Abstract
Taphonomic biases dictate how organisms are represented in the fossil record, but their effect on studies of vertebrate diversity dynamics is poorly studied. In contrast to the high diversity and abundance of small-bodied animals in extant ecosystems, small-bodied dinosaurs are less common than their large-bodied counterparts, but it is unclear whether this reflects unique properties of dinosaurian ecosystems or relates to taphonomic biases. A new, fully domed pachycephalosaurid dinosaur, Acrotholus audeti, from the Santonian of Alberta predates incompletely domed taxa, and provides important new information on pachycephalosaur evolution and the completeness of the ornithischian fossil record. Here we provide the first empirical evidence that the diversity of small-bodied ornithischian dinosaurs is strongly underestimated based on ghost lineages and the high proportion of robust and diagnostic frontoparietal domes compared with other pachycephalosaur fossils. This suggests preservational biases have a confounding role in attempts to decipher vertebrate palaeoecology and diversity dynamics through the Mesozoic.
Similar content being viewed by others
Introduction
The diversity dynamics of dinosaurs through the Mesozoic era and their pattern of species richness leading up to the end Cretaceous extinction event continue to be hotly debated1,2,3,4,5. Recent studies have emphasized the influence of sampling biases on our understanding of vertebrate diversity patterns through time, but have focused on identifying and correcting for uneven sampling intensity2,6,7. Taphonomic biases in the form of selective preservation dictate how organisms are preserved and enter the fossil record, but the effect of these biases on large-scale palaeontological studies of vertebrate diversity dynamics and quantitative macroevolutionary patterns have been comparatively poorly studied8. The bones of large-bodied terrestrial vertebrates are often better represented in fossil assemblages than their small-bodied counterparts because of strong taphonomic biases against the preservation of small vertebrates in a variety of host systems8,9,10. These factors have significant potential to effect perceptions of diversity dynamics of vertebrates through time.
In contrast to the comparatively high diversity and abundance of small-bodied mammals and reptiles in extant ecosystems11,12, small-bodied (<100 kg) dinosaurs are considerably less common than their large-bodied counterparts in most well-sampled assemblages throughout the Mesozoic13. This paradox is further underscored by the apparent rarity of small, herbivorous ornithischians when compared with the diversity of small-bodied theropods13,14. Furthermore, it has been suggested that ontogenetic niche shifts within large-bodied dinosaur taxa are responsible for the perceived low α-diversity of small- and medium-sized dinosaurs (1–1,000 kg)15. Whether this pattern reflects a unique property of dinosaurian ecosystems or is an artifact of taphonomic or other biases has not been addressed, but species fidelity in dinosaur fossil assemblages could have major implications for studies of dinosaur palaeocology and diversity dynamics over both large and small timescales.
Pachycephalosaurs (Ornithischia: Marginocephalia) are an enigmatic group of primarily small-bodied herbivorous ornithischians characterized by thickened cranial domes16,17 that are integral to understanding patterns of ornithischian evolution, as well as the function and evolution of bizarre structures in dinosaurs18,19,20,21. Here we describe fossils of a new pachycephalosaur from Santonian-aged deposits of Alberta, Canada, which represent the oldest unequivocal member of this clade from North America16,19,21,22, and possibly the world23. This new taxon predates all putatively more primitive and incompletely domed taxa, yet is remarkable for having a fully developed cranial dome, and therefore provides additional information on the evolutionary timing of their distinctive cranial characters and the completeness of the pachycephalosaur fossil record. The special taphonomic properties of pachycephalosaurs’ robust cranial domes, including frequent preservation and phylogenetically informative morphology that is diagnostic to low taxonomic levels, provide a unique opportunity to address the nature of the small-bodied dinosaur fossil record, with implications for studies of palaeoecology and diversity dynamics.
Results
Systematic palaeontology.
Dinosauria Owen 1842 Ornithischia Seeley 1888 Pachycephalosauridae Sternberg 1945 Acrotholus audeti gen. et. sp. nov.
Etymology. From the Greek akros, meaning highest, and tholos, meaning dome; in reference to its greatly thickened cranial vault. The specific epithet honours Roy Audet, for allowing access to his ranch where the holotype skull was found.Type series. TMP (Royal Tyrrell Museum of Palaeontology) 2008.045.0001 (holotype), nearly complete frontoparietal dome (Fig. 1; Supplementary Fig. S1; DigiMorph); ROM (Royal Ontario Museum) 2962 (paratype), anterior half of frontoparietal dome (Fig. 2).Locality and horizon. TMP 2008.045.0001, ROM 2962 and ROM 2964 (Supplementary Fig. S2) were collected from the Deadhorse Coulee Member of the Milk River Formation exposed in southern Alberta, Canada (see Supplementary Note S1 and Supplementary Figs S3 and S4). The holotype was recovered 1.5 km east of Writing-On-Stone Provincial Park, 22.9 m above the base of the Deadhorse Coulee Member. ROM 2962 and ROM 2964 have less precise stratigraphic data, but both specimens were collected ∼9.5 km east of Writing-On-Stone Provincial Park in exposures adjacent to Black Coulee (formerly Deadhorse Coulee). The Deadhorse Coulee Member of the Milk River Formation has been dated as Late Santonian in age (see Supplementary Note S1). Detailed locality data is on file at the TMP and ROM.Diagnosis. Medium-sized pachycephalosaurid with the following autapomorphies: ovoid dome in dorsal view in which the width of the frontoparietal dome is less than two thirds its total length, distinct midline ridge on the dorsal surface of the posteromedian process of the parietal. Differs from Stegoceras validum and Colepiocephale in the absence of grooves between the frontonasal boss and the supraorbital lobe, the full incorporation of supraorbitals into the dome, and in the symmetry of the dome in lateral view. Differs from Pachycephalosaurus and Sphaerotholus in that the postorbital extends higher on the dome than the posterior supraorbital, and their sutural surfaces are strongly arched dorsally.Comments. Sullivan16,24 described ROM 2964, an incomplete, poorly preserved dome from the Milk River Formation, showing clear signs of pathology, but was not able to assign it to a particular taxon or assess its phylogenetic position. ROM 2964 has a similar overall shape to TMP 2008.045.0001, and may be referable to the new taxon (Supplementary Fig. S2).
Comparative description
The new frontoparietal material includes a complete, well-preserved frontoparietal (Fig. 1 and Supplementary Fig. S1), and a second, equally well-preserved specimen that consists of the frontal region of the cranial dome (Fig. 2). The elongate ovoid shape of the dome in A. audeti is distinct from all known pachycephalosaurid taxa. The thickened domes are relatively large and notably massive, with a maximum thickness above the cerebral fossa (55 mm) of almost half of the total length in TMP 2008.015.0001. The apex of the frontoparietal dome occurs centrally, such that it is symmetrical in lateral view, with a slight depression over the parietal region. The dorsal dome surface is devoid of tesserae or minute tubercles that are characteristic of ‘flat-headed’ pachycephalosaurs and juveniles of domed taxa, which is probably indicative of a relatively mature ontogenetic stage for the known specimens25,26,27,28. Histological data from high-resolution computed tomography (CT) scans show extremely low relative vascularity, high density and fully internally fused frontal–frontal and frontoparietal sutures in the holotype specimen (Fig. 3), which further supports a mature ontogenetic stage for this specimen (see Supplementary Methods). The dorsally convex frontonasal boss is short relative to Stegoceras validum (e.g., University of Alberta Laboratory for Vertebrate Paleontology 2 and Colepiocephale lambei), and it is not separated from the anterior supraorbital lobe by grooves that characterize Campanian-aged pachycephalosaurid taxa from North America25. The dorsoventral thickness of the boss is ∼50% that of the thickest region of the dome (55 mm) above the cerebral fossa.
The position, morphology and relative size of the vertically striated sutural surfaces for the peripheral elements are nearly identical in TMP 2008.015.0001 and ROM 2962, where preserved in both specimens. The sutural surfaces for the peripheral bones are very well developed and high on the dome, indicating that the peripheral bones were completely incorporated into the dome. The posterior supraorbital sutural surface and the combined prefrontal–anterior supraorbital sutural surface are subequal in size, approximately half that of the massive sutural surface for the postorbital. The anterior supraorbital sutural surface is limited to only a thin-slip anterior to the sutural surface for the posterior supraorbital. The extent that the supraorbitals are incorporated into the dome is equal to, or surpasses, that in ‘fully domed’ pachycephalosaurids, such as Pachycephalosaurus and Prenocephale, and is notably greater than in Stegoceras validum and Colepiocephale lambei. The dorsal margins of the posterior supraorbital and the postorbital sutural surfaces are strongly arched, resulting in a small diastema between these bones, as in Stegoceras and Prenocephale, but unlike Sphaerotholous and Pachycephalosaurus. The rugose region posterior to the postorbital sutural surface represents the sutural surface for the squamosal. The cranial roof exceeds 15 mm in thickness over the supratemporal fossa, and it is clear that supratemporal fenestrations are absent (that is, the supratemporal fenestrae are closed).
In dorsal view, the posteromedian extension of the parietal tapers posteriorly to a blunt point. Its dorsal surface bears a raised midline ridge that extends to the distal end of the parietal. A ridge of fused nodes occurs on some juvenile specimens of Stegoceras validum (for example, University of Calgary Museum of Zoology 2008.01), but these are never raised above the rest of the parietal surface, particularly in large specimens (UALVP 2). This posterior end of the posteromedian process is slightly damaged in the holotype. However, the sutural surface for the left squamosal extends to the posterior end of the posteromedian process, such that the squamosals could have only been separated by a very thin slip of the parietal, if at all, along the posterior margin of the parietosquamosal bar. Hypertrophied nodes indicative of a parietosquamosal node row are absent on the parietal. The dorsal surface of the parietal is slightly depressed above of the posterior region of the temporal chambers, as in Sphaerotholus goodwini and Prenocephale prenes, but it lacks a stepped transition to a prominent parietosquamosal shelf, as in Colepiocephale lambei29 and variably present in Stegoceras validum24,30. The lateral profile of the parietal suggests a weakly developed parietosquamosal shelf intermediate in morphology between the horizontal posteromedian extension of the parietal of Stegoceras validum and the smoothly rounded parietal morphology (sometimes referred to as ‘down-turned’) of Sphaerotholus and Prenocephale24,25.
The ventral surface of the frontoparietal dome has three major depressions: the orbital cavity, the endocranial fossa and the temporal fossa. The total length of the endocranial fossa in the holotype measures 35 mm from the anterior end of the olfactory bulbs to the posterior margin of the cerebral fossa, and the maximum width of the bulbs is ∼40% that of the widest point of the endocranial cavity (25 mm). The large olfactory bulbs join the anterior end of the cerebral fossa via short olfactory peduncles, as is typical in pachycephalosaurids. The distinctly rugose sutural surface for the attachment of the sphenoid bones separates the orbital cavity from the endocranial fossa. The orbital fossae are only slightly concave and pierced by a large number of small foramina. Posterior to the cerebral fossa, the parietal is broken above the level of contact with the supraoccipital. Here it forms a thick midline bridge that extends from the endocranial fossa to the posterior end of the skull and separates the left and right temporal fossae. The roof of the temporal chamber is weakly arched, with a rugose scarring for temporal muscle attachment medially, and a relatively smooth lateral surface pierced by a series of small foramina. In lateral view, the roof of the temporal chamber is shallowly inclined, but not highly arched as in Sphaerotholus25.
Morphometric analyses
Allometric analyses (Fig. 4a, Table 1, see also Supplementary Methods, Supplementary Figs S5–S7 and Supplementary Table S1) show that numerous aspects of cranial form are strongly related to size in the sample, with poor taxonomic distinction. The thickness of the dome and the height of the nasal boss are positively allometric contrary to Chapman et al.31 and do not show significant differences among the taxa in the sample. Variability is greatest in the degree to which the supraorbital bones are incorporated into the dome (H:aso/pso). Stegoceras validum differs from other taxa in having lower supraorbital joint surfaces, especially compared with those in Prenocephale-grade taxa. A. audeti is notable for the massively thickened supraorbital region of the skull, and the full incorporation of the supraorbitals into the dome (Fig. 4).
A principle component analysis (PCA) was conducted on the data set using the software program PAST32 for the correlation matrix. The oblong dome of A. audeti is separated from all other taxa in the PC morphospace, supporting its recognition as a distinct taxon (Fig. 4b). The first three principal components (PCs) account for 93% of the total variation in the data set (see Supplementary Tables S2 and S3). PC1 accounts for the majority of the total variance in the sample (71%). It is strongly correlated with frontoparietal length (r=0.93) and most other variables (except W:sq/sq and to a lesser extent L:aso) load strongly, and in the same direction, onto this component, indicating it is largely related to size. PC2 and PC3 do not show significant correlations with frontoparietal length (r=−0.14 and 0.13, respectively), and so reflect variation that may be most phylogenetically informative. Four variables show loadings with magnitudes greater than 0.3 on PC2: L:aso, L:pso, W:sq/sq loaded negatively and L:po loaded positively. Two variables are strongly associated with PC3: W:sq/sq (positive) and L:aso (negative). The plot of PC2 versus PC3 (Fig. 4b) shows that Prenocephale-grade taxa are relatively tightly clustered together, whereas specimens of Stegoceras validum, including Ornatotholus browni28, at several stages of development are more widely dispersed, but do not overlap with Prenocephale-grade taxa.
Phylogenetic analysis
A phylogenetic analysis of 16 pachycephalosaurian in-group taxa and 50 morphological characters resulted in 13 most parsimonious trees (Supplementary Methods, Supplementary Note S2, Supplementary Table S4 and Supplementary Fig. S8). A time-calibrated phylogeny of the most stratigraphically consistent MPT is shown in Fig. 5. The time calibration reveals substantial missing diversity in the pachycephalosaur fossil record, which would be considerably greater without taxa known only from their robust domes (Fig. 5).
Pachycephalosaur taphonomy
Analysis of preservational modes using a global database of virtually all known non-dental pachycephalosaur specimens (n=575) illustrates that the vast majority of specimens consist of isolated cranial elements (86%) with comparatively few isolated postcranial elements, and even fewer associated or articulated skeletons (Fig. 6a, see also Supplementary Table S5). This pattern is consistent across all North American collections and formations, with the isolated cranial dome material always making up more than three quarters of the specimens, and often making up a much greater proportion. This indicates that the pattern of preservation is not driven by properties of individual formations or historical collecting practices, but is a consistent pattern for the North American pachycephalosaur fossil record. Available data from Asia suggests that this pattern may not be as strong in representative Asian formations, but the sample sizes are exceedingly small and with fewer independent samples.
Ornithischian diversity
Records of ornithischian α-diversity through the final three stages of the Cretaceous, obtained from the Paleobiology Database ( http://paleodb.org/), were compiled and compared (Supplementary Table S6). The results show that clades comprised predominantly of small-bodied taxa (Leptoceratopsidae, Thescelosauridae) exhibit low diversity compared with those clades dominated by large-bodied taxa (Hadrosauridae, Ceratopsidae). Pachycephalosaur diversity is much higher than clades that exhibit a similar body size range, especially in the Campanian and Maastrichtian, but this is only true when a large number of taxa represented only by frontoparietal domes are included. Otherwise, the diversity of pachycephalosaurs compares readily with the other small-bodied ornithischian groups (Fig. 6b).
Discussion
A new phylogenetic analysis recovers A. audeti as the sister taxon to Prenocephale prenes from the Maastrichtian of Mongolia (Fig. 5). The flat-headed Wanannosaurus is recovered as the sister taxon to all other pachycephalosaurs, consistent with most previous analyses17,24,25,30. However, Goyocephale and Homalocephale are more closely related to fully domed taxa, including A. audeti, P. prenes and pachycephalosaurines, than they are to Stegoceras, and are not outside the clade of domed pachycephalosaurs as is traditionally thought30. This supports the recent hypothesis that these taxa may represent juvenile individuals of domed taxa27,28,33.
Recent reviews have questioned the taxonomic assignment of the putative earliest members of the clade, including Yaverlandia, Stenopelix and Ferganocephale, and concluded that there is no clear evidence of pachycephalosaurs before the Santonian16,22. As a result, the early evolutionary history of the group is one of the most poorly understood aspects of dinosaurian evolution16,19,22,34. The Late Santonian age of A. audeti predates all other pachycephalosaurs from North America16,24. Other reports of older pachycephalosaurs based on isolated teeth are unsubstantiated16,35,36. Other skull material appears in the North American fossil record in the middle Campanian16,28, approximately five million years after Acrotholus. Acrotholus also predates the well-known series of Asian pachycephalosaurs, including the flat-headed taxa Goyocephale and Homalocephale16,37. Watabe et al.23 recently described the oldest unequivocal pachycephalosaur from Asia based on a frontoparietal from the upper Bayn Shireh Formation of Mongolia, which has been suggested to be Santonian in age38, approximately equivalent in age to Acrotholus.
The thickened and highly vaulted dome in A. audeti demonstrates that numerous traits associated with derived pachycephalosaurs (completely closed supratemporal fenestrae, loss of a prominent posterior parietosquamosal shelf, complete incorporation of the supraorbital bones into the dome) evolved at least by the Santonian stage of the late Cretaceous and well before the first appearance of putatively flat-headed (Goyocephale, Homalocephale and Wannanosaurus) and incompletely domed taxa (for example, Stegoceras validum, Colepiocephale lambei) that are often hypothesized to exhibit primitive pachycephalosaur traits17,24,25,30.
Temporal calibration of the phylogenetic tree suggests major sampling issues in the fossil record of Pachycephalosauria (Fig. 5). Although this approach is sensitive to phylogenetic accuracy39,40, ghost lineages calculated from the phylogeny suggest that the diversity of pachycephalosaurs is severely underestimated, perhaps by a factor of five times or more in well-sampled intervals of the middle and late Campanian2. This poor sampling is corroborated by the strongly supported sister group relationship between Pachycephalosauria and Ceratopsia18,21, which results in a massive ghost lineage that spans from the late Jurassic (Oxfordian) occurrence of Yinlong downsi, the earliest known ceratopsian, to A. audeti, a span of at least 66 million years that encompasses globally well-sampled intervals in the latest Jurassic and early Cretaceous2.
The small size of most pachycephalosaurs41, typically less than 40 kg, makes them among the smallest ornithischian dinosaur taxa. Actualistic taphonomic experiments that demonstrate strong biases against the preservation of small-bodied terrestrial vertebrates in a variety of host systems8,9 suggest that the diversity of small-bodied dinosaur taxa may be dramatically underestimated in the fossil record. Taphonomic biases against preservation of small species appears to be due to the greater susceptibility of small bones to destruction by carnivores, breakage through bioturbation and weathering processes8,9,42. Unlike their relatively delicate postcranial remains, the massively constructed frontoparietal domes of pachycephalosaurids are robust elements resistant to predepositional destruction. They are also phylogenetically informative, diagnostic to the species level and are easy to recognize in the field. Not surprisingly, the robust frontoparietal domes and associated peripheral elements account for the vast proportion of the pachycephalosaur fossil record (Fig. 6a). Isolated cranial remains of pachycephalosaurs in museum collections (for example, the American Museum of Natural History, the Canadian Museum of Nature, ROM and TMP) outnumber postcranial remains by a factor of at least 7 to 1 (Fig. 6a). In terms of skeletal representation of individual taxa, greater than 66% of named taxa are known strictly from cranial material (predominantly frontoparietal domes), and only six taxa have any associated postcrania. As such, the ratio of observed to true diversity is likely to be higher for pachycephalosaurs than for other similar small-bodied ornithischians that lack such robust, diagnostic skeletal elements. When only taxa with known postcrania are considered, the pachycephalosaur fossil record closely resembles those of other small-bodied ornithischians, where there are relatively few taxa with reasonably complete skeletons that are widely distributed in time and space (such as heterodontosaurs43,44, thescelosaurids and other small-bodied ornithopods45,46, and leptoceratopsids47; Fig. 6b).
In modern terrestrial mammal dominated faunas, field surveys conducted by Behrensmeyer et al.9 noted that all mammal species greater than 100 kg body mass were easily recognized in their sampled bone assemblages, but that species fidelity of smaller species in the same bone assemblages was inversely related to body size. Terrestrial vertebrate fossil assemblages of Mesozoic age are typically derived from alluvial deposits that preserve evidence for bone or carcass transport and reworking48,50. In these deposits, small skeletons are rare relative to those of large dinosaurs42,49,50. Unlike mammals, the less complex and stereotyped tooth morphology in most major dinosaur groups provides poor information on α-diversity patterns at low taxonomic levels, and therefore microvertebrate assemblages likely provide little meaningful insights into the species richness of small-bodied dinosaurs. Extensive work on variation in small theropod teeth over the last three decades has allowed modest resolution of their diversity in vertebrate microfossil assemblages51,52,53, but the generalized foliform morphology of isolated ornithischian teeth has made inferences of taxonomic diversity in small-bodied herbivorous dinosaurs based on vertebrate microfossil assemblages much more difficult2,54, beyond the presence or absence of major groups22,55. Pachycephalosaurs likely had broadly similar ecological requirements and, with the exception of the robust frontoparietal domes, had comparable preservation potential to other groups of small-bodied ornithischian dinosaurs, including leptoceratopsids, small-bodied ornithopods and heterodontosaurs. If estimates of missing diversity implied by the unique fossil record of pachycephalosaurs can be extended to these other small-bodied ornithischian groups, their true α-level diversity is also extremely poorly known. The same is likely true for small theropods49.
The unique nature of the pachycephalosaur record provides empirical evidence that α-level diversity of small-bodied ornithischian dinosaurs is strongly underestimated. The scant fossil record of small-bodied dinosaurs in general56,57,58,59 indicates preservational biases have a major, confounding role in attempts to model the diversity dynamics and ecology of dinosaur-dominated ecosystems through the Mesozoic Era. Relatively high recovery potential of small-bodied dinosaur diversity is likely tied to lagerstätten, which are non-randomly distributed in time and space60. Because of this, overall patterns of small-bodied dinosaur diversity are heavily influenced by lagerstätten effects, which confound methods attempting to control for sampling intensity, particularly model-based approaches generated using regression methods1,2,6,7. Future studies of diversity dynamics should attempt to control for these body size biases in species fidelity, perhaps by focusing on large-bodied taxa given their higher probability of preservation and recovery in alluvial and other continental depositional settings9, as well as analysing taphonomically equivalent depositional settings.
Methods
Frontoparietal bone histology
High-resolution CT scans of the holotype specimen of A. audeti, TMP 2008.045.0001, were performed to examine the gross histology of this specimen and calculate its relative void space, a proxy for vascularity28. See Supplementary Methods for additional details.
Morphometric analyses
To assess the range of variation in the shape of pachycephalosaurid domes and test the morphological distinctiveness of A. audeti, we measured 15 landmark-based indices based on those of Schott et al.28 on 15 complete, non-pathological pachycephalosaurid domes from five small-bodied taxa from the late Cretaceous of North America (Supplementary Table S1). Using these measurements, we conducted a series of bivariate analyses and a PCA to test the distinctiveness of Acrotholus, and assess size and shape variation in pachycephalosaurs. All measurements were log-transformed to fit the linear allometric growth function before analysis, and total length of the frontoparietal (L:fp) was used as the standard (x) variable for the bivariate plots. This measurement was not included in the PCA, to allow us to test for size dependence of the PCs. PCA results in Fig. 4b were obtained using the correlation matrix (although both were tested), which gives equal weight to measurements of varying magnitude. See Supplementary Methods for additional details.
Phylogenetic analysis
A species-level phylogenetic analysis was conducted based on a new data matrix comprising 16 in-group taxa and 50 morphological characters that incorporate the new comparative morphometric data (see Supplementary Methods, Supplementary Note S2 and Supplementary Table S4). Parsimony was used as the selection criterion under standard parameters, and both bootstrap and Bremer decay support values were calculated (details in Supplementary Methods). To time-calibrate the phylogeny, a single tree needed to be selected. To choose between the resulting most parsimonious trees, we used the Stratigraphic Consistency Index and the Gap Excess Ratio based on the age of each taxon. These methods were consistent in their results and allowed us to select the single most stratigraphically consistent MPT to use for time calibration of the phylogeny (Fig. 5). Time calibration was carried out to the highest resolution possible for each taxon using published data23,24,25 corrected based on our data as necessary. Species richness, for both observed and ghost taxa, was calculated at the substage level.
Pachycephalosaur taphonomy
Taphonomic data on virtually all known pachycephalosaur specimens (excluding isolated teeth) were collected based on knowledge of museum collections. This data set consists of 575 specimens from the Cretaceous of North America and Asia. For each specimen, the housing institution, genus, geological formation of origin, and if the material consisted of isolated cranial, isolated postcranial or an articulated/associated specimen was recorded (Supplementary Table S5).
Ornithischian diversity
Records of ornithischian diversity through the final three stages of the Late Cretaceous were obtained from the Paleobiology Database ( www/paleodb.org). Records for Hadrosauridae, Leptoceratopsidae and Ceratopsidae were obtained using the Count Taxa feature of the PDBD, accessed on 11 August 2012. The Leptoceratopsidae record was corrected using the data in Ryan et al.47. Thescelosauridae data was obtained by using the Taxon Counts feature for the constituent North American genera of this family following Brown et al.46. Pachycephalosaur data were obtained using the specimen level pachycephalosaur data set (Supplementary Table S6) segregated into total diversity and diversity of taxa known from articulates/associated skeletons. In all cases, occurrence-based species diversity in each time bin was recorded.
Nomenclatural act
This published work and the nomenclatural acts it contains have been registered in ZooBank, the proposed online registration system for the International Code of Zoological Nomenclature. The ZooBank LSIDs (Life Science Identifiers) can be resolved and the associated information viewed through any standard web browser by appending the LSID to the prefix ‘ http://zoobank.org/’. The LSIDs for this publication are: urn:lsid:zoobank.org:act:D9254894-8009-487F-8490-F3090044EC9C; urn:lsid:zoobank.org:pub:CBE485DA-ABDA-42AC-9834-FB6EE9548C3B.
In addition, high-resolution CT scans of the holotype specimen were performed by the University of Texas High-Resolution X-ray CT Facility, and visualizations of those scans were provided by the Digital Morphology (DigiMorph) project. The scan data and visualizations can be freely accessed online ( http://digimorph.org/specimens/Acrotholus_audeti/).
Additional information
How to cite this article: Evans D. C. et al. The oldest North American pachycephalosaurid and the hidden diversity of small-bodied ornithischian dinosaurs. Nat. Commun. 4:1828 doi:10.1038/ncomms2749 (2013).
Change history
11 February 2014
A correction has been published and is appended to both the HTML and PDF versions of this paper. The error has not been fixed in the paper.
References
Archibald, J. D. Shape of Mesozoic dinosaur richness: comment and reply. Geology 33, e75 (2005).
Barrett, P. M., McGowan, A. J. & Page, V. Dinosaur diversity and the rock record. Proc. R. Soc. London Ser. B 276, 2667–2674 (2009).
Fastovsky, D. E. et al. Shape of Mesozoic dinosaur richness. Geology 32, 877–880 (2004).
Sullivan, R. M. In Late Cretaceous Vertebrates from the Western Interior eds Lucas S. G., Sullivan R. M. 403–405New Mexico Museum of Natural History and Science Bulletin (2006).
Upchurch, P., Mannion, P. D., Benson, R. B. J., Butler, R. J. & Carrano, M. T. In Comparing the Geological and Fossil Records: Implications For Biodiversity Studies eds McGowan A. J., Smith A. B. Geological Society of London, Special Publications358, 209–240 (2011).
Benson, R. B. J. & Butler, R. J. Uncovering the diversification history of marine tetrapods: ecology influences the effect of geological sampling biases Geological Society of London, Special Publications358, 191–208 (2011).
Butler, R. J., Benson, R. B. J., Carrano, M., Mannion, P. D. & Upchurch, P. Sea level, dinosaur diversity and sampling biases: investigating the ‘common cause’ hypothesis in the terrestrial realm. Proc. R. Soc. London Ser. B 278, 1165–1170 (2011).
Kidwell, S. M. & Flessa, K. W. The quality of the fossil record: populations, species, and communities. Ann. Rev. Earth Planet. Sci. 24, 433–464 (1996).
Behrensmeyer, A. K., Western, D. & Dechant Boaz, D. E. New perspectives in vertebrate paleoecology from a Recent bone analysis. Paleobiology 5, 12–21 (1979).
Behrensmeyer, A. K. In Palaeobiology II eds Briggs D. E. G., Crowther P. R. 318–321Blackwell Science: Oxford, (2001).
Damuth, J. Population density and body size in mammals. Nature 290, 699–700 (1981).
Jetz, W., Carbone, C., Fulford, J. & Brown, J. H. The scaling of animal space use. Science 306, 266–268 (2004).
Peczkis, J. Implications of body-mass estimates for dinosaurs. J. Vertebr. Paleontol. 14, 520–533 (1994).
Carbone, C., Pattorelli, N. & Stephens, P. A. The bigger they come, the harder they fall: body size and prey abundance influence predator–prey ratios. Biol. Lett. 7, 312–315 (2011).
Codron, D., Carbone, C., Müller, D. W. H. & Clauss, M. Ontogenetic niche shifts in dinosaurs influenced size, diversity and extinction in terrestrial vertebrates. Biol. Lett. 8, 620–623 (2012).
Sullivan, R. M. A taxonomic review of the Pachycephalosauridae (Dinosauria: Ornithischia). N. Mexico Museum Natural History Sci. Bull. 35, 347–365 (2006).
Maryańska, T., Chapman, R. E. & Weishampel, D. B. In The Dinosauria 2nd edn eds Weishampel D. B., Osmólska H., Dodson P. 464–477University of California Press: Berkeley, (2004).
Butler, R. J., Upchurch, P. & Norman, D. B. The phylogeny of the ornithischian dinosaurs. J. Syst. Palaeontol. 6, 1–40 (2008).
Butler, R. J. & Zhao, Q. The small bodied ornithischian dinosaur Micropachycephalosaurus hongtuyanensis and Wannanosaurus yansiensis from the Late Cretaceous of China. Cretaceous Res. 30, 63–77 (2009).
Horner, J. R. & Goodwin, M. B. Extreme cranial ontogeny in the Upper Cretaceous dinosaur Pachycephalosaurus. PLoS ONE 4, 1–11 (2009).
Xu, X., Forster, C. A., Clark, J. M. & Mo, J. A basal ceratopsian with transitional feature from the Late Jurassic of northwestern China. Proc. R. Soc. B 273, 2135–2140 (2006).
Butler, R. J. & Sullivan, R. M. The phylogenetic position of the ornithischian dinosaur Stenopelix valdensis from the Lower Cretaceous of Germany and the early fossil record of Pachycephalosauria. Acta Palaeontol. Pol. 51, 21–34 (2009).
Watabe, M., Tsogtbaatar, K. & Sullivan, R. M. A new pachycephalosaurid from he Baynshire Formation (Cenomanian–late Santonian), Gobi Desert, Mongolia. N. Mexico Museum Natural History Sci. Bull. 53, 489–497 (2011).
Sullivan, R. M. Revision of the dinosaur Stegoceras Lambe (Ornithischia, Pachycephalosauridae). J. Vertebr. Paleontol. 23, 181–207 (2003).
Williamson, T. E. & Carr, T. D. A new genus of derived pachycephalosaurian from western North America. J. Vertebr. Paleontol. 22, 779–801 (2002).
Goodwin, M. B. & Horner, J. R. Cranial histology of pachycephalosaurs (Ornithischia: Marginocephalia) reveals transitory structures inconsistent with head-butting behavior. Paleobiology 30, 253–267 (2004).
Evans, D. C., Brown, C. M., Ryan, M. & Tsogtbaatar, K. Cranial ornamentation and ontogenetic status of Homalocephale calathocercos (Ornithischia: Pachycephalosauria) from the Nemegt Formation, Mongolia. J. Vertebr. Paleontol. 31, 84–92 (2011).
Schott, R. K. et al. Cranial ontogeny in Stegoceras validum (Dinosauria: Pachycephalosauria): A quantitative model of pachycephalosaur dome growth and variation. PLoS ONE 6, e21092 (2011).
Schott, R. K., Evans, D. C. & Williamson, T. E. The anatomy and systematics of Colepiocephale lambei (Dinosauria: Pachycephalosauridae). J. Vertebr. Paleontol. 29, 771–786 (2009).
Sereno, P. C. In The Age of Dinosaurs in Russia and Mongolia (eds. Benton M. J., Shishkin M. A., Unwin D. M., Kurochkin E. N. 480–515Cambridge University Press: London, (2000).
Chapman, R. E., Galton, P. M., Sepkoski, J. J. & Wall, W. P. A morphometric study of the cranium of the pachycephalosaurid dinosaur Stegoceras. J. Paleontol. 55, 608–618 (1981).
Hammer, O., Harper, D. A. T. & Ryan, P. D. PAST: Paleontological Statistics software package for education and data analysis. Palaeontol. Electron. 4, (2001).
Longrich, N. R., Sankey, J. & Tanke, D. H. Texacephale langstoni, a new genus of pachycephalosaurid (Dinosauria: Ornithischia) from the upper Campanian Aguja Formation, south Texas, USA. Cretaceous Res. 31, 274–284 (2010).
Brown, C. M. & Russell, A. P. Homology and architecture of the caudal basket of Pachycephalosauria (Dinosauria: Ornithischia): the first occurrence of Myorhabdoi in Tetrapoda. PLoS ONE 7, e30212 (2012).
Cifelli, R. L., Gardner, J. D., Nydam, R. L. & Brinkman, D. Additions to the vertebrate fauna of the Antlers Formation (Lower Cretaceous), Southeastern Oklahoma 202, 3715–3730. Oklahoma Geol. Notes 57, 124–131 (1997).
Cifelli, R. L. et al. In Vertebrate Paleontology in Utah ed. Gillette D. D. 219–242Utah Geological Survey: Salt Lake City, (1999).
Jerzykiewicz, T. In The Age of Dinosaurs in Russian and Mongolia (eds. Benton M. J., Shishkin M. A., Unwin D. M., Kurochkin E. N. 279–296Cambridge University Press: London, (2000).
Hicks, J. F., Brinkman, D. L., Nichols, D. J. & Watabe, M. Paleomagnetic and palynologic analyses of Albian to Santonian strata at Bayn Shireh, Burkhant, and Khuren Dukh, eastern Gobi Desert, Mongolia. Cretaceous Res. 20, 829–850 (1999).
Wagner, P. J. & Sidor, C. A. Age rank/clade rank metrics - sampling, taxonomy, and the meaning of “stratigraphic consistency”. Syst. Biol. 49, 463–479 (2000).
Wagner, P. J. The quality of the fossil record and the accuracy of phylogenetic inferences about sampling and diversity. Syst. Biol. 49, 65–86 (2000).
Paul, G. In Dinofest International (eds. Wolberg D. L., Stump E., Rosenberg G. D. 39–45The Academy of Natural Sciences: Arizona State University, (1997).
Brown, C. M., Evans, D. C., Campione, N. E., O’Brien, L. J. & Eberth, D. A. Evidence for taphonomic size bias in the Dinosaur Park Formation (Campanian, Alberta), a model Mesozoic terrestrial alluvial paralic system. Palaeogeogr. Palaeoclimatol. Palaeoecol. 372, 108–122 (2013).
Butler, R. J. et al. Lower limits of ornithischian dinosaur body size inferred from a new Jurassic heterodontosaurid from North America. Proc. R. Soc. B 277, 375–381 (2010).
Pol, D., Rauhut, O. W. M. & Becerra, M. A Middle Jurassic heterodontosaurid dinosaur from Patagonia and the evolution of heterodontosaurids. Naturwissenschaften 98, 396–379 (2011).
Boyd, C. A., Brown, C. M., Scheetz, R. D. & Clarke, J. A. Taxonomic revision of the basal neornithischian taxa Thescelosaurus and Bugenasaura. J. Vertebr. Paleontol. 29, 758–770 (2009).
Brown, C. M., Boyd, C. A. & Russell, A. P. A new basal ornithopod dinosaur (Frenchman Formation, Saskatchewan, Canada), and implications for late Maastrichtian ornithischian diversity in North America. Zool. J. Linnaean Soc. 163, 1157–1198 (2011).
Ryan, M. J., Evans, D. C., Currie, P. J., Brown, C. M. & Brinkman, D. New leptoceratopsids from the Upper Cretaceous of Alberta, Canada. Cretaceous Res. 35, 69–80 (2012).
Eberth, D. A., Shannon, M. & Noland, B. G. in Bonebeds: Genesis, Analysis, and Paleobiological Significance (eds. Rogers R. R., Eberth D. A., Fiorillo A. R. 103–119University of Chicago Press: Chicago, (2007).
Brocklehurst, N., Upchurch, P., Mannion, P. D. & O’Connor, J. The completeness of the fossil record of Mesozoic Birds: Implications for early avian evolution. PLoS ONE 7, e39056 (2012).
Eberth, D. A., Xing, X. & Clark, J. M. Dinosaur death pits from the Jurassic of China. Palaios 25, 112–125 (2010).
Currie, P. J., Rigby, J. K. J. & Sloan, R. E. In Dinosaur Systematics: Approaches and Perspectives eds Carpenter K., Currie P. J. 107–125 Cambridge University Press: Cambridge, (1990).
Sankey, J., Brinkman, D., Guenther, M. & Currie, P. J. Small theropod and bird teeth from the Late Cretaceous (Late Campanian) Judith River Group, Alberta. J. Paleontol. 76, 751–763 (2002).
Larson, D. W. Diversity and variation of theropod dinosaur teeth from the uppermost Santonian Milk River Formation (Upper Cretaceous), Alberta: a quantitative method supporting identification of the oldest dinosaur tooth assemblage in Canada. Canadian J. Earth Sci. 45, 1455–1468 (2009).
Parker, W. G., Irmis, R. B., Nesbitt, S. J., Martz, J. W. & Browne, L. S. The Late Triassic pseudosuchian Revueltosaurus callenderi and its implications for the diversity of early ornithischian dinosaurs. Proc. R. Soc. London Ser. B Biol. Sci. 272, 963–969 (2005).
Brinkman, D. B., Ryan, M. J. & Eberth, D. A. The paleogeographic and stratigraphic distribution of ceratopsids (Ornithischia) in the Upper Judith River Group of Western Canada. Palaios 13, 160–169 (1998).
Longrich, N. R. & Currie, P. J. A microraptorine (Dinosauria–Dromaeosauridae) from the Late Cretaceous of North America. Proc. Natl Acad. Sci. 106, 5002–5007 (2009).
Weishampel, D. B. et al. In The Dinosauria eds Weishampel D. B., Dodson P., Osmolska H. 517–608University of California Press: Berkeley, (2004).
Horner, J. R., Goodwin, M. B. & Myhrvold, N. Dinosaur census reveals abundant Tyrannosaurus and rare ontogenetic stages in the Upper Cretaceous Hell Creek Formation (Maastrichtian), Montana, USA. PLoS ONE 6, e16574 (2011).
Carbone, C., Turvey, S. T. & Bielby, J. Intra-guild competition and its implications for one of the biggest terrestrial predators, Tyrannosaurus rex. Proc. R. Soc. B Biol. Sci. 278, 2682–2690 (2011).
Zhou, Z., Barrett, P. M. & Hilton, J. An exceptionally preserved Lower Cretaceous ecosystem. Nature 421, 807–814 (2003).
Acknowledgements
We thank R. Benson, D. Brinkman, D. Eberth, M. Goodwin, N. Longrich, R. Sullivan, T. Williamson and M. Vavrek for discussions. D. Brinkman and B. Strilisky (TMP) provided loans, and I. Morrison (ROM) prepared the holotype fossil. P. MacDonald, P. Currie and E. Koppelhus provided differential GPS data. Three-dimensional surface scan imagery was performed by P. Bloskie and A. Tirabasso, and K. Latanville executed the half-tone illustrations. We thank M. Colbert and J. Maisano for HRCT scanning. Funding was provided by the National Sciences and Engineering Research Council of Canada (Discovery Grant to D.C.E.), the ROM, the Dinosaur Research Institute and the Jurassic Foundation.
Author information
Authors and Affiliations
Contributions
D.C.E. conceived the project; C.M.B., D.W.L., D.C.E. and M.J.R. collected the specimen; D.C.E described the specimen; R.K.S. and D.C.E. collected and analysed the morphometric data; R.K.S. and D.C.E. collected and analysed the phylogenetic data; C.M.B., D.W.L., D.C.E. and R.K.S. collected and analysed the taphonomic and diversity data; R.K.S. and D.C.E. collected and analysed the histological data; D.W.L. collected and analysed the stratigraphic data; all authors contributed to the preparation and writing of the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Supplementary information
Supplementary Information
Supplementary Figures S1-S8, Supplementary Tables S1-S6, Supplementary Note 1-2, Supplementary Methods and Supplementary References (PDF 2559 kb)
Rights and permissions
About this article
Cite this article
Evans, D., Schott, R., Larson, D. et al. The oldest North American pachycephalosaurid and the hidden diversity of small-bodied ornithischian dinosaurs. Nat Commun 4, 1828 (2013). https://doi.org/10.1038/ncomms2749
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/ncomms2749
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.