugal was identified as an autapomorphy by Modesto et al. (2001), but it may diagnose a more inclusive grouping within Procolophonidae ( Modesto and Damiani 2007) .

Description

The main focus of the description will be NMQR 3602 View Materials ( Figs. 5 View Fig , 6 View Fig ) as it is by far the most complete of the three specimens in this study. The other two specimens, NMQR 3544 View Materials ( Figs. 1 View Fig , 2 View Fig ) and NMQR 3556 View Materials ( Figs. 3 View Fig , 4 View Fig ), will be used to supplement the description of NMQR 3602 View Materials where applicable. Based on comparisons of the humeri, NMQR 3602 View Materials is approximately 80% the size of the holotype SAM−PK−11192. The remaining two specimens are considerably smaller than the holotype and NMQR 3602 View Materials . Most of the centra are inaccessible in NMQR 3602 View Materials , but the few that are exposed (e.g., presacral 5) are not fused to their respective neural arches, indicating immaturity. Similarly, SAM−PK−11192 was interpreted to be a juvenile by Modesto and Damiani (2007) because it exhibited open neurocentral sutures. Because NMQR 3544 View Materials and NMQR 3556 View Materials are smaller in size than the holotype, they too can be regarded as immature. The new material has also allowed for a composite skeletal reconstruction to be drafted ( Fig. 7) .

Skull.—The skull of Sauropareion anoplus has been previ−

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ously described in detail by Modesto and Damiani (2007) and MacDougall and Modesto (2011). Accordingly, only areas of the skull offering new information will be considered in this study.

Skull roof: The posterior emargination of the parietals that was described in the holotype ( Modesto and Damiani 2007) is not present in NMQR 3602 View Materials ( Figs. 5 View Fig , 6 View Fig ) or NMQR 3556 View Materials ( Figs. 3 View Fig , 4 View Fig ) to the degree that it is in the holotype (the posterior of the skull in NMQR 3544 View Materials [ Figs. 1 View Fig , 2 View Fig ] is not informative, because a large majority of it is not preserved). This lack of emargination may be attributable to ontogenetic changes, as the largest of the new specimens ( NMQR 3602 View Materials ) is approximately 80% the size of the holotype. It is also possible that this difference is attributable to individual variation and preservational artefacts. The difference between NMQR 3602 View Materials and the holotype is most likely the result of preservational factors affecting both specimens. The posterior−most portion of the skull in NMQR 3602 View Materials appears to be crushed. The posterior of the skull in the holotype is also considerably damaged and this most likely makes the emargination appear more pronounced than it actually is. Additionally, there seems to be no emargination of the parietals in NMQR 3556 View Materials , but it appears that the posterior of the skull roof of this specimen also suffers from preservational damage .

Braincase: The palatal view of NMQR 3544 ( Fig. 2A View Fig ) reveals that the parabasisphenoid and the basioccipital are preserved. The ventral surface of the parabasisphenoid (a fusion of the basisphenoid and the parasphenoid) can be clearly seen posterior to the elements of the palate. The parabasisphenoid is a large robust element that is partially obscured by the copula resting on its ventral surface. The anterior−most portion of the parabasisphenoid exhibits the cultriform process located medially. It is triangular in shape, being broad posteriorly and tapering off anteriorly as a sharp tip, extending forward into the interpterygoid vacuity to the level of the posterior portion of the pterygoid. The cultriform process found in Sauropareion anoplus is considerably longer than the very short processes of Hypsognathus fenneri ( Sues et al. 2000) and Leptopleuron lacertinum ( Säilä 2010a) . Located on either side of the base of the cultriform process are the two blunt, basipterygoid processes, which extend anterolaterally. The posterior portion of the parabasisphenoid exhibits the cristae ventrolaterales, two ventral ridges that run anteroposteriorly along the dorsal surface; between the ridges is a smooth curved depression. Posterior to the parabasisphenoid is the basioccipital, which does not exhibit any areas of interest due to its poor preservation.

Mandible: MacDougall and Modesto (2011) estimated that the (complete) dentary of BP/1/5779 exhibited 12 or 13 tooth positions. The left mandible of NMQR 3556 ( Fig. 4B View Fig ) clearly shows that there are 15 tooth positions, all of which are occupied by conical homodont teeth. NMQR 3602 and NMQR 3544 do not offer any new substantial information about the mandible.

Hyoid apparatus: Of the three Vangfontein specimens, only the skull of NMQR 3544 has been prepared in ventral aspect and reveals the hyoid apparatus ( Fig. 2A View Fig ). The preserved hyoid apparatus offers some new information that differs slightly from what was found in the holotype ( Modesto and Damiani 2007). The central element of the hyoid apparatus, the copula ( Carroll and Lindsay 1985) or corpus hyoideum ( Reisz and Scott 2002), is a boomerang−shaped element in ventral aspect, and on each side of the corpus hyoideum, curving laterally and posteriorly, are two processes. This shape differs from the bowtie−shaped corpus hyoideum described in the holotype ( Modesto and Damiani 2007), probably because this specimen is smaller and thus likely to be ontogenetically younger than the holotype. The ceratohyal of Sauropareion anoplus was described as being asymmetric in the holotype, with the posterior end of the bone being a distinctly different shape from the anterior ( Modesto and Damiani 2007); the left ceratohyal of NMQR 3544 (the right is missing its posterior end) is fully preserved and is indeed asymmetric. It exhibits a broad flat posterior end and a considerable narrower anterior end, similar in structure to the ceratohyal of “ Owenetta ” kitchingorum ( Reisz and Scott 2002) . This suggests that Modesto and Damiani (2007) were correct in proposing that the ceratohyal of the holotype may not have been completely ossified or was damaged during preparation, because the holotypic ceratohyal ( Modesto and Damiani 2007: fig. 4) does not exhibit the broad posterior end seen in NMQR 3544.

Postcranial axial skeleton.—NMQR 3602 exhibits an articulated vertebral column consisting of a string of 27 vertebrae that begins with the axis and runs to the pelvic girdle ( Fig. 5 View Fig ). Of these 27, six appear to be cervical vertebrae, although due to preservation and supportive matrix this number is tentative. The first 25 vertebrae are presacral, and the last two in the articulated series are sacral. It is likely that a third sacral is either obscured by overlying bone or not preserved, because procolophonids and owenettids possess three sacral vertebrae ( Ivakhnenko 1979; Reisz and Scott 2002; deBraga 2003). Both the axis and atlas are present, but the atlas is not fully exposed, being partly obscured by the supportive matrix of the skull. The atlas brings the presacral vertebrae count up to 26, which is comparable to the 27 presacral vertebrae present in Procolophon trigoniceps ( deBraga 2003). The remaining two posterior−most articulated vertebrae are clearly sacral based on the short, partially damaged sacral ribs, which can be seen on the left side. Near the pelvis there are also two disarticulated caudal vertebrae partially exposed in either anterior or posterior aspect (exact orientation cannot be determined owing to disarticulation and poor preservation). There also appear to be two partial caudal ribs near the left ischium, but they are disarticulated and damaged. The vertebrae themselves are all similar in structure; they consist of rounded, robust neural spines, which curve dorsally and slightly posteriorly, comprising the dorsal third of the entire vertebrae. The anterior zygapophyses possess facets that are tilted slightly inward, contrary to the posterior zygapophyses, which have facets that are tilted slightly outward. The centrum and transverse processes cannot be seen in most of the vertebrae, because they are preserved in dorsal view with the ventral portion being embedded in the matrix; however, the fifth presacral vertebra clearly exhibits the anterior portion of the centrum. Additionally, the two disarticulated caudal vertebrae are oriented in a manner that exposes part of either their anterior or posterior surface, allowing for part of their centra to be exposed. The exposed centra are robust, spool−shaped structures with a slight circular depression on their ends.

The majority of the preserved ribs of NMQR 3602 are found articulated with vertebrae; the presacral ribs are slender, pointed elements that possess a posterior curvature. There are 15 ribs preserved on the left side of the vertebral column and 13 ribs on the right; the anterior−most and posterior−most ribs are short, with the ribs between being significantly longer. It appears that most of the cervical ribs are not preserved or are covered by supportive matrix; however, the right anterior−most disarticulated rib would have likely articulated with the seventh presacral vertebra, which is the posterior−most cervical. The large majority of the remaining ribs are associated with dorsal vertebrae. However, the two sacral vertebrae also show their much shorter sacral ribs, which are visible only on the left side. The proximal ends of the presacral ribs are not exposed (being overlapped by the vertebrae or supportive matrix) and cannot be accessed in NMQR 3602; however, NMQR 3556 clearly exhibits the heads of several of its dis−

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articulated ribs ( Fig. 3 View Fig ). Each head is triangular in outline, being most broad proximally and narrowing distally, which eventually transitions to the more gracile body. The head clearly shows that the ribs are holocephalous. The bodies of the ribs possess a gentle posterior curvature that gives the ribs their shape. The sacral ribs are much shorter than even the smallest of the preserved presacral ribs; they are short robust elements fused directly to the sacral vertebrae. In NMQR 3602 the relatively short size of even the longest presacral ribs compared to the glenoid acetabular distance suggests that the trunk of Sauropareion anoplus was not as robust as some of its relatives. DeBraga (2003) estimated that Procolophon trigoniceps had a body width that was 90% the distance of its glenoid−acetabular length. However, it should be noted that the robust ribcage of Procolophon trigoniceps described by deBraga (2003) may not be accurate. Säilä (2010a) points out that deBraga does not justify the unusual attachment of ribs to the vertebral column shown in his reconstruction. Sclerosaurus armatus , another procolophonid, also possesses a large ribcage, with a width that is almost equivalent to the length of its glenoid−acetabular distance ( Sues and Reisz 2008). In comparison, the rib cage of S. anoplus is approximately one third the length of the glenoid−acetabular distance, making it appear to be a rather gracile procolophonid, similar in stature to the owenettid “ Owenetta” kitchingorum (see Reisz and Scott 2002).

Pectoral appendicular skeleton.—The pectoral girdles of each specimen offer some unique information and together reveal the structure of this region in Sauropareion anoplus . Both scapulae are preserved in NMQR 3602 ( Fig. 5 View Fig ); the scapula itself is a tall blade that curves for its entire length. The glenoids of the scapulae cannot be seen beneath matrix. Articulating with the dorsal surface of the right scapula is the clavicle, which is a flat curved element that is broad at its anterior end, becoming slimmer posterodorsally, and eventually terminating with a sharp point. The posterior tip of the clavicle articulates with the cleithrum, which is a narrow bone resembling an elongated grain of rice. Previous to this study the cleithrum has only been described in the Procolophonoidea twice: in the holotype of S. anoplus ( Modesto and Damiani 2007) and in the owenettid “ Owenetta ” kitchingorum ( Reisz and Scott 2002) . As concluded by Modesto and Damiani (2007) and confirmed in this study, the cleithrum of S. anoplus is relatively shorter than the cleithrum of “ O. ” kitchingorum . NMQR 3556 is the only one of the three specimens that has a clearly visible interclavicle ( Fig. 3 View Fig ). This element is a T−shaped bone, composed of paired anterolateral processes (the right process is obscured by the overlying anterior coracoid) and a long, flat posterior process. The point at which the posterior process meets the posteromedial margin of the anterolateral processes is a gentle curve, which is common for procolophonoids ( Cisneros 2008b). NMQR 3556 also preserves the two anterior coracoids, which are flat subcircular elements, and the posterior coracoid, which is much more triangular.

Both forelimbs of NMQR 3602 are present ( Fig. 5 View Fig ), but the manus of the right forelimb is either not preserved or obscured by supporting matrix ( Fig. 6C View Fig ). The humerus of the left forelimb is a cast, as the original humerus was removed for histological analysis prior to this study ( Botha−Brink and Smith 2012). The humerus is a robust element with a particularly stout proximal end and a smaller distal end separated by a hefty shaft. The distal end exhibits a flat trochlea and an ovoid capitulum, which articulate with the ulna and the radius, respectively. The proximal end is set at a distinct angle to the distal end, and clearly exhibits the entepicondylar foramen (or groove). As in the holotype ( Modesto and Damiani 2007), there is no supinator process on the humerus.

The radius and the ulna of NMQR 3602 ( Figs. 5 View Fig , 6C View Fig ) are relatively slender bones that are considerably more gracile and shorter and than the humerus, with the ulna being 20% shorter and the radius being 30% shorter. The ulna is also considerably more robust than the radius, being about twice as wide at the narrowest part of the shaft. The proximal end of the ulna is more expanded in comparison to its distal end because of the olecranon process, distinguishing it from the radius, which possesses proximal and distal ends of similar size. The shaft of the ulna is slightly bowed, unlike the radius, which is relatively straight. The distal ends of the ulna and the radius exhibit smooth, oval facets that articulate with the proximal carpals; NMQR 3544 clearly shows that the facet on the ulna articulated with the ulnare and the intermedium, and the facet on the radius for the radiale.

The right manus of NMQR 3602 is mostly covered by supportive matrix; only a portion of the intermedium is exposed ( Fig. 6C View Fig ). Fortunately the left manus is extremely well preserved; it lacks only the phalanges associated with digit I, and a few carpals. The carpus is partially obscured by the rest of the manus, which is twisted and preserved in ventral aspect. It exhibits a distal row of two carpal bones and a proximal row of four elements, which are likely the radiale, the ulnare, the intermedium, and the pisiform, although this is not certain thanks to the manner in which the manus is preserved. The two distal carpals that are present are all that are visible of the five that are normally present. This manus possesses five well−preserved metacarpals; they are the longest bones of the manus, excluding the metacarpal of digit I, which is significantly shorter than the other metacarpals. The metacarpals clearly ar−

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ticulate with their respective phalanges, excluding the metacarpal of digit I. With the exception of the unguals, the phalanges are all similarly shaped elements, being short and robust with broadened proximal and distal ends; the unguals themselves are broad recurved elements, longer than the penultimate phalanges. NMQR 3602 exhibits a phalangeal formula of?−3−4−5−3, which is comparable to that of other early amniotes including Procolophon trigoniceps , which has a phalangeal formula of 2−3−4−5−3 ( deBraga 2003).

Pelvic appendicular skeleton.—The pelvic girdle of NMQR 3602 ( Fig. 5 View Fig ) is preserved in such a way that the majority of it is only visible in dorsal aspect; the main portions of the girdle that can be identified are the left ischium, most of the right ischium (some bone is missing from the posterior edge), and the partially exposed left and right ilia. The pubis cannot be seen in NMQR 3602; however, the right pubis is partially preserved in NMQR 3556 ( Fig. 3 View Fig ), it is found next to the disarticulated right ischium but is not fused to it, as this is a juvenile specimen. The remaining elements of the girdle are either not preserved, or lie below overlying bone and matrix.

The ilium in NMQR 3556 ( Fig. 3 View Fig ) consists of a small gracile neck and a large, distinctive hatchet−shaped iliac blade, unlike the fan−shaped iliac blade in Procolophon trigoniceps ( deBraga 2003). (It should be noted that one of the specimens in deBraga [2003] is not assignable to Procolophon trigoniceps [ Modesto and Damiani 2007; Cisneros 2008c], and so was not used for comparisons in any part of our study). The portion of the acetabulum on the ilium cannot be seen as the left ilium is embedded in the matrix in its proper position with only its anterior edge visible, and the right ilium is exposed so that only its medial surface can be seen. The ischium of NMQR 3602 ( Fig. 5 View Fig ) is a broad fan−shaped element, being most broad posteriorly and becoming smaller anteriorly; it contributes to the pubioischiadic plate of the girdle. It is generally similar in shape to the ischium of Procolophon trigoniceps ( deBraga 2003) and Leptopleuron lacertinum ( Säilä 2010a) , a shape that is common among early amniotes ( Säilä 2010a). The pubis of NMQR 3556 ( Fig. 3 View Fig ) is not as well preserved as the ilia, and the only feature that stands out is the edge of the pubis that contributes to the pubioischiadic plate.

NMQR 3602 has extremely well preserved hind limbs ( Fig. 5 View Fig ). Both are well articulated, excluding several bones of the left pes that are obscured by other bones or not preserved. The femur is a robust bone that is 9% longer than the humerus. It possesses broad proximal and distal ends, which are moderately expanded in comparison to the shaft. The femur differs from that of Procolophon trigoniceps ( deBraga 2003) in possessing a smaller, less robust proximal end. The distal end clearly exhibits the medial and lateral condyles, separated by the intercondylar fossa. The proximal end does not appear to possess any informative features.

The tibia and the fibula of NMQR 3602 are not as long as the femur, with the tibia being 23% shorter and the fibula being 27% shorter. The tibia is the more robust of the two epipodials, being approximately twice as wide at the narrowest part of its shaft. The proximal end of the tibia is expanded and is divided into two articular surfaces for the femoral condyles. The more gracile fibula is a bowed element possessing expanded proximal and distal ends. The distal ends of both the tibia and the fibula articulate with the astragalus and the calcaneum.

The tarsus of NMQR 3602 is composed of astragalus, calcaneum, and several other small elements ( Fig. 5 View Fig ). The rectangular astragalus and ovoid calcaneum are fused into a single large quadrangular element, separated by only a small line of contact posterior to the perforating foramen, suggesting that, as a juvenile, they were not yet completely fused. This astragalocalcaneal complex is not uncommon among procolophonids and their relatives, and has also been described in Leptopleuron lacertinum ( Huene 1920; Säilä 2010a), pareiasaurs ( Lee 1997), Barasaurus besairiei ( Ketchum and Barrett 2004) , Sclerosaurus armatus ( Sues and Reisz 2008) , Macroleter poezicus ( Tsuji and Müller 2008) , and Emeroleter levis ( Tsuji et al. 2012) .

MACDOUGALL ET AL.—POSTCRANIAL SKELETON OF EARLY TRIASSIC PARAREPTILE 745

20 mm

Distal to the astragalocalcaneal complex are four subcircular tarsal elements, which articulate with the metatarsals. These are the longest bones of the pes, being relatively long and gracile except for the metatarsal of pedal digit I, which is shorter. The more proximal phalanges are robust, and the more distal phalanges gracile. Each digit terminates with a recurved ungual, and the unguals are 40% longer than the penultimate phalanges. Large unguals have also been reported in other procolophonid taxa. The pedal unguals of Procolophon trigoniceps are 50% longer than the penultimate phalanges ( deBraga 2003), and those of Sclerosaurus armatus almost twice as long ( Sues and Reisz 2008). The ventral surface of the ungual bears a relatively prominent flexor tubercle near the proximal end of the bone; this can be seen best on digit III of the right pes. Based on information from both pedes of NMQR 3602, the phalangeal formula is 2−3−4−5−3?. This formula is common for early amniotes, and is the same as the pedal phalangeal count reported by deBraga (2003) for P. trigoniceps .

Stratigraphic and geographic range.—Barendskraal and Vangfontein farms in Middelburg District, Eastern Cape Province, Republic of South Africa, Palingkloof Member of the Balfour Formation and lower strata of the Katberg Formation, Beaufort Group, Karoo Supergroup, Induan portion of the Lystrosaurus Assemblage Zone , Lower Triassic.

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