Yi qi, Xu & Zheng & Sullivan & Wang & Xing & Wang & Zhang & O’Connor & Zhang & Pan, 2015

Yi qi gen. et sp. nov.

Etymology. The generic and specific names are derived from Mandarin Yi (wing) and qi (strange), respectively, referring to the bizarre wings of this animal. The intended pronunciation of the name is roughly ‘‘ee chee’’.

Holotype. STM 31-2 ( housed at the Shandong Tianyu Museum of Nature), an articulated partial skeleton with associated soft tissue preserved on a slab and counter slab. The specimen was collected by a local farmer, but its provenance and authenticity have been confirmed by multiple lines of evidence including sedimentology, taphonomy and computed tomography (CT) data (Extended Data Figs 1–4 View Figure 1 View Figure 2 View Figure 3 View Extended ; see also Supplementary Information).

Locality and horizon. Mutoudeng, Qinglong County, Hebei Province, China. Tiaojishan Formation, Callovian–Oxfordian stage 4 , 11 . On the basis of the provenance of the specimen, Yi qi is a member of the Daohugou (or Yanliao) Biota 12.

Diagnosis. A scansoriopterygid theropod distinguishable from other scansoriopterygids in having a low midline crest along the nasals, a relatively small and posteriorly located external mandibular fenestra, tooth crowns that are symmetrical in lateral view and considerably wider mesiodistally than their corresponding roots, a humerus and ulna that are long relative to the tibiotarsus (length ratios are 1.16 and 1.08, respectively, compared to 0.96 and 0.78 in Epidendrosaurus and 0.79 and 0.66 in Epidexipteryx ), an extremely short humeral deltopectoral crest, and a long rod-like bone articulating with the wrist.

Key osteological features are as follows. STM 31-2 ( Fig. 1 View Figure 1 ) is inferred to be an adult on the basis of the closed neurocentral sutures of the visible vertebrae, although this is not a universal criterion for maturity across archosaurian taxa 12. Its body mass is estimated to be approximately 380 g, using an empirical equation 13.

The skull and mandible are similar to those of other scansoriopterygids, and to a lesser degree to those of oviraptorosaurs and some basal birds such as Sapeornis and Jeholornis 11,14–17: the skull is relatively robust, the snout is short (approximately 40% of skull length), the large premaxilla bears a well-developed subnarial process and extends further ventrally than the small maxilla, the parietal is anteroposteriorly long, the antorbital fossa is much smaller than the orbit, the infratemporal fenestra is large, the anterior end of the robust mandible is downturned, four slightly procumbent premaxillary teeth are located anterior to the external naris, the first premaxillary tooth is larger than the more posterior ones, and the anterior dentary teeth are strongly procumbent ( Fig. 1 View Figure 1 a–d). The thoracic appendage resembles that of other paravians in that the scapula is proportionally short and the humerus is long and robust, and further resembles that of other scansoriopterygids 14 – 16 in having a robust scapular blade, a short humeral deltopectoral crest, a straight ulna that is only slightly more robust than the radius, a metacarpal IV that is longer and more robust than metacarpal III (we identify the three manual digits of Yi and other maniraptorans as II–III–IV, following the position-based numbering used in most ornithological literature, although we acknowledge that an anatomy-based I–II–III numbering convention is preferred by most dinosaur workers), and non-ungual phalanges of digit IV that are all greatly elongated ( Fig. 1a, b, e View Figure 1 ).

The most striking feature of Yi is the presence of an anomalous, slightly curved, distally tapered, rod-like structure (see Supplementary Information for further description), whose length considerably exceeds that of the ulna, associated with each wrist and apparently extending from the ulnar side of the carpus ( Fig. 1a, b, f View Figure 1 and Extended Data Fig. 5 View Extended ). These structures resemble the preserved bones on the slab in colour, and in displaying a granular texture under magnification. Energy dispersive spectrometry (EDS) analysis of the elemental composition of the rod extending from the right wrist confirms that it is a bone (or possibly a skeletal element composed of calcified cartilage) and not a soft-tissue structure (Extended Data Fig. 6 View Extended ; see also Supplementary Information). However, the rod-like bone of the forelimb of Yi is morphologically unlike any normal theropod skeletal element. Indeed, no equivalent of the rod-like bone is known in any other dinosaur even outside Theropoda, but similar structures are present in a diverse array of extant and extinct flying or gliding tetrapod groups 6 – 10. For example, a rod of bone or cartilage is attached to the wrists of petauristine squirrels 18; the elbows of anomalurid squirrels 19, the gliding marsupial Petauroides volans 19 and the Oligocene epoch eomyid rodent Eomys quercyi 9; the ankles of many bats, including some early ones 9, 10; and the wrists of all pterosaurs 8 (that is, the pteroid). In particular, the rod-like bone of Yi is strikingly similar to the enlarged carpally situated element seen in some petauristines 7, including the Japanese giant flying squirrel Petaurista leucogenys (Extended Data Fig. 7 View Extended ; see also Supplementary Information). For convenience, we adopt ‘styliform element’ as a general term for unjointed, rod-like bony or cartilaginous structures that extend from distal limb joints in tetrapods.

Integumentary structures and preserved melanosomes are as follows. Two major types of integumentary structure are preserved (see Supplementary Information for further description): feathers and membranous soft tissue ( Figs 1a, b View Figure 1 , 2 View Figure 2 and Extended Data Fig. 5 View Extended ). Thin stiff filamentous feathers are distributed around the skull (15– 20 mm long; Fig. 2a View Figure 2 ), and both above and below the neck (about 30 mm long; Extended Data Fig. 5a View Extended ). The feathers attached to the forelimb (35–60 mm long; Fig. 2b View Figure 2 and Extended Data Fig. 5b, c View Extended ), and to the hindlimb including the metatarsus (up to 60 mm long; Fig. 2c View Figure 2 and Extended Data Fig. 5e View Extended ), are much larger than the skull and neck feathers. Some of the filamentous feathers, including those on the skull and neck, appear to exhibit a simple branching pattern, but their dense preservation makes morphological details difficult to observe. Nevertheless, some isolated feathers clearly comprise multiple radiating filaments ( Fig. 2d View Figure 2 and Extended Data Fig. 5d View Extended ), and the majority of the limb feathers have a unique paintbrush-like morphology ( Fig. 2e View Figure 2 ): the proximal three-fourths of each feather is a wide (about 1.2 mm), undifferentiated shaft-like structure, whereas the distal part is composed of numerous near-parallel filaments.

Several patches of membranous soft tissue are exposed around the styliform element and digits in both hands ( Figs 1a, b View Figure 1 , 2f View Figure 2 and Extended Data Fig. 5f, g View Extended ). Additional patches appear to exist, but cannot be easily exposed (see Supplementary Information). The tissue has a sheet-like appearance, making it clearly distinguishable from the individual filaments or small groups of filaments that represent feathers ( Fig. 2g View Figure 2 ), and in some areas displays prominent ripple-like striations that may represent either fibres or closely spaced folds. The membranous tissue does not closely resemble any type of integumentary structure previously reported in theropods from the Mesozoic era deposits of northeastern China.

We examined the integumentary structures using scanning electron microscopy (Extended Data Fig. 8 View Extended ), revealing what we interpret as preserved melanosomes on both feathers and membranous tissue patches (although several studies have questioned the identification of melanosomes in theropod fossils 20, 21). The melanosomes are highly variable in size (long axis 300–2,100 nm), shape (aspect ratio of 1.0 to 3.6) and density (Extended Data Fig. 9 View Extended ). It is noteworthy that some of the preserved melanosomes are among the largest known from either fossil or modern feathers 5. The membranous tissue contains only small phaeomelanosomes (long axis 300–400 nm), unlike the filamentous feathers in which eumelanosomes predominate and relatively few phaeomelanosomes are present (see Supplementary Information for details).

A numerical phylogenetic analysis places Yi within the enigmatic Scansoriopterygidae family 14 – 17, which in turn is posited as the sister taxon to other paravians ( Fig. 3 View Figure 3 and Extended Data Fig. 10). Scansoriopterygids including Yi have numerous unusual skeletal features, including a highly elongated third finger and a highly modified pelvis 14, 16, 17. They also display unusual integumentary features: despite being basal paravians, they lack pinnate feathers, but their filamentous feathers resemble the pinnate feathers of other pennaraptorans in having morphologically diverse melanosomes 5. Given that scansoriopterygids are phylogenetically nested within Pennaraptora, they appear to represent a case of extreme morphological divergence near the origin of birds, involving not only extensive modification of the skeleton but also secondary loss of normal pennaraptoran pinnate feathers.

Large flight feathers and even propatagia are present in the basal oviraptorosaur Caudipteryx and the basal deinonychosaurs Anchiornis and Microraptor 1 – 3 (and a propatagium has been identified in the scansoriopterygid Epidendrosaurus 22), indicating that the feathered wing is a primitive feature of the Pennaraptora even though basal members of this group are flightless 23. Both phylogenetic bracketing 24 and the preserved morphology of the shoulder girdle and forelimb suggest that Yi resembles other basal paravians in the overall skeletal structure of its thoracic girdle and appendages. In Yi, however, the large flight feathers present in other pennaraptorans appear to be at least partly replaced by membranes supported by the styliform element and manual digits, in stark contrast to the archetypal wings that are universal in birds and their closest relatives. The highly elongated manual digit IV of Yi and other scansoriopterygids is unique among theropods but superficially similar to the long manual digits II–V of bats and the highly elongated fourth finger in pterosaurs. Furthermore, some major components of the wing of Yi, such as the membrane and styliform element, are not known in other winged theropods. The discovery of Yi thus adds considerably to the known diversity of thoracic appendage morphologies present near the transition to birds.

Because other amniotes that possess a styliform element invariably utilize this structure to support an aerodynamic membrane that contributes to gliding or powered flight 6 – 10, and alternative functions for a long, unjointed rod of bone or cartilage extending from a distal limb joint are difficult to imagine (see Supplementary Information), the occurrence of a styliform element in Yi is a strong indication that membranous aerodynamic surfaces and some degree of aerial capability were present in this taxon. Further evidence that Yi was volant comes from the preserved patches of membranous tissue associated with the styliform element and digits, and from the proportions of the appendicular skeleton (see Supplementary Information). It is worth emphasizing that, even if our inference that Yi was an aerially adapted taxon with membranous wings proves incorrect, the styliform element and membranous tissue patches will stand as highly unusual features that imply some kind of equally distinctive forelimb function in this peculiar theropod.

Even under our preferred interpretation, the flight apparatus of Yi cannot be confidently reconstructed due to the incomplete preservation of the wing membrane in the only known specimen, combined with uncertainties regarding the styliform element’s orientation and connection to the wrist. However, the range of possible flight apparatus configurations can be explored by considering different reconstructions ( Fig. 3 View Figure 3 and Extended Data Fig. 7 View Extended ) that are supported to varying degrees by morphological and taphonomic information from the specimen, fundamental aerodynamic principles, and the aerial locomotion of other volant tetrapods. Preliminary analysis of the wing loadings and other properties of some of these configurations supports the plausibility of Yi as a volant taxon (see Supplementary Information). In having wings with a well-developed membranous component, Yi would differ from other volant paravians but resemble distantly related groups including pterosaurs, bats and many gliding mammals, representing a striking case of convergent evolution of the aerodynamic apparatus among tetrapods 6 – 10.

The mode of aerial locomotion that might have been used by Yi is difficult to reconstruct on the basis of present evidence. Yi may have been capable of flapping flight or only of gliding, or may have combined the two locomotor styles as in many extant birds and some bats (see Supplementary Information). There are some indications that Yi may have relied more on gliding than on flapping, including the lack of strongly expanded muscle attachment surfaces on the forelimb bones and the possibility that the unwieldy styliform element would have interfered with the rapid oscillations and rotations of the distal part of the forelimb needed for efficient flapping flight, but the mode of aerial locomotion that is most likely for Yi remains uncertain. Regardless, the evident occurrence in this taxon of a membranous wing supported by a styliform element represents an unexpected aerodynamic innovation close to the origin of birds, and highlights the breadth of flight-related morphological experimentation that took place in the early stages of paravian history.