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A giant dromaeosaurid theropod from the Upper Cretaceous (Turonian) Bissekty Formation of Uzbekistan and the status of Ulughbegsaurus uzbekistanensis

Published online by Cambridge University Press:  22 December 2022

Hans-Dieter Sues*
Affiliation:
Department of Paleobiology, National Museum of Natural History, Smithsonian Institution, MRC 121, P.O. Box 37012, Washington, DC 20013-7012, USA
Alexander Averianov
Affiliation:
Zoological Institute of the Russian Academy of Sciences, Universitetskaya Emb. 1, 199034 St Petersburg, Russia
Brooks B. Britt
Affiliation:
Museum of Paleontology, Department of Geological Sciences, Brigham Young University, Provo, UT 84602, USA
*
Author for correspondence: Hans-Dieter Sues, Email: [email protected]
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Abstract

The Upper Cretaceous (Turonian) Bissekty Formation of Uzbekistan has yielded many isolated bones and teeth representing a variety of non-avian theropod dinosaurs. A pedal phalanx II-2 indicates the presence of a dromaeosaurid theropod that attained a larger body size than any previously known member of that clade. The same formation also yielded a large maxillary fragment that has recently been described as a neovenatorid carcharodontosaurian (Ulughbegsaurus uzbekistanensis). However, this specimen lacks unambiguously diagnostic features of that clade, and its purported carcharodontosaurian characters are either taphonomic artefacts or also shared by dromaeosaurids. Thus, the phylogenetic relationships of Uleghbegsaurus uzbekistanensis remain uncertain. A giant dromaeosaurid occurred together with the medium-sized tyrannosauroid Timurlengia euotica in the Bissekty assemblage.

Type
Original Article
Creative Commons
To the extent this is a work of the US Government, it is not subject to copyright protection within the United States. Published by Cambridge University Press.
Copyright
© Smithsonian Institution, Washington, DC, U.S.A., Brigham Young University, Provo, Utah, U.S.A., and Russian Academy of Sciences, 2022

1. Introduction

The Turonian-age Bissekty Formation in the central Kyzylkum Desert of Uzbekistan has yielded one of the most diverse assemblages of early Late Cretaceous terrestrial and freshwater vertebrates found to date. The dinosaurs from this assemblage include representatives of various clades of non-avian theropods: a tyrannosauroid (Timurlengia euotica, Brusatte et al. Reference Brusatte, Averianov, Sues, Muir and Butler2016); dromaeosaurids (Itemirus medullaris and a large-bodied form, Sues & Averianov, Reference Sues and Averianov2014); troodontids (Urbacodon sp., Averianov & Sues, Reference Averianov and Sues2007); alvarezsaurids (Dzharaonyx etsi, Averianov & Sues, Reference Averianov and Sues2022); an unnamed ornithomimid; at least two unnamed taxa of therizinosauroids; and a caenagnathid (Caenagnathasia martinsoni, Sues & Averianov, Reference Sues and Averianov2015). In addition, there are two form taxa for distinctive small theropod teeth, Richardoestesia americana and Paronychodon asiaticus (Sues & Averianov, Reference Sues and Averianov2013; Averianov & Sues, Reference Averianov and Sues2019). Recently, Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) described what they considered a neovenatorid carcharodontosaurian, Ulughbegsaurus uzbekistanensis, which will be further discussed in this paper.

Although almost invariably dissociated, the bones and teeth of these dinosaurs are often exquisitely preserved and provide a wealth of anatomical information. At Dzharakuduk in the Navoi District of Uzbekistan, strata of the Bissekty Formation are widely exposed along an escarpment that extends from approximately 42° 06′ 22.60″ N, 62° 37′ 09.00″ E to 42° 05′ 44.22″ N, 62° 4′ 06.49″ E. The Bissekty Formation encompasses an up to 80 m thick succession of poorly lithified, medium-grained and cross-bedded fluvial sandstones and several laterally extensive, clast-supported intraformational conglomerates (Redman & Leighton, Reference Redman and Leighton2009). The Bissekty Formation is underlain by the Dzheirantui Formation and overlain by the Aitym Formation, both of which were deposited in marginal- or shallow-marine environments. Based on the fieldwork by the late Christopher King (pers. comm.), the Dzheirantui Formation can be dated as latest early Turonian based on the co-occurrence of two taxa of inoceramid bivalves, Mytiloides aff. M. labiatus and Mytiloides subhercynicus. The Meshekeli Member of the Aitym Formation is late Turonian primarily based on the presence of the inoceramid Mytiloides incertus. Thus, the age of the Bissekty Formation is middle Turonian (Averianov, Reference Averianov2010).

Most bones and teeth of non-avian dinosaurs from the Bissekty Formation have been recovered by surface collecting. As expected in a fluvial depositional setting, many skeletal remains show signs of postmortem transport. For some bones, preservation was further adversely affected by prolonged surface exposure in the harsh present-day desert climate.

Institutional abbreviations: BYU – Museum of Paleontology, Department of Geological Sciences, Brigham Young University, Provo, Utah, USA; CCMGE – Chernyshev’s Central Museum of Geological Exploration, Saint Petersburg, Russia; UALVP – University of Alberta Vertebrate Palaeontology Lab, Edmonton, Alberta, Canada; UzSGM – State Geological Museum of the State Committee of the Republic of Uzbekistan on Geology and Mineral Resources, Tashkent, Uzbekistan; YPM – Peabody Museum of Natural History, Yale University, New Haven, Connecticut, USA; ZIN PH – Zoological Institute, Paleoherpetological Collection, Russian Academy of Sciences, Saint Petersburg, Russia.

2. Systematic palaeontology

DINOSAURIA Owen, Reference Owen1842

THEROPODA Marsh, Reference Marsh1881

PARAVES Sereno, Reference Sereno1997

DROMAEOSAURIDAE Matthew & Brown, Reference Matthew and Brown1922

EUDROMAEOSAURIA Longrich & Currie, Reference Longrich and Currie2009

Gen. et sp. indet.

Sues & Averianov (Reference Sues and Averianov2014) tentatively assigned all dromaeosaurid bones and teeth to Itemirus medullaris, which was originally named on the basis of an excellently preserved partial braincase (Kurzanov, Reference Kurzanov1976). Further review suggests most of the material represents a small- to medium-sized dromaeosaurid (based on fully closed sutures between the bones of the holotypic braincase and the closed neurocentral sutures on the available vertebrae), to which we apply the binomen Itemirus medullaris, and a very large dromaeosaurid that is the subject of the present study.

A complete left pedal phalanx II-2 ZIN PH 11/16 (Figs 1 and 2c) has a greatest length of 84.5 mm (correcting the measurement in Sues & Averianov, Reference Sues and Averianov2014). It was briefly described by Sues & Averianov (Reference Sues and Averianov2014). The proximal width of this phalanx is 41.3 mm and its distal width is 39.8 mm. The phalanx is proportionately shorter anteroposteriorly and wider transversely than the homologous bones in most known dromaeosaurids except in Achillobator giganticus from the Upper Cretaceous (Cenomanian–Santonian) Bayn Shire Formation of Mongolia (Perle et al. Reference Perle, Norell and Clark1999, pl. 13; length: 56.4 mm – PJ Currie, pers. comm.). By comparison, pedal phalanges II-2 of the up to 3 m long Deinonychus antirrhopus, from the Lower Cretaceous (Aptian–Albian) Cloverly Formation of Montana and Wyoming (Ostrom, Reference Ostrom1969), have lengths of up to 49.9 mm (Brusatte et al. Reference Brusatte, Vremir, Csiki-Sava, Turner, Watanabe, Erickson and Norell2013), and two pedal phalanges II-2 of Austroraptor cabazai from the Upper Cretaceous (Maastrichtian) Formation of Argentina are 58.1 and 58.8 mm long, respectively (Currie & Paulina Carabajal, Reference Currie and Paulina Carabajal2012). The phalanx ZIN PH 11/16 has a long, in dorsal/ventral view lobate proximoventral flange or ‘heel’ (Fig. 1c, d). The ventral surface of this heel is gently convex transversely rather than flat as in Deinonychus antirrhopus (YPM VP.005205). The presence of a well-developed proximoventral heel on pedal phalanx II-2 has been hypothesized as diagnostic for Eudromaeosauria (Longrich & Currie, Reference Longrich and Currie2009; Turner et al. Reference Turner, Makovicky and Norell2012). The proximal articular facet extends onto the heel and is asymmetrically divided by a median ridge into a lateral and a wider medial articular surface. Its dorsal margin forms a distinct median ‘lip’. As in Achillobator giganticus (Perle et al. 1999; Fig. 2b), the body of the phalanx is only slightly constricted in side view. By contrast, the body has a clearly defined ‘neck’ between the two articular ends in most other dromaeosaurids such as Deinonychus antirrhopus (YPM VP.005205; Fig. 2a). The distal end of ZIN PH 11/16 forms a grooved ginglymoid articular facet, which is semicircular (∼180°) in side view and narrower transversely than the proximal facet. As in other dromaeosaurids, its articular facet extends farther proximally onto the ventral surface than onto the dorsal surface of the bone. The lateral and medial surfaces of the distal end of the phalanx bear collateral ligament pits positioned posterodorsal to the geometrical centre of the ginglymus arc. The lateral pit is obscured by tightly adhering matrix whereas the medial pit is well-developed and visible even in dorsal view.

Fig. 1. Eudromaeosauria gen. et sp. indet., Bissekty Formation, left pedal phalanx II-2 (ZIN PH 11/16), in (a) lateral, (b) medial, (c) dorsal, (d) ventral, (e) proximal and (f) distal views. Scale bar = 3 cm. Abbreviations: clp, collateral ligament pit; pvh, posteroventral ‘heel’.

Fig. 2. Pedal phalanges II-2 of (a) Deinonychus antirrhopus (YPM VP.005205, reversed), (b) Achillobator giganticus and (c) ZIN PH 11/16, shown at the same scale for comparison. (a) Courtesy of DL Brinkman and (b) scanned and reversed from Perle et al. (1999, pl. 13). Scale bars each equal 1 cm. Abbreviations: clp, collateral ligament pit; pvh, posteroventral ‘heel’.

Sues & Averianov (Reference Sues and Averianov2014) described two fragments of the posterior ends of large maxillae, which closely resemble the postalveolar portions of the maxillae of Dromaeosaurus albertensis (Currie, Reference Currie1995). The more complete and better-preserved fragment of the posterior portion of a left maxilla (CCMGE 600/12457) is c. 150 mm long and preserves the posterior four alveoli and parts of two preceding the former. The posterior ramus of the maxilla extends posteriorly well behind the tooth row, which closely resembles the condition in dromaeosaurids such as Achillobator giganticus (Turner et al. Reference Turner, Makovicky and Norell2012) and Dromaeosaurus albertensis (Currie, Reference Currie1995) but is also present in some carcharodontosaurians (e.g. Acrocanthosaurus atokensis, Currie & Carpenter, Reference Currie and Carpenter2000).

3. Affinities of Ulughbegsaurus uzbekistanensis

Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) reported a fragment of a left maxilla of a large theropod from the Bissekty Formation, which they designated as the holotype of a new taxon of neovenatorid carcharodontosaurian, Ulughbegsaurus uzbekistanensis. Based on this specimen, the authors argued that the non-avian theropod assemblage from the Bissekty Formation resembles that from the Cenomanian Mussentuchit Member of the Cedar Mountain Formation in Utah (USA), in which the large neovenatorid Siats meekerorum (Zanno & Makovicky, Reference Zanno and Makovicky2013) occurred together with the diminutive tyrannosauroid Moros intrepidus (Zanno et al. Reference Zanno, Tucker, Canoville, Avrahami, Gates and Makovicky2019). If the identification of Ulughbegsaurus uzbekistanensis as a neovenatorid were substantiated, the Bissekty material would represent the geologically youngest example of a non-avian theropod assemblage in which a large carcharodontosaurian co-occurred with a medium-sized tyrannosauroid.

The holotype of Ulughbegsaurus uzbekistanensis (UzSGM 11-01-02) is a fragment of a left maxilla without erupted teeth (Fig. 3a, b) from Dzharakuduk. Here we reassess the phylogenetic relationships of this taxon based on the description and figures published by Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021).

Fig. 3. Partial maxillae of Ulughbegsaurus uzbekistanensis (holotype, UzSGM 11-01-02; a, b) and Utahraptor ostrommaysi (BYU 19965, reversed; c, d), each in (a, c) lateral and (b, d) medial views. (a, b) From Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) – CC BY 4.0. Scale bars each equal 5 cm. Abbreviations: amp, anteromedial process of maxilla; af, accessory fossa; aofe, margin of antorbital fenestra; aofo, antorbital fossa; idp, interdental plate; mfe, maxillary fenestra; nf, nutrient foramen; ‘pmfo’, ‘promaxillary fossa’; ps, palatal shelf; slf, supralabial foramen.

Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) listed several purported synapomorphies in support of the referral of U. uzbekistanensis to neovenatorid carcharodontosaurians. Firstly, they cited the rugose lateral surface of the holotypic maxilla. Their excellent photographs (Tanaka et al. Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021, figs 1a, 2a; Fig. 3a) show that the lateral surface of UzSGM 11-01-02 is badly eroded. The lateral surface of the maxilla fragment presents a distinctly fibrous internal structure, which is commonly observed on vertebrate bones after prolonged abrasion by sediment-laden flowing water (Behrensmeyer, Reference Behrensmeyer1978). Some of the bony fibres cross the margins of eroded neurovascular canals, creating the appearance of ‘ridging’. This pattern does not resemble the distinct ridging present on the lateral surface of the maxilla in undisputed carcharodontosaurians such as Carcharodontosaurus spp. (Brusatte & Sereno, Reference Brusatte and Sereno2007; Delcourt & Grillo, Reference Delcourt and Grillo2018; Ibrahim et al. Reference Ibrahim, Sereno, Varricchio, Martill, Dutheil, Unwin, Baidder, Larsson, Zouhri and Kaoukaya2020). Furthermore, we note that maxillae of various other theropods have rugose lateral surfaces with ridges and grooves extending from the neurovascular foramina, including Abelisauridae (Lamanna et al. Reference Lamanna, Martínez and Smith2002; Sampson & Witmer, Reference Sampson and Witmer2007), Dromaeosauridae (e.g. Dromaeosaurus albertensis, Utahraptor ostrommaysi, Fig. 3c) and Tyrannosauridae (e.g. Tarbosaurus bataar, Hurum & Sabath, Reference Hurum and Sabath2003). Thus, rugose lateral surfaces of the maxillae are not unique to carcharodontosaurians and, in the case of UzSGM 11-01-02, this feature is a taphonomic artefact.

Secondly, Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) considered the position of what they identified as a ‘promaxillary fossa’ on the anterior rim of the antorbital fossa as comparable to the condition in allosauroids. Their illustration (reproduced here as Fig. 3a) shows a small, round pit with irregular edges on the rounded anteroventral rim of the antorbital fossa, but it is unclear whether this is a genuine morphological feature or merely taphonomic damage similar to another, larger pit on the margin of the antorbital fossa. A small maxillary foramen is present in this position in Carcharodontosaurus spp. (Brusatte & Sereno, Reference Brusatte and Sereno2007) and a large maxillary fenestra in Neovenator salerii (Brusatte et al. Reference Brusatte, Benson and Hutt2008). However, the carcharodontosaurid Shaochilong moartuensis lacks such a foramen (Brusatte et al. Reference Brusatte, Chure, Benson and Xu2010). Given the variability in this feature even among carcharodontosaurians, its diagnostic value is questionable. Dromaeosaurids have promaxillary fenestrae of various sizes (Powers et al. Reference Powers, Fabbri, Doschak, Bhullar, Evans, Norell and Currie2022).

Thirdly, Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) cited the presence of fused, slightly rugose interdental plates in Ulughbegsaurus uzbekistanensis. The absence of distinct interdental plates is not restricted to most but not all allosauroids (Currie, Reference Currie1995) but is shared by abelisaurids (Lamanna et al. Reference Lamanna, Martínez and Smith2002; Sampson & Witmer, Reference Sampson and Witmer2007), the megalosauroid Torvosaurus spp. (Britt, Reference Britt1991; Hendrickx & Mateus, Reference Hendrickx and Mateus2014), dromaeosaurids (Currie, Reference Currie1995; Turner et al. Reference Turner, Makovicky and Norell2012) and troodontids (Currie, Reference Currie1987). By contrast, the tyrannosauroid Timurlengia euotica from the Bissekty Formation has distinct interdental plates (Averianov & Sues, Reference Averianov and Sues2012). Rugose interdental plates also occur in other non-avian theropods (e.g. Tarbosaurus bataar, Hurum & Sabath, Reference Hurum and Sabath2003).

Fourthly, Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) cited the presence of alveoli that are labiolingually narrower than mesiodistally long in Ulughbegsaurus uzbekistanensis as a similarity to carcharodontosaurians. However, dromaeosaurids (e.g. Saurornitholestes langstoni, UALVP 12339) also have alveoli that are distinctly more narrow labiolingually than long mesiodistally with ratios of labiolingual width to mesiodistal length of c. 0.5, comparable to the ratios cited by Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) for Ulughbegsaurus uzbekistanensis.

We could not identify a single feature that unambiguously supports referral of Ulughbegsaurus uzbekistanensis to neovenatorid carcharodontosaurians. Three of the purported synapomorphies cited by Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) are also shared by dromaeosaurids. In addition, some features like the sub-vertical contact between the premaxilla and maxilla and the smooth junction between the ventral margin of the antorbital fossa and the lateral surface of the maxilla ventral to this margin (Powers et al. Reference Powers, Fabbri, Doschak, Bhullar, Evans, Norell and Currie2022) are present in both Ulughbegsaurus uzbekistanensis and some dromaeosaurids such as Utahraptor ostrommaysi (Fig. 3c,d).

Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) presented a phylogenetic analysis that included only allosauroids and tyrannosauroids and excluded all other non-avian theropod clades. This selective taxon sampling assumed relationships a priori and did not allow a comprehensive assessment. Dromaeosaurids such as Achillobator giganticus from the Late Cretaceous (Cenomanian–Santonian) Bayn Shire Formation of Mongolia (Perle et al. 1999; Turner et al. Reference Turner, Makovicky and Norell2012) and Utahraptor ostrommaysi from the Lower Cretaceous (Barremian–Aptian) Upper Yellow Cat Member of the Cedar Mountain Formation of Utah (Kirkland et al. Reference Kirkland, Burge and Gaston1993) attained linear dimensions comparable to those of other large theropods. Indeed, Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) even made reference to ZIN PH 11/16 discussed here.

Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) referred the two fragments of maxillae described by Sues & Averianov (Reference Sues and Averianov2014) to Ulughbegsaurus uzbekistanensis, even though there is no anatomical similarity or overlap between the three specimens. They then reconstructed a remarkably long maxilla by combining the holotype and CCMGE 600/12457 (Tanaka et al. Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021, fig. S7) and based a high estimate of body size on this reconstruction. However, this reconstruction cannot be justified since there are no anatomical landmarks to associate the two fragments and determine their relative positions.

Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) referred CCMGE 600/12457 to Ulughbegsaurus uzbekistanensis based on the ‘beading’ along the ventral rim of the antorbital fossa. This ‘beading’ on the two jaw fragments is likely not an anatomical feature. For example, the ventral rim of the antorbital fossa on the lateral surface of the maxilla of the Utahraptor ostrommaysi is closely associated with a number of neurovascular foramina (Fig. 3c). Even slight surficial erosion would generate ‘beads’ from the slightly thickened bone around canals associated with these openings. This is clearly evident on the eroded lateral surface of the holotypic maxilla of Ulughbegsaurus uzbekistanensis (Tanaka et al. Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021, fig. 2b).

The structure of CCMGE 600/12457 resembles that in some carcharodontosaurians (e.g. Acrocanthosaurus atokensis, Currie & Carpenter, Reference Currie and Carpenter2000) but also that in dromaeosaurids such as Dromaeosaurus albertensis (Currie, Reference Currie1995). Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) cited the ‘approximately 20° ventral orientation at the jugal’ as a carcharodontosaurian synapomorphy but their assessment is based only on the referred fragment CCMGE 600/12457. Furthermore, this character-state is also shared by dromaeosaurids such as Achillobator giganticus (Perle et al. 1999) and Dromaeosaurus albertensis (Currie, Reference Currie1995).

The anteromedial process of the maxilla with a medial horizontal groove for contact with adjacent cranial elements in Ulughbegsaurus uzbekistanensis does not resemble the homologous feature in undisputed carcharodontosaurians (e.g. Neovenator salerii, Brusatte et al. Reference Brusatte, Benson and Hutt2008) but matches those in dromaeosaurids (Dromaeosaurus albertensis, Currie, Reference Currie1995; Utahraptor ostrommaysi, Fig. 3d).

Among the hundreds of non-avian theropod remains from the Bissekty Formation personally examined by AA and H-DS, there were no bones that could definitively be assigned to carcharodontosaurians. Tanaka et al. (Reference Tanaka, Anvarov, Zelenitsky, Ahmedshaev and Kobayashi2021) surmised that some of the larger isolated teeth assigned to Timurlengia euotica (Averianov & Sues, Reference Averianov and Sues2012) might belong to carcharodontosaurians. While this cannot be ruled out, at least none of the numerous teeth referred to Timurlengia euotica and examined by AA and H-DS shows features inconsistent with attribution to tyrannosauroids.

4. Conclusions

A pedal phalanx II-2 demonstrates the presence of a dromaeosaurid in the Bissekty Formation that attained larger body size than any other known member of this clade. Among dromaeosaurids, several taxa are distinguished by large body size: Utahraptor ostrommaysi with a femur length of 56.5 cm (Turner et al. Reference Turner, Makovicky and Norell2012); Austroraptor cabazai, from the Upper Cretaceous (Campanian–Maastrichtian) Allen Formation of Argentina, with a femur length of 56 cm (Novas et al. Reference Novas, Pol, Canale, Porfiri and Calvo2009); the possibly chimaeric Dakotaraptor steini, from the Upper Cretaceous (Maastrichtian) Hell Creek Formation of South Dakota, with a femur length of 55.8 cm (DePalma et al. Reference DePalma, Burnham, Martin, Larson and Bakker2015); and Achillobator giganticus with a femur length of 55 cm (Turner et al. Reference Turner, Makovicky and Norell2012). In addition, isolated teeth from the Lower Cretaceous (Barremian) Wessex Formation of England (Sweetman, Reference Sweetman2004) and the Upper Cretaceous (Campanian) Tar Heel Formation of North Carolina (Brownstein, Reference Brownstein2018) record dromaeosaurids as large as or larger than Deinonychus antirrhopus. The dimensions of the pedal phalanx II-2 of the giant Bissekty dromaeosaurid considerably exceed those of the corresponding phalanges in Achillobator giganticus and Austroraptor cabazai, respectively. Turner et al. (Reference Turner, Pol, Clarke, Erickson and Norell2007) estimated the total length of Achillobator giganticus at 4.85 m, and Novas et al. (Reference Novas, Pol, Canale, Porfiri and Calvo2009) provided an estimate of 5 m for the total length of Austroraptor cabazai. Achillobator giganticus and Utahraptor ostrommaysi are placed in Dromaeosaurinae (Turner et al. Reference Turner, Makovicky and Norell2012; Powers et al. Reference Powers, Fabbri, Doschak, Bhullar, Evans, Norell and Currie2022). By contrast, Austroraptor cabazai is a representative of Unenlagiinae, a predominantly South American clade of Dromaeosauridae. Thus, evolution toward very large body-size occurred at least twice among Dromaeosauridae (Wang et al. Reference Wang, Zhang, Tan, Jiangzuo, Zhang and Tan2022). Giant (>4 m long) dromaeosaurids clearly were apex predators in several Cretaceous terrestrial ecosystems.

The holotypic maxilla of Ulughbegsaurus uzbekistanensis presents several features that are found in both carcharodontosaurians and dromaeosaurids. In view of its highly fragmentary nature and the lack of unambiguous apomorphies linking it to any particular clade of non-avian theropods, the phylogenetic position of Ulughbegsaurus uzbekistanensis remains unresolved. It does not definitively establish the presence of carcharodontosaurian theropods in the Bissekty Formation. In the absence of autapomorphies or a diagnostic combination of character-states for Ulughbegsaurus uzbekistanensis, we also consider this binomen a nomen dubium.

Acknowledgements

H-DS thanks PJ Currie and AH Turner for sharing information on Achillobator giganticus, and AK Behrensmeyer for discussions concerning bone erosion. MJ Powers and CD Brownstein provided comments on the manuscript. DL Brinkman kindly provided photographs of the pedal phalanx II-2 of YPM VP.005205.

References

Averianov, AO (2010) The osteology of Azhdarcho longicollis Nessov, 1984 (Pterosauria, Azhdarchidae) from the Late Cretaceous of Uzbekistan. Proceedings of the Zoological Institute RAS 314, 264317.CrossRefGoogle Scholar
Averianov, AO and Sues, H-D (2007) A new troodontid (Dinosauria: Theropoda) from the Cenomanian of Uzbekistan, with a review of troodontid records from the territories of the former Soviet Union. Journal of Vertebrate Paleontology 27, 8798.CrossRefGoogle Scholar
Averianov, AO and Sues, H-D (2012) Skeletal remains of Tyrannosauroidea (Dinosauria: Theropoda) from the Bissekty Formation (Upper Cretaceous: Turonian) of Uzbekistan. Cretaceous Research 34, 284–97.CrossRefGoogle Scholar
Averianov, AO and Sues, H-D (2019) Morphometric analysis of the teeth and taxonomy of the enigmatic theropod Richardoestesia from the Upper Cretaceous of Uzbekistan. Journal of Vertebrate Paleontology 39, e1614941. doi: 10.1080/02724634.2019.1614941.CrossRefGoogle Scholar
Averianov, AO and Sues, H-D (2022) New material and diagnosis of a new taxon of alvarezsaurid (Dinosauria, Theropoda) from the Upper Cretaceous Bissekty Formation of Uzbekistan. Journal of Vertebrate Paleontology 42, e2036174. doi: 10.1080/02724634.2036147.Google Scholar
Behrensmeyer, AK (1978) Taphonomic and ecologic information from bone weathering. Paleobiology 4, 150–62.CrossRefGoogle Scholar
Britt, BB (1991) Theropods of Dry Mesa Quarry (Morrison Formation, Late Jurassic), Colorado, with emphasis on the osteology of Torvosaurus tanneri . Brigham Young University Geology Studies 37, 172.Google Scholar
Brownstein, CD (2018) A large dromaeosaurid from North Carolina. Cretaceous Research 92, 17.CrossRefGoogle Scholar
Brusatte, SL, Averianov, A, Sues, H-D, Muir, A and Butler, IB (2016) New tyrannosaur from the mid-Cretaceous of Uzbekistan clarifies evolution of giant body sizes and advanced senses in tyrant dinosaurs. Proceedings of the National Academy of Sciences of the United States of America 113, 3447–52.CrossRefGoogle ScholarPubMed
Brusatte, SL, Benson, RBJ and Hutt, S (2008) The osteology of Neovenator salerii (Dinosauria: Theropoda) from the Wealden Group (Barremian) of the Isle of Wight. Monographs of the Palaeontographical Society 162, 175.Google Scholar
Brusatte, SL, Chure, DJ, Benson, RBJ and Xu, X (2010) The osteology of Shaochilong maortuensis, a carcharodontosaurid (Dinosauria: Theropoda) from the Late Cretaceous of Asia. Zootaxa 2334, 146.CrossRefGoogle Scholar
Brusatte, SL and Sereno, PC (2007) A new species of Carcharodontosaurus (Dinosauria: Theropoda) from the Cenomanian of Niger and a revision of the genus. Journal of Vertebrate Paleontology 27, 902–16.CrossRefGoogle Scholar
Brusatte, SL, Vremir, M, Csiki-Sava, Z, Turner, AH, Watanabe, A, Erickson, GM and Norell, MA (2013) The osteology of Balaur bondoc, an island-dwelling dromaeosaurid (Dinosauria: Theropoda) from the Late Cretaceous of Romania. Bulletin of the American Museum of Natural History 374, 1100.CrossRefGoogle Scholar
Currie, PJ (1987) Bird-like characteristics of the jaws and teeth of troodontid theropods (Dinosauria, Saurischia). Journal of Vertebrate Paleontology 7, 7281.CrossRefGoogle Scholar
Currie, PJ (1995) New information on the anatomy and relationships of Dromaeosaurus albertensis (Dinosauria: Theropoda). Journal of Vertebrate Paleontology 15, 576–91.CrossRefGoogle Scholar
Currie, PJ and Carpenter, K (2000) A new specimen of Acrocanthosaurus atokensis (Theropoda, Dinosauria) from the Lower Cretaceous Antlers Formation (Lower Cretaceous, Aptian) of Oklahoma, USA. Geodiversitas 22, 207–46.Google Scholar
Currie, PJ and Paulina Carabajal, A (2012) A new specimen of Austroraptor cabazai Novas, Pol, Canale, Porfiri and Calvo, 2008 (Dinosauria, Theropoda, Unenlagiidae) from the latest Cretaceous (Maastrichtian) of Río Negro, Argentina. Ameghiniana 49, 662–7.CrossRefGoogle Scholar
Delcourt, R and Grillo, ON (2018) Reassessment of a fragmentary maxilla attributed to Carcharodontosauridae from Presidente Prudente Formation. Cretaceous Research 84, 515–24.CrossRefGoogle Scholar
DePalma, RA, Burnham, DA, Martin, LD, Larson, PL and Bakker, RT (2015) The first giant raptor (Theropoda: Dinosauria) from the Hell Creek Formation. The University of Kansas, Paleontological Institute, Paleontological Contributions 14, 116.Google Scholar
Hendrickx, C and Mateus, O (2014) Torvosaurus gurneyi n. sp., the largest terrestrial predator from Europe, and a proposed terminology of the maxilla anatomy in nonavian theropods. PLOS ONE 9, e88905. doi: 10.1371/journal.pone.0088905.CrossRefGoogle Scholar
Hurum, JH and Sabath, K (2003) Giant theropod dinosaurs from Asia and North America: skulls of Tarbosaurus bataar and Tyrannosaurus rex compared. Acta Palaeontologica Polonica 48, 161–90.Google Scholar
Ibrahim, N, Sereno, PC, Varricchio, DJ, Martill, DM, Dutheil, DB, Unwin, DM, Baidder, L, Larsson, HCE, Zouhri, S and Kaoukaya, A (2020) Geology and paleontology of the Upper Cretaceous Kem Kem Group of eastern Morocco. ZooKeys 928, 1216.CrossRefGoogle ScholarPubMed
Kirkland, JI, Burge, D and Gaston, R (1993) A large dromaeosaur (Theropoda) from the Lower Cretaceous of eastern Utah. Hunteria 2, 116.Google Scholar
Kurzanov, SM (1976) [Structure of the braincase of the carnosaur Itemirus gen. nov. and some questions of dinosaur cranial anatomy.] Paleontologicheskii Zhurnal 1976(3), 127–37 (in Russian).Google Scholar
Lamanna, MC, Martínez, RD and Smith, JB (2002) A definitive abelisaurid theropod dinosaur from the early Late Cretaceous of Patagonia. Journal of Vertebrate Paleontology 22, 5869.CrossRefGoogle Scholar
Longrich, NR and Currie, PJ (2009) A microraptorine (Dinosauria–Dromaeosauridae) from the Late Cretaceous of North America. Proceedings of the National Academy of Sciences of the United States of America 106, 5002–7.CrossRefGoogle ScholarPubMed
Marsh, OC (1881) Principal characters of American Jurassic dinosaurs. Part V. American Journal of Science, Series 3, 21, 417–23.CrossRefGoogle Scholar
Matthew, WD and Brown, B (1922) The family Deinodontidae, with notice of a new genus from the Cretaceous of Alberta. Bulletin of the American Museum of Natural History 46, 367–85.Google Scholar
Novas, FE, Pol, D, Canale, JI, Porfiri, JD and Calvo, JO (2009) A bizarre Cretaceous theropod dinosaur from Patagonia and the evolution of Gondwanan dromaeosaurids. Proceedings of the Royal Society B 276, 1101–7.CrossRefGoogle ScholarPubMed
Ostrom, JH (1969) Osteology of Deinonychus antirrhopus, an unusual theropod from the Lower Cretaceous of Montana. Bulletin of the Peabody Museum of Natural History, Yale University 30, 1165.Google Scholar
Owen, R (1842) Report on British fossil reptiles. Part II. Reports of the Meetings of the British Association for Advancement of Science 11, 60204.Google Scholar
Perle, A, Norell, MA and Clark, JM (1999) A New Maniraptoran Theropod - Achillobator Giganticus (Dromaeosauridae) - from the Upper Cretaceous of Burkhant, Mongolia. Ulan Bator: National University of Mongolia, 104 pp.Google Scholar
Powers, MJ, Fabbri, M, Doschak, MR, Bhullar, B-AS, Evans, DC, Norell, MA and Currie, PJ (2022) A new hypothesis of eudromaeosaurian evolution: CT scans assist in testing and constructing morphological characters. Journal of Vertebrate Paleontology 42, e2010087. doi: 10.1080/02724634.2021.2010087.Google Scholar
Redman, CM and Leighton, LR (2009) Multivariate faunal analyses of the Turonian Bissekty Formation: variation in the degree of marine influence in temporally and spatially averaged fossil assemblages. Palaios 24, 1826.CrossRefGoogle Scholar
Sampson, SD and Witmer, LM (2007) Craniofacial anatomy of Majungasaurus crenatissimus (Theropoda, Abelisauridae) from the Late Cretaceous of Madagascar. Society of Vertebrate Paleontology Memoir 8, 32102.CrossRefGoogle Scholar
Sereno, PC (1997) The origin and evolution of dinosaurs. Annual Review of Earth and Planetary Sciences 25, 435–89.CrossRefGoogle Scholar
Sues, H-D and Averianov, A (2013) Enigmatic teeth of small theropod dinosaurs from the Upper Cretaceous (Cenomanian–Turonian) of Uzbekistan. Canadian Journal of Earth Sciences 50, 306–14.CrossRefGoogle Scholar
Sues, H-D and Averianov, A (2014) Dromaeosauridae (Dinosauria: Theropoda) from the Bissekty Formation (Upper Cretaceous: Turonian) of Uzbekistan and the phylogenetic position of Itemirus medullaris Kurzanov, 1976. Cretaceous Research 51, 225–40.Google Scholar
Sues, H-D and Averianov, A (2015) New material of Caenagnathasia martinsoni (Dinosauria: Theropoda: Oviraptorosauria) from the Bissekty Formation (Upper Cretaceous: Turonian) of Uzbekistan. Cretaceous Research 54, 50–9.CrossRefGoogle Scholar
Sweetman, SC (2004) The first record of velociraptorine dinosaurs (Saurischia, Theropoda) from the Wealden (Early Cretaceous, Barremian) of southern England. Cretaceous Research 25, 353–64.CrossRefGoogle Scholar
Tanaka, K, Anvarov, OUO, Zelenitsky, DK, Ahmedshaev, AS and Kobayashi, Y (2021) A new carcharodontosaurian theropod dinosaur occupies apex predator niche in the early Late Cretaceous of Uzbekistan. Royal Society Open Science 8, 210923. doi: 10.1098/rsos.210923.CrossRefGoogle ScholarPubMed
Turner, AH, Makovicky, PJ and Norell, MA (2012) A review of dromaeosaurid systematics and paravian phylogeny. Bulletin of the American Museum of Natural History 371, 1206.CrossRefGoogle Scholar
Turner, AH, Pol, D, Clarke, JA, Erickson, GM and Norell, MA (2007) A basal dromaeosaurid and size evolution preceding avian flight. Science 317, 1378–81.CrossRefGoogle ScholarPubMed
Wang, S, Zhang, Q, Tan, Q, Jiangzuo, Q, Zhang, H and Tan, L (2022) New troodontid theropod specimen from Inner Mongolia, China clarifies phylogenetic relationships of later-diverging small-bodied troodontids and paravian body size evolution. Cladistics 38, 5982.CrossRefGoogle ScholarPubMed
Zanno, LE and Makovicky, PJ (2013) Neovenatorid theropods are apex predators in the Late Cretaceous of North America. Nature Communications 4, 2827. doi: 10.1038/ncomms3827.CrossRefGoogle ScholarPubMed
Zanno, LE, Tucker, RT, Canoville, A, Avrahami, HM, Gates, TA and Makovicky, PJ (2019) Diminutive fleet-footed tyrannosauroid narrows the 70-million-year gap in the North American fossil record. Communications Biology 2, 64. doi: 10.1038/s42003-019-0308-7.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Eudromaeosauria gen. et sp. indet., Bissekty Formation, left pedal phalanx II-2 (ZIN PH 11/16), in (a) lateral, (b) medial, (c) dorsal, (d) ventral, (e) proximal and (f) distal views. Scale bar = 3 cm. Abbreviations: clp, collateral ligament pit; pvh, posteroventral ‘heel’.

Figure 1

Fig. 2. Pedal phalanges II-2 of (a) Deinonychus antirrhopus (YPM VP.005205, reversed), (b) Achillobator giganticus and (c) ZIN PH 11/16, shown at the same scale for comparison. (a) Courtesy of DL Brinkman and (b) scanned and reversed from Perle et al. (1999, pl. 13). Scale bars each equal 1 cm. Abbreviations: clp, collateral ligament pit; pvh, posteroventral ‘heel’.

Figure 2

Fig. 3. Partial maxillae of Ulughbegsaurus uzbekistanensis (holotype, UzSGM 11-01-02; a, b) and Utahraptor ostrommaysi (BYU 19965, reversed; c, d), each in (a, c) lateral and (b, d) medial views. (a, b) From Tanaka et al. (2021) – CC BY 4.0. Scale bars each equal 5 cm. Abbreviations: amp, anteromedial process of maxilla; af, accessory fossa; aofe, margin of antorbital fenestra; aofo, antorbital fossa; idp, interdental plate; mfe, maxillary fenestra; nf, nutrient foramen; ‘pmfo’, ‘promaxillary fossa’; ps, palatal shelf; slf, supralabial foramen.