Alvarezsaurian dinosaurs, a group of bizarre theropods with greatly shortened and modified forelimbs, are known mostly from the Cretaceous of Asia and South America. Here we report a new alvarezsaurian, Shishugounykus inexpectus gen. et sp. nov, based on a specimen recovered from the Middle–Upper Jurassic Shishugou Formation of the Junggar Basin, western China. Together with two other alvarezsaurians from this formation, i.e., Haplocheirus sollers and Aorun zhaoi, these Shishugou forms represent the only known Jurassic alvarezsaurians worldwide. Similar to the two other Shishugou alvarezsaurians, this new alvarezsaurian displays early stages in the development of the highly modified alvarezsaurian forelimb, but it possesses a number of manual features closer to the typical coelurosaurian theropod condition. Combining morphological and histological features, our analysis indicates that the earliest known alvarezsaurians are variable in size and other important morphological features, and in particular display a mosaic distribution of forelimb features.
Alvarezsauria was first recognized when Bonaparte named the Alvarezsaurus calvoi from the Coniacian-Santonian of Argentina1. Since then, fossil remains of this group have been recovered from the Upper Cretaceous of North America2,3, South America1,4,5, Asia6,7,8,9,10,11,12,13,14,15, and Europe16. Many of these Upper Cretaceous taxa, such as Mononykus, possess highly shortened and modified forelimbs and many derived features that also occur in birds, and they were once interpreted as flightless birds4,6,8,17,18,19,20,21,22. The avialan affinities of late-branching alvarezsaurians were questioned by many subsequent studies7,23,24 and Alvarezsauria has since been placed in various positions outside Avialae in coelurosaurian phylogeny25,26,27,28,29,30,31,32. The discovery of Haplocheirus sollers from the upper part of the Shishugou Formation (Oxfordian) in Junggar Basin, Xinjiang, China, extended the fossil record of the group by nearly 70 million years and helped confirm the early-branching maniraptoran status of the group within theropods33. More recently, Aorun zhaoi, a small theropod also known from the Shishugou Formation , was placed within the Alvarezsauria by a phylogenetic analysis , adding additional diversity of the group in the Jurassic. Here we describe a new specimen recovered from the Shishugou Formation, which represents the third alvarezsaurian species in this formation, and which demonstrates significant anatomical variability previously unappreciated among the earliest known alvarezsaurians.
Theropoda Marsh, 1881
Maniraptora Gauthier, 1986
Alvarezsauria Bonaparte, 1991
Shishugounykus inexpectus gen. et sp. nov
The generic name is a combination of Shishugou (Chinese Mandarin for the formation which produced the holotype specimen of the new animal; translates as “rock” “tree” “wash” for the abundant petrified wood in the formation) and onyx (Greek, “claw); the specific name refers to the unexpected discovery of a new alvarezsaurian species from the Middle-Late Jurassic Shishugou Formation, which has produced fossils of two other Jurassic alvarezsaurians, i.e., Haplocheirus sollers and Aorun zhaoi.
IVPP V23567, a partial skeleton (Fig. 1) including several cranial elements (possible partial right frontal and partial right parietal, partial left frontal, partial right angular, and right articular), three dorsal vertebrae, four sacral vertebrae, three caudal vertebrae, partial right scapula, partial left humerus, partial right ulna and radius, nearly complete right manus, partial left ilium, ischium, and pubis, complete right femur, partial left femur, nearly complete left and right tibiae, partial left and right fibula, a distal tarsal, partial left metatarsals II and III, left pedal phalanges III-1 and 2, IV-1, 2, and 4, and a few rib fragments and unidentifiable pieces. All recovered bones are clearly from one individual given that they are preserved in a small area (about 0.2 square meters), without any other bone nearby.
Locality and Horizon
Wucaiwan, Junggar Basin, Xinjiang, People’s Republic of China, Middle-Upper Jurassic Shishugou Formation34,35,36,37. The holotype-fossil-bearing bed is located between two volcanic tuff layers with radiometric (40Ar/39Ar) ages of 161.2 ± 0.2 and 158.7 ± 0.3 Ma, respectively35,36,37,38. The two tuff layers are separated by a section of fluvial sediments that is 90 meters thick, and assuming constant sedimentation rates this means that each meter of sediment is around 0.0278 million years36, if the sedimentation rate was relatively constant. Based on a section thickness of 36 meters between the holotype-fossil-bearing bed and the lower tuff layer, we infer that the holotype-bearing bed is ∼160.2 Ma. Using a similar method, previous studies estimate the geological ages of the fossil-bearing beds for Aorun zhaoi (about 13 m below the lower tuff) and Haplocheirus sollers (about 40 m above the lower tuff) fossils are ∼161.6 Ma and ~160.1 Ma37, respectively.
Shishugounykus inexpectus differs from all other alvarezsaurians in having the following unique combination of features (* marks the autapomorphies; we use the II-III-IV identity of manual digits in tetanurans): supratemporal fossa occupying large portion of frontal and with indistinct anterior border (sharp anterior border in early-branching alvarezsaurians such as Haplocheirus sollers and supratemporal fossa occupying a small portion of frontal in late-branching alvarezsaurians); scapula with hollow acromial process but without lateral concavities*; humeral internal tuberosity mediolaterally constricted distally*, giving it a “pinched” appearance; metacarpal III straight in dorsal view (laterally bowed in most other alvarezsaurians including Haplocheirus sollers); ungual III-3 subequal in size to ungual II-2 (considerably smaller in most other alvarezsaurians including Haplocheirus sollers); iliac medial surface with step-wise transition from ischial peduncle to pubic peduncle*; distal end of metatarsal II asymmetrically ginglymoid*.
Skeletal description and comparisons
The Shishugounykus inexpectus holotype displays three features suggesting a relatively early ontogenetic stage: the neurocentral sutures are only partially closed in one anterior caudal vertebra (Fig. 2); the fusions between the sacral centra are not complete (Fig. 2); and metacarpal II is preserved without the incorporation of the distal ‘semilunate’ carpal39. However, the smooth surfaces and well ossified articular ends of all preserved long bones suggest that it is not a hatchling; furthermore, the neurocentral sutures are closed in most preserved vertebrae (Fig. 2A,B,E), though many of them preserve only a small portion of the neural arch, thus suggesting a relatively late ontogenetic stage. We further investigated the ontogenetic stage of holotype individual using bone histological data (see below). Interestingly, histological features like the presence of an outside lamina of parallel-fibered tissue and abundant secondary remodeling bone tissues, suggest that the Shishugounykus inexpectus holotype is in a late ontogenetic stage40,41. Combing the evidence above, we infer this individual is an adult, close to but not at its full body size. The Shishugounykus inexpectus holotype is small in size, with an estimated body mass of 6.8 kg based on an empirical equation for theropod dinosaurs42.
The skull and mandible are represented by a partial frontal, partial laterosphenoid, partial parietal, partial angular, and articular. Most of these bones are damaged or fragmentary, and their identification was made possible with comparison to the nearly complete cranial materials from Haplocheirus sollers and the partial cranial material of Xiyunykus pengi33,43. However, we remain tentative about these identifications.
The frontal is represented by a partial left frontal (Fig. 1B) and a piece of bone tentatively identified as the posterior portion of the right frontal. The dorsal surface of the frontal is smooth and slightly convex. As in early-branching alvarezsaurians such as Haplocheirus sollers and Xiyunykus pengi33, the supratemporal fossa occupies a large portion of the frontal and has an anteriorly convex border, but unlike the former the anterior border is indistinct, a feature more similar to the condition in late-branching alvarezsaurians such as Shuvuuia deserti8. In ventral view, a strongly curved crest (the crista crania) is present, terminating close to the orbital rim. There is a depression along the posterior margin of the postorbital process of the tentatively identified right frontal, which represents the articular surface for the frontal process of the postorbital.
A piece of bone tentatively identified as the partial right parietal is represented only by partial lateral portion (Fig. 1C). In dorsal view, the posteromedial margin of the preserved parietal is slightly raised, representing the posteromedial border of the supratemporal fossa. Although both the right frontal and right parietal display some morphological features consistent with the frontal and parietal identifications, only the suspected crista crania represents an indication of the endocranial cavity, and thus they are only tentatively identified as frontal and parietal, awaiting confirmation by better preserved material.
A posteroventral portion of the right angular is preserved (Fig. 1D). The preserved portion suggests that the angular contributed to a proportionally larger portion of the posterior half of the mandible than in Haplocheirus sollers33. The lateral surface is slightly convex, similar to that of Haplocheirus sollers33. The medial surface is medially concave, forming the ventral part of the internal mandibular fossa. There is a wide, oblique groove along the posterior half of the ventral surface of the preserved angular, which forms the articular facet for the articular.
One isolated element is tentatively identified as a nearly complete right articular (Fig. 1E), which displays several unusual features. It has a sub-rectangular outline in dorsal view. The articular surface for the surangular is partially broken, but a large and deep transverse groove is present, which has not been previously reported in other alvarezsaurians. Also unusual are two features unknown in other alvarezsaurians: the anteromedial corner of the element, which represents the contact surface for the prearticular, displays a distinctive medial extension that is relatively larger than Haplocheirus33 and differs from the strap-like extension in Shuvuuia19; the glenoid portion is slightly convex rather than concave. However, some other features are similar to those in early-branching alvarezsaurians such as Haplocheirus and Xiyunykus33,43: there is a small notch on the lateral margin of the element in dorsal view and the retroarticular process is short and transversely broad.
Three dorsal vertebrae are preserved, and they are identified as an anterior one, a middle one, and a posterior one (the latter is likely the posteriormost one). All three dorsal centra are well preserved, but their neural arches are mostly broken. All preserved dorsals have elongate centra (much longer anteroposteriorly than dorsoventrally) and lack a pneumatic fossa on their central lateral surface as in most other alvarezsaurians except Linhenykus monodactylus11,19. Micro CT scans reveal that some internal pneumatic chambers are present bilaterally on a dorsal portion of the preserved posterior centrum (Fig. 2B), like those of Archaeornithomimus44, but without any fossa or foramina on the surface of the centrum. The middle of the centrum is occupied by trabecular bone, and pneumatic chambers are located ventrally (Fig. 2B), which are not present in those of Archaeornithomimus44.
The anterior dorsal has a transversely narrow centrum (Fig. 1F), and its posterior articular surface is slightly wider transversely than dorsoventrally. Both the anterior and posterior surfaces of the anterior dorsal centrum are concave, but with the latter distinctly larger than the former in posterior view. There is a distinct tubercle projecting laterally and posteriorly at the base of the posterior end of the neural arch, a feature appearing also in Xiyunykus pengi and Bannykus wulatensis but to a much lesser degree43. A posteroventrally extending ridge is identified as the posterior centrodiapophyseal lamina, but pneumatic fossae surrounding it are poorly developed, as in Bannykus wulatensis43. The centrum of the middle dorsal has slightly concave anterior and posterior articular surfaces, which are transversely wider than dorsoventrally deep. The central lateral surface is slightly depressed close to the neurocentral suture, though a pneumatic fossa is absent. The posterior dorsal is similar to the middle one in general outline except that the centrum is proportionally wider transversely (Fig. 1G). Both anterior and posterior articular surfaces of the posterior dorsal centrum are flat or even slightly convex, somewhat similar to the biconvex condition in the Cretaceous alvarezsaurians such as Bannykus wulatensis, Xiyunykus pengi, Mononykus olecranus and Shuvuuia deserti19,43,45.
Four sacral vertebrae are preserved. The anteriormost two sacral vertebrae are fused to each other (Fig. 1H), and both are represented by a complete centrum and a small portion of the neural arch; two separated posterior sacral vertebrae (probably the posteriormost two) are both represented by only the centra. Pleurocoels are absent in all four sacrals as in other alvarezsaurians. However, CT scans reveal bilaterally located pneumatic chambers in the middle part of centrum (Fig. 2C). The first sacral centrum is only slightly compressed dorsoventrally, with its anterior articular surface slightly wider transversely than dorsoventrally, but the remaining sacral centra are highly compressed dorsoventrally (e.g., the anterior articular surface of the third sacral centrum is about twice as wide transversely as dorsoventrally deep). The first sacral centrum bears a slightly concave anterior articular surface, somewhat similar to the condition in Cretaceous alvarezsaurians17,22,33. The ventral surfaces of the first and last sacral centrum are broadly convex, but those of the middle two sacral centra bear a shallow sulcus, a feature common in theropods, but unlike the keeled ventral surfaces in many Cretaceous alvarezsaurians including Xiyunykus pengi43, Shuvuuia deserti19, and Mononykus olecranus17.
Three separate caudal vertebrae are preserved, and they are identified as an anterior one, an anteromedian one, and a middle one. All preserved caudal centra are amphicoelous, lack pneumatic fossae, and bear no longitudinal ventral sulcus.
The anterior caudal is nearly complete (Fig. 1I), and its centrum and neural arch are firmly sutured together, but with the suture visible. The centrum of the anterior caudal is longer anteroposteriorly than dorsoventrally in lateral view and has a rounded ventral surface. The prezygapophyses extend anterodorsally considerably beyond the anterior central articular surface, with the articular surfaces dorsomedially oriented. A deep infra-spinal fossa is present at the base of the anterior margin of the neural spine between the prezygapophyses. The postzygapophyses extend posteriorly slightly beyond the level of the posterior central articular surface. The transverse processes have a centrally positioned, anteroposteriorly broad base and are much longer mediolaterally than anteroposteriorly wide. There are pneumatic chambers located close to the base of transverse processes (Fig. 2D), like those of Archaeornithomimus44. They extend posterolaterally, with the distal end about the level of the posterior central articular surface. There is a tall caudal neural spine located immediately above the postzygapophyses. The blade-like neural spine is anteroposteriorly narrow in lateral view and posterodorsally oriented. This spine is different from those of Haplocheirus sollers, in which the neural spines have a wide base and are oriented nearly dorsally33.
The preserved antero-middle caudal is represented by an incomplete centrum. It is shallower in lateral view and slightly more compressed transversely than the anterior caudal centrum. The middle caudal is nearly complete, missing postzygapophyses and parts of neural spine and transverse processes. The middle caudal (Fig. 1J) is much longer than the anterior caudal (about 1.5 times as long as the latter), a feature also known in some South American alvarezsaurians such as Alvarezsaurus1. The centrum is about 2.5 times as long anteroposteriorly as dorsoventrally deep in lateral view, and transverse width and dorsoventral depth of the anterior and posterior articular surfaces are about the same. Also similar to some South American alvarezsaurians, the neural arch is positioned anteriorly, the prezygapophyses are short (projecting slightly beyond the anterior central articular end), and the transverse processes are positioned posteriorly. CT scans reveals two bilateral pneumatic chambers, slightly ventral to the spinal foramen (Fig. 2E), which are nonexistent in Archaeornithomimus44. The neural spine is a low ridge, and its posterior portion is inferred to be more prominent than the anterior portion.
A middle chevron is mostly preserved, missing both anterior and posterior extremities. It is inferred to be shaped somewhat like an inverted T lateral view. It is strongly expanded anteroposteriorly distally to form an anterior and a posterior process, with the anterior one transversely thinner and probably anteroposteriorly shorter than the latter.
The right scapula is preserved (Fig. 1K), missing much of the acromial process and the distal portion. The scapula is in general similar to that of Haplocheirus sollers33: the acromial process is large and expands anteriorly and medially from the scapula blade, a large fossa is present on the scapular lateral surface close to the proximal end, the glenoid process is short and projects posteriorly nearly perpendicular to the scapular blade, a small lip is present dorsal to the glenoid fossa, the proximal portion of the anterior margin of scapular blade is sharp and the proximal half of the posterior margin of the scapular blade is robust, and the scapular blade is strongly curved medially and is distally expanded. However, there are some differences in scapular morphology between the two taxa. Compared to Haplocheirus sollers33, the acromial process is longer proximodistally and much thicker transversely, the fossa is relatively shallower, the articular surface for the coracoid is proportionally much wider transversely, and the proximal half of the posterior margin of the scapular blade is proportionally thicker transversely. Most unusually, the acromial process is hollow inside.
The left humerus is preserved (Fig. 1L), missing part of the deltopectoral crest and the distal portion. The humeral head is relatively small, and it expands proximally and posteriorly, but not anteriorly. The internal tuberosity is large and proximodistally long. Unlike some late-branching alvarezsaurians such as Mononykus olecranus and Shuvuuia deserti19, it is relatively thin anteroposteriorly rather than strongly expanded, is lower than the humeral head, and the separation from the latter is minimal. Haplocheirus sollers possesses a deep notch between the internal tuberosity and the humeral head as in some late-branching alvarezsaurians33 and late-branching therizinosaurs46, but this might be a preservational artefact. A shallow notch is present on the medial margin of the internal tuberosity in anterior or posterior view, a feature appearing to be also present in Xiyunykus pengi. In medial view, the internal tuberosity is pinched distally, while in other alvarezsaurians it is consistent in width along the length. There is an obliquely extended elongate tubercle on the posterior surface of the internal tuberosity, which is also seen in Bannykus wulatensis43. The deltopectoral crest is mostly broken, but it is inferred to be large and extends anterolaterally rather than anteriorly as in late-branching alvarezsaurians. A shallow groove runs distally immediately distal to the deltopectoral crest, a feature also seen in Xiyunykus pengi and some other maniraptorans, but it is longer and located more distally than in other taxa43. The diaphysis displays a sub-triangular cross section where it is broken about 15 mm distal to the deltopectoral crest. An isolated bone fragment is probably a portion of the humeral shaft, and the rounded cross section shows the bone is extremely thin-walled (about 1.5 mm in thickness compared to a 10-mm-diameter for the cross section of the bone).
The ulna (Fig. 1M) is represented only by the partial proximal end of the right ulna. The olecranon process is mostly missing, but it is inferred to be large. As in most theropods, the olecranon process is in line with the coronoid process and is sub-triangular in cross section, unlike the anteroposteriorly compressed and medially extended one in Cretaceous alvarezsaurians. The coronoid process is relatively small, and there is a large articular facet for the humerus on the coronoid process, which extends proximally onto the olecranon process. The lateral flange is small but robust, and bears a flat articular facet for the humerus. There is a longitudinal ridge along the lateral surface extending distally.
The radius (Fig. 1N) is represented only by a partial proximal portion of the right radius. The radius is much thinner than the ulna. The proximal end has an elongate oval shape in proximal view and bears a deep fossa representing the articular facet for the humerus.
The right manus is mostly preserved (Fig. 1O), missing all carpals, metacarpal IV, and phalanx IV-3. Over all the hand has a robust digit II and two slender lateral digits. Digit III is markedly longer than digits II and IV, and it is much slenderer than digit II.
Metacarpal II is short and stout, but proportionally more slender than that of Haplocheirus sollers (proximodistal length/transverse width ratio 1.64, compared to 1.26 in Haplocheirus sollers33). As in other alvarezsaurians, the proximal articular surface is sub-L-shaped due to the lack of a ventral extension of the proximolateral corner, rather than sub-triradiate due to a prominent ventral extension as in most other tetanuran theropods, and the lateral portion of the proximal articular surface is slightly inclined distally. As in most tetanuran theropods, a proximomedial process is present, and it is proportionally smaller than in Haplocheirus sollers33. The proximomedial process is defined medially by a depression on the ventral surface. The dorsal surface of metacarpal II is shallowly concave and the ventral surface is broad and flat. There is a distinct dorsal projection at the proximolateral corner of the bone, the lateral surface of which contributes to part of the articular facet for metacarpal III. The articular facet for metacarpal III is slightly concave and occupies more than the proximal half of the lateral surface of metacarpal II. The distal end is strongly ginglymoid, with two hemicondyles separated by a deep groove. The hemicondyles are asymmetrical, with the lateral condyle extending distally far more than the medial one. The collateral ligament pits are nearly absent, though the medial surface of the distal end is slightly concave.
Metacarpal III is much thinner than metacarpal II. It is straight in dorsal view, unlike the laterally bowed one in most other alvarezsaurians including Haplocheirus sollers and Aorun zhaoi33,37. Similar to Cretaceous alvarezsaurians but unlike Haplocheirus sollers and Aorun zhaoi33,37, metacarpal III is flattened dorsoventrally, with a transverse width greater than its dorsoventral depth. The dorsal surface is flat and lacks a longitudinal thick ridge along the medial edge of the proximal portion of the shaft as in some alvarezsaurians such as Haplocheirus sollers and Bannykus wulatensis33,43. As in Bannykus wulatensis43, there is a lateral flange overhanging the lateral surface of the proximal one-fourth of the shaft, together with the lateral surface forming the articular facet for metacarpal IV, while Haplocheirus sollers lacks such a lateral flange33. The ventral surface of the proximal portion is slightly concave and that of the remaining shaft is slightly convex. There is a slightly curved, longitudinal ridge along the lateral edge of the ventral surface, emanating from the proximal end, and terminating at the level of the proximal two-thirds of the shaft. There is a shallow extensor pit on the dorsal surface near the distal end, while it is absent in Aorun zhaoi and Haplocheirus sollers37. The distal end of metacarpal III is ginglymoid with a well-developed trochlea extending onto the dorsal surface of the phalanx, and the lateral hemicondyle is larger than the medial one.
As in other alvarezsaurians, phalanx II-1 is the most robust element, with a shaft diameter much greater than any other phalanx. Phalanx II-1 is longer than metacarpal III and phalanx III-2, while the opposite is true in Haplocheirus sollers33. It is straight in medial or lateral views, unlike the ventrally curved one in many other alvarezsaurians including Haplocheirus sollers and Aorun zhaoi33,37. The ventral surface of the middle portion is slightly concave, but a fully developed ventral furrow as in many other alvarezsaurians including Haplocheirus sollers is absent33. However, a flexor pit is present immediately proximal to the distal end. The dorsal surface of phalanx II-1 is transversely convex, the medial surface is slightly inclined laterally, and the lateral surface is vertical, while in Haplocheirus sollers and Aorun zhaoi33, the shaft has a sub-triangular cross section, with both the medial and lateral surfaces inclined toward the central. The distal end is ginglymoid with more dorsally displaced collateral ligament than in Haplocheirus sollers but similar to the condition in Aorun zhaoi33. In medial or lateral views, the hemicondyles are more elongated proximodistally than in Haplocheirus sollers.
Phalanx III-1 is a dorsoventrally flattened element, with a relatively greater transverse width, while the opposite is true for Haplocheirus sollers and Aorun zhaoi33,37. It has an asymmetrical proximal articular surface with a mediolaterally narrow medial cotyle and a wide lateral cotyle. The proximal end is expanded both transversely and ventrally, and bears a proximoventral heel which is particularly prominent along the medial side. The ventral surface is flat and distally displays a well-developed flexor fossa. The distal end is strongly ginglymoid and the collateral ligament pits are located centrally.
Phalanx III-2 is subequal in length to metacarpal III, similar to the condition in Aorun zhaoi but unlike in Haplocheirus sollers where phalanx III-2 is distinctly shorter than metacarpal III33. The proximal articular surface is mediolaterally narrow and sub-triangular in outline. The proximal half of the shaft is highly compressed transversely as in Aorun zhaoi37, though in the latter, the whole shaft is strongly compressed. The distal end is strongly ginglymoid with a relatively wider trochlea between the hemicondyles, compared to the compressed distal end and narrow trochlea of Aorun zhaoi. Deep collateral ligament pits are dorsally displaced.
Phalanges IV-1 and IV-2 are similar in size. Both are mediolaterally narrow, unlike the relatively robust ones in Haplocheirus sollers33. Phalanx IV-1 is relatively slender, with a ratio of proximodistal length/mid-shaft width 4.1, compared to 3.2 in Haplocheirus sollers. The distal end is strongly ginglymoid with shallow ligament pits, while in Haplocheirus sollers they are absent33. Phalanx III-2 has a large proximoventral heel, which is more prominent along the medial side. The distal end bears shallow ligament pits.
Ungual II is relatively small, estimated to be shorter in length than phalanx II-1 as in Aorun zhaoi37, whereas in Haplocheirus sollers33 it is considerably longer than phalanx II-2. It is curved ventrally, to a degree intermediate between Haplocheirus sollers and Aorun zhaoi33,37. The proximal articular surface is about twice as tall dorsoventrally as wide mediolaterally, and is a dorsoventrally tall ellipse in outline, unlike in Cretaceous alvarezsaurians where the proximal surface is proportionally lower dorsoventrally and has sub-rectangular outline17,19. The flexor tubercle is slightly distally located, and is relatively small and somewhat compressed transversely, unlike the transversely expanded one in Haplocheirus sollers. The ungual is laterally compressed, with a sub-oval cross section.
Ungual III is subequal in size to ungual II, proportionally much larger than that of other alvarezsaurians including like Haplocheirus sollers and Aorun zhaoi33,37. It curves ventrally much more than that of Haplocheirus sollers and Aorun zhaoi33,37. The flexor tubercle is only slightly distally displaced. The cross section of ungual III is sub-triangular, with a transversely flat ventral surface which inclines medially. The medial collateral groove is positioned higher than the lateral one.
Ungual IV is significantly smaller than the other two unguals, with the proximal end about half the height of that of ungual III. It is relatively robust, with a length/depth ratio of about 2.0 compared to 3.3 in Haplocheirus sollers33,37. It curves ventrally much more so than in Haplocheirus sollers and Aorun zhaoi. The flexor tubercle is only slightly displaced distally, small in size, and transversely narrow, unlike the distally located and transversely expanded one in Haplocheirus sollers33.
The ilium is represented only by the acetabular region of the left ilium (Fig. 1P). The pubic peduncle is mostly broken, but it is inferred to be level with the iliac blade rather than medially projected. The supraacetabular crest expands laterally near the center of the acetabulum but more anteriorly it inclines ventrally to form a hood, unlike the supraacetabular crest of Bannykus wulatensis which projects laterally along nearly whole length of the acetabulum43. These features are closer in condition to Late Cretaceous parvicursorine alvarezsaurians such as Xixianykus10. The ischial peduncle is relatively small and well developed along the transverse axis showing an oblate articular facet for the ischium. This transverse widening may represent the initial development of the highly modified ischial peduncle of Late Cretaceous alvarezsaurians17. In medial view, the acetabular opening is subtriangular in outline, as in other alvarezsaurians (e.g., Mononykus olecranus, Patagonykus puertai)4,17. There are several unusual features in the ilium: the medial surface of the ischial peduncle is flat, and with a step-wise transition to that of the pubic peduncle which is strongly convex; a deep and round fossa is positioned anterodorsal to the ischial peduncle on the medial surface of iliac blade. These features might be autapomorphies of Shishugounykus inexpectus if they are not preservational artefacts.
Only a small piece of the left pubis is preserved (Fig. 1Q). The shaft is considerably narrower than the ischial shaft in lateral view, with a longitudinal oblique groove running along the lateral surface of the preserved shaft. The pubic apron has a slightly convex anterior surface and a flat posterior surface, and it emanates from the anterior surface of the pubic shaft.
A proximal portion of the left ischium is preserved (Fig. 1R). The pubic peduncle is large and at an angle of about 110 degrees to the pubic shaft. The proximal articular facet for the pubis is sub-semi-circular in outline, which is transversely much narrower anteriorly than posteriorly. The iliac peduncle is slightly slenderer than the pubic peduncle in lateral view but is transversely wider than the latter. The articular facet for the ilium is sub-rectangular. There is a lateral tubercle at the anterolateral corner of the iliac peduncle. An obturator process is absent in the preserved portion of the ischium, suggesting that it is either absent as in Late Cretaceous alvarezsaurians or more distally positioned than in Haplocheirus. The ischial shaft is rod-like but much wider anteroposteriorly than transversely. The lateral surface of the ischial shaft is flat, and the medial surface is convex. There is a longitudinal groove along the posterior surface of the ischium, a feature also reported in Xixianykus zhangi10.
The femur is represented by the nearly complete right femur (Fig. S1) and most of the left one, which is missing the proximal end. The femoral head is oriented medially and is slightly lower than the greater trochanter, without a constricted neck from the latter. Its articular surface is extensive, with a relatively large distal component, which is different from Late Cretaceous alvarezsaurians such as Xixianykus10. There is an oblique ligament groove on the posterior surface of the femoral head, but its lateral border is indistinct. The greater trochanter is narrower anteroposteriorly than the femoral head and is oriented anteromedially rather than anteroposteriorly. An anteroposteriorly narrow trochanteric shelf is present on the femoral lateral surface immediately below the greater trochanter. The lesser trochanter, which is separated from the great trochanter by a deep notch, is proximally broken, but it is inferred to be wing-like structure and to lower than the greater trochanter, as in early-branching alvarezsaurians including Bannykus wulatensis43. The bump-like posterolateral trochanter is present distal to the trochanter shelf on the femoral lateral surface, separated from the lesser trochanter by a shallow groove. The fourth trochanter is present as a thick ridge, emanating about 35 mm distal to the proximal end of the femur and running distally for 25 mm along the posteromedial margin. There is a shallow groove immediately lateral to the fourth trochanter on the femoral posterior surface. The femoral shaft is slender and slightly bowed anteroposteriorly. Distally, the anterior surface is smooth, without an anterior longitudinal groove like in Patagonykus puertai4. The posterior surface is transversely concave, bears a shallow, triangular depression (popliteal fossa) bounded by the lateral and medial ridges emanating from the lateral and medial distal condyles, respectively. The popliteal fossa opens distally as in Patagonykus puertai and Alvarezsaurus calvoi1,4 but differs from the distally closed ones in Mononykus olecranus and Shuvuuia deserti8,17,22. The medial condyle is rectangular in distal view and is anteroposteriorly convex. The ectocondylar tuber is sub-hemispherical, with the media surface convex and lateral surface flat. The lateral surface of the ectocondylar tuber also appears to be flat in some late-branching alvarezsaurians such as Mononykus olecranus and Xixianykus zhangi10,17. The tuber is proximodistally elongate and transversely narrow, and is distally separated from the lateral condyle by a shallow notch. The lateral condyle is cone-shaped and extends further distally than the medial condyle as in all known alvarezsaurians19.
A nearly complete left tibia (Fig. 1T) and the proximal and distal portions of right tibia are preserved. The proximal articular surface of the tibia is almost flat and slightly inclined laterally, and it has a semicircular anteromedial margin, like that of Patagonykus puertai4. In proximal view, the cnemial crest is prominent like that of Patagonykus puertai4, and differs from the robust and proximodistally short cnemial crest of Late Cretaceous alvarezsaurians such as Mononykus olecranus17. Like Patagonykus puertai4, it projects proximally only to the level of the proximal part of the fibular (lateral) and posterior condyle, rather than beyond them as in some theropods47,48,49. In anterior view, the cnemial crest is cylindrical, and it gradually narrows as a ridge on the anterior surface of the tibial shaft distally. A short, thick ridge is present on the lateral surface of the cnemial crest, which is absent or weak in early-branching alvarezsaurians including Xiyunykus pengi and Patagonykus puertai4,43. There is no accessory medial crest as in Mononykus olecranus17. The cnemial crest is separated from the fibular (lateral) condyle by a smooth and wide notch. Overall, the fibular condyle resembles those of early-branching alvarezsaurians including Xiyunykus pengi and Patagonykus puertai4,43, which is composed of a comparatively small anterior prominence and a bulky posterior prominence. These two prominences are separated by a shallow depression. Comparatively, the anterior prominence of Shishugounykus is intumescent and orbicular rather than weak and pyramidal like the anterior prominence in Xiyunykus pengi and Patagonykus puertai4,43. The fibular and posterior condyles are separated by a narrow notch, which is shallow and wide compared to Xiyunykus pengi and Patagonykus puertai4,43. The posterior condyle is triangular in proximal view, and its surface inclines anterodistally, but is not as oblique as that of Xiyunykus pengi43. The fibular crest is relatively prominent and is located about 10 mm distally from the fibular condyle, as in Xiyunykus pengi and Patagonykus puertai4,43, but unlike the fibular crest connecting to the proximal end in Haplocheirus sollers33. The shaft is straight and circular in cross section. The distal end is mediolaterally much broader than anteroposteriorly narrow, with the medial margin much thicker than the lateral margin in distal view. There is a distally tapered, relatively long groove on the anterior surface of the distal portion of the tibia, representing the contact surface for the ascending process of the astragalus. The groove is deeper and mediolaterally broader than that in Aorun zhaoi. Further, this groove is slightly oblique from mediodistal to lateroproximal, which is different from the almost proximodistally oriented grooves in Aorun zhaoi and Tugulusaurus faciles37,50.
The fibulae are represented by the proximal end of both right and left bones (Fig. 1U). The proximal end is crescentic in outline in proximal view and it is nearly symmetrical in lateral view, unlike the asymmetrical condition in Haplocheirus sollers and Patagonykus puertai4,33, but close to the condition in Xiyunykus pengi43. There is a shallow fossa on the medial surface immediately distal to the proximal end, from which is a shallow groove extends distally along the shaft.
A lamelliform distal tarsal is preserved, implying no fusion between it and the proximal metatarsals. Only the distal portion of left metatarsal II and III are preserved (Fig. 1V). The distal end of metatarsal III is symmetrical while the slightly ginglymoid one of metatarsal II is asymmetrical, with the lateral hemicondyle much larger than the medial one. Both metatarsals bear distinct collateral ligament pits on both lateral and medial surfaces of the distal end.
The left pedal phalanges III-1 and 2, IV-1, 2, and 4 are well preserved (Fig. 1V). Phalanx III-1 is the longest of all the preserved phalanges, with a slender and circular-cross-sectioned shaft. The proximal articular surface is concave, and the distal end is slightly ginglymoid. A well-developed extensor ligament pit immediately proximal to the distal condyle is nearly as wide as the shaft. Phalanx III-2 is similar in general morphology to III-1, but is shorter (about 80% of the latter in length) and has a deeper ginglymus distally. Phalanges IV-1 and 2 are stouter than those of digits III, and their extensor ligament pits are shallower than those of digit III. Phalanx IV-4 is short and its distal end is asymmetric where the lateral condyle is more developed than the medial one.
Histological description and comparisons
The cortex of the sampled femoral section is about 1.6 mm thick, compared to a femoral diameter of 16.1 mm at the sampled region (Fig. 3A). The cortex is mostly composed of fibrolamellar tissues like most of published sections of alvarezsaurians, but differs from the woven-tissue dominated condition in Aorun zhaoi37. There is a lamina of parallel-fibered tissue at the outermost of the section, possibly representing an EFS structure. Most of the osteocyte lacunae are oval in fibrolamellar bone, and are mostly flattened in parallel-fibered tissue. The longitudinal primary osteons occupy most of the cross section without distinct secondary reconstruction. A very thin but continuous layer of endosteal lamellae (i.e., the parallel-fibered tissue) lines the marrow cavity, suggesting a termination of dilatation of the cavity. Five LAGs are preserved in the cortex, and the widest interval is the one between the endosteal surface and the first LAG. Moving outward, the intervals between LAGs are all smaller than the first interval, but they are subequal except the outmost interval. The marrow cavity is big, and 4 LAGs are inferred to be eroded by the expansion of the medullary cavity based on the size of the marrow cavity and the interval between preserved LAGs. Noteworthy is that the parallel-fibered tissue is present only at the endosteal and periosteal surfaces of the section, unlike some small theropods in which the parallel-fibered tissues are present alternating with the fibrolamellar tissues throughout the cortical section51,52,53.
The tibial section shares similar histological features with the femur section (Fig. 3B), but has a thicker cortex (2.6 mm), smaller marrow cavity, thicker endosteal lamellae (Fig. 3B-ii), and thicker outermost avascular parallel-fibered layer (Fig. 3B-ii). Most of the lacunae are oval and flattened lacunae are rare. The tibial section also preserves 5 LAGs with 4 missing as a result of erosion of the marrow cavity.
The fibular section has a 0.8 mm thick cortex and a well-developed marrow cavity (Fig. 3C), which differs from undeveloped marrow cavities in most fibular sections of other coelurosaurians54. Most of the fibular cortex comprises fibrolamellar bone with well-developed longitudinal secondary osteons. Secondary remodeling occurred at least twice, as indicated by newly formed secondary osteons overlapping on the previously formed secondary osteons. The distribution of secondary osteons is uneven, laterally rare and anteriorly dense. The outermost cortex displays a fully developed EFS structure, with at least 5 tightly bunched LAGs and non-vascularized parallel-fibered tissue. The EFS in the outermost section and the endosteal lamellae located in the innermost part of the fibular section form a bistratal structure, representing convincing evidence for the termination of growth of the fibula.
Three Shishugou theropods, i.e., Shishugounykus inexpectus, Haplocheirus sollers and Aorun zhaoi, were placed at the base of the Alvarezsauria by our numerical phylogenetic analysis, with Haplocheirus sollers more crownward than the other two species, the phylogenetic relationships of which are unresolved relative to each other. The alvarezsaurian affinities of these three species are supported by the following synapomorphies: internal tuberosity of humerus offset from humeral head by distinct notch (char. 386.1; note that this feature is also a synapomorphy of therizinosaurians diverging after Neimongosaurus/Erliansaurus); lack of collateral ligament fossae on the distal condyles of metacarpal II (char. 418.1); ungual II distinctly larger than other unguals (char. 440.1); the proximal end of the lateral grooves of manual ungual II-2 partially enclosed by lateral notches (char. 446.1); the distal projection of lateral femoral distal condyle is distinctly further than medial condyle (char. 532.1); a low and rounded fibular crest (char. 543.1); and the bracing for the ascending process of the astragalus on the tibia is step-like and running proximodistally (char. 546.2).
Alvarezsaurians are among the few theropod subgroups that have only relatively small representatives (all known alvarezsaurians have a body mass less than 50 kg, smaller than most other theropod subgroups) and some late-branching alvarezsaurians are among the smallest non-avialan dinosaurs (e.g., Xixianykus zhangi has an adult-body-size of 0.5 kg)10,51,55,56,57. Compared to late-branching alvarezsaurians, early branching alvarezsaurians have relatively large body sizes. Based on an empirical equation for theropod body size58, the holotypes of the Shishugou alvarezsaurians Shishugounykus inexpectus, Aorun zhaoi, and Haplocheirus sollers are estimated to be about 7 kg, 4 kg, and 19 kg in body-mass, respectively; the holotypes of the Early Cretaceous alvarezsaurians Xiyunykus pengi and Bannykus wulatensis are about 15 and 24 kg, respectively; and the Late Cretaceous alvarezsaurians range in body mass from 0.25 to 50 kg, but most are lighter than 2 kg in weight. Even considering the ontogenetic variability in body-size estimation (e.g., the holotype of Aorun zhaoi is an early juvenile individual), the data indicates that early-branching alvarezsaurians remained at relatively large body sizes for about 50 million years in their early evolution and significant miniaturization occurred only in the Late Cretaceous. Alvarezsaurian size evolution therefore seems to be more complex than originally thought, and further studies are required, for example, determining whether the very large Kol ghuva indeed represents a member of the lineage. Comparing the body-size data and ontogenetic-stage data of the known early alvarezsaurian specimens, we infer that Shishugounykus inexpectus is probably the smallest early-branching alvarezsaurian, and is about one-third of the body-mass of the near-contemporary Haplocheirus sollers. This suggests that size variation in early alvarezsaurians that is greater than size variation in Late Cretaceous taxa, although sample sizes are low. Several previous studies have suggested insectivorous diets for alvarezsaurians (although Haplocheirus has been suggested to have been omnivorous59). The coexistence of two different-sized anteaters in South America, Myrmecophaga tridactyl and Tamandua tetradactyla60 suggests that even if the Shishugou alvarezsaurians were insectivores they could have coexisted within an ecosystem.
Body size variation among close relatives is also found in other theropods, such as tyrannosaurid theropods. The biggest tyrannosaurid Tyrannosaurs rex shares similar lifespan and an exponential growth period with its close but smaller relatives such as Daspletosaurus torosus, but the it has a much higher maximum growth rate and thus has a much larger body size54,61. The slow growth rate of Shishugounykus inexpectus holotype is supported histologically by the dominance of longitudinal canals and a relatively lower porosity. Therefore, we infer that the maximum body size of Shishugounykus inexpectus was constrained by its very slow growth rate. Further histological investigation is needed to test this observation, for example by comparison with histological condition of the large Shishugou alvarezsaurian Haplocheirus sollers.
Parvicursorine alvarezsaurians such as Mononykus and Linhenykus have the most specialized forelimb, and particularly the most specialized hand, among the non-avialan theropods, and these specializations have been suggested to be adaptations to fossorial activities10,11,62. The evolution of a typical tetanuran hand to the highly specialized hand of parvicursorines mainly involves three major modifications: broadening and flattening of the palm, enlargement and modification of the thumb, and reduction of two lateral digits. Numerous features related to these three major modifications had already evolved in some or all three Shishugou alvarezsaurians (Fig. 4): metacarpals II and III are proportionally broader transversely and thinner dorsoventrally than typical coelurosaurian metacarpals II and III, metacarpal III is laterally bowed and distally highly asymmetrical with a much larger lateral hemicondyle, metacarpal IV is proportionally shorter and thinner than typical for coelurosaurian metacarpal IV and lacks the ginglymus on its distal end, manual phalanges II-1 and -2 are enlarged and specialized in a number of features (depressing of medial and lateral surfaces and ventral axial furrowing of phalanx II-1), and manual digits III and IV displays initial shortening and narrowing.
However, these features are not equally developed in the three Shishugou alvarezsaurians (Fig. 4). Haplocheirus sollers has the most specialized hand, which is more similar to that of Cretaceous alvarezsaurians than that of Shishugounykus inexpectus and Aorun zhaoi. Metacarpal II is proportionally wider transversely and thinner dorsoventrally in Haplocheirus sollers than in Shishugounykus inexpectus and Aorun zhaoi; manual phalanx II-1 is proportionally wider transversely in Haplocheirus sollers than in Shishugounykus inexpectus and Aorun zhaoi, is distally curved ventrally in lateral view (straight in Shishugounykus inexpectus and slightly curved in Aorun zhaoi), and has a shaft with depressed medial and lateral surfaces (slightly convex in Shishugounykus inexpectus and slightly depressed in Aorun zhaoi) and with furrowed ventral surface (only slightly furrowed in Shishugounykus inexpectus and Aorun zhaoi); metacarpal III is laterally bowed in dorsal view (straight in Shishugounykus inexpectus and laterally bowed in Aorun zhaoi); manual phalanx III-2 is shorter than metacarpal III (subequal in Shishugounykus inexpectus and Aorun zhaoi); metacarpal IV is about 45% the length of metacarpal III (slightly shorter than metacarpal III in Aorun zhaoi); unguals III and IV are relatively straight in lateral view (more recurved in Shishugounykus inexpectus and relatively straight in Aorun zhaoi) and have more distally located flexor tubercles.
Interestingly, there are a few manual features in which Shishugounykus inexpectus and/or Aorun zhaoi display a condition closer to that in Cretaceous alvarezsaurians than Haplocheirus sollers does (Fig. 4). A pair of flexor processes are present at the proximal end of metacarpal II in Aorun zhaoi, but are absent in Shishugounykus inexpectus and Haplocheirus sollers; metacarpal III is dorsoventrally compressed in Shishugounykus inexpectus, but remains dorsoventrally deep in Aorun zhaoi and Haplocheirus sollers; metacarpal IV is much thinner than other metacarpals in Aorun zhaoi (it is proportionally thinner in Haplocheirus sollers, but not to the degree in Aorun zhaoi); the flexor tubercles of all unguals are strongly compressed transversely in Aorun zhaoi and slightly compressed in Shishugounykus inexpectus, but expanded in Haplocheirus sollers; ungual II is relatively straight in lateral view in Aorun zhaoi, but is strongly curved ventrally in Shishugounykus inexpectus and Haplocheirus sollers; ungual IV is about half the size of ungual III in Shishugounykus inexpectus, compared to two-thirds in Aorun zhaoi and Haplocheirus sollers. Finally, Shishugounykus inexpectus and Aorun zhaoi share several features related to the transverse narrowing of manual phalanges III and IV, though it is more developed in Aorun.
It is noteworthy that some of these features are also present in ornithomimosaurians (e.g., relatively straight unguals with distally located flexor tubercles and the presence of a pair of flexor processes at the proximal end of manual phalanx II-1), suggesting that these features are either synapomorphies of a more inclusive group comprising ornithomimosaurians, alvarezsaurians and some other theropod groups, or independently evolved in ornithomimosaurians and alvarezsaurians. Nevertheless, the variability of the anatomy in the manus of the closely related Shishugou alvarezsaurians is surprising. These features indicate that the acquisition of alvarezsaurian hand features, specifically the broadening and flattening of the palm, the enlargement and modification of the thumb, and reduction of two lateral digits, was a complex process, and there is a strong mosaic distribution of hand features in early alvarezsaurian evolution. However, the lack of multiple specimens of any of the three species means that some of these features may have been variable intraspecifically.
Our stratigraphic and radiometric data indicate that Aorun zhaoi, Shishugounykus inexpectus, and Haplocheirus sollers lived between 161.2 and 158.7 Ma, representing the only known Jurassic alvarezsaurians to date. The discoveries of three alvarezsaurian taxa living at roughly the same time (probably within at most 1.5 million years of each other) from the Wucaiwan Locality are unexpected, and these discoveries demonstrate an early diversification at the base of the Alvarezsauria near the Middle-Late Jurassic boundary. The earliest known alvarezsaurians not only process a taxonomical diversification and substantial body size variation (see above), but also have a large number of morphological variations.
In the phylogenetic framework set by our numerical phylogenetic analysis, 9 synapomorphies have been identified for the Alvarezsauria. Furthermore, there are at least 77 morphological differences between the three Shishugou alvarezsaurian, including 58 variations in the character-matrix and 19 additional variations (Tables S2 and S3), indicating the presence of a large number of morphological variations in the three Shishugou alvarezsaurians spanning only 1.5 million years. The new data thus suggests a large number of skeletal modifications in early alvarezsaurians, and it is particularly evident for the forelimbs, which represent the mostly specialized anatomical region of the body.
Descriptions and comparisons
The descriptions of the new taxon are accomplished with the observations on the holotype specimen IVPP 23567. Comparisons were based on direct observations of other specimens, published descriptions and images. It is worth mentioning that we homologize the three fingers of alvarezsaurians with digits II, III and IV of the early-branching Theropoda manus63.
Alvarezsauria: the most inclusive clade containing Alvarezsaurus calvoi but not Passer domesticus or Ornithomimus edmontonicus.
The phylogenetic analysis of IVPP V23567 was performed on a broadly sampled theropod data matrix from Xu et al.43. The dataset was assembled in Excel 2016 and analyzed on TNT v.1.564. The phylogenetic analysis followed the parsimony optimality criterion performed with the New Technology Search on TNT v.1.5 with search strategies including Sectorial Searches and Tree Drift64. Our phylogenetic analysis provided 202 most parsimonious trees (MPTs) with a tree length of 3202 steps, a CI (consistency index) of 0.218 and a RI (retention index) of 0.602. Based on the pool of 202 MPTs, the strict consensus topologies (see Supplementary text: Fig. S1) were calculated64. The Absolute Bremer support test65 for nodes was also calculated saving suboptimal trees up to 10 steps and storing up to 10,000 trees in memory (see Supplementary text: Fig. S1).
High-resolution CT scanning
Every element of IVPP V 23567 was scanned by a 225kv (for small skeletal elements) or a 450 kV (for large skeletal elements) micro-computerized-tomography apparatus at Key Laboratory of Vertebrate Evolution and Human Origins, CAS66. The initial CT scanning data was processed by a two-dimensional reconstruction software developed by the Institute of High Energy Physics, CAS66. And the three-dimensional segmentation and rebuilding of these data was performed on Mimics.
The ontogenetic stage of IVPP V23567 was assessed by histological analysis on ground sections from its femur, tibia and fibula. The manufacturing flow of these ground sections was performed in the histological lab at the Key Laboratory of Vertebrate Evolution and Human Origins, CAS, with standard palaeohistological techniques67. Specimens were embedded in resin, then cut by a circular saw (EXAKT400CP) fitted with a diamond-tipped wafering blade. By using the circular saw (EXAKT400CP) and a wheel grinder (EXAKT400CS), research materials were manufactured into thin slices with final thickness between 50 to 80 mm. Finally, each slice was capped with a glass cover slip and then labeled. After this manufacturing flow, ground sections were observed and photographed in normal and polarized light on a microscope (ZEISS Axio Imager 2) at the Key Laboratory of Vertebrate Evolution and Human Origins, CAS68.
This published work and its nomenclatural acts have been registered in ZooBank which is a proposed online registration system for the International Code of Zoological Nomenclature (IZCN). The LSID (Life science identifiers) for this publication is urn:lsid:zoobank.org:pub:B12FD816-4CEA-4681-A4B3-AE1E6639D969. The associated information can also be viewed through any standard web browser by appending the LSID to the prefix “http://zoobank.org/”.
The phylogenetic analysis was performed using TNT v.1.5 software (https://cladistics.org/tnt/); The 3D segmentation and rebuilding of the CT data was performed using Mimics (Version 10.01); The images (including the skeletal restoration and silhouettes) were produced using Adobe Illustrator CC, which is available at www.adobe.com/products/illustrator.html.
The holotype specimen IVPP V23567 is housed in the Collection House of IVPP, which is accessible to both professionals and the general public through applications. The data reported in this publication are detailed in the main text and its supplementary files.
Bonaparte, J. F. Los vertebrados fósiles de la Formación Río Colorado, de la ciudad de Neuquén y cercanías, Cretácico superior, Argentina. Rev. del Museo argent. de Ciencias Naturales” Bernardino Rivadavia” Paleontologia 4, 17–123 (1991).
Hutchinson, J. R. & Chiappe, L. M. The first known alvarezsaurid (Theropoda: Aves) from North America. Journal of Vertebrate Paleontology 18, 447–450 (1998).
Longrich, N. R. & Currie, P. J. Albertonykus borealis, a new alvarezsaur (Dinosauria: Theropoda) from the Early Maastrichtian of Alberta, Canada: implications for the systematics and ecology of the Alvarezsauridae. Cretaceous Research 30, 239–252 (2009).
Novas, F. E. Anatomy of Patagonykus puertai (Theropoda, Avialae, Alvarezsauridae), from the Late Cretaceous of Patagonia. Journal of Vertebrate Paleontology 17, 137–166, https://doi.org/10.1080/02724634.1997.10010959 (1997).
Martinelli, A. G. & Vera, E. Achillesaurus manazzonei, a new alvarezsaurid theropod (Dinosauria) from the Late Cretaceous Bajo de la Carpa Formation, Río Negro Province, Argentina. Zootaxa 1582, 1–17 (2007).
Perle, A., Norell, M. A., Chiappe, L. & Clark, J. M. Flightless bird from the Cretaceous of Mongolia. Nature 362, 623–626 (1993).
Karhu, A. & Rautian, A. A new family of Maniraptora (Dinosauria: Saurischia) from the Late Cretaceous of Mongolia. Paleontological journal c/c of paleontologicheskii zhurnal 30, 583–592 (1996).
Chiappe, L. M., Norell, M. A. & Clark, J. M. The skull of a relative of the stem-group bird Mononykus. Nature 392, 275–278 (1998).
Alifanov, V. R. & Barsbold, R. Ceratonykus oculatus gen. et sp. nov., a new dinosaur (?Theropoda, Alvarezsauria) from the Late Cretaceous of Mongolia. Paleontological Journal 43, 94–106, https://doi.org/10.1134/S0031030109010109 (2009).
Xu, X. et al. A basal parvicursorine (Theropoda: Alvarezsauridae) from the Upper Cretaceous of China. Zootaxa 2413, 1–19 (2010).
Xu, X. et al. A monodactyl nonavian dinosaur and the complex evolution of the alvarezsauroid hand. Proceedings of the National Academy of Sciences of the United States of America 108, 2338–2342 (2011).
Averianov, A. & Sues, H. D. The oldest record of Alvarezsauridae (Dinosauria: Theropoda) in the Northern Hemisphere. Plos One 12, e0186254 (2017).
Xu, X. et al. Osteology of the alvarezsauroid Linhenykus monodactylus from the Upper Cretaceous Wulansuhai Formation of Inner Mongolia, China, and comments on alvarezsauroid biogeography. Acta Palaeontologica Polonica 58, 25–46 (2013).
Pittman, M., Xu, X. & Stiegler, J. B. The taxonomy of a new parvicursorine alvarezsauroid specimen IVPP V20341 (Dinosauria: Theropoda) from the Upper Cretaceous Wulansuhai Formation of Bayan Mandahu, Inner Mongolia, China. PeerJ 3, e986 (2015).
Hone, D. W. E., Choiniere, J. N., Tan, Q. & Xu, X. An articulated pes from a small parvicursorine alvarezsauroid dinosaur from Inner Mongolia, China. Acta Palaeontologica Polonica 58, 453–458 (2013).
Naish, D. & Dyke, G. J. Heptasteornis was no ornithomimid, troodontid, dromaeosaurid or owl: the first alvarezsaurid (Dinosauria: Theropoda) from Europe. Neues Jahrbuch fur Geologie und Palaontologie Monatshefte 7, 385–401 (2004).
Perle, A., Chiappe, L. M., Barsbold, R., Clark, J. M. & Norell, M. A. Skeletal morphology of Mononykus olecranus (Theropoda: Avialae) from the late Cretaceous of Mongolia. American Museum Novitates 3105, 1–29 (1994).
Chiappe, L. M., Norell, M. A. & Clark, J. M. Phylogenetic position of Mononykus (Aves: Alvarezsauridae) from the Late Cretaceous of the Gobi Desert. Memoirs of the Queensland. Museum 39, 557–582 (1996).
Chiappe, L. M., Norell, M. A. & Clark, J. M. In Mesozoic birds: above the heads of dinosaurs (eds Luis M. Chiappe & Witmer, L. M.) 87–120 (University of California Press, 2002).
Novas, F. E. Alvarezsauridae, Cretaceous maniraptorans from Patagonia and Mongolia. Memoirs of the Queensland Museum 39, 675–702 (1996).
Holtz, T. R. Jr. A new phylogeny of the carnivorous dinosaurs. Gaia 15, 5–61 (1998).
Suzuki, S. et al. A new specimen of Shuvuuia deserti Chiappe et al., 1998, from the Mongolian Late Cretaceous with a discussion of the relationships of alvarezsaurids to other theropod dinosaurs. Contributions in Science (Los Angeles) 494, 1–18 (2002).
Feduccia, A. The great dinosaur debate. Living bird 13, 28–33 (1994).
Zhou, Z. H. Is Mononykus a bird? Auk 112, 958–963 (1995).
Sereno, P. C. The evolution of dinosaurs. Science 284, 2137–2147 (1999).
Sereno, P. Alvarezsaurids: birds or ornithomimosaurs. New perspectives on the origin and early evolution of birds, 69–98 (2001).
Norell, M. A., Clark, J. M. & Makovicky, P. J. In New perspectives on the origin and evolution of birds (eds Gauthier, J. & Gall, L. F.) 49–67 (Yale University Press, 2001).
Novas, F. E. & Pol, D. In Mesozoic birds: above the heads of dinosaurs (eds Chiappe, L. M. & Witmer, L. M.) 87–120 (University of California Press, 2002).
Hwang, S. H., Norell, M. A., Ji, Q. & Gao, K. New specimens of Microraptor zhaoianus (Theropoda: Dromaeosauridae) from northeastern China. American Museum Novitates 3381, 1–44 (2002).
Makovicky, P. J., Apesteguı´a, S. & Agnolı´n, F. L. The earliest dromaeosaurid theropod from South America. Nature 437, 1007–1011 (2005).
Göhlich, U. B. & Chiappe, L. M. A new carnivorous dinosaur from the Late Jurassic Solnhofen archipelago. Nature 440, 329–332 (2006).
Turner, A. H., Nesbitt, S. J. & Norell, M. A. A large alvarezsaurid from the Late Cretaceous of Mongolia. American Museum Novitates 3648, 1–14, https://doi.org/10.1206/639.1 (2009).
Choiniere, J. N. et al. A basal alvarezsauroid theropod from the early Late Jurassic of Xinjiang, China. Science 327, 571–574 (2010).
Clark, J., Xu, X., Forster, C., Wang, Y. & Andres, B. New small dinosaurus form the Upper Jurassic Shishugou Formation at Wucaiwan, Xinjiang, China. Journal of Vertebrate Paleontology 22(suppl), 44A (2002).
Clark, J., Xu, X. & Forster, C. The fauna of the Middle-Upper Jurassic Shishugou Formation, western China. Journal of Vertebrate Paleontology 26(suppl), 50A (2006).
Eberth, D. A., Xu, X., Clark, J. M. & Machlusm, M. The dinosaur-bearing Shishugou Formation (Jurassic, northwest China) revealed. Journal of Vertebrate Paleontology 26(suppl), 58A (2006).
Choiniere, J. N. et al. A juvenile specimen of a new coelurosaur (Dinosauria: Theropoda) from the Middle–Late Jurassic Shishugou Formation of Xinjiang, People’s Republic of China. Journal of Systematic Palaeontology 12, 177–215, https://doi.org/10.1080/14772019.2013.781067 (2013).
Eberth, D. A., Xu, X. & Clark, J. M. Dinosaur death pits from the Jurassic of China. Palaios 25, 112–125, https://doi.org/10.2110/palo.2009.p09-028r (2010).
Xu, X., Han, F. & Zhao, Q. Homologies and homeotic transformation of the theropod ‘semilunate’ carpal. Scientific reports 4 (2014).
Chinsamy, A. The Microstructure of Dinosaur Bone: Deciphering Biology with Fine-Scale Techniques. 195 (The Johns Hopkins University Press, 2005).
Erickson, G. M. On Dinosaur Growth. Annual Review of Earth and Planetary Sciences 42, 675–697, https://doi.org/10.1146/annurev-earth-060313-054858 (2014).
Campione, N. E., Evans, D. C., Brown, C. M. & Carrano, M. T. Body mass estimation in non-avian bipeds using a theoretical conversion to quadrupedal stylopodial proportions. Methods in Ecology and Evolution 5, 913–923 (2014).
Hu, D. et al. A bony-crested Jurassic dinosaur with evidence of iridescent plumage highlights complexity in early paravian evolution. Nature Communications 9, 217, https://doi.org/10.1038/s41467-017-02515-y (2018).
Watanabe, A. et al. Vertebral Pneumaticity in the Ornithomimosaur Archaeornithomimus (Dinosauria: Theropoda) Revealed by Computed Tomography Imaging and Reappraisal of Axial Pneumaticity in Ornithomimosauria. PLoS One 10, e0145168, https://doi.org/10.1371/journal.pone.0145168 (2015).
Altangarel, P., Chiappe, L. M., Rinchen, B., Clark, J. M. & Norell, M. A. Skeletal morphology of Mononykus olecranus (Theropoda: Avialae) from the Late Cretaceous of Mongolia. American Museum Novitates 3105, 1–29 (1994).
Zanno, L. E., Gillette, D. D., Albright, L. B. & Titus, A. L. A new North American therizinosaurid and the role of herbivory in “predatory” dinosaur evolution. Proceedings of the Royal Society B 276, 3505–3511 (2009).
Makovicky, P. J., Kobayashi, Y. & Currie, P. J. In The Dinosauria (second edition) (eds Weishampel, D. B., Dodson, P. & Osmolska, H.) 137–150 (University of California Press, 2004).
Holtz, T. R. In The Dinosauria (second edition) (eds Weishampel, D. B., Dodson, P. & Osmólska, H.) 111–136 (University of California Press, 2004).
Carrano, M. T. & Sampson, S. D. The phylogeny of Ceratosauria (Dinosauria: Theropoda). Journal of Systematic Palaentology 6, 183–236 (2008).
Rauhut, O. W. M. & Xu, X. The small theropod dinosaurs Tugulusaurus and Phaedrolosaurus from the Early Cretaceous of Xinjiang, China. Journal of Vertebrate Paleontology 25, 107–118 (2005).
Erickson, G. M. et al. Was dinosaurian physiology inherited by birds? Reconciling slow growth in archaeopteryx. PLoS ONE 4, e7390, https://doi.org/10.1371/journal.pone.0007390 (2009).
Padian, K., Horner, J. R. & De Ricqlès, A. Growth in small dinosaurs and pterosaurs: the evolution of archosaurian growth strategies. Journal of Vertebrate Paleontology 24, 555–571 (2004).
Lee, A. H. & O’Connor, P. M. Bone histology confirms determinate growth and small body size in the noasaurid theropodMasiakasaurus knopfleri. Journal of Vertebrate Paleontology 33, 865–876, https://doi.org/10.1080/02724634.2013.743898 (2013).
Erickson, G. M., Currie, P. J., Inouye, B. D. & Winn, A. A. Tyrannosaur life tables: An example of nonavian dinosaur population biology. Science 313, 213–217, https://doi.org/10.1126/Science.1125721 (2006).
Turner, A. H., Pol, D., Clarke, J. A., Erickson, G. M. & Norell, M. A. A basal dromaeosaurid and size evolution preceding avian flight. Science 317, 1378–1381 (2007).
Butler, R. J. et al. Lower limits of ornithischian dinosaur body size inferred from a new Upper Jurassic heterodontosaurid from North America. Proceedings of the Royal Society B-Biological Sciences 277, 375–381, https://doi.org/10.1098/Rspb.2009.1494 (2010).
Agnolin, F. L., Powell, J. E., Novas, F. E. & Kundrat, M. New alvarezsaurid (Dinosauria, Theropoda) from uppermost Cretaceous of north-western Patagonia with associated eggs. Cretaceous Research 35, 33–56, https://doi.org/10.1016/J.Cretres.2011.11.014 (2012).
Christiansen, P. & Richard, A. F. Mass Prediction in Theropod Dinosaurs. Historical Biology An International. Journal of Paleobiology 16, 85–92 (2004).
Choiniere, J. N., Clark, J. M., Norell, M. A. & Xu, X. Cranial Osteology of Haplocheirus sollers Choiniere et al., 2010 (Theropoda: Alvarezsauroidea). American Museum Novitates 51, 1–44 (2014).
Desbiez, A. L. J. & Medri, Í. M. Density and habitat use by giant anteaters (Myrmecophaga tridactyla) and southern tamanduas (Tamandua tetradactyla) in the Pantanal wetland, Brazil. Edentata 11, 4–11 (2010).
Horner, J. R. & Padian, K. Age and growth dynamics of Tyrannosaurus rex. Proceedings. Biological sciences/The Royal Society 271, 1875–1880, https://doi.org/10.1098/rspb.2004.2829 (2004).
Nesbitt, S. J., Clarke, J. A., Turner, A. H. & Norell, M. A. A small alvarezsaurid from the eastern Gobi Desert offers insight into evolutionary patterns in the Alvarezsauroidea. Journal of Vertebrate Paleontology 31, 144–153 (2011).
Xu, X. et al. A Jurassic ceratosaur from China helps clarify avian digital homologies. Nature 459, 940–944 (2009).
Goloboff, P. A., Farris, J. S. & Nixon, K. C. TNT, a free program for phylogenetic analysis. Cladistics 24, 774–786, https://doi.org/10.1111/j.1096-0031.2008.00217.x (2008).
Bremer, K. Branch support and tree stability. Cladistics 10, 295–304 (1994).
Wang, Y.-F. et al. Development and applications of paleontological computed tomography. Development and applications of paleontological computed tomography 57, 84–92, https://doi.org/10.19615/j.cnki.1000-3118.170921 (2019).
Padian, K. & Lamm, E.-T. Bone histology of fossil tetrapods. 285 (University of California Press, 2013).
Zhao, Q., Benton, M. J., Sullivan, C., Martin Sander, P. & Xu, X. Histology and postural change during the growth of the ceratopsian dinosaur Psittacosaurus lujiatunensis. Nature Communications, https://doi.org/10.1038/ncomms3079 (2013).
We thank Haijun Wang, Lishi Xiang, He Sicai, Renfang Cao, and Yu Tao for excavating and preparing specimens, and Aijuan Shi for the skeletal silhouettes in Fig. 1. This work was supported by grants from the National Natural Science Foundation of China (41688103, 91514302, and 41120124002), and NSF of USA (EAR 0922187), the Strategic Priority Research Program of the Chinese Academy of Sciences (Grant No. XDB18030504). The South African NRF IRG grant number 95449 funded Jonah Choiniere’s participation in the project. We are grateful to the Willi Hennig Society for their support of the phylogenetics package TNT. We thank Michael Pittman, Nick Longrich and an anonymous reviewer for their careful work and thoughtful suggestions that have helped improve our paper substantially.
The authors declare no competing interests.
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Qin, Z., Clark, J., Choiniere, J. et al. A new alvarezsaurian theropod from the Upper Jurassic Shishugou Formation of western China. Sci Rep 9, 11727 (2019). https://doi.org/10.1038/s41598-019-48148-7
New manual unguals of Trierarchuncus prairiensis from the Hell Creek Formation, Montana, and the ontogenetic development of the functional alvarezsaurid hand claw
Cretaceous Research (2021)
Dental anatomy of the apex predator Sinraptor dongi (Theropoda: Allosauroidea) from the Late Jurassic of China
Canadian Journal of Earth Sciences (2020)
Biological Reviews (2020)