INTRODUCTION

The Brontotheriidae is an exclusively Eocene family of perissodactyls, notable for having evolved bony frontonasal protuberances (or “horns”) and body sizes approximating those of extant rhinos and elephants. The bulk of the known brontothere fossil record is from inner and outer Mongolia and western North America (Osborn 1929a, 1929b; Granger and Gregory, 1943; Yanovskaya, 1980; Wang, 1982). Although brontothere records are fewer and more fragmentary in other regions, it is evident that brontotheres had essentially a holarctic distribution, with the exception of western Europe (Pilgrim, 1925; Colbert 1938; Takai, 1939; Gazin, 1942; Dehm and Oettingen-Spielberg, 1958; West, 1980; Kumar and Sahni, 1985; Qi and Beard, 1996; Eberle and Storer, 1999; Holroyd and Ciochon, 2000; Miyata and Tomida, 2003).

Although brontothere taxonomy is widely regarded as being in need of revision (e.g., Prothero, 1994), it is clear that this family was one of the most diverse ungulate clades during the Eocene. A dizzying array of subfamilial names have been given to brontotheres throughout the history of their study, but rigorous testing of brontothere phylogeny has been minimal for North American taxa (Mader, 1989, 1998) and is nonexistent for Asian taxa. For lack of a sound taxonomy or phylogenetic framework for brontotheres, particularly outside of North America, we refer to those brontotheres possessing frontonasal protuberances (horns) as the “horned” brontotheres, and the probable paraphyletic assemblage of more primitive brontotheres that lack frontonasal protuberances as the “hornless” brontotheres.

The new genus and species of horned brontothere, Aktautitan hippopotamopus, described here from eastern Kazakstan, is the first middle Eocene record of a brontothere known from complete skeletons west of the Gobi region.

GEOLOGICAL CONTEXT

The Ily basin of eastern Kazakstan is the western portion of a paleo-Tien Shan basin that extended into western China (fig. 1). In the Ily basin, the Cenozoic section is best exposed at and around Aktau Mountain in the southern foothills of the Dzhungarian Alatau. At Aktau Mountain, the Cenozoic section is about 2.5 km thick and mostly of Neogene age (Lavrov and Rayushkina, 1983). The lower 150 m or so of this section are of Eocene age and are assigned to the Kyzylbulak Formation (figs. 2, 3A), which is best exposed at Kyzyl Murun, at the core of the Aktau Mountain anticline (Lucas et al., 1997). Here, the Kyzylbulak Formation is siliciclastic red beds of sandstone, conglomerate, mudstone, and shale. The Aktau Formation disconformably overlies the Kyzylbulak Formation and yields late Oligocene (Tabenbulukian) mammals in its lower part, and early Miocene mammals in its middle to upper parts (Lucas et al., 1997).

The brontothere bonebed at Aktau Mountain was discovered in May 1996. It extends over a strike of ∼200 m at and around UTM zone 44, 361142E, 4874810N (datum WGS 84) in approximately the middle of the Kyzylbulak Formation exposure at Kyzyl Murun (fig. 2). The bone bed is in a ∼0.5-m- thick bed of green, bentonitic shale (figs. 2, 3D). In addition to the brontotheres, the bonebed at Kyzyl Murun yields fossils of a Teleolophus-like tapiroid, a new species of the rhinocerotoid Rhodopagus and the amynodontid rhinoceros Sharamynodon mongoliensis (Lucas and Emry, 2001; Emry and Lucas, 2003). These fossils indicate an Irdinmanhan (middle Eocene) age for the brontothere bonebed at Kyzuyl Murun.

In the brontothere bonebed at Kyzyl Murun, complete, articulated brontothere skeletons are preserved in green, smectictic shale. In at least two of the excavated brontothere skeletons, articulated feet were found upright in the shale, with the remaining skeleton lying on its side. The bone-bearing shale has a lenticular geometry, fine laminations, and lacks any evidence of pedogenesis. These features are consistent with a pond or lake deposit, not as floodplain muds in the otherwise fluvial deposits of the Kyzylbulak Formation (cf. Lucas et al., 1997). We thus conclude that at least some (or all) of the brontothere remains at Kyzyl Murun were preserved in a lacustrine deposit, and at least some of the animals apparently died while mired in mud.

SYSTEMATIC PALEONTOLOGY

DESCRIPTION

The completeness and position of the brontothere skeletons in the sediment suggest that the animals were trapped in deep mud and preserved completely (although some of the specimens had been eroded away). All of the feet were preserved deepest in the mudstone (30 cm or more below the level of the thorax). The digits of the feet were hyperflexed, extending outward and upward from the distal ends of the metapodials (see figs. 12, 16). Some of the longbones, especially those of the lower limbs, were preserved vertically in the sediment, with the remainders of the skeletons collapsed directly over the limbs and feet. Compression of the mudstone bed has resulted in deformation of the bones within it, and those longbones preserved more or less vertically are substantially shorter that their counterparts that were preserved more or less horizontally.

The skull of the holotype (KAN N2/875) is essentially complete, although it was lying on its side and is somewhat compressed laterally. The referred skull (KAN N2/873) is compressed obliquely (more laterally than vertically). This distortion compromises the measurement of various cranial dimensions. The postcranial material belonging to the holotype, KAN N2/875, consists of the entire skeleton, missing only some parts of the right tarsus and proximal metatarsus (the right ankle was the only part of this individual exposed at the surface). Much of the thorax and forelimbs remain articulated in a large block, preventing detailed study of some of the individual bones.

Asian brontotheres are rarely known from associated skulls and postcrania. The entire skeleton of Rhinotitan mongoliensis (Wang, 1982) and parts of the skeletons of Metatitan relictus (= Protitan khatishinus Yanovskaya, 1980, see below), cf. Parabrontops gobiensis (PIN 3109, mistakenly referred to Metatitan relictus by Yanovskaya, 1980; see below for explanation), and Embolotherium andrewsi (Yanovskaya, 1980) have been described. The skeletons of many North American taxa are better known. They include essentially complete skeletons of Brontops, Dolichorhinus, and Palaeosyops and partial postcranial material from several other North American taxa (Peterson, 1924; Osborn, 1929a). The postcranial remains of Aktautitan hippopotamopus are compared to Asian taxa when possible, but due to the lack of abundant comparative material, observations of the skeletons of North American species have been included as points of reference.

POSSIBLE AKTAUTITAN TRACKWAYS

Aktautitan? tracks are exposed at Kyzyl Murun near Aktau Mountain (fig. 1) at UTM zone 44, 362307E, 4873406N (datum: WGS 84). They are in the Kyzylbulak Formation in the upper part of unit 26 of the measured section of Lucas et al. (1997: fig. 3) (see fig. 2 of this paper). The track-bearing stratum is a 0.1-m-thick bed of light greenish-gray (5 GY 8/1), very fine-grained calcareous silty sandstone that is ∼0.5 m above the bonebed dominated by the complete, articulated skeletons of Aktautitan hippopotamopus.

At Kyzyl Murun, about 100 tracks are preserved as “potholes” in sandstone (fig. 17). The footprints are preserved in concave epirelief, generally lack clear orientation, and are crowded and superimposed to indicate a trampled surface. All are round, ovoid, or oblong in shape and have diameters of ∼0.2 m and depths of up to ∼0.1 m. They lack clear indications of digits, pads, or hooves and obviously are underprints. A single partial trackway indicates the trackmaker was a quadruped with a gleno-acetabular length of ∼1.2 m and a trackway width of ∼0.4 m.

The mammal tracks reported here closely resemble those previously reported Paleogene mammal tracks attributed to brontotheres or rhinoceroses. Thus, the tracks attributed to large perissodactyls and described by Hamblin et al. (1998, 1999) from the Uintan (middle Eocene) of Utah are approximately the same size and shape as those from Kyzyl Murun. Sarjeant and Langston (1994: p. 40–41, pls. 4, 24) described and illustrated large perissodactyl tracks from the Chadronian (late Eocene) of Texas that are larger than, but otherwise very similar to, the Kyzyl Murun tracks. Other tracks attributed to Chadronian brontotheres (e.g., Chaffee, 1943) are also larger than, but similar to, the Kyzyl Murun tracks.

The Kyzyl Murun tracks are undertracks that poorly record the foot shape and other anatomical details of the trackmaker. Thus, a precise identification is impossible, though a large perissodactyl trackmaker seems most likely. Body fossils from the underlying strata of the Kyzylbulak Formation belong to the brontothere Aktautitan hippopotamopus and the amynodont rhinocerotoid Sharamynodon, both possible trackmakers. Although it is difficult to reconstruct the general body proportions of A. hippopotamopus from the material at hand, Rhinotitan mongoliensis is of similar size and is known from a mounted skeleton and can therefore be used for size estimates (Wang, 1982). Thus, femur lengths suggest A. hippopotamopus is about 70% the size of Rhinotitan, which would give A. hippopotamopus an estimated gleno-acetabular length of about 1.1 m and manus and pes diameters (minus any fleshy pads) of 14–19 cm. Based on Osborn (1936), Sharamynodon has a gleno-acetablular length of 1.4 m and manus and pes diameters (minus fleshy pads) of 16–19 cm. Thus, based on size and foot shape, either Aktautitan or Sharamynodon are plausible trackmakers of the Kyzyl Murun footprints. The abundance of the brontothere and the relative rarity of the amynodont lead us to suggest that the brontothere was the more probable trackmaker.

The Kyzyl Murun tracks are the first report of fossil mammal tracks from Kazakstan. They fit well into what is known of Paleogene mammal tracks, namely that they are mostly the footprints of primitive large ungulates and carnivores. Paleogene tracks are known mostly from North America and are dominantly the footprints of primitive perissodactyls, artiodactyls, and carnivores (e.g., Chaffee, 1943; Curry, 1957; Sarjeant and Wilson, 1988; Lucas and Williamson, 1993; Sarjeant and Langston, 1994; Hamblin et al., 1998, 1999). Records from outside of North America—from China, Peru, western Europe, and Iran—also fit this pattern (e.g., Lockley et al., 1999; Ataabadi and Sarjeant, 2000).

PHYLOGENETIC ANALYSIS

Granger and Gregory (1943) presented the first explicit hypothesis of Asiatic brontothere phylogeny (fig. 18A) and regarded the horned members of the family as a single radiation. These were included in the Epimanteocerotinae (paraphyletic) and Embolotheriinae (a monophyletic clade nesting within the Epimanteocerotinae). Granger and Gregory (1943) viewed this radiation as separate from that of the North American horned brontotheres (diplacodonts sensu lato, Mader, 1989). Asian horned brontothere evolution was depicted as a bushlike middle Eocene (Irdinmanhan) radiation stemming from a Telmatherium-like North American ancestor. Two temporally persistent lineages extending to the terminal Eocene (considered early Oligocene at the time) were interpreted as rising from the primitive Irdinmanhan horned genus Protitan: a Rhinotitan-Parabrontops- Metatitan lineage and a separate Embolotherium lineage. Yanovskaya (1980) and Wang (1982), using methods no more sophisticated than those of Granger and Gregory (1943), suggested a different hypothesis with a Protitan-Rhinotitan-Embolotherium lineage and a separate Metatitan lineage originating independently from Telmatherium (fig. 18B).

It is widely recognized that Asiatic brontothere phylogeny is minimally understood (Schoch, 1983; Prothero, 1994). The only published cladistic hypotheses of brontothere phylogeny exclude Asian taxa (Mader, 1989, 1998). Nevertheless, emerging evidence indicates that North American and Asiatic brontotheres form phylogenetically mixed assemblages, due to several intercontinental dispersal events in the middle Eocene (Mihlbachler, 2003a). A more comprehensive analysis of brontothere phylogeny will be presented elsewhere, but a preliminary analysis is reported here to gain an initial understanding of Asiatic brontothere interrelationships and the phylogenetic status of Aktautitan hippopotamopus.

A cladogram of 17 taxa was generated from 40 characters (23 skull, 8 upper dentition, 2 dentary, 7 lower dentition) with 58 character-state transformations via PAUP version 4.0b10 (Swofford, 2001) utilizing the branch-and-bound search option. The North American Bridgerian brontotheres Palaeosyops robustus and Telmatherium validus were used as outgroups. Palaeosyops is generally regarded as the most primitive brontothere known from abundant fossil material. Telmatherium is widely regarded as the ancestor or sister taxon of horned brontotheres of North America and Asia (Osborn, 1929a; Granger and Gregory, 1943; Mader 1989, 1998). Brachydiastematherium transylvanicum, the only brontothere known from Europe, was included in the analysis due to its obvious paleogeographic significance in relation to Aktautitan.

An analysis with ordered multistate characters (except character 35, which lacked a clear morphoclinal order) yielded nine trees, 97 steps long (CI = 0.62, RI = 0.73), with a relatively resolved strict consensus cladogram (fig. 18C). Inclusion of Microtitan mongoliensis generates a substantially less well-resolved tree with a polytomy including Epimateoceras-Dolichorhinoides, Protitan, and Microtitan. This polytomy can be attributed to missing data in Microtitan, a taxon known only from cheekteeth. Our results are neither congruent with Granger and Gregory's (1943) phylogenetic hypothesis nor with those of Yanovskaya (1980) and Wang (1982). These earlier hypotheses suggested that Embolotherium and Metatitan are widely separate lineages. In our tree, Metatitan and Embolotherium form a robust clade. The genus Metatitan is paraphyletic; Metatitan progressus groups with Embolotherium; and Brachydiastematherium resides in an unresolved trichotomy with Metatitan relictus (the type species of Metatitan) and Metatitan primus. Aktautitan is the sister taxon to the Metatitan-Embolotherium-Brachydiastematherium clade. Remaining taxa form a relatively comb-shaped succession down to the base of the cladogram. The multispecific genera Protitan and Rhinotitan were recovered as monophyletic.

TAXONOMIC REVISIONS

Emry et al. (1997), Lucas and Emry (2001), and Emry and Lucas (2002, 2003), based largely on comparison to Yanovskaya (1980), provisionally attributed the Ily Basin brontothere to Protitan. This assignment is contradicted by the phylogenetic evidence presented above, but this misdiagnosis has led us to realize a misleading problem with the taxonomic histories of both Protitan and Metatitan. Yanovskaya (1980) named two new species, Protitan khaitshinus and Protitan reshetovi, with material from the Khaychin Formation, Mongolia. The referral of these species to Protitan seems to have been based on the presence of two characteristics: (1) large paired pits on the ventral surface of the body of the sphenoid and (2) a wide emargination surrounding the anterior and lateral margins of the posterior nares. However, neither character is diagnostic of Protitan (sensu Granger and Gregory, 1943). Specimens originally referred to Metatitan relictus Granger and Gregory, 1943, including the holotype (AMNH 26391), seem to possess the paired sphenoidal pits as well, although a conclusive interpretation based on the material originally described by Granger and Gregory (1943) is hindered by the state of preservation of the specimens. It is nonetheless possible that Metatitan relictus possessed the paired sphenoidal pits seen in Protitan. Paired pits on the ventral surface of the body of the sphenoid can also be found in a variety of North American taxa such as Sphenocoelus uintensis, Pseudodiplacodon progressum, and Sthenodectes australis (=? Protitanotherium emarginatum) (Osborn, 1895; Mihlbachler, unpubl. data). Additionally, Metatitan and Embolotherium share the wide emargination of the posterior nares seen in Protitan. Therefore, the criteria used by Yanovskaya (1980) to assign the species P. khaitshinus and P. reshetovi to the genus Protitan are also consistent with Metatitan. Further comparison indicates that these species are actually more similar to Metatitan.

Protitan Granger and Gregory, 1943 is characterized by a relatively wide flat forehead, with small elliptical horns positioned far apart and very low on the skull (fig. 19A, B). The dorsal surface of the skull behind the orbits is convex, and the parasagittal ridges are greatly constricted medially over the sagittal region of the skull. Dentally, Protitan is recognizable by its conical upper and lower incisors, often with small diastemas between them, that form a broad arch anterior to the canines, a postcanine diastemata, and a metaconid present only on p4.

Metatitan Granger and Gregory, 1943 can be distinguished from Protitan by the more deeply concave forehead, closely positioned, elevated frontonasal horns, and raised nasal process (fig. 19C, D). In Metatitan, the region of the skull posterior to the orbits is greatly widened with expanded parietal and squamosal sinuses and a greatly widened occiput. The parasagittal ridges are widely separated over the parietal region. The incisors are reduced in size, and all but the I3 are globular in shape and form a straight line between the canines. A postcanine diastema is absent and a metaconid is present on p3 and p4 (but lacking on p2).

The skulls of Protitan khaitshinus (PIN 3745-1, PIN 3745-2) match Metatitan in every respect (except the incisors, which are missing) and should be referred to Metatitan. Specifically, they most closely resemble Metatitan relictus. Therefore, we consider Protitan khaitshinus to be a junior objective synonym of Metatitan relictus. The skull of Protitan reshetovi (PIN 3745-11) possesses a partial set of diagnostic Metatitan features, including elevated and closely positioned frontonasal protuberances with elevated nasal processes, no postcanine diastema, and widely separated parasagittal ridges with a widened occiput. However, the premolars are significantly more molarized that those of Metetitan relictus, with two distinct lingual cusps, and the posterior region of the skull lacks the swollen appearance seen in Metatitan relictus and Metatitan primus. Additionally, the incisors (known only from a partial I3 crown) appear not to have been reduced in size in contrast to M. relictus and M. primus. In most of these respects, P. reshetovi resembles Aktautitan hippopotamopus. However, the premolars of A. hippopotamopus are significantly less molarized than those of P. reshetovi. Protitan reshetovi is probably a valid species that is somewhat intermediate in morphology between Aktautitan and Metatitan. We hesitate to assign it to either of these genera without directly examining the material, but we state with confidence that Protitan reshetovi should be removed from the genus Protitan.

In addition to these errors, Yanovskaya (1980) referred skeletal material (PIN 3109) from the Ergilin Dzo Formation, Mongolia, to Metatitan relictus. The skull (PIN 3109- 90), however, does not compare favorably with Metatitan relictus Granger and Gregory, 1943. The frontonasal horns and nasal processes are more massive and not highly elevated above the orbits. The anterior margin of the posterior nares is positioned anterior to the M3, the posterior portion of the cranium is not expanded or widened, the zygomatic arch is more massive, there is a postcanine diastema, and the number of incisors is reduced. The description of this material conforms very closely to that of Parabrontops gobiensis (Osborn, 1925).

The discovery of Aktautitan hippopotamopus in the Ily Basin of Kazakstan does not contribute substantially to the total geographic range of the Brontotheriidae, but it is the first relatively complete brontothere found west of the Gobi and therefore offers significantly improved knowledge of Old World brontotheres toward the western periphery of their distribution. A single specimen of Brachydiastematherium transylvanicum Böckh and Maty, 1876, from Andrashaza, Romania, is the only known record of a European brontothere. Although it is known only from its holotype, an incomplete mandible, it is of extraordinary importance because it is the extreme westward occurrence of Old World middle Eocene Brontotheriidae. Lucas (1983) and Lucas and Schoch (1989) considered B. transylvanicum a synonym of the North American Diplacodon. Although Diplacodon is currently recognized as a nomen dubium (Mader, 2000), it was considered at the time to be a senior synonym of another North American genus, Protitanotherium (Lucas, 1983). Protitanotherium is currently recognized as a valid genus (Mader, 1989); however, Brachydiastematherium differs from Protitanotherium in two significant ways; there is no postcanine diastema, and the p3 possesses a large molariform metaconid.

The Metatitan-like brontothere, Aktautitan, from Kazakstan establishes the occurrence of middle Eocene brontotheres in the region between Europe and the Gobi. It now seems more parsimonious to presume that B. transylvanicum shares closer phylogenetic affinities with an Asiatic taxon than with North American Protitanotherium. Among these, only Metatitan shares with Brachydiastematherium the previously mentioned derived conditions, a molariform p3 metaconid, and the lack of a postcanine diastema. The phylogenetic position of B. transylvanicum among Asian brontotheres suggests that it is most closely related to, if not synonymous with, Metatitan relictus or Metatitan primus, rather than Protitanotherium. If this hypothesis is further corroborated by more extensive phylogenetic analysis, Metatitan Granger and Gregory, 1943 is a junior synonym of Brachydiastematherium Böckh and Maty, 1976. At present, we hesitate to judge the taxonomic validity of Metatitan pending a more comprehensive phylogenetic analysis that includes North American brontotheres.

EVOLUTION OF FRONTONASAL “RAM” IN EMBOLOTHERIINAE

A limited number of the derived frontonasal characteristics seen in Metatitan and Aktautitan (frontonasal protuberances and nasal processes elevated on tall superorbital pillars) can be found in other brontothere taxa. For instance, the horns in the North American species Pseudodiplacodon progressum and the Asian species Rhinotitan mongoliensis are also raised above the orbits on tall superorbital pillars. However, the frontonasal horns remain separate and widely spaced. The nasal processes of Pseudodiplacodon are not elevated as in Aktautitan and Metatitan. The nasal processes of Rhinotitan are thicker and are not elevated to the level of the horn peaks as in Metatitan and Aktautitan. Also, they are angled slightly upward in contrast to the downwardly angled nasal processes of Aktautitan. The frontonasal horns of the North American Chadronian brontotheres Megacerops and Brontops are often connected by a tall crest of bone that stretches transversely between the frontonasal horns and connects them at their bases (Osborn, 1929a). The nasal processes are raised on this crest, and in lateral view the appearance of the entire region bears superficial resemblance to the frontonasal process of Metatitan and Aktautitan. However, the frontonasal horns of these taxa are massive and widely divergent rather than convergent toward the midline.

Although the exact relationships of Asian brontotheres with North American species is not yet understood, the cladogram topology indicates close phylogenetic affinities between Aktautitan, Metatitan, and Embolotherium and resolves conflicting interpretations made by earlier researchers on the homology of one of the most bizarre cranial specializations in mammalian history, the “battering ram” of Embolotherium. Osborn (1929b) believed that the distinctive Embolotherium battering ram was a novel structure, formed by an enlarged and uplifted nasal process, and was not homologous to the paired frontonasal horns of other brontotheres, as represented by Protitan grangeri (fig. 19A, B). He therefore assigned Embolotherium to its own subfamily, Embolotheriinae. Osborn's primary evidence regarding the structural components of the ram came from a juvenile specimen of Embolotherium grangeri (AMNH 26040) in which the frontonasal suture was visible on the right side of the skull just above the orbit (fig. 20). Although the frontal appears not to ascend the dorsal surface of the ram, the cranial fragment of the Embolotherium grangeri juvenile is too incomplete to determine whether a frontal process rides up over the nasal bone. Realistically, one cannot readily discern from the available specimens whether the ram of Embolotherium grangeri incorporates the frontal element. This raises difficulties for phylogenetic reconstruction because one must postulate homologies a priori to analysis. In considering Osborn's (1929b) theory, the ram of E. grangeri could be interpreted as a nasal process that has been enlarged and angled upward to nearly 45°, having nothing to do structurally with a frontonasal horn.

The nasal process of Rhinotitan mongoliensis is similarly oriented upward, albeit at a shallower angle. Additionally, the nasal process of Epimanteoceras formusus, although thinner and horizontally oriented, is remarkably similar in other respects to the ram of Embolotherium grangeri. Both widen distally, are very rectangular in cross section, and both have a wide flat distal edge. For lack of better evidence, Embolotherium grangeri was coded in the phylogenetic analysis as having an enlarged and upwardly angled nasal-process and as lacking frontonasal horns. Embolotherium andrewsi was interpreted differently, as explained below.

Following his theory that the Embolotherium ram was not homologous to the frontonasal horns, Osborn (1929b: fig. 3C; reprinted in Granger and Gregory, 1943: fig. 7C) illustrated a frontonasal suture in Embolotherium andrewsi showing that the ram was formed entirely by the nasal bone. In reexamining the available specimens that preserve the ram (AMNH 26001, 26003, 26009), we conclude that this was an inference rather than a concrete observation. A suture between the nasal and maxilla is clearly identifiable in these specimens as they appear in Osborn's figure, but we cannot locate a discernible frontonasal suture where Osborn (1929b) had inferred it to be.

In contrast to Osborn's idea that the ram was an enlarged nasal bone, Granger and Gregory (1943) interpreted the battering ram as homologous to the paired frontonasal horns of other brontotheres and described a transformational sequence from a Metatitan- like configuration to an elevated, fused frontonasal process, with the frontal stretching to the peak of the ram. The nasal process itself was regarded as being absorbed by the transverse crest at the peak of the structure. (Note that despite the similarities between Metatitan and Embolotherium described by Granger and Gregory, they regarded these taxa as only distantly related, as depicted in their phylogeny shown here in fig. 18A.)

The frontonasal battering ram hypothesis of Granger and Gregory (1943) is supported by a series of taxa that are essentially transitional forms between an Aktautitan-Metatitan-like morphology and that of Embolotherium andrewsi. “Metatitan” progressus is one of these transitional forms, represented only by a cranial fragment (AMNH 26014) that includes a portion of the orbit, frontonasal process, and a nasal process. The frontonasal process is nearly vertical and intermediate in height between the Aktautitan- Metatitan condition and that of Embolotherium andrewsi (fig. 19F, H). The frontonasal suture is clearly discernible on the dorsal surface of AMNH 26014, indicating that the frontal bone ascended to the peak of the ram (fig. 19G). At the peak, the frontal bone is joined by the nasal bone in forming a continuous transverse ridge of bone. “Metatitan” progressus retains a large nasal process, with deeply downfolded lateral sides, that projects anteriorly from the peak of the frontonasal process. A similar groove that could actually be visible remnants of the frontonasal suture is usually visible at the peak of the ram in most specimens of Embolotherium andrewsi. This would confirm that the full length of the battering ram of Embolotherium andrewsi is indeed formed by both the frontal and nasal bones.

Protembolotherium efremovi Yanovskaya, 1954 is another transitional form further derived toward the direction of Embolotherium andrewsi (fig. 19I,J). The frontonasal process forms a large Embolotherium-like ram, but this species often retains a small horizontal nasal process elevated at the peak (Yanovskaya, 1980). These morphologically transitional taxa and the apparent remnants of the frontonasal suture in E. andrewsi specimens suggest that the ram in this species is best interpreted as homologous to the frontonasal horns of other brontotheres. The actual nasal process appears to have been lost (or “absorbed” in the words of Granger and Gregory, 1943).

Therefore, the battering rams of two Embolotherium species are structurally contradictory; one species seems to possess an enlarged and raised nasal process (E. grangeri), whereas a series of transitional forms clearly indicates that the ram of Embolotherium andrewsi is actually homologous to the frontonasal horns of other brontotheres. Despite these dissimilarities, which are reflected in multiple characters used in the phylogenetic analysis presented above, these two species, together with “Metatitan” progressus, form a monophyletic trichotomy and are positioned in a larger clade with Aktautitan and other species of Metatitan. The recovered phylogeny clearly suggests that the Embolotherium ram is likely to have been derived from an Aktautitan-Metatitan-like morphology, as Granger and Gregory (1943) conjectured. That the ram of Embolotherium grangeri superficially resembles the nasal processes rather than the frontonasal horns of other brontotheres appears to have been a secondarily derived autapomorphic modification.

In light of the structural similarities of the frontonasal structures and their apparent common phylogenetic origin, we suggest that the subfamily Embolotheriinae be extended to include Aktautitan, Metatitan, “Metatitan” progressus, Protembolotherium, and Embolotherium, with Brachydiastematherium as a provisional member. Titanodectes, a somewhat dubious taxon, represented by partial mandibles, may also belong to Embolotheriinae (Granger and Gregory, 1943).

ECOLOGICAL SIGNIFICANCE OF LIMB PROPORTIONS

The limb proportions of Aktautitan hippopotamopus are conspicuously short in comparison to other brontotheres, and are convergent upon those of hippos and a variety of other large ungulates (hence, the significance of the trivial name applied to this new species). Log-ratio diagrams (Simpson, 1941) of the main limb segments (humerus, radius, third metacarpal, femur, tibia, and third metatarsal) were constructed to compare the limb proportions of various brontotheres and those of other large ungulates (fig. 21). Tapirus indicus was used as the species of reference, so that the y-axis (a straight line) represents the limb proportions of the tapir.

In comparison to the tapir, the central (tibia and radius) and distal (metacarpal and metatarsal) limb segments of brontotheres are proportionately shorter relative to the proximal segments (humerus and femur) (fig. 21A). In two exceptions, Rhinotitan and Dolichorhinus, the tibia is proportionately longer. Aktautitan is an extreme case with greatly shortened distal limb segments. The log- ratios of Aktautitan form a broad S-shaped curve. The curves of Palaeosyops and Dolichorhinus are generally S-shaped as well, but are much narrower than those of Aktautitan. The log-ratio curves of Rhinotitan and Brontops are not S-shaped. Figure 21B displays the log-ratios of various rhinocerotoids and the primitive ceratomorph Hyrachyus. The curves of these species are relatively narrow, with proportions similar to that of the tapir.

Brontotheres are often confused as early rhinos by nonspecialists, not only because of the similarity in the position of their horns, but because their body plans are superficially similar. However, it is apparent from the log- ratios that brontotheres have shorter distal limb segments than do modern rhinoceroses. The final log-ratio diagram (fig. 21C) includes the two modern hippo species, Hippopotamus and Hexaprotodon, and other extinct species that have convergently evolved hippolike limb proportions. Note that the S- shaped curved of Hexaprotodon most resembles that of Palaeosyops. The curves of Hippopotamus, the amynodont rhinocerotoid (Metamynodon), two rhinos (Chilotherium and Teleoceras), and the notoungulate (Toxodon) are more broadly S-shaped and closely resemble the curve of Aktautitan.

The remarkable similarity in size and proportions of this phylogenetically disparate group of taxa begs the question of the adaptive significance of the unusually shortened limb proportions. Cope (1879) first noted the superficial similarities in limb proportions between Teleoceras (a Miocene rhinoceros) and Hippopotamus. Osborn (1929a) observed that hippolike proportions had convergently evolved in several extinct large ungulates (many of those seen in fig. 21C) and grouped them into a separate locomotor category, graviportal short-limbed digitigrades. Because the only living member of this morphological group was a hippo, Osborn considered these animals semiaquatic. (Semiaquatic animals are those that spend significant proportions of their lives on land and in water but are not fully adapted to either environment). Although Osborn's (1929a) locomotor category has fallen into obscurity, the unusually short-limbed ungulates lumped into this category have been consistently interpreted as semiaquatic hippo-analogs by many paleontologists (Scott, 1913; Troxell, 1921; Simpson, 1980; Webb, 1983; Prothero et al, 1989; Prothero, 1998; Wall, 1998).

Skeletal adaptations of other semiaquatic mammals (e.g., beavers) include increased bone density, shortened hind limbs, and increased hind limb musculature (Stein, 1989). However, the skeletal modifications of most semiaquatic mammals are arguably adaptations for swimming. This argument is invalid for hippos because they do not swim, but rather, perform a peculiar form of “submarine” locomotion best described as running on the bottom substrate (fig. 22). It has been said that hippos cannot float or swim (Eltringham, 1999). To resolve this issue, one of us (M.C.M.) spent several days observing and filming hippos in a large pool (∼3 m deep) from behind a glass wall that allows onlookers to view the hippos from a “submerged” point of view at Busch Gardens, Tampa Bay, Florida. Hippos were never seen swimming at the surface. All locomotor activity involving forward locomotion for more than a few seconds was achieved, literally, by adopting a gait kinematically analogous to the trot of a horse slowed down by at least an order of magnitude. This gait is described in more detail by Mihlbachler (2001). At no time were hippos observed swimming or floating, but quite frequently juvenile hippos were witnessed leaping from the bottom of the pool to the water's surface to reach floating fruit. During these leaps the hippos usually would “dogpaddle” vigorously at the surface, but within a few seconds would begin to sink, rump first. Hippos are known to have denser limb bones than those of similarly sized modern rhinos, due primarily to increased cortical bone thickness (Wall, 1983). This increased density, at least partially, accounts for the apparent inability of hippos to float or swim at the surface. (Note that this conclusion applies to freshwater only. We do not reject the possibility that hippos could achieve buoyancy in denser salt water.)

The shortened limbs of the large hippolike ungulates, therefore, cannot readily be explained as a swimming adaptation. Wall (1999) argued, using lever mechanics, that the shortened limbs provide mechanical advantage for slogging through the muddy substrate of a river, lake, or marsh. Wall's argument that the shortened distal limb elements and elongated input arms, such as the olecranon process and calcaneal tuber, provide greater mechanical advantage is mechanically sound. However, the conclusion that increased mechanical advantage is specifically an adaptation for aquatic locomotion is arguable. All observed hippo locomotion was very slow, about 0.5 meters per second (msec⁻¹), and hippos moving underwater do not appear to be under great strain. Viscous forces would be negligible for objects as large as a hippo, and drag is relatively unimportant at low velocities (Vogel, 1988). Adult hippos trot underwater with a stride frequency of 1 stride every 6–7 sec with suspension phases (total time that no feet touch the ground during a complete stride) lasting about 20% of that time (1.2–1.5 sec). This stride frequency is about 12–14 times slower than that of trotting and galloping cursorial ungulates (Heglund and Taylor, 1988). Despite a very slow stride frequency and long suspension phases, hippos visibly move through liquid at a constant velocity, confirming that water resistance is nearly an insignificant force at a velocity of 0.5 msec⁻¹. If water had presented a significant resistance force, the hippo's motion would have been noticeably jerky.

Although water was not a significant resistance force to horizontal motion, buoyancy (upward force exerted on a submerged object by the water) severely limits the amount of horizontal (frictional) force that can be exerted during the submerged gait. The weight of a submerged hippo is the difference of its mass and the mass of the equivalent volume of water. Most animals are similar in density to water, and although hippos may be somewhat denser than most vertebrates, their weight underwater would be only a small fraction of their land weight. Because friction is a function of force (weight), the amount of horizontal force a hippo could exert during submerged locomotion is minimized by the reduced amount of friction generated between the feet and the substrate. More horizontal force could be exerted if the feet were planted deeply in mud, but the limited weight would also limit a hippo's ability to do this. For these reasons, the argument that increased mechanical advantage is an adaptation to underwater locomotion is questionable.

Wall (1999) identified other potential semiaquatic adaptations in hippos. The most promising of these includes elevated orbits and reduced thoracic dorsal spines. However, neither of these characters is totally correlated with the occurrence of shortened limbs. While orbital position may indeed be an aquatic adaptation among hippos, none of the extinct large hippolike ungulates in question possesses elevated orbits. (Wall [1999] interpreted Metamynodon as having elevated orbits, but the orbital position of Metamynodon is, realistically, only subtly different from that of other amynodont rhinos and is less extreme than the raised orbits of a hippo.) Reduced thoracic spines could relate to an aquatic lifestyle because the nuchal ligaments do not support the head and neck when submerged. Metamynodon and hippos share relatively short thoracic spines, but those of Teleoceras, Toxodon, and Aktautitan are remarkably long and do not visibly differ in proportion from those of many brontotheres and rhinoceroses.

Depositional environments are also cited as evidence for the hippo analogy. For instance, the rhinocerotoid Metamynodon primarily occurs in sandstone channels (Wall, 1998). Teleoceras remains are found in large numbers in fluvial or pond settings (Prothero, 1998). Likewise, the Aktautitan hippopotamopus bonebed was found in what appears to be a lacustrine environment. Nevertheless, many mammals (e.g. equids) from the same types of deposits are clearly terrestrial. Nor does the relative abundance of the fossil material occurring in such an environment indicate a hippolike lifestyle. All of the largest living land mammals (hippos, elephants, rhinos) are metabolically dependent on standing water and frequently wallow in shallow water (Owen-Smith, 1988). Extant rhinos, which are all predominantly terrestrial species, tend to die in or near water (Hitchins and Anderson, 1983; Dinerstein and Price, 1991). Thus, the occurrence of large bone beds does not indicate aquatic behaviors different from those of large terrestrial mammals such as rhinos. It has also been argued that the demographic structures of large Teleoceras fossil assemblages resemble those of hippos rather than rhinos, supporting the hippo analogy (Mead, 2000). However, it has been subsequently demonstrated that the mortality patterns of Teleoceras fossil assemblages are more like those of modern rhinos than those of hippos (Mihlbachler, 2003b). Its remains possible that shortened limbs prevent hippos from becoming fatally mired in mud on banks or in marshes. Elephants are known to become fatally mired (Haynes, 1991), but (to our knowledge) there are no adequate data to compare the frequency of fatal mirings in rhinos and hippos to indicate that the difference between hippo and rhino limb proportions gives hippos a selective advantage against the possibility of fatal mirings. The apparently mired condition of Aktautitan hippopotamopus skeletons indicates that this particular species could have been susceptible to mirings, despite the shortened distal limb segments. (Regarding apparently mired fossil animals such as large extinct ungulates or dinosaurs, the fossil record does not usually reveal whether the miring itself was fatal or if an already sick or weakened animal simply died while in a mired position, but the miring itself was not necessarily the cause of death.)

Hippos emerge from the water at night and are known to travel long distances to feeding areas (Eltringham, 1999). Therefore, hippos expend more energy on terrestrial locomotion than on aquatic locomotion and depend on the terrestrial environment for food. An alternative explanation for the short limbs is as an adaptation for feeding close to the ground. Many grazing ungulates possess a downwardly flexed cranium (Osborn, 1929a: Zeuner, 1945; Loose, 1975). This has been interpreted as an adaptation for grazing on short grasses. The grazing African rhino, Ceratotherium, for instance, possesses such a downwardly flexed head orientation. All of the short-limbed ungulates in question, including hippos, retain the horizontal head orientation, but Heissig (1989) suggested, for Chilotherium, that shortened limbs are an alternative solution for grazing close to the ground. Most other short-limbed taxa seem to conform to this interpretation. Hippos are short-grass grazers and are short enough to feed close to the ground without kneeling. Teleoceras and Toxodon retain the horizontal head orientation. Both possess relatively hypsodont molars and have been interpreted as grazers or mixed feeders from isotopic evidence (MacFadden and Shockey, 1997; MacFadden, 1998). However, Aktautitan contradicts the grazing hypothesis for the origin of hippolike limb proportions. Dental microwear patterns of brontotheres indicate that all brontotheres were leaf-dominated browsers (Mihlbachler, 2002). Microwear analysis has not been done on Aktautitan, although the dental morphology and macroscopic wear of the teeth offer no indication that the diet of Aktautitan was unusual. Additionally, all brontotheres lived before the spread of grass-dominated ecosystems (Jacobs et al., 1999). Aktautitan, nonetheless, might have specialized in feeding on very low browse. The minimal amount of wear on its incisors suggests that cropping low terrestrial plants was not a significant aspect of its feeding behavior. It remains possible that Aktautitan fed on low, soft aquatic vegetation and thus benefited energetically from shortened limbs. However, this interpretation is little more than speculation.

Unfortunately, we cannot reach a strong conclusion on the ecological significance of the hippolike limb proportions in Aktautitan and other extinct “hippo-ecomorphs”. Neither the semiaquatic or grazing hypotheses are entirely satisfactory, although the grazing hypothesis is congruent with the probable grazing adaptations of most of the hippolike taxa and is entirely testable (e.g., with dental microwear techniques). It is entirely possible that there is no single adaptive explanation for these convergent limb configurations. Due to the dubious paleoecological significance of this character, we do not recommend that it be used to infer a semiaquatic lifestyle for Aktautitan or any other extinct hippolike ungulate, as has been frequently done in the past.