Moropus, Marsh, 1877
publication ID |
https://doi.org/ 10.1206/0003-0090(2004)285<0191:c>2.0.co;2 |
persistent identifier |
https://treatment.plazi.org/id/03A28D75-FFEC-2D16-C4ED-F91BB95AFB94 |
treatment provided by |
Felipe |
scientific name |
Moropus |
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Moropus (?) sp.: Merriam, 1911: 267. Moropus merriami : Holland and Peterson, 1914. Macrotherium merriami : Matthew, 1929: 519.
‘‘ Chalicotherium meriami ’’: von Koenigswald,
1932: 22. Moropus merriami : Colbert, 1935: 13.? Macrotherium merriami : Stirton, 1939: 629. Moropus merriami : Coombs, 1978: 11; 1998:
564.
SYNTYPES: UCMP 12596 View Materials , P4 ; UCMP 19404 View Materials , astragalus ; UCMP 19406, fused proximal and middle phalanges (duplex bone) of digit II of the manus; UCMP 10723 View Materials , ungual phalanx ; UCMP 12595 View Materials , m2 ; UCMP 19405 View Materials , calcaneum ; UCMP 19407 View Materials , large ungual phalanx. The first four specimens are from the Virgin Valley local fauna, Humboldt County, Nevada ( UCMP Locality 1065), and the last three specimens are from the High Rock Canyon local fauna ( UCMP Localities 1106 and 1107). All specimens were figured by Merriam (1911: figs. 39–45) .
COMMENT: In naming the species Moropus merriami , Holland and Peterson (1914) designated as types all of the remains ‘‘which have been well described and figured by Professor Merriam’’ (1911). Because these remains come from several localities in two different counties, they are clearly not a single individual. The International Code of Zoological Nomenclature, article 74 ( International Commission on Zoological Nomenclature, 1999), allows a reviser to designate a single lectotype from a type series. I have given careful consideration to this issue and have evaluated each of the syntypes in terms of its possible sufficiency to be lectotype. At this time, I conclude that the complete type series gives the best sense of the species and therefore neither designate a lectotype nor eliminate any of the syntypes from the type series.
HYPODIGM: Additional material from the Virgin Valley local fauna, including UCMP 11605, astragalus; UCMP 11625, calcaneum; UCMP 11746, proximal end of radius; UCMP 11842, several phalanges, partial metapodials, and a broken astragalus; UCMP 78727, cuboid; UCMP 31417, Mt III, unciform, and magnum; UCMP 11858, Mt II and duplex of digit II of the manus; UCMP 41031, scaphoid; UCMP 136621, large duplex of digit II of the manus; UCMP 136616, large ungual phalanx; UCMP 136623, duplex of the pes. Additional material from the High Rock Canyon local fauna in the Washoe Formation, including UCMP 24303, two duplexes of the pes; UCMP 35582, distal end of tibia, partial M3 and small Mt III; UCMP 136618, distal end very large Mc III. The hypodigm specimens noted here are among those most useful for the comparisons in the present paper. Undescribed chalicothere material from several additional Nevada faunas of late Hemingfordian and early Barstovian age can also be included in M. merriami ( Coombs, 1998: 564) .
Chalicothere specimens from the Lower Snake Creek fauna of the Olcott Formation, Sioux County, Nebraska, are also referable to M. merriami . From Echo Quarry (or Campsite Echo Quarry): F:AM 54164, a right ramus with p4–m3, roots of p2–3, and part of coronoid process; F:AM 54898, ramus with p2–m1; F:AM 54899, juvenile ramus with dp2–dp4; F:AM 54187, right dp3; F:AM 54165, upper molar; F:AM 54166, upper molar; F:AM 54167, upper molar; F:AM 54168, P 4 in maxilla with M1 roots; F:AM 104897, maxilla fragment with very worn M1, M2; F:AM 54181, proximal end ulna; F:AM 54171, distal end radiusulna; F:AM 140018, scaphoid; F:AM 54180, Mc IV; F: AM 54178, Mc IV proximal end; F:AM 54177, tibia; F:AM 54174, calcaneum; F: AM 54175, calcaneum; F:AM 140020, small abraded astragalus; F:AM 54176, Mt III; F: AM 54172, Mt IV; F:AM 54169, duplex of pes; F:AM 54170, duplex of pes; F:AM 54173, duplex of pes; F:AM 54179, duplex of pes. From Prosynthetoceras Quarry : F: AM 54183, P 4 in maxilla; F:AM 54182, ramus with worn p3–m2. From Humbug Quarry: F:AM 140019, proximal end juvenile Mt II.
REVISED DIAGNOSIS: A species of Moropus in which (1) wear on P4 quickly incorporates the protocone, (2) the metacone is well separated from the mesostyle in unworn upper molars, and no crista is present, (3) the lower jaw diastema is shorter than the premolar row and the symphysis ends well anterior to p2, (4) the ungual phalanx of digit II of the manus is tall and transversely compressed, (5) the astragalus is relatively broad and low with a reduced distal neck, (6) the ectal facet on the calcaneum is wide and does not extend far onto the calcaneal tuber, (7) metatarsals (especially Mt II and Mt III) are wider and deeper relative to length than in other North American chalicotheres, (8) dorsal and plantar facets between Mt III and Mt IV are strongly confluent, and (9) proximal and middle phalanges of digit II of the pes are fused.
DESCRIPTION AND COMPARISON: The following description, rather than detailing all known elements of Moropus merriami , emphasizes major aspects of skeletal morphology and characters that are important for placing specimens from the Olcott Formation of Nebraska in this species.
Like other chalicotheres, M. merriami shows substantial size variation consistent with sexual dimorphism ( Coombs, 1975). Average size for this species is fairly close to that of T. skinneri , much larger than M. oregonensis , and slightly smaller than M. elatus . A few specimens collected from Virgin Valley and High Rock Canyon (for example, UCMP 136621, a duplex, and UCMP 136618, the distal end of Mc III) are much larger than the average, and a few (for example, the Mt III included in UCMP 35582) are smaller, despite strong similarity in general morphology. The largest specimens are among the biggest chalicotheres known from North America. Most of the known specimens from Nebraska are close to the average size for the species.
Virtually nothing of the skull and only isolated parts of the upper dentition are known. P4 is the only known upper premolar (fig. 15.1E, F), with UCMP 12596 included among the species syntypes. The ectoloph of UCMP 12596 is both worn and damaged. Wear continues about equally along the protoloph and metaloph to and around the tip of the protocone. F:AM 54168 and F:AM 54183 from Nebraska are less worn examples of P4. On F:AM 54183 the protocone and transverse lophs are virtually unworn, whereas on F:AM 54168 slight wear encroaches on the protocone both anteriorly and from along the posterior surface of the metaloph. All three specimens of P4 preserve a small paraconule and fuse the lingual cingulum to the base of the protocone. F:AM 54168 and F:AM 54183 have greater development of anterolingual and posterolingual cingula than does UCMP 12596 and thus are slightly more squared in occlusal outline. However, none of the P 4 specimens of M. merriami is squared to the degree seen in Tylocephalonyx skinneri , and the parastyle is also less developed. The wear pattern is also more similar to that of Moropus oregonensis or Moropus elatus , rather than to Tylocephalonyx skinneri , in which the transverse lophs are strongly worn before significant wear encroaches on the protocone.
UCMP 35582 includes the only upper molar yet known of a Nevada chalicothere. Although only the anterior twothirds of this tooth is preserved, its posterior narrowing suggests identification as M3 (fig. 15.1C). Three isolated upper molars from Echo Quarry (fig. 15.1A, B, D) show no wear on the segment of the ectoloph posterior to the metacone and thus may also represent M3; alternatively some of these teeth could represent M2 of young individuals in which m3 had not yet erupted. All are less worn than UCMP 35582, though F:AM 54166 is closest in morphology and degree of wear. UCMP 35582, F:AM 54166, F:AM 54165, and F: AM 54167 resemble one another in having weak development of the cingulum lingual to the protocone and some degree of enamel folding on the posterolabial base of the protocone in the central valley. The three Nebraska specimens share the following additional features not seen in UCMP 35582 because of breakage or wear: labial metaloph origin more separated from the mesostyle than in M. oregonensis and M. elatus , even when the tooth is little worn; protocone more pointed than in T. skinneri ; cingulum posterior to postfossette higher than in M. oregonensis and M. elatus , but lower than in T. skinneri ; no crista or crochet; and a variable (weak or absent) ectoloph rib at the paracone.
UCMP 12595 (fig. 15.2B) is one of the species syntypes and the only lower tooth among the Nevada material that can be compared with better specimens from Nebraska (fig. 15.2A, C, D). This m2 has relatively straight lophids and weak cingula. F:AM 54164 and F:AM 54898 also have straight rather than curved lophids on the lower molars, but the cingula are stronger and there is a distinct low lingual cingulum along the opening of the talonid basin. The strong metastylid resembles that of M. elatus more than the weaker metastylid of T. skinneri . Premolar/molar row length proportions are close to those of M. elatus and higher (0.51 in F:AM 54164) than the average in T. skinneri (see table 3 in Coombs, 1979). The p2 of F:AM 54898 has a smaller, blunter paraconid and talonid than counterparts in M. elatus , but the talonid is less reduced and compressed against p3 than in T. skinneri . Wellpreserved dp2–dp 4 in F:AM 54899 are comparable to permanent lower molars of F: AM 54164 in having straight lophids, a strong metastylid, and a lingual cingulum at the opening of the talonid basin on dp3 and dp4. Like p2, dp2 is less shortened than dp 2 in T. skinneri .
F:AM 54164 preserves the diastema and much of the lower jaw symphysis (fig. 15.2A, C). No incisors are preserved, but two small alveoli lie above the much larger mental foramen, which is thus near the anterior end of the diastema rather than partway along it as in M. cf. oregonensis , M. elatus , and T. skinneri . The diastema is relatively short, only about twothirds the length of the premolar row. Among North American chalicotheres that retain this part of the jaw, only M. cf. oregonensis has a shorter relative diastema (about half the length of the premolar row), whereas that in M. elatus and T. skinneri equals or exceeds the premolar length ( Coombs et al., 2001). The jaw symphysis also is short, ending well anterior to p2.
Known parts of the forelimb include fragments of the radius and ulna, individual carpals and metacarpals, and some phalanges. Except for an unusual enlargement on the radial side of the olecranon process of the ulna on F:AM 54181, the long bones show no notable differences compared to species ( M. elatus , M. hollandi , T. skinneri ) in which these bones are better known. The anconeal process on the ulna is strongly developed, comparable to that in T. skinneri . As in other chalicotheres, the radius and ulna are strongly fused at their distal ends (F:AM 54171).
The scaphoids of UCMP 41031 and F:AM 140018 (fig. 15.3D, E) are quite similar, although articular facets in UCMP 41031 are much less well preserved. Both scaphoids show clear presence of a trapezium facet, thus confirming the presence of this bone, in contrast to its loss in M. hollandi . The distal process is less developed and less squared than its counterpart in M. elatus or M. hollandi , resulting in a more oblique facet for the magnum on the ulnar surface of its distal end. This facet is only weakly visible on the abraded scaphoid of UCMP 41031, but the presence of an oblique contact between the scaphoid and magnum is confirmed by the scaphoid facet on UCMP 31417, a magnum also from Virgin Valley. T. skinneri also reduces the distal process somewhat and has an oblique facet between the scaphoid and magnum.
F:AM 54178 (fig. 15.4A) and F:AM 54180 are the only metacarpals referable to M. merriami that preserve the proximal articulations. While F:AM 54180 preserves the entire bone, its articular surfaces are damaged by abrasion. Both specimens have a notch in the ulnoplantar surface near the proximal end, suggesting the retained presence of a vestigial Mc V; however, no well defined facet for this bone exists. Mc IV of M. merriami resembles those of M. elatus and M. hollandi in having the facet for Mc III on the radial surface of the proximal end extend all the way from the dorsal to the plantar edge. In contrast, only the dorsal part of the Mc III facet occurs in T. skinneri . The dorsal part of the facet for Mc III is much larger than the plantar part and has an extensive distally directed tongue at the dorsoradial angle of the bone. The smaller, more plantar part of the Mc III facet has an entirely radial orientation. The two parts of the Mc III facet are continuous but delineated by a ridge. Another ridge delineates the Mc III facet from the radial margin of the unciform facet, which occupies the proximal surface of Mc IV.
Like other species of Moropus , M. merriami enlarged the phalanges of digit II of the manus into a prominent clawed hook. The syntypes of M. merriami include proximal and medial phalanges of digit II that have fused to form a duplex (UCMP 19406; Merriam, 1911: fig. 43). This duplex is more robust for its length and more asymmetrical in its fusion and development of the facet for Mc II than counterparts in M. elatus and M. hollandi ; it resembles T. skinneri in these respects. The syntypes of M. merriami also include two ungual phalanges, UCMP 19407 ( Merriam, 1911: fig. 45) and UCMP 10723 ( Merriam, 1911: fig. 44). UCMP 19407 and UCMP 136616 represent enlarged claws of digit II of the manus of big individuals. They are unusually compressed transversely, with a prominent subungual process and a relatively short but thick dorsal process. Transverse compression is much greater than that seen in M. elatus , M. hollandi , and T. skinneri ( Coombs, 1979: table 12) but is similar to that of AMNH 9076, part of the type of Moropus matthewi Holland and Peterson (1914). The nearly right angle bend in the claw articulation for the duplex suggests very little movement between these phalanges. UCMP 10723 is a smaller (but still goodsized), less compressed ungual; the digit to which it belongs is unclear. Unfortunately, no phalanges clearly attributable to the manus and no unguals have been recovered among the specimens of M. merriami from Nebraska.
Hindlimbs of M. merriami are represented by some long bone material and a number of tarsals, metatarsals, and phalanges. UCMP 35582 includes the distal end of the tibia and F:AM 54177, a complete tibia of a subadult individual. Proportions of these bones are, in general, comparable to counterparts in M. elatus , M. hollandi , and T. skinneri .
The syntypes of M. merriami include both an astragalus (UCMP 19404, Merriam, 1911: fig. 42) and a calcaneum (UCMP 19405, Merriam, 1911: fig. 41). Additional specimens of both bones are found among the UCMP collections from northwest Nevada. Collections from the Olcott Formation include a small abraded astragalus (F:AM 140020) and two calcanea (F:AM 54174, F: AM 54175). The astragalus of M. merriami resembles that of M. elatus and M. hollandi in being less symmetrical than that of T. skinneri , with the fibular side of the trochlea broader and more gradually slanted than the tibial side. On the other hand, it differs from the earlier Miocene species M. elatus and M. hollandi , and resembles T. skinneri , in its reduced distal neck. Reduction of the distal neck and trochlear height compared to width seems to occur gradually over time in schizotheriine chalicotheres (see Coombs, 1978: table 4); reduction of the height of the astragalus never, however, reaches proportions observed in chalicotheriine chalicotheres such as Chalicotherium . As in other species of Moropus , the distal surface of the astragalus articulates only with the navicular, with no trace of a facet for the cuboid.
Figure 15.5 View Fig shows the similarities in proportions and facet shapes between calcanea from Nevada and Nebraska. The ectal facet is transversely broad but does not extend far onto the calcaneal tuber, a similarity with T. skinneri . In contrast, the ectal facet in M. elatus and M. hollandi is narrower but extends more substantially onto the tuber. In UCMP 19405 the ectal facet extends far enough in the tibial direction to contact the sustentacular facet, though the two facets are still delineated by a distinct ridge. In F:AM 54174 and F:AM 54175 the ectal and sustentacular facets remain separated by a groove; this condition is probably the more common one in M. merriami overall, as suggested by additional calcanea and astragali from the Virgin Valley collections. The part of the ectal facet on the tuber is raised on a platform, which, when the astragalus and calcaneum are articulated, can form a contact with the tibia in continuation with the astragalar trochlea. This platform and its articular surfaces are best seen in UCMP 19405 (fig. 15.5A).
Metatarsals of M. merriami are reasonably well known and very useful taxonomically. Table 15.1 gives length:width proportions for metatarsals of a number of North American chalicotheres. Moropus merriami has proportionately the shortest and broadest Mt II of any North American chalicothere, and Mt III and Mt IV among the shortest and broadest. Mt III is the only metatarsal for which complete elements from both northwest Nevada and Nebraska are available, and these bones are very similar in proportions, thus helping to confirm the species identity of the Nebraska material. Coombs (1979: table 9) also reported length:maximum distal depth and length:minimum shaft depth proportions for Mt III of North American chalicotheres. UCMP 35582 and UCMP 31417 have the lowest length:distal depth (2.3 and 2.4) and lowest length:shaft depth (4.2 and 4.1) of any of the specimens listed; F:AM 54176 has similarly low ratios, with length:distal depth = 2.4 and length:shaft depth = 4.3. Both the width and depth of Mt III compared to length can be observed in figure 15.6. Another important issue concerns the relative lengths of Mt III and Mt IV in M. merriami . As has been noted elsewhere ( Coombs, 1978, 1979), Mt IV is slightly longer than or subequal in length to Mt III in Moropus , whereas Mt III is longest in Tylocephalonyx and other schizotheriine chalicotheres such as Ancylotherium . Although F:AM 54176 (Mt III) and F: AM 54172 (Mt IV) from Echo Quarry are not associated, they appear to belong to a similarsized animal and articulate well with each other. Of these specimens Mt IV is longer (135.5 mm, versus 128.3 mm for Mt III), suggesting the length proportions typical of Moropus .
UCMP 11858 is the bestpreserved specimen of Mt II. Although proportionately shorter and more robust, it resembles Mt II of T. skinneri and M. matthewi in having its proximal articulation for the mesocuneiform in the form of an equilateral triangle with its apex midway on the tibial side (in M. elatus the triangular facet is not equilateral and its apex is at the plantar extremity of the tibial side). Another similarity to T. skinneri and M. matthewi is the more proximal orientation of the plantar half of the ectocuneiform facet (in M. elatus the ectocuneiform facet has a more strictly fibular orientation). Facets for the ectocuniform and Mt III are confluent on the fibular surface. UCMP 11858 has a lengthy rugose area in the location of the oblique ridge observed in M. elatus ( Coombs, 1978: fig. 18). F:AM 140019, from Humbug Quarry, shares characters of the proximal facets with UCMP 11858 but, being immature with a missing distal epiphysis, has a slenderer shaft with no rugosities.
The Mt IIIs of UCMP 31417 and F:AM 54176 are extremely similar in proportions and morphology (fig. 15.6). A sharp ridge separates the ectocuneiform facet on the dorsal surface and the adjacent Mt IV facet on the fibular surface. The dorsal and plantar parts of the Mt IV facet are broadly confluent, a character unique to M. merriami . In M. elatus , M. cf. hollandi , and T. skinneri , there are distinctive dorsal and plantar parts to the Mt IV facet. The long, undivided facet probably allowed some abduction of Mt IV, a distinct difference from T. skinneri , in which Mt III and IV appear to have interlocked tightly. Tylocephalonyx skinneri also lacks the sharp ridge between the ectocuneiform and Mt IV facets, but there is sometimes a short gap between the facets instead. On the tibial surface of Mt III, the articular facet for Mt II forms a continuous dorsal to plantar band with small tonguelike distal expansions at both ends. Unlike T. skinneri , the shaft of Mt III is deep rather than compressed in depth and the phalangeal articulation is convex in all directions rather than flat or transversely concave.
F:AM 54172 (fig. 15.4B), a Mt IV, can be referred to M. merriami on the basis of confluent dorsal and plantar parts of the facet for Mt III. The more proximal part of this large facet merges into a more proximally oriented contact with the ectocuneiform. Although no ectocuneiform is available from these collections, it is clear when F:AM 54172 and F: AM 54176 (Mt III) are articulated that Mt IV would articulate with the ectocuneiform. A Mt IV to ectocuneiform contact is characteristic of Moropus and does not occur in Tylocephalonyx .
Coombs and Rothschild (1999) reviewed phalangeal fusion in schizotheriine chalicotheres. Whereas the proximal and middle phalanges of digit II of the manus are known to fuse to form a duplex in Moropus , Tylocephalonyx , Phyllotillon , and Ancylotherium , fusion of other phalanges is more restricted. Fusion of proximal and middle phalanges of digit II of the pes occurs in approximately 11% of known specimens of M. elatus and 60% of known specimens of T. skinneri ( Coombs and Rothschild, 1999: table 1). Synonymy of M. distans with M. oregonensis ( Coombs et al., 2001) means that a duplex occurs in the only specimen of M. oregonensis for which these phalanges are known. Duplex phalanges of the pes are smaller than those of digit II of the manus and lack the distinctive facet enlargements and asymmetries ( Coombs, 1978: figs. 19, 20; 1979: fig. 25; Coombs and Rothschild, 1999). Among specimens of M. merriami from Nevada, there are six duplexes that do not belong to digit II of the manus; four duplexes from Echo Quarry also do not belong to digit II of the manus. Because the only other digit for which duplex fusion is known is digit II of the pes, it is logical to assume that all ten of these duplexes should be attributable to this digit. No unfused proximal and medial phalanges of digit II of the pes are known, so fusion appears to be 100%. Figure 15.3A– C View Fig gives dorsal views of three of the ten duplexes: UCMP 136623, F:AM 54179, and F: AM 54169. All three of these duplexes are relatively large. UCMP 136623 and F:AM 54179 are robust bones, which are wide for their length. F:AM 54169 is much more slen der than the other two duplexes figured, as is F:AM 54170. While some size variation is expected, the degree of difference in size and shape is surprising for the phalanges of a sin
(C) views of Mt III of M. merriami . On left,
UCMP 31417, a right Mt III from Virgin Valley local fauna, Humboldt County, Nevada. On right,
F:AM 54176, a left Mt III from Echo Quarry,
Sioux County, Nebraska. Scale bar = 4 cm. gle digit. While some (and perhaps all) of these duplexes probably belong to digit II of the pes, it is possible that fusion of phalanges of other digits has occurred. More associated material is needed to help resolve this issue.
TAXONOMIC DISCUSSION: Moropus merriami is clearly a derived schizotheriine chalicotheriid, and its reference to Moropus is confirmed by the subequal lengths of Mt III and Mt IV and by articulation between Mt IV and the ectocuneiform. It further differs from T. skinneri in having earlier wear of the P4 protocone, a weaker cingulum immediately posterolingual to the protocone on upper molars, straighter (less curved) lower molar lophids and larger metastylids, a less reduced premolar row, a shorter diastema and jaw symphysis, a plantar component on the articulation between Mc IV and Mc III, a taller, more transversely compressed ungual phalanx of digit II of the manus, a more asymmetrical astragalus, wider and deeper Mt II and Mt III relative to length, more moveable articulation between Mt III and Mt IV with confluent dorsal and plantar facets, and fusion of all known proximal and middle phalanges of digit II of the pes. Moropus merriami does resemble T. skinneri in some regards, such as reduced lower incisors, robust duplex of digit II of the manus, shortened astragalus with reduced distal neck, shape of ectal facet on the calcaneum, shape of proximal facets on Mt II, and some degree of metatarsal shortening and broadening (especially Mt IV).
Moropus merriami differs from M. elatus in having smaller lower incisors, a shorter diastema and lower jaw symphysis, somewhat lower crowned and less elongated molar teeth, a less squared distal process on the scaphoid and a more oblique facet for the magnum, a more robust duplex of digit II of the manus, a taller and more laterally compressed ungual phalanx of digit II of the manus, a broader shorter astragalus with reduced distal neck, a wider ectal facet on the calcaneum which extends less onto the calcaneal tuber, much wider and shorter metatarsals, Mt II with the mesocuneiform facet forming more of an equilateral triangle and with a more proximal orientation of the plantar part of the ectocuneiform facet, strong confluence of the dorsal and plantar facets between Mt III and Mt IV, and fusion of all known proximal and middle phalanges of digit II of the pes. These differences also apply in general to M. hollandi , though M. hollandi also differs in losing the trapezium.
Moropus merriami is much larger than M. oregonensis and is more derived in losing the crista and having a larger distance between the mesostyle and metacone on unworn upper molars. Metatarsals and an astragalus that have been referred to M. cf. oregonensis also lack the derived broadening and shortening that occurs in M. merriami . However, there are resemblances between M. oregonensis and M. merriami in the wear pattern on P4, general molar shape and cusp morphology, short diastema (see M. cf. oregonensis in Coombs et al., 2001), and fusion of known proximal and middle phalanges of digit II of the pes.
Moropus matthewi Holland and Peterson (1914) from northeastern Colorado has poor type locality information, which makes its (possibly early Barstovian) age assignment difficult to verify (see Skinner, 1968). The fragmentary material of this species shows some similarities to M. merriami , for example, the tall, transversely compressed large ungual phalanx of digit II of the manus. However, known Mt II specimens of M. matthewi show less shortening and broadening than occurs in Mt II of M. merriami (table 15.1).
Despite the substantial similarities between material of M. merriami from the Olcott Formation and Nevada specimens from Virgin Valley and High Rock Canyon, some minor differences do occur. Specimens from the Olcott Formation have better developed anterolingual and posterolingual cingula on P4 and more development of lingual cingula opposite the talonid basin on the lower molars. The Olcott collection of pedal duplexes includes some specimens that are proportionally more slender than any of the Nevada specimens. These differences can be considered within the range of a single species, especially in view of the geographic distance between the two populations.
The present paper omits detailed discussion of Frick chalicothere material collected from Observation Quarry in Dawes County, Nebraska. The fauna from Observation Quarry has been considered to be roughly equivalent to the Lower Snake Creek fauna and thus early Barstovian in age ( Tedford et al., 1987). Chalicothere material from Observation Quarry includes a skull and jaws (F:AM 54889), a large humerus (F:AM 54891), and a large femur (F:AM 54890). The teeth of F:AM 54889 are extremely worn and are thus difficult to compare with those of other chalicotheres. The skull is clearly not domed and thus is unlikely to belong to Tylocephalonyx . The posterior part of the mandibular ramus is well preserved and displays a large angular process. The humerus and femur are more robust, especially in shaft width, than in any other known North American chalicothere. In contrast, available limb bones of M. merriami (parts of radius and ulna, tibia) are not too different from material of M. elatus , M. hollandi , and T. skinneri and are inconsistent with the unusually robust proportions of the humerus and femur from Observation Quarry. It is possible that the Observation Quarry chalicothere elements represent an individual variant, most likely a large, old male. While this chalicothere needs to be kept in mind in any discussion of M. merriami , its taxonomic referral is still uncertain.
UCMP |
University of California Museum of Paleontology |
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Moropus
COOMBS, MARGERY C. 2004 |
Moropus
Matthew, W. D. 1929: 519 |
Merriam, J. C. 1911: 267 |