Shri devi Turner, Montanari and Norell, 2021
publication ID |
https://doi.org/ 10.4202/app.01065.2023 |
persistent identifier |
https://treatment.plazi.org/id/7D59CF29-DD2A-FFEF-72BF-19F42AA099C4 |
treatment provided by |
Felipe |
scientific name |
Shri devi Turner, Montanari and Norell, 2021 |
status |
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Shri devi Turner, Montanari and Norell, 2021
Figs. 2–4 View Fig View Fig View Fig .
1981 Velociraptor sp. Osborn, 1924; Osmólska 1981: 88, table 2.
1982 Velociraptor sp. Osborn, 1924; Osmólska 1982: 445.
1999 Velociraptor mongoliensis Osborn, 1924 ; Barsbold and Osmólska 1999: 191, figs. 7A–F, 8.
1999 Dromaeosauridae indet. Matthew and Brown, 1922; Norell and Makovicky 1999: 3, fig. 24.
2007 Velociraptor mongoliensis Osborn, 1924 ; Feduccia et al. 2007: 376, fig. 2.
2021 Eudromaeosauria indet. Longrich and Currie, 2009; Napoli et al. 2021: 39.
Holotype: MPC-D 100/980, a partial articulated skeleton (including cervical, dorsal, and proximal caudal vertebrae, the right femur, the right and left tibiotarsa, and the right pes) lacking a skull ( Turner et al. 2021).
Type locality: Khulsan, Ömnögovi Province, Gobi Desert, Mongolia.
Type horizon: Baruungoyot strata,?Campanian, Upper Cretaceous ( Jerzykiewicz and Russell 1991).
Material. — ZPAL MgD-I/97, a partial skull (including left jugal, left lacrimal, left maxilla, fragment of the right maxilla, palatine elements, both dentaries lacking the anteriormost portions, both splenials, surangulars, and angulars) in close association with a distal portion of the left hindlimb (containing the distal parts of the left fibula and tibia, astragalus and complete pes, with four metatarsals and all phalanges) from the type locality and horizon .
Emended diagnosis. — Turner et al. (2021) diagnosed Shri devi on base of the following unique combination of features: large epipophyses on the first dorsal vertebra overhanging the posterior margin of the postzygapophysis (autapomorphy); two first dorsal vertebrae each with two dorsoventrally aligned pleurocoels on each side (autapomorphy); posteriorly inclined scar on the lateral surface of the neural arch (autapomorphy), a relatively long metatarsus (44% of the femur length), and proportionally long ungual phalanx on pedal digit II (101% to 104% of the metatarsal II length in MPC-D 100/980 and ZPAL MgD-I/97, respectively; modified after Turner et al. 2021).
Based on data derived from the new material, S. devi can befurtherdiagnosedby:ashortantorbitalfenestraofsubequal anteroposterior and dorsoventral axes with the ventral margin steeply inclined anterodorsally (shared with Atrociraptor marshalli , Saurornitholestes langstoni , and Sinornithosaurus millenii ); a distinct longitudinal labial ridge determining the ventral margin of the antorbital fossa just above the supralabial foramina row, parallel to the alveolar margin of maxilla (shared with Velociraptor mongoliensis but more prominent in S. devi ); the last maxillary tooth positioned posterior to the anterior extremity of the maxillo-jugal suture (shared with Atrociraptor marshalli and Saurornitholestes langstoni ); the Z-shaped suture between maxilla and jugal (shared with Atrociraptor marshalli and Saurornitholestes langstoni ); the anteroventral process of quadratojugal projecting anterior to the posterior orbital margin of the jugal (autapomorphy); a short posterodorsal process of the lacrimal (autapomorphy); weakly developed, laterally positioned longitudinal tubercles on the anterior surfaces of metatarsals II and III (shared with Linheraptor exquisitus ).
Description. — ZPAL MgD-I/97 represents a medium-sized individual of a velociraptorine dromaeosaurid. The partial skull is closely associated with a left pes, such that the ungual of the fourth digit is below the lateral surface of the left dentary ( Fig. 2 View Fig ).
The left maxilla lacks the nasal process, and only a small posterior fragment of the right bone is preserved ( Fig. 3 View Fig ). The antorbital fenestra length is only 105.7% of its height (measured in the posterior portion, just in front of the lacrimal), in contrast to the elongated condition seen in Velociraptor mongoliensis , Linheraptor exquisitus , and Tsaagan mangas Table 1, Figs. 5 View Fig , 6 View Fig ). The antorbital fenestra is roughly equal in height and length or taller than longer in Saurornitholestes langstoni UALVP 55700, Sinornithosaurus millenii IVPP V 12811 ( Xu and Wu 2001; Currie and Evans 2020), and most likely in Atrociraptor marshalli ( Powers et al. 2022) . The ventral margin of the antorbital fenestra tapers anterodorsally, at an angle equal to 24° (measured between the ventral margin of the antorbital fossa and ventral margin of the antorbital fenestra), which is an angle not observed in any specimen of V. mongoliensis (up to 15°); however, it is similar to that of Bambiraptor feinbergi AMNH FARB 30556 and Atrociraptor marshalli ( Burnham et al. 2000; Currie and Varricchio 2004). The ventral margin of the antorbital fossa extends below the dorsal extent of maxillary alveoli, as in V. mongoliensis , Shanag ashile , and Saurornitholestes langstoni , but in contrast to “ Velociraptor ” osmolskae, T. mangas and L. exquisitus ( Powers et al. 2022) .
Ventrally,thereisasinglerowofa neurovascular (=supralabial) foramina. Similarly, as in V. mongoliensis ( AMNH FARB 6515, MPC-D 100/54), L. exquisitus , and T. mangas , there is a groove-like, elongate neurovascular foramen extending above the few posterior alveoli. Just above the row there is a distinct longitudinal labial ridge delimiting the antorbital fossa ventrally ( Fig. 3A View Fig 7 –A View Fig 10). The ridge is 4 mm high dorsoventrally and protrudes laterally for a 1.5 mm. The ridge reaches the maxillo-jugal suture posteriorly, being much more prominent than the ventral delimitation of the antorbital fossa seen in V. mongoliensis ( MPC-D 100/25, MPC-D 100/54) and Velociraptor sp. ( MPC-D 100/982).
Only the anteroventral and posterior margins of the relatively large maxillary fenestra are preserved ( Fig. 3A View Fig 7 View Fig ). It is positioned close to the anterior margin of the antorbital fenestra, extending more posteriorly than in some specimens of V. mongoliensis ( MPC-D 100/25, PIN 3143/8) and Velociraptor sp. MPC-D 100/982, resulting in a relatively anteroposteriorly short pila interfenestralis, with a constriction at its dorsoventral midpoint. The greatest longitudinal diameter of the fenestra is 9 mm long, and it equals 44.8% of the distance between the anterior margin of the antorbital fossa and the antorbital fenestra. The precise anteroposterior position and size of the fenestra is known to vary even in a single specimen (it is relatively larger and positioned more caudally on the left side of the MPC-D 100/54; see Table 1). In L. exquisitus and T. mangas the anterior portion of the maxillary fenestra is tucked into the anterior margin of the antorbital fossa ( Norell et al. 2006; Xu et al. 2010). The dorsoventral position of the fenestra is about the midpoint height of the antorbital fenestra in ZPAL MgD-I/97.
Anteriorly, there is a narrow promaxillary fenestra that is constrained into the anterior margin of the antorbital fossa. There are two promaxillary fenestra of a similar size in some specimens of V. mongoliensis ( MPC-D 100/25, MPC-D 100/54), whereas in AMNH FARB 6515 one fenestra is slit-like and the second one is smaller in size ( Barsbold and Osmólska 1999). It is not possible to determine the number and sizes of the promaxillary fenestrae in ZPAL MgD-I/97 as the specimen is incompletely preserved in this area. The promaxillary fenestra is at the level of the ventral margin of the maxillary fenestrae in ZPAL MgD-I/97, similar to V. mongoliensis MPC-D 100/25. It differs from the condition seen in L. exquisitus , and T. mangas where the single promaxillary fenestra is more ventral than the maxillary one ( Norell et al. 2006; Xu et al. 2010, 2015). Closely located maxillary and promaxillary fenestrae are also seen in Achillobator giganticus , Atrociraptor marshalli , and “ V. ” osmolskae ( Currie and Varricchio 2004; Godefroit et al. 2008; Turner et al. 2012); however, in the latter, the promaxillary fenestra is of similar large size as the maxillary one.
There is no lateral recess posterior to the maxillary fenestra in ZPAL MgD-I/97, in contrast to Acheroraptor te- mertyorum, L. exquisitus , and T. mangas ( Evans et al. 2013; Xu et al. 2015; Brownstein 2021). Such a structure is related to the development of the postantral wall (additional maxillary pneumatic fenestra sensu Brownstein 2021). However, as the pila postantralis is positioned relatively more anteriorly in ZPAL MgD-I/97 than in “ V. ” osmolskae, and given the preserved portion of the postantral wall, that leans medioventrally, it is possible that in S. devi the postantral wall was less visible in the lateral view than in other dromaeosaurids.
Ventral to the antorbital fossa, the maxilla is as low as in V. mongoliensis , but unlike L. exquisitus and T. mangas . It tapers posteriorly as in other velociraptorines. The ventral margin of the maxilla is nearly straight below the antorbital fossa, as in most of the V. mongoliensis specimens (except MPC-D 100/54).
The Z-shaped suture between the maxilla and jugal is visible in lateral view. The dorsal portion of the suture directs posteroventrally, while at the level of the ventral margin of the antorbital fossa it abruptly projects anteriorly, and below the labial ridge again continues posteroventrally ( Fig. 3A View Fig 6 – A View Fig 7 View Fig ). In V. mongoliensis (AMNHFARB6515,MPC-D100/25, MPC-D 100/54), L. exquisitus (IVVP V1692) and T. mangas ( MPC-D 100/1015) there is a simple suture with the maxillary process of the jugal overlapping the maxilla dorsally. The longitudinal notch on the posterior part of the jugal ramus of the Atrociraptor marshalli TMP 1995.166.0001 maxilla suggests the presence of the Z-shaped suture ( Currie and Varricchio 2004; Powers et al. 2022). that is also visible on the left side of the specimen of Saurornitholestes langstoni UALVP 55700 ( Currie and Evans 2020).
The preserved part of the jugal, which is missing its dorsal and posterior regions, measures 59.5 mm. The bone is triangular in lateral view, and is distinctly deeper in the posterior portion. Contribution of the jugal to the margin of the antorbital fenestra is very limited. Similar to V. mongoliensis , there is no dorsoventral constriction at the contact between maxilla and jugal in ZPAL MgD-I/97, observed in L. exquisitus . In the posteroventral corner of the antorbital fossa, just below the contact with the lacrimal, there is a distinct fossa, the jugal pneumatic recess (sensu Witmer 1997), similar to that in V. mongoliensis ( MPC-D 100/54, see also: Barsbold and Osmólska 1999) and T. mangas ( Norell et al. 2006) . CT data reveals that this recess deeply penetrates the suborbital ramus of the jugal to the level of the midpoint of the orbit. It differs from the apparently solid suborbital ramus of the jugal in Tsaagan ( Norell et al. 2006) . The ventral margin of the jugal bone in ZPAL MgD-I/97 projects posteroventrally in the lateral view for the majority of the orbital length. In V. mongoliensis ( MPC-D 100/25, MPC-D 100/54, PIN 3143/8), and Velociraptor sp. MPC-D 100/982 the ventral margin projects nearly parallel to the ventral margin of the orbit for nearly its whole length. In contrast, the ventral margin of the jugal of L. exquisitus projects much more posteroventrally. The orbital margin of the jugal is slightly concave in ZPAL MgD-I/97, similar as in V. mongoliensis and T. mangas . In some specimens of V. mongoliensis it is straight, similar as in L. exquisitus , while being slightly convex in the midlength of Adasaurus mongoliensis MPC-D 100/20.
In ZPAL MgD-I/97, the lateral surface of the jugal is smooth and flat. The ventral margin is thin, in contrast to the condition seen in Adasaurus mongoliensis ( MPC-D 100/20), L. exquisitus , and V. mongoliensis ( AMNH FARB 6515, MPC-D 100/24, 25, PIN 3143/8), where a longitudinal ridge is present, parallel to the ventral margin of the postorbital process of the jugal. Near the ventral margin of the jugal there is a shallow longitudinal groove in ZPAL MgD-I/97. It is most likely the anteriormost portion of the groove receiving the jugal process of the quadratojugal. If interpreted correctly, this would mean that either the jugal bone was relatively short anteroposteriorly in ZPAL MgD-I/97 or the jugal process of the quadratojugal was relatively long. In any case, the quadratojugal recess is not present anterior to the posterior orbital margin of the jugal in any other velociraptorine specimen ( Fig. 7 View Fig ). The only exception may be Adasaurus mongoliensis ( MPC-D 100/20), where there is a longitudinal groove developing in the posterior part of the jugal, dorsally to the ventral margin of the bone, nearly reaching the level of the midlength of the orbit. The contact with the quadratojugal is positioned dorsal to the level of the alveolar maxillary margin, similar as in V. mongoliensis and Velociraptor sp. ( MPC-D 100/982), in contrast to L. exquisitus and T. mangas , where it lies significantly more ventrally. In medial view, there is a robust ridge on the jugal, extending to the level of the contact with the ectopterygoid Fig. 3A View Fig 2 View Fig , A 3 View Fig ), which was also reported in other dromaeosaurids ( Xu et al. 2015). In the posterior part, in the region of the postorbital process of the jugal, there is an extensive concavity below the medial longitudinal ridge. In the anterior corner there is a contact surface for the ectopterygoid.
The lacrimal is T-shaped in lateral view, similar to that in other dromaeosaurids. The anterior process of the lacrimal bone is not preserved, and the posterior process is very short ( Fig. 3A View Fig 1 View Fig ) when compared to Kuru kulla ( MPC-D 100/981), L. exquisitus , Saurornitholestes langstoni , T. mangas , and V. mongoliensis . It results in the contact between the lacrimal and frontal being positioned more anteriorly in ZPAL MgD-I/97 than in other dromaeosaurids. The lateral margin of the posterior process directs acutely posteromedially in ZPAL MgD-I/97, forming an angle of 49° with the longitudinal axis of the skull when seen in the dorsal view. It differs from the condition seen in V. mongoliensis where the lateral margin of the lacrimal is directed more posteriorly than posteromedially (in range from 18° in MPC-D 100/24 to 28° in MPC-D 100/25). The dorsal surface is flat and is dorsally inclined posteromedially to the much greater degree than in Velociraptor sp. ( MPC-D 100/982) and K. kulla MPC-D 100/981). There are several small foramina on the dorsal surface, similar as in L. exquisitus ( Xu et al. 2015)
and V. mongoliensis ( MPC-D 100/54) (see also Brownstein 2021). Just above the lacrimal shaft there is a shallow longitudinal convexity in ZPAL MgD-I/97. The lateral and orbital edges bear small rugosities, overhanging the ventral process of the bone.
Posterolaterally, there is a small projection, a lacrimal boss ( Fig. 3A View Fig 1 View Fig , A 6 View Fig , A 7 View Fig ), similar to that seen in V. mongoliensis ( AMNH FARB 6515, MPC-D 100/25, MPC-D 100/54), L. exquisitus , “ Velociraptor ” osmolskae, Bambiraptor feinbergi ( AMNH FARB 30556), Deinonychus antirrhopus ( YPM 5232), and Utahraptor ostrommaysorum ( Kirkland et al. 1993; Godefroit et al. 2008; Xu et al. 2015). Kuru kulla ( MPC-D 100/981, Napoli et al. 2021) has a small but very distinct lacrimal hornlet, that is positioned more dorsally, while Tsaagan mangas purportedly lacks the lacrimal boss ( Norell et al. 2006; Xu et al. 2015). The bone is highly pneumatized with the pneumatic foramen of the lacrimal recess (sensu Witmer 1997) present in the posterodorsal corner of the antorbital fossa, dorsal to the distinct lacrimal duct.
In lateral view the ventral process of lacrimal is nearly vertically oriented, different from what is seen in Adasaurus mongoliensis ( MPC-D 100/20) where the bone is arched anteroventrally. The bone is relatively straight in V.mongoliensis ( AMNH FARB 6515, MPC-D 100/25, PIN 3143/8) and Linheraptor while being slightly curved in V. mongoliensis ( MPC-D 100/54) and Velociraptor sp. ( MPC-D 100/982). In anterior and posterior view the bone is more laterally concave than in other velociraptorines ( Fig. 3A View Fig 6 View Fig ). The contact with the maxilla is restricted by the maxillary process of the jugal ( Fig. 3A 3 View Fig ). The ventral process is thin ventrally in the lateral view, but extends anteroposteriorly in the dorsal half of the lacrimal in ZPAL MgD-I/97. It differs from the condition of the anteroposteriorly thin lacrimal ventral process visible in V. mongoliensis and Velociraptor sp. ( MPC-D 100/982); however, does not expand anteroposteriorly to the degree visible in L. exquisitus or “ V. ” osmolskae. The lateral lamina is somewhat sinuous in lateral view, with the anterior margin protruding slightly anteriorly than the medial lamina in ZPAL MgD-I/97. In Velociraptor and Linheraptor , the lateral lamina is more or less parallel to the medial one.
The palate of ZPAL MgD-I/97 was described in detail by Barsbold and Osmólska (1999). It preserves elements of palatine, pterygoid, vomer, and ectopterygoid ( Fig. 3A View Fig 4 View Fig , A 5 View Fig ).
The pterygoid bears a distinct longitudinal ridge on its ventral surface ( Fig. 3A View Fig 5 View Fig ), as was reported for Linheraptor ( Xu et al. 2015) . Medial to it there is a shallow fossa, that however is not flush with the ventral ectopterygoid recess. A partial left palatine is preserved in ZPAL MgD-I/97 ( Fig. 3A View Fig 4 View Fig , A 5 View Fig ) including the choanal process with a distinct longitudinal fossa on its dorsal surface. On the dorsal surface, along the contact with maxilla there is a pneumatic recess. Anterolaterally there is a short maxillary process. The elongated lacrimal process of the palatine contacts with the lacrimal, overlaps the posterior ramus of maxilla. The elongated pterygoid process of the palatine overlaps dorsally the anterior part of the nearly completely preserved ectopterygoid ( Fig. 3A View Fig 4 View Fig , A 5 View Fig ). Ventrally there is a ventral recess (sensu Witmer 1997) on ectopterygoid consisting of two fossae with a low crest separating them on the posterior wall of the recess (see Barsbold and Osmólska 1999). There is no dorsal ectopterygoid recess in ZPAL MgD-I/97 unlike that reported to be present in V. mongoliensis ( MPC-D 100/25, MPC-D 100/54), L. exquisitus , and possibly Velociraptor sp. ( MPC-D 100/982), while absent in T. mangas ( Norell et al. 2006; Xu et al. 2015). The bone seems to be less robust than that in V. mongoliensis ( MPC-D 100/25, MPC-D 100/54).
The dentary ( Fig. 3A 3 View Fig , A 7 View Fig , A 13 –A 16) is dorsoventrally low in ZPAL MgD-I/97 (with its height equal to 16 mm), which is similar to V. mongoliensis . The anteriormost portion of the dentaries are not preserved in the specimen. The dorsal and ventral margins are nearly parallel to each other. The bone is gently bowed ventrally in lateral view, as in V. mongoliensis and T. mangas ; however, this is to a lesser degree than observed in L. exquisitus . It contrasts with the nearly straight dentary of K. kulla . On the lateral surface, the relatively shallow, longitudinal groove housing neurovascular foramina along the dorsal margin is present. The second row of the foramina is visible along the ventral margin, and it terminates far more anteriorly than the dorsal one ( Fig. 3A View Fig 14). In K. kulla ( MPC-D 100/981) there is only a dorsal row of the foramina present. The long posteroventral process extends along the lateral surface of the splenial bone. Lingually there is a shallow and wide longitudinal Meckelian groove visible on both dentaries. There is a thin furrow present close to the alveolar margin in the anterior portion of the dentary, that bears a row of foramina in the anteriormost portion, as noted by Barsbold and Osmólska (1999). The well-developed, longitudinal anterior mylohyoid foramen is anterior to the level of the last two dentary teeth which is more anterior than in T. mangas .
The splenial is extensively exposed in the lateral view, as in V. mongoliensis and other dromaeosaurids. The posterior ramus of the bone with a surface for contact with the angular is directed relatively more posteroventrally than in other velociraptorines. The angular bone contacts the splenial anteriorly, defining the ventral margin of the external mandibular fenestra, and becomes much thinner posteriorly. There is a shallow groove on the lateral surface of the bone, with a very thin crest along the anteroventral margin, next to the contact with the splenial bone. Such a crest is not visible in T. mangas nor L. exquisitus , but is present in V. mongoliensis . The prearticular forms most of the medial region of the mandible posterior to the dentary. Posteriorly, it forms the well-defined anteroventral and ventral margins of the adductor fossa. The small, triangular coronoid is preserved medially on both sides of the specimen, being wedged between the surangular and prearticular.
The ventral margin of the external mandibular fenestra in ZPAL MgD-I/97 seems to extend significantly below the ventral margin of the dentary, as it can be indicated from the morphology of the lateral surface of the angular bone, lower than in Dromaeosaurus albertensis ( AMNH FARB 5356), L. exquisitus , Saurornitholestes langstoni , T. mangas , V. mongoliensis , and Velociraptor sp. ( MPC-D 100/982). Therefore, the mandible of ZPAL MgD-I/97 was likely deeper posterior to the dentary than in other velociraptorines; however, the contacts between the splenial and angular, as well as between the dentary and surangular, were most likely movable in the velociraptorines, allowing some passive rotation of the anterior portion of the dentary Barsbold and Osmólska 1999; Norell et al. 2006) and reconstruction of the exact in vivo placement of the bones might be taphonomically vulnerable.
The surangular bone is only partially preserved on the left side of the specimen ( Fig. 3A 3 View Fig , A 7 View Fig ). It is very thin in lateral view, being eroded at the level of the dorsal margin of the external mandibular fenestra. No posterior parts of the bone are preserved; hence it is not possible to compare it with the surangular of the K. kulla MPC-D 100/981 also known from Khulsan ( Napoli et al. 2021), although the surangular shelf seems to be less developed in ZPAL MgD-I/97.
The posteriormost nine maxillary teeth are preserved with the left maxilla and the posterior six (without the posteriormost one) with the right one. The largest maxillary teeth of ZPAL MgD-I/97 are 8.8–10.4 mm in apical length (measured from the most mesial point of the tooth crown base to the crown apex). Gaps between the tooth crown bases are 1.4–3.5 mm posteroventrally. Tooth roots are mediolaterally compressed, as in other velociraptorines. Approximately each second tooth is bigger than the preceding one, making a series of teeth differing in size, as seen in V. mongoliensis ( Barsbold and Osmólska 1999) . It seems that such tooth replacement pattern is less strict in ZPAL MgD-I/97, as the second and third preserved teeth of the left maxilla are of relatively similar, large size (as estimated by the widths at the bases of the teeth). As a result, the second, third, fifth, and seventh preserved teeth are the largest. However, it also varies within the V. mongoliensis sample and the clear pattern representing the alternating cycles of tooth replacement ( Barsbold and Osmólska 1999; Norell et al. 2006) is seen only in few specimens. In “ Velociraptor ” osmolskae, the maxillary teeth differ in size to some degree ( Godefroit et al. 2008), while in L. exquisitus and T. mangas the maxillary teeth are of similar size, with the anterior teeth being generally larger than the posterior ones. However, in Tsaagan the alternating pattern is visible within dentary teeth ( Norell et al. 2006; Xu et al. 2015).
In ZPAL MgD-I/97 the last maxillary tooth is positioned posterior to the anteriormost extent of the maxillo-jugal suture, just in front of the level of the lacrimal ( Fig. 3A View Fig 2 View Fig , A 3 View Fig , A 7 View Fig ). It differs from the condition seen in other eudromaeosaurians, where most of the maxilla posterior to the midpoint of the antorbital fenestra is edentulous, with exception for Atrociraptor marshalli and Saurornitholestes langstoni ( UALVP 55700). In V. mongoliensis the maxillary teeth usually are not present below the posterior half of the antorbital fenestra (e.g., AMNH FARB 6515, MPC-D 100/25; Table 2). On the left side of the T. mangas ( MPC-D 100/1015), and in Velociraptor sp. ( MPC-D 100/982), the last maxillary tooth is preserved relatively posteriorly, but not to the degree seen in ZPAL MgD-I/97. In “ V.” osmolskae ten maxillary teeth were reported ( Godefroit et al. 2008) and the last one seems to be present somewhere proximal to the midlength of the antorbital fenestra. In Linheraptor exquisitus , the last tooth is below the proximal third of the antorbital fenestra.
There are ten teeth preserved in the right dentary and nine in the left one. The longest dentary teeth are 8 mm long and spaces between the alveoli are 2–3 mm wide. The last dentary tooth is anterior to the last maxillary tooth.
Both labial and lingual surfaces of maxillary and dentary teeth are smooth, without the longitudinal ridges (sensu Hendrickx et al. 2015) visible on labial surfaces of some of the maxillary teeth of V. mongoliensis ( AMNH FARB 6515, MPC-D 100/54). There are about 4.5–5, and 5–5.5 denticles per millimeter on the distal carinae of maxillary and dentary teeth of ZPAL MgD-I/97, respectively. The denticles are simple and perpendicularly oriented in relation to the longer axis of the tooth. The mesial surface of the teeth is often rounded, similar to L. exquisitus and T. mangas . Only on the second and fifth preserved tooth of the right maxilla there is a very weakly preserved mesial serration ( Fig. 3A View Fig 11, A 12). The presence of the mesial serration only on some teeth is visible also in another velociraptorine specimen from the Baruungoyot strata, ZPAL MgD-I/102, while being absent in some isolated teeth collected from Khulsan ( ZPAL MgD-I/200). It suggests that the feature of presence of the mesial denticles may be more related to the tapho- nomic conditions than reflecting the diagnostic differences between the taxa (see also Barsbold and Osmólska 1999).
Only an incomplete distal portion of the thin left fibula is preserved in ZPAL MgD-I/97. It is attached to the lateral side of the tibia. It is 5.5 mm wide and subtriangular in cross-section. Its distalmost portion is not preserved. Only a distal portion of the left tibia is preserved ( SOM: fig. 1). It is 31 mm wide just above the calcaneum, and its shaft is 23.5 mm wide above the ascending process of the astragalus. The tibia is flattened anteroposteriorly, with a depth equal to 15.5 mm.
The astragalus bears an ascending process ( SOM: fig. 1). The process is taller laterally (33.9 mm) than medially (22 mm) and its dorsal extremity slopes medially, giving the bone an overall comma-like shape, similar to that in the holotype of Shri devi ( MPC-D 100/980; Turner et al. 2021), V. mongoliensis ( MPC-D 100/986; Norell and Makovicky 1999), and L. exquisitus ( IVPP V16923). Distally, the ascending process of the astragalus covers all of the anterior wall of the distal end of tibia. The body of the astragalus is not completely preserved. On the anterior wall of the ascending process of the astragalus, above the basal body, there is a distinct lateromedial groove. The preserved portion of the lateral condyle suggests that the astragalus and calcaneum were not fused to each other, similar to Achillobator giganticus , L. exquisitus , and Deinonychus antirrhopus , but in contrast to Adasaurus and V. mongoliensis . Only a small portion of a calcaneum is preserved on ZPAL MgD-I/97. Although the elements of the hindlimb are articulated, the distal tarsals and calcaneum are not preserved.
The first four metatarsals of the left pes are almost completely preserved in articulation ( Figs. 2 View Fig , 4A View Fig 1 –A View Fig 4 View Fig ), lacking only their proximalmost extremities. The preserved length along the third metatarsal is 91 mm, whereas the proximal width of the combined metatarsals II–IV is 32.7 mm. The metatarsal I is the shortest one ( Fig. 4A View Fig 8 View Fig ). It tapers proximally, among its arched shaft. The flat portion of the lateral surface indicates its contact with the shaft of the second metatarsal. Distally there is a nonarticular shaft of the bone present, similar as in S. devi ( MPC-D 100/980), but not present in K. kulla ( MPC-D 100/981). The shallow ligament pit is present only on the lateral surface, with no trace of the medial ligament pit, condition similar to S. devi ( MPC-D 100/980) and V. mongoliensis ( Norell and Makovicky 1997) , in contrast to K. kulla ( MPC-D 100/981, Napoli et al. 2021). The articular surface is divided by a gentle fossa. The bone has a very shallow longitudinal fossa on the lateral surface, distal to the articulation with metatarsal II, even less distinct than the one in S. devi ( MPC-D 100/980, Turner et al. 2021), and much shallower than in V. mongoliensis ( AMNH FARB 6518, MPC-D 100/985, MPC-D 100/986; Norell and Makovicky 1997).
The metatarsal II is shorter than the third and fourth ones. In the anterior view, the shaft of the second metatarsal is nearly rectangular, with a longer anteroposterior axis than a mediolateral one. Its contact with the metatarsal I is positioned distal to the midline of the bone’s shaft, as in most coelurosaurs, including the majority of V. mongoliensis specimens ( Norell and Makovicky 1997, 1999). An exception is MPC-D 100/986 V. mongoliensis from Chimney Buttes, where the attachment site for metatarsal I is more proximal ( Norell and Makovicky 1999; Hattori 2016). Proximally, metatarsal II is wider than metatarsal III. Although the proximalmost portion of the metatarsal II is not preserved in ZPAL MgD-I/97, this condition is similar, although less prominent, to S. devi ( MPC-D 100/980), L. exquisitus ( IVPP V16923), and Deinonychus antirrhopus , and differs from a very thin proximally metatarsal II of Adasaurus mongoliensis ( MPC-D 100/21), K. kulla ( MPC-D 100/981), and V. mongoliensis ( MPC-D 100/54, 100/985, 100/986, with exception of MPC-D 100/25, where the preserved part of the right pes suggests a proximally constricted metatarsal III). On the anterior surface there is a small tubercle present near the contact with metatarsal III ( Fig. 4A View Fig 1 View Fig , A 2 View Fig ), suggested as the attachment site for M. tibialis cranialis by Norell and Makovicky (1997). In ZPAL MgD-I/97 it is positioned laterally, as in S. devi ( MPC-D 100/980), and L. exquisitus ( IVPP V16923), whereas in V. mongoliensis it is located more centrally. On the posterior surface, near the medial margin there is a subtle longitudinal tubercle, near the contact with metatarsal I, a medial plantar crest sensu Norell and Makovicky (1997) ( Fig. 4A View Fig 3 View Fig , A 4 View Fig ). In ZPAL MgD-I/97 it is less prominent than the one observed in S. devi ( MPC-D 100/980). Just above the ginglymoid distal articulation, the shaft of the metatarsal II is slightly narrower in ZPAL MgD-I/97, similar to V. mongoliensis ( MPC-D 100/985, MPC-D 100/986) but unlike the condition of a constant width of the bone’s shaft in S. devi MPC-D 100/980, Turner et al. 2021). The lateral hemicondyle is slightly larger than the medial one, which twists medially more distinctly than in S. devi ( MPC-D 100/980), V. mongoliensis ( MPC-D 100/985) (see Norell and Makovicky 1997) or L. exquisitus .
Metatarsal III is the longest one, being slightly compressed lateromedially by adjacent bones. The preserved proximalmost portion is subrectangular in cross-section and the lateroventral region is elongated anteroposteriorly. The proximalmost width of the third metatarsal is narrower than the adjacent metatarsals. On the anterior surface, there is a small, weakly developed longitudinal tubercle on the lateral margin of the bone ( Fig. 4A View Fig 1 View Fig , A 2 View Fig ), proximal to the distal articulation, as in the S. devi holotype ( MPC-D 100/980) and in L. exquisitus ( IVPP V16923). A better developed, centrally positioned tubercle is visible in V. mongoliensis MPC-D 100/54, 100/985, 100/986) and Deinonychus antirrhopus ( YPM 5205, Turner et al. 2021). In ZPAL MgD-I/97 the bone lacks the distinct dorsal ridge covering metatarsal IV at the midlength level of metatarsal II seen in V. mongoliensis ( MPC-D 100/986) from the Chimney Buttes locality. The distal preginglymoid width of a metatarsal III is 20% wider than the adjacent metatarsals in ZPAL MgD-I/97, similar to V. mongoliensis ( Norell and Makovicky 1999) , while in L. exquisitus metatarsal III is nearly two times wider than metatarsal II in that region.
The metatarsal IV is intermediate in length between the metatarsal II and III, as in all velociraptorines. In proximal view it is triangular in cross section, extending laterally with a ventrolateral flange, as in V. mongoliensis ( MPC-D 100/985, 100/986, Norell and Makovicky 1997) and L. exquisitus , but not in S. devi ( MPC-D 100/980, Turner et al. 2021). Proximally, the bone is the widest of all metatarsals. There is a small lateral crest present, the same as the lateral plantar crest reported for V. mongoliensis by Norell and Makovicky (1997), where it is positioned just below the proximal articulation, suggesting that the metatarsus is only slightly eroded proximally in ZPAL MgD-I/97. In the distal portion the bone is slightly narrower mediolaterally and projects slightly laterally from the shaft of metatarsal III. The lateral margin of the bone is concave, similar to V. mongoliensis ( Norell and Makovicky 1997) .
All pedal phalanges are preserved and are fairly complete in ZPAL MgD-I/97 ( Fig. 4A View Fig 5 –A View Fig 8 View Fig ). The distal margin of the phalanx I-1 exceeds the distal margin of the second metatarsal when in articulation with the first metatarsal, similar to V. mongoliensis MPC-D 100/985 ( Norell and Makovicky 1997). There is a small plantar crest extending posteriorly and overlapping the articular surface of the first metatarsal, similar to V. mongoliensis ( Norell and Makovicky 1997) . The plantar surface of the crest is flat in ZPAL MgD-I/97, whereas it has a small tubercle in V. mongoliensis MPC-D 100/985. Both the medial and lateral ligament pits are distinct on the distal head. The ungual of the first digit is nearly equal to the I-1. It is oval in the proximal, and weakly curved in the lateral view. On both sides there are distinct grooves for the claw sheath along nearly the whole length of the bone.
Phalanx II-1 ( Fig. 4A View Fig 7 View Fig ) is shorter than II-2, as in S. devi ( MPC-D 100/980) and V. mongoliensis , but in contrast to the elongated II- 1 in Adasaurus mongoliensis ( MPC-D 100/21) and Kuru kulla ( MPC-D 100/981). The proximal portion of the bone is dorsoventrally compressed in lateral view. On the proximal surface, there is a proximoventral keel. It was reported for V. mongoliensis ( MPC-D 100/985) that such a tongue is connected with a distal medial trochlea by a ridge ( Norell and Makovicky 1997). In ZPAL MgD-I/97 there is only a short ridge present on the medial side of the ventral keel, similar to that in MPC-D 100/980 ( Turner et al. 2021). Relatively deep ligament fossae are present on both sides of the distal articulation, just above the midpoint of the trochlear dorsoventral height. A shallow but distinct hyperextensor fossa is present on the dorsal surface, in contrast to the weakly developed extensor tendon pit reported for K. kulla ( MPC-D 100/981, Napoli et al. 2021). The lateral hemicondyle is slightly wider than the medial one. Phalanx II-2 has an asymmetrical proximoventral keel, as in other dromaeosaurids. On the proximal surface of the bone there is an extensive ventral keel, and the distal trochlea are very narrow, with an extensive ginglymoid, as in other dromaeosaurids ( Norell and Makovicky2004). The medial ridge is present on the ventral surface of the keel. Ligament fossae on the distal articular surface are very small and positioned dorsally. The lateral hemicondyle has larger size and is positioned more distally than the medial one. There is no extensor tendon pit visible.
The ungual of the second digit is relatively hypertrophied. Its outer curvature is equal to 80 mm, being 104.2% of the second metatarsal length, more similar to the holotype of S. devi ( MPC-D 100/980) than V. mongoliensis ( Fig. 4B View Fig ; see SOM). The ungual cross section is very narrow. The flexor tubercle, positioned near the ventral border of the articular surface is relatively large and robust. Grooves for the claw sheath are present on both sides of the ungual, with the lateral one positioned more dorsally than the medial one, as in other dromaeosaurids ( Kirkland et al. 1993; Norell and Makovicky 1997). In the distal region the lateral groove is located dorsally and is even visible on the medial side, near the claw tip, whereas the medial groove ends anterior to the distal 1/8 of the bone. In L. exquisitus the second digit ungual is not completely preserved, but seemingly it was more robust proximally than in V. mongoliensis , and less hypertrophied than in MPC-D 100/980 and ZPAL MgD-I/97. It was reported that the second digit ungual was relatively reduced in K. kulla ( MPC-D 100/981), suggesting its close affinities with Adasaurus mongoliensis ( Napoli et al. 2021) . Despite that the femora of K. kulla ( MPC-D 100/981) and S. devi ( MPC-D 100/980) are of similar size, all the phalanges of the former are significantly smaller. However, given the relative sizes of the ungual II-3 and phalanx II- 2 in K. kulla ( MPC-D 100/981) being similar to that seen in V. mongoliensis and S. devi , K. kulla clearly differs from the condition seen Adasaurus mongoliensis , where only the ungual II-3 is reduced.
Phalanx III-1 ( Fig. 4A View Fig 6 View Fig ) is the second longest phalanx of the pes. In the proximal view the bone is nearly rectangular in cross section, and is only slightly skewed medially, similar to V. mongoliensis ( MPC-D 100/985, Norell and Makovicky 1997). Just above the distal trochlea, the relatively large extensor fossa is present. The distal articular surface is ginglymoid and the medial hemicondyle is greater in size than the lateral one. The collateral ligament pits are distinct and positioned at the midpoint of the trochlea. The dorsomedial inclination of the trochlear ridges, reported in V. mongoliensis ( Norell and Makovicky 1997) are not observed here, as the lateral trochlea is inclined dorsolaterally. Phalanx III-2 is much shorter than III-1 and is similar in length as II-2. The proximal portion in the plantar view is more developed medially, responding to the distal asymmetry of III-1. In the proximal view, both III-2 and III-3 lean laterally, in contrast to the medially skewed condition in V. mongoliensis ( MPC-D 100/985, Norell and Makovicky 1997). The distal articular surface of III-2 is ginglymoid, with a slightly wider lateral trochlea than the medial one; however, the latter is oriented more distinctly outwarded medially. The medial collateral ligamentar fossa is shallower than the lateral one, and both are positioned slightly above the center of the trochlea. Phalanx III-3 is similar in length to III-2 but is narrower. A very small tubercle is present proximally on the lateral side of the plantar surface. An extensor fossa is not visible on the dorsal surface. The collateral ligament fossae are small, especially the medial one, which is slit-like and positioned near the dorsal margin of the bone. The lateral ligament fossa is oval, deeper, and positioned only slightly below the level of the medial one. Ungual III-4 is preserved in the slab with the left side of the skull ( Fig. 3A View Fig 2 View Fig ). It was digitally removed from the rock matrix ( Fig. 7C View Fig ). It is weakly curved and has a small flexor tubercle. Its relative size is similar to that seen in other velociraptorines.
Phalanx IV-1 ( Fig. 4A View Fig 5 View Fig ) is slightly shorter than III-1. It is gently arched medially, especially in its distal portion. There is no distinct lateral crest on the proximal articular surface, seen in V. mongoliensis ( MPC-D 100/985). In the proximal view, the bone is skewed medially, for accommodation of the asymmetrical metatarsal IV, similar as in V. mongoliensis MPC-D 100/985. In plantar view there is a longitudinal ridge present at the proximal lateral margin, but no medial ridge visible in V. mongoliensis ( MPC-D 100/986). The distal articulation is ginglymoid, and the extensor fossa is relatively large. The lateral ligament fossa is deeper than the medial one. Phalanx IV-2 is skewed laterally in the proximal view. The flexor fossa is shallow. Phalanges IV-3 and IV-4 are symmetrical in the proximal view. No differences in slope of the lateral and medial articular surface are seen, in contrast to V. mongoliensis MPC-D 100/985. The phalanges are nearly of the same length, with IV-4 being much narrower. The ungual of the fourth digit is not completely preserved, being weakly curved, with a small, but distinct flexor tubercle. The grooves for the claw sheath are positioned at the same level on both sides, and the ventral portion of the ungual is significantly more massive.
Stratigraphic and geographic range.— Type locality and horizon only.
ZPAL |
Zoological Institute of Paleobiology, Polish Academy of Sciences |
AMNH |
American Museum of Natural History |
PIN |
Paleontological Institute, Russian Academy of Sciences |
YPM |
Peabody Museum of Natural History |
SOM |
Bulgarian Academy of Sciences |
IVPP |
Institute of Vertebrate Paleontology and Paleoanthropology |
No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.
Kingdom |
|
Phylum |
|
Family |
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Genus |
Shri devi Turner, Montanari and Norell, 2021
Czepiński, Łukasz 2023 |
Velociraptor mongoliensis
Feduccia, A. & Martin, L. D. & Tarsitano, S. 2007: 376 |
Velociraptor mongoliensis
Barsbold, R. & Osmolska, H. 1999: 191 |
Dromaeosauridae
Norell, M. A. & Makovicky, P. J. 1999: 3 |
Velociraptor sp.
Osmolska, H. 1982: 445 |
Velociraptor sp.
Osmolska, H. 1981: 88 |