The origin of avian flight is a classic macroevolutionary transition with research spanning over a century. Two competing models explaining this locomotory transition have been discussed for decades: ground up versus trees down. Although it is impossible to directly test either of these theories, it is possible to test one of the requirements for the trees-down model, that of an arboreal paravian. We test for arboreality in non-avian theropods and early birds with comparisons to extant avian, mammalian, and reptilian scansors and climbers using a comprehensive set of morphological characters. Non-avian theropods, including the small, feathered deinonychosaurs, and Archaeopteryx, consistently and significantly cluster with fully terrestrial extant mammals and ground-based birds, such as ratites. Basal birds, more advanced than Archaeopteryx, cluster with extant perching ground-foraging birds. Evolutionary trends immediately prior to the origin of birds indicate skeletal adaptations opposite that expected for arboreal climbers. Results reject an arboreal capacity for the avian stem lineage, thus lending no support for the trees-down model. Support for a fully terrestrial ecology and origin of the avian flight stroke has broad implications for the origin of powered flight for this clade. A terrestrial origin for the avian flight stroke challenges the need for an intermediate gliding phase, presents the best resolved series of the evolution of vertebrate powered flight, and may differ fundamentally from the origin of bat and pterosaur flight, whose antecedents have been postulated to have been arboreal and gliding.
Citation:Dececchi TA, Larsson HCE (2011) Assessing Arboreal Adaptations of Bird Antecedents: Testing the Ecological Setting of the Origin of the Avian Flight Stroke. PLoS ONE 6(8): e22292. doi:10.1371/journal.pone.0022292
Editor: Andrew Allen Farke, Raymond M. Alf Museum of Paleontology, United States of America
Received: February 18, 2011; Accepted: June 23, 2011; Published: August 9, 2011
Copyright: © 2011 Dececchi, Larsson. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding:This research was supported by a Fonds Québécois de la Recherche sur la Nature et les Technologies doctoral fellowship to TAD, and a Natural Sciences and Engineering Research Council Discovery Grant (261796) and Canada Research Chair to HL. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
The origin of avian flight has long been considered a classic macroevolutionary transition . The ecological setting of this transition is significant because it influences the evolutionary drivers for critical components of this transition, such as the flight stroke or flight feathers. Initially, the argument for the origin of avian flight hinged on two competing scenarios: the ground-up and trees-down hypotheses. This dichotomy was originally based on debates of the phylogenetic relationship of birds to other archosaurs. The trees-down proponents favoured a “thecodont” antecedent and the ground-up supporters championed a theropod dinosaur origin of birds (see  for a review). A theropod ancestry of birds was first proposed by Huxley , resurrected by Ostrom , and is supported by an overwhelming wealth of new fossils and phylogenetic analyses in recent years (see ,  for brief reviews of supporting data). In spite of the dinosaurian ancestry of birds, the debate on the ecological setting of the origin of avian flight is still in flux. The plesiomorphic state for non-avian theropods is undoubtedly terrestrial , but the possibility of tree-dwelling, small-bodied theropods closely related to birds has resurrected intense debates that bird antecedents may have been arboreal and gliding , .
The ground-up scenario implies that the capacity for powered flight evolved from a fully terrestrial theropod precursor. This hypothesis suggests feathered limbs evolved for a non-locomotor function, such as display or insulation, and the flight stroke developed to aid in high speed running or traversing steep inclines , , . The trees-down scenario implies that powered flight evolved in an arboreal lineage of theropods, where, feathered limbs were selected for increased surface area and functioned primarily for parachuting and gliding –.
Compelling cases for an arboreal origin of flight have been made based on body size, feather placement, and pedal claw geometry of new, small, feathered, non-avian theropods –. Equally convincing arguments for a terrestrial origin of flight have been made with corrections to older methods of claw geometrics , lack of a reversed perching hallux –, and feasible biomechanical models of flight from high-speed running . The apparent dichotomy of the ecological setting for the origin has been blurred, and perhaps made moot  with recent discoveries that many extant birds have a peculiar behaviour called wing assisted incline running (WAIR) , . WAIR is used by extant birds to ascend steeply inclined, vertical, and even slight overhanging surfaces with the aid of a powerful flight stroke. Although this behaviour allows access into trees, WAIR is essentially a specialized form of terrestrial locomotion that is related to the running-flapping model .
Although the arboreal-terrestrial dichotomy may be less clear cut than originally proposed, many recent authors have argued for a trees-down, gliding model based on a arboreal, climbing bird antecedent , , , ,  and that the flight stroke was derived either simultaneously or shortly after from wing-assisted descents from trees . An arboreal context for the origin of the flight stroke requires avian antecedents to have been tree-dwelling. Extant arboreal vertebrates have a suite of adaptations different from their terrestrial counterparts to aid in moving along thin diameter branches, such as large phalangeal indices and extremely mobile shoulder/hip and wrist/ankle joints . An arboreal origin of the flight stroke is expected to be tied with a suite of arboreal adaptations. Although WAIR could have facilitated ascent into trees, it does nothing to aid in movement along branches or descent. Any arboreal setting for the origin of flight, preceded by either a climbing and gliding pathway or a terrestrial-based WAIR origin of the flight stroke and access to the trees, is expected to present some degree of arboreal adaptations in avian antecedents. Conversely, a terrestrial origin of the flight stroke is not expected to have any trace of arboreal adaptations.
To better understand the context of the origin of the flight stroke and powered flight in birds, we need knowledge of the functional, behavioural, and ecological repertoire available to the antecedents of the first fliers. In this paper, we tested for evidence of arboreality in bird ancestors. The trees-down hypothesis is predicated on the existence a lineage of highly arboreal theropods preceding the evolution of the aerofoil and gliding locomotion , , , . We examined anatomical support for arboreality in non-avian theropods using a suite of well-known morphological characters relevant to arboreal locomotion in extant taxa, rather than focusing on any single trait. Given that the plesiomorphic locomotory state for Theropoda is terrestrial cursoriality, we will start with the assumption that all non-avian theropods are terrestrial. If morphological adaptations to facilitate movement into, out of, and within trees are absent, we can argue against an arboreal ancestry of birds and, therefore, the trees down hypothesis.
The sister taxon to Aves is either Deinonychosauria (composed of Dromeaosauridae and Troodontidae) or the enigmatic Scansoriopterigidea , . It is within these groups that one would expect the evolution of anatomical traits to facilitate and refine climbing, descending, and branch-walking locomotion. We selected morphological characters that are associated with a clear functional role in arboreal locomotion and/or climbing and are widely distributed across extant and extinct tree dwellers including some pterosaurs, non-mammalian therapsids, mammals, birds and other reptiles –.
Materials and Methods
No live animals were used in this study.
Categorizing arboreal and terrestrial taxa
Occasional climbers, require little behavioural or morphological adaptations. However, similar to the ability to swim, these non-specialized taxa show little propensity in the act and are at greater risk of injury from falling , . Truly arboreal tetrapods, or those for whom a scansorial lifestyle occupies a large portion of their foraging regimes, have convergent solutions to the twin problem of securing themselves while maintaining manoeuvrability , , –. Today's arboreal vertebrates include quadrupedal salamanders, frogs, mammals, and lizards, bipedal birds, and limbless snakes. We compiled data for extant quadrupedal and bipedal taxa to encompass the complete range of potential locomotory modes of non-avian theropods within an arboreal environment.
We focused on claw and grip-based climbing adaptations because non-avian theropods show no evidence for more specialized climbing methods such as suction, capillary action, or dry adhesion that are present in climbing salamanders, frogs, and many lizards. We followed the categorization of arboreal, scansorial, and terrestrial of Van Valkenburgh  for non-bird taxa. Arboreal is defined as “[r]arely on the ground, forages and shelters in the trees”; scansorial is “[c]apable of climbing, usually climbs for escape”; and terrestrial is “[r]arely or never [c]limbs…” Although these categories have indiscrete boundaries, they provide straightforward definitions that are in general use. These categories allow us to clearly define endpoints while attempting to account for the continuum of the transition from primarily terrestrial (e.g. the horse), occasional climbers (e.g. the housecat) to those that primarily live in the trees, but are capable of foraging on the ground (e.g. the grey squirrel). We did not differentiate between subsets of locomotion within each category (i.e. cursorial and fossorial taxa were included in terrestrial).
Five foraging categories were used for avian taxa based on Glen and Bennet  with some modifications. These consist of ground based, ground foragers (Gg and Ga of ), aerial foragers (A) (Ag and Aa of Glen and Bennet ), climbers, and birds of prey. With the exception of ground based birds, which rarely or never roust or perch in trees, the majority of living birds spend at least part of their lives in trees. Even taxa that forage primarily on the ground require some arboreal adaptations.
Due to the uncertainty involved in the possible stance adopted by theropods within an arboreal setting, either retaining the bipedal one common to all terrestrial forms , or using a more quadrupedal stance, we ran multiple analyses to test all possible permutation. These included a “naive” analysis using the entire dataset (including both bipedal birds and quadrupedal taxa, regardless of stance) and separate bipedal and quadrupedal permutations. Due to bipedalism being plesiomorphic for theropods , this stance allowed the forelimbs of theropods to evolve without the constraints involved in locomotion. Because the forelimbs of many theropods were likely used for prey capture –, and characters associated with predation and climbing often overlap –, the predatory nature of theropods could influence our analysis and give a false positive for climbing. To attempt to minimize this possibility we also performed forelimb and hindlimb only analyses. This division of fore- and hindlimbs is also warranted as it has been suggested that climbing adaptations often manifest themselves primarily in the hindlimb , . This is due, in grip based climbers, to the necessity to secure a safe purchase while reaching for new supports , ,  and in claw based climbing specialists in the evolution of reversible hindfeet and head first descent . Thus, we suspect that the hindlimb should be more informative in assessing arboreality than the forelimb in theropods, necessitating separate analyses.
Seventy-four extant mammals, nine lizards (including two chameleons and the extinct glider Xuanlong), and three extinct arboreal taxa (the synapsid Suminia and the enigmatic drepanosaur diapsids Megalancosaurus and Vallesaurus) were used to represent quadrupeds and scored for all characters. Although lizard locomotion differs fundamentally from that of theropods, the inclusion of a sample of sprawling lizards (including two “flying” lizards, the extant genus Draco and the extinct Xianlong) was done to ensure a diversity of climbing styles was represented in our study. The sprawling gait of lizards (with the exception of the chameleon) is fundamentally different in terms of loading mechanics, limb retraction, and kinematics during locomotion from the parasagittal gait found in mammals, birds and theropods , . These factors, combined with the general small body size of lizards (>80% of taxa are less than 50 g  compared to paravians (~700–2000 g ) and the evolution in highly arboreal species with toe pads to enhance grip –, generally make lizards unsuitable analogs for theropod behaviour or locomotion. Most lizards, including all used in this analysis, are scansorial and often climb rocks, trees, and bushes . We included only the chameleon in the analyses discussed here because it is the most arboreal of all lizards and has a unique parasagittal stride  similar to that expected in an arboreal bird antecedents.
Due to the high degree of morphological disparity between birds and other tetrapods and the bipedal terrestrial and arboreal locomotion of birds, a separate analysis was performed using thirty-one avian taxa that sample each of the five foraging categories of extant birds. Although the absolute value of some metrics may not be directly comparable to quadrupeds, similar trends should be repeated in non-avian theropods as a general solution to the problems of ascending, moving within, and descending from trees.
Twenty-one well preserved theropod specimens, representing fifteen different genera, were included to examine how they clustered with the extant groups. Quantitative and qualitative data of non-avian and avian theropods were taken directly from museum specimens and the literature. A dataset of the most complete non-avian and early avian theropod taxa was used in the cluster analysis. Additional, less complete, non-avian theropods were used for individual quantitative indices to gather the widest phylogenetic and body size ranges of these taxa. Measurements of Epidendrosaurus are suspect given this taxon's early ontogenetic stage  (pers. obs.) but included for completeness.
Qualifying and quantifying arboreal adaptations
Seventeen discrete characters diagnostic for habitat preference were used to compare both non-avian theropods and basal birds to non-avian tetrapods. These characters have been demonstrated to be indicators of increasing arboreality , , . These included the presence of an opposable hallux and/or pollex, the ability of the tail to act as a prehensile organ or as a support on a vertical surface, the ability to pronate/supinate the forelimb, hindfoot reversal and claw curvature. A set of commonly used quantitative indices were applied including the brachial index (BI, ulnar length/humeral length), crural index (CI, tibial length/femoral length), manual and pedal phalangeal indices (MPI and PPP, non-ungual length of the digital ray length/metapodial length), and overall limb lengths. Overall limb lengths were calculated from stylopodial (humerus/femur) and zeugopodial (ulna/tibia) segment lengths divided by trunk length. Only these two limb segments were used to maintain a common comparator between plantigrade to digitigrade taxa. CI does not have the same functional relationship in birds as it does in non-avian tetrapods because of the horizontal position of the femur and different hindlimb biomechanics, and bone proportions in living birds –. The avian tarsometatarus length was divided by the tibial length to derive a more comparable index of distal segment elongation for use in the combined dataset in all extant avians and advanced fossil birds (i.e. Ornithothoraces). We also performed the analyses using the “traditional” CI index for both the advanced fossil and extant birds, and it does not significantly alter the results (results not shown). Qualitative multistate characters were used to characterize joint mobility variation. We define low mobility as movement restricted to a single plane, or allowing very limited active movement in multiple planes (e.g. the ankle of a horse). Medium mobility is defined as movement in more than one plane, but an inability to fully abduct/adduct or invert/evert that segment without discomfort (e.g. wrist of the house cat). Highly mobile joints are defined as those that can freely and fully abduct/adduct and even circumduct (e.g. the wrist of tree squirrels).
Eight characters associated with climbing and perching abilities in extant birds were used to compare extinct theropods to their living descendents –. In addition to PPI and claw curvature, these characters include relative hindlimb, tibial, and metatarsal length (standardized to body mass), the presence and extent of a reversed hallux, presence of zygodactyly, and any modification of tail feathers to act as a supporting strut. Because of the differences in non-avian theropods and bird hindlimbs, tibial and metatarsal indices were standardized against the mean of each clade to generate comparable values. Mass values for non-avian theropods were calculated based on femoral length or circumference estimates, with the lowest value chosen.
These metrics can be divided into those that reduced the distance between the centre of mass and the substrate (i.e. BI), those that facilitate securing a purchase (i.e. claw curvature, PPI) and those that permit greater mobility (i.e. joint flexibility characters). We substituted the functional homologue Ph.III-I for the central metatarsus when computing PPI, as suggested in Hopson  because of the digitigrade stance of the theropod foot.
The musculoskeletal characters used in our analyses were selected, a priori, to be not restricted to any particular taxonomic group and show a broad distribution and association with arboreality in unrelated extant clades. The dissociation between these characters and phylogeny is demonstrated by the lack of phylogenetic signal in the clustering results. Continuous characters were also used to examine general trends from terrestriality to arboreality, without regard to absolute values. The patterns of these trends are also non-phylogenetic because they are repeated across unrelated lineages in response to arboreal demands and only used to derive qualitative trends from assemblages of unrelated clades. Correlation cluster algorithms, principal coordinate analyses (PCO), and linear regressions were performed in PAST v.2.00 (PAlaeontological STastics)  and R . Complete data and statistical results are given in Table S1, S2, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S13, S14 and Text S1.
Results and Discussion
PCO and clustering analyses.
All PCO and clustering analyses of the total and partitioned data revealed the same result; that non-avian theropods are most similar to extant terrestrial taxa (Figure 1, 2, S1, S2, S3, S4, S5, S6, S7, S8). In all PCO analyses, the first axis best discriminates terrestriality from arboreality in the quadrupedal and bird-specific datasets. It is noteworthy that all theropods, including all birds, are located in the same range of this axis as the most cursorial of mammals when examined together (Figure 1A, B). PCO plots readily separate terrestrial mammals and ground-based birds from their arboreal counterparts. There is some overlap between the terrestrial and scansorial mammal hulls, such as the terrestrially classified rat and scansorial mustelids, like the fisher and martin. The scansoreal and arboreal mammal hulls also partially overlap, with mammals such as the scansorial possum (Didelphis) with arboreal grip-based climbers like primates. As expected, all PCO and cluster analyses grouped lizards with scansorial and arboreal clawed-based climbers. In no analysis did lizards group with any non-avian theropod, bird, or cursorial mammal.
PCO values are calculated in Euclidean and presented for the total dataset of a selection of extant mammals, scansorial lizards, a scansorial and arboreal chameleon, and three extinct arboreal taxa (A), the total taxon set using only hindlimb morphologies (B), a partition of only quadrupedal mammals and reptiles with non-avian theropods and Archaeopteryx using only hindlimb morphologies (C), and a partition of only non-avian theropods and birds using a dataset tailored for bird morphologies (D). Each category of taxa are plotted within their respective convex hulls and category labels are given near each category's average, denoted by a star. Non-avian theropods are represented in green hulls, birds in blue hulls, mammals in purple hulls, scansorial lizards in yellow hulls, and fossil arboreal taxa in grey hulls. Basal Mesozoic birds are plotted as red filled circles. The variance explained by each PCO axis is given in parentheses after each axis label. [planned for page width].
(A) are extant quadrupedal mammals and reptiles compared to non-avian theropods and (B) extant birds to non-avian theropods and Mesozoic birds. PCO values are calculated in Euclidean. Note that non-avian theropods and Archaeopteryx cluster with terrestrial taxa at the extreme left of the graphs and have no overlap with scansorial or arboreal mammals and reptiles nor perching birds. The arboreal and scansorial chameleons are plotted to the right of the scansorial lizards. The variance explained by each PCO axis is given in parentheses after each axis label. Basal birds are labelled as: Archaeopteryx, A; Confuciusornis, C; Jeholornis, J; Pengornis, P; Sapeornis, Sa; Sinornis, Si. The filled circles represent positions for figured taxa. In (A), non-avian theropods = Microraptor zhaoianus, terrestrial = horse (Equus), scansorial = Red Panda (Ailurus filgens), arboreal = Grey Squirrel (Sciurus carolinensis), scansorial lizards – Anolis carolinensis, fossil arboreal – Megalancosaurus. In (B) non-avian theropods = Microraptor zhaoianus, basal birds = Sinornis santensis, ground based birds = Ostrich (Struthio camelus), ground foragers = Common Raven (Corvus corax), birds of prey = Great Horned Owl (Bubo virginianus), aerial foragers = Chimney Swift (Chaetura pelagica), climbers = Eurasian Nuthatch (Sitta europaea). Silhouettes of Microrapor and Sinornis are based on Hu and colleagues  and Sereno and Rao , respectively. Silhouettes are not to scale. [planned for page width].
There is no overlap in the morphospaces of ground-based birds with all other bird groups when examined with both the quadrupedal and bipedal-specific morphological characters. When examined together, no bird or mammal group overlap, although ground-based birds and terrestrial mammals near each other at their most cursorial taxa, such as ratites and horses.
Non-avian theropods occupy a surprisingly small morphospace for their phylogenetic diversity and large body mass range. The morphospace of non-avian theropods maps within the terrestrial cursorial range of mammals in the total and quadrupedal-partitioned analyses. Non-avian theropods also map within the ground-based bird morphospace in the total and bird-partitioned analyses. Archaeopteryx always plots within the non-avian theropod morphospace. However, more derived Mesozoic birds cluster within the morphospace realm of perching birds, and most are positioned within the morphospace of the generalist, ground foraging birds, such as corvids and the European Starling (Sturnus vulgaris). These results support earlier proposals of the ecology of these basal birds –.
Cluster analyses also group all non-avian theropods with terrestrial mammals and ground-based birds. Arboreal quadrupedal taxa are divided into two main groups: claw-based (sciurids and carnivores) and grip-based (primates, chameleon, marsupials, and the kinkajou) climbers. This division supports the hypothesis that each strategy enforces differential selection pressures. Claw-based climbers generally clustered closer to terrestrial and scansorial taxa, suggesting they are less specialized for arboreality. All non-avian theropods cluster within the terrestrial “cursorial” species grouping. When hindlimb and tail characters are partitioned from the total data, this partition yields a similar pattern, but with less resolution than the whole body dataset. As expected, if only the forelimbs of quadrupeds and non-avian theropods and Archaeopteryx are examined, the hulls of each group broadly overlap each other and there is little distinction between each group in the cluster analysis (Figure S9, S10). In general, non-avian theropods clustered with scansorial and grip-based climbing taxa, though the compsognathids and tyrannosaurs grouped with the lizards. This clustering is likely due to anatomical similarities between the predatory function of non-avian theropod forelimbs with grip-based climbers, such as the high MPI and a divergent pollex, both of which allow for enhanced gripping of small diameter objects or prey items.
Forelimb and hindlimb lengths.
Relative fore- and hindlimb lengths of some extant arboreal taxa are significantly longer when compared to their terrestrial counterparts (Table S1). Much of this elongation is from the stylopodial bone, resulting in a reduced BI and CI, to create a long limb that effectively folds the stylopodium and zeugopodium together. Yet non-arboreal cursors and specialist jumpers also show significant hindlimb elongation but with elongated zeugopodial and metapodial bones. The purported “arboreal” theropods, Microraptor, Anchiornis and Epidendrosaurus, have significantly increased fore- and hindlimb indices when compared to other non-avian theropods (uneven t-test tforelimb = −10.971, P(α = 0.05)<0.0001, hindlimb = −3.4059, P = 0.005). This may be partly due to the small body size of these taxa as within theropods there is a strong negative correlation between trunk length and limb length (Dececchi and Larsson unpublished data). However, their elongate limbs are largely due to their elongated zeugopodial and metapodial bones, suggesting a rather cursorial mode of locomotion.
The bird dataset indicates that total leg length was significantly longer in GB birds, with C and A birds having the lowest scores. Within theropods, Microraptor, Anchiornis and Archaeopteryx show scores more similar to GB birds than any other avian category (Figure 3A). The purported “arboreal” theropods have values greater than 120% the non-avian theropod average, comparable to other small terrestrial theropods, and much larger than basal avians.
Data are plotted for (A) hindlimb, (B) tibial, (C) tarsometarsus, and (D) pedal phalangeal indices for non-avian theropods and basal and extant birds. To reduce allometric influences, only non-avian theropod taxa less than 111 kg (mass of the largest bird in the sample) are plotted for all indexes except PPI. Outliers 1.5 times the standard deviation above or below the box are denoted by a circle, those 3 times by a star. Note the only taxon more than three times is the Chimney Swift for PPI. Note that Microraptor and Archaeopteryx are within the range of ground based and ground foraging birds. [planned for single column width].
Brachial index (BI).
Increased levels of arboreality are associated with decreased BI values ,  i.e. relatively longer zeugopodial elements in the forelimb. Microraptorines have significantly larger BI values compared to non-avian theropods (unequal variance t-test t = −4.4725, P = (same)<0.0001) (Figure 3A). Theropods increase their BI values along the lineage toward Aves, most notably within maniraptorans (Table S8, S14). Within Theropoda, there is an allometric scaling component to this signal, although the preponderance of reduced forelimbs in some of the largest taxa (tyrannosaurids and abelisaurids) could be influencing this.
Crural index (CI).
CI elongation, i.e. relatively longer zeugopodial elements of the hindlimb, often corresponds to increased cursoriality or leaping in extant clades , . Microraptorines have significantly increased CI values compared to other non-avian theropods (unequal variance t-test = −6.2351, P<0.0001). Within theropods, CI is strongly correlated to femur length (Figure S12). The low CI of Epidendrosaurus may be due to its hatchling age because crural ratios increase during ontogeny in extant avians ,  and other theropods . It should be noted that the sister taxon to Epidendrosaurus, Epidexipteryx (CI = 1.24), a nearly mature individual , does not show a similar reduction in CI. There is a general increase in CI throughout the evolution of non-avian theropods toward Aves (Table S9, S14), although this may be linked to decreased body sizes in advanced maniraptorans.
Ground based birds showed the highest tibial and tarsometatarsal index values, significantly higher than either climbing or arboreal feeders (Figure 3A, B). Similarly, Microraptor, Anchiornis and Archaeopteryx have high levels of relative elongation in these bones, larger than similar sized non-avian theropods, with levels of metatarsal elongation similar to cursorial taxa such as tyrannosaurs, ornithomimids, and Caudipteryx. Basal birds more advanced than Archaeopteryx have reduced tibial and tarsometatarsal index values compared to non-avian theropods and Archaeopteryx.
Manual phalangeal index (MPI).
Claw and grip-based climbing taxa tend to have enlarged MPI values , . Microraptorines have significantly lower indices of approximately 1.0 (t = 8.7188, P<0.0001) compared to a mean non-avian theropod value of 1.45. The ratio of the penultimate to proximal phalanx lengths gives a similar result, with microraptorines having significantly smaller values (unequal. var. t = 2.7862, P = 0.017) and Archaeopteryx not significantly different than the non-avian theropod mean (unequal. var. t = 0.081254, P = 0.94). There is no significant correlation between metacarpal length and manual MPI in theropods (r = 0.16242, n = 69 P(uncorrelated) = 0.18241). Phylogenetic reconstructions of the evolution of this value toward birds indicated the general gripping manus present in non-avian basal coelurosaurs is not enhanced in purported “arboreal” taxa; in fact, microraptorine dromaeosaurs and the earliest birds show a trend of reduced grasping ability relative to other theropods (Table S12, S14). Although these results are based on the central digital ray, as in previous analyses , using digit III, which in all maniraptorans is extremely gracile compared to digit II, yielded similar results. Microraptor has the second lowest MPI of all non-avian theropods, and it's penultimate to other phalanges ratio is the lowest of any deinonychosaurs (Table S12). Archaeopteryx had a similarly low MPI, but a relatively high penultimate phalangeal ratio, that is comparable to the cursorial ornithomimids. These values for putative arboreal non-avian theropods are directly contrary to what is expected for a grip- or claw-based climber, which have enlarged MPIs to aid in branch grasping.
Pedal phalangeal index (PPI).
The PPI shows a pattern similar to the manus. Although Anchiornis ( = 1.67) and Archaeopteryx ( = 1.54–1.79) are well above the non-avian theropod average (1.44), the majority of microraptorine specimens are below, with only one exception (Figure 3D, Table S13). The values of Anchiornis and Archaeopteryx are not exceptional with values similar to unquestioned terrestrial taxa, such as Coelophysis ( = 1.58), Huaxignathus ( = 1.70) and Procompsognathus ( = 1.59). Microraptorines have PPI values that are identical to terrestrial non-avian theropods (mean = 1.36, unequal variance t-test, t = −0.05196, P = 0.96) but significantly smaller than basal avians (t = 4.3525, P = 0.002). Unlike in the manus, PPI has a positive correlation with pes length (r = −0.537, P(uncorrelated)<0.001, n = 57) and Epidendrosaurus has a slightly smaller than expected phalangeal index.
Within extant avians, there is a clear separation between terrestrial and arboreal taxa  with arboreal taxa and climbing birds having significantly larger PPI values than either ground based or ground foragers (un-equal variance t-test A/GB = 9.7524, C/Gb = 10.623, G/C = 6.615, P<0.0001, G/A = 3.8172, P = 0.0003). Comparison of the purported “arboreal” theropods to extant birds shows that theropods have a PPI below that expected for arboreal taxa, even after accounting for allometry. Putative “arboreal” non-avian paravians have PI values similar to those expected for terrestrial avians of similar body size (Figure 3D).
Although the shoulder joint of non-avian paravians has a laterally facing glenoid, this articulation still restricted the humerus to motions beneath the horizontal plane, unlike the full dorsal extension possible in extant birds for flapping flight , ,  and arboreal mammals . Pronation and supination of the forelimb gives greater freedom of movement and allows animals to grip and manipulate small objects. Although the ability to freely pronate and supinate is not restricted to arboreal taxa, its presence allows climbers to utilize branches regardless of their orientation , . No theropods can freely pronate or supinate their forelimb, because of the absence of a “radial notch” in the distal contact surface of the ulna and a circular “roller” shape for the distal radius , ). These morphologies restrict the manus to a medially facing neutral position . Within advanced maniraptorans, there is a degree of pronation-supination between the carpals and the radius , yet this is not “active” because this motion is associated with wrist extension , . These restrictive movements of the shoulder, elbow, and wrist would limit the climbing ability of non-avian theropods.
Femoral abductive abilities are critical for all arboreal, limbed tetrapods because of the requirements of a large range of motion to select and secure holds, and to reduce the distance between the centre of mass and climbing substrate on small diameter or non-horizontal surfaces . The dinosaurian acetabulum is restricted to an erect stance, verses the semi-sprawling quadrupedal gait of basal archosaurs, with a well-defined supra-acetabular crest that would have limited femoral abduction , . The maximal range of hip motion in non-avian theropods is estimated to have been similar to that of extant birds, whose soft tissues further restrict abductive motion, such that most femoral mediolateral movement is done via rotation along the bone's long axis . It is important to note that the hips of Microraptor are not significantly different from other theropods with regard to osteological inhibitors of leg abduction and estimated size of leg abductor muscle ,  (pers. obs.). In addition, the basal troodontid Anchiornis huxleyi, the oldest deinonychosaur , , has a distinct and well formed supra-acetabular crest , : see fig. S4 therein). A similar crest is present on the well preserved ilium of Microraptor zhaoianus (Chinese Academy of Geological Sciences, CAGS 20-8-001) ) and the well preserved ilium of the London specimen of Archaeopteryx lithographica (British Museum of Natural History, NMH 37001) (Figure S11). The presence of this crest would restrict femoral abductive capability preventing the “splayed” posture typically seen in “four-winged” theropod reconstructions. Despite this osteological restriction, we reran our PCO analyses with scores for non-avian paravian theropods with more mobility in the hips (scoring them as 1, similar to the house cat) to account for different interpretations of this crest. This permutation does not significantly alter the results (Figure S6, S7).
Microraptorines and scansoriopterigids do not have pedal claw curvature values within the range of extant climbing birds, but are more similar to ground-based foragers (e.g. pigeon) . This contradicts previous work on these taxa , , which relied on the claw curvature data from Feduccia . Feduccia's dataset is unreliable, in part because “[b]irds with unusual adaptations - such as raptors, long-legged marsh birds, long-legged birds (for example, seriamas) that roost and nest low in bushes or trees, birds that resemble Archaeopteryx, and so forth - were avoided to eliminate as much as possible birds with claws adapted for strange habits or perceived to be generally convergent with those of Archaeopteryx for whatever reason.”  pg. 790. The exclusion of morphologically convergent taxa eliminates extant behavioural analogues.
Additionally, predatory bird claw geometry is indistinguishable from that of either perchers or climbers  and their inclusion would have significantly diminished Feduccia's categorization of Archaeopteryx as arboreal. Glen and Bennet's  data encompasses a broader range of bird ecomorphologies/behaviours and limit claw morphometrics to only the dorsal arch of the ungual rather than including the variable and rarely preserved ventral arch and joint of the toe pad (that were included by Feduccia , see  for a discussion). Recently, Manning and colleagues  suggested that dromaeosaur claws were capable of climbing based on finite element analysis of a Velociraptor manual claw. Besides our reservations of the use of only manual unguals, the extant “climbing” species used for comparison was the Eagle Owl (Bubo bubo), a raptorial bird which uses its claws for prey capture, not climbing . Birn-Jeffery and Rayfield  compared pedal claws of dromaeosaurs and trunk climbing birds and found no similarities in design or function. Manual claws of theropods are rarely used in analyses of locomotor function because their primary use is assumed to have been prey capture, and resemble the claws of raptorial birds. Highly recurved manual claws are found in a number of large bodied, undoubtedly terrestrial theropods, including, but not limited to, spinosauroids , , allosauroids . therizinosaurs , , and oviraptorids .
Mobility in multiple planes in the ankle joint is critical for arboreal locomotion in extant organisms , , . All theropods have a mesotarsal ankle joint inherited from their ornithodiran ancestors, which consists of a simple, transversely oriented hinge with movement restricted to the anteroposterior plane . This architecture makes an efficient running joint  but is highly ineffective for arboreal locomotion because it limits the mediolateral movement required on the complex surfaces of the arboreal canopy and precludes the hind foot rotation required for head-first descent.
Requirements for arboreal locomotion
Extant quadrupedal climbers and scansors show modifications to minimize the energy expended during ascent, movement on and between branches and, most critically, descent , . The ability to reverse the hindlimb and descend head first is a signature trait of arboreal specialists , . In descending head first, the animal gains the ability to accurately gauge and modify the speed and location of its descent , . Additionally the ability to freely pronate and supinate the forelimb ,  and highly recurved pedal claws to ensure interlocking with the substrate ,  are necessary to secure a purchase in the complex three-dimensional environment of the canopy. Other characters, such as highly mobile joints (especially the hips and shoulder) and reduction of crural and brachial indices, allowing the centre of mass to be brought closer to the substrate ,  [and references therein] evolved in multiple lineages of advanced climbers and scansors , , , . A notable exception are the brachiating primates, whose locomotion is grip-based and unique among arboreal specialists. Paravian taxa also had long manual feathers that would not have permitted trunk hugging , as observed in some modern non-arboreal specialists such as bears and viverids , . Thus non-avian theropods would have been unable to descend using either head or tail first methods, a necessary function in any pre-gliding non-avian taxa.
All non-avian theropods lack the level of flexibility in the hindlimbs, especially the ankle joint, present in advanced climbers. Without the ability to rotate their ankles or even to slightly invert them, non-avian theropods would not have been able to grip branches with their hindfeet except when standing orthogonal to it. All non-avian theropods, and the first bird Archaeopteryx, lack a reversed hallux . A reversed hallux has been argued for the London specimen of Archaeopteryx, but this state is the result of disarticulation  (pers. obs.). A definitive, reversed hallux first appeared in the basal avian Sapeornis , is present in many other Cretaceous birds , and is crucial for arboreal locomotion in extant birds ,  because they cannot rotate their ankles. In addition, the hallucal ungual is often hypertrophied to maximize the digital distance angle and adductive forces applied by the foot, which combined with reduced hindlimb length, minimize energy expenditures while climbing , .
The presence of long feathers on the tibia and tarsus of non-avian paravians has been cited as evidence for a four winged gliding origin of flight and an arboreal stage in avian evolution , . It has been argued these feathers would have interfered with terrestrial locomotion which would have induced feather damage . This argument fails to account for the fact that even if Microraptor was an arboreal animal it would have to move within the branches (either as a biped or a quadruped), thus engendering the same degree of damage as in a terrestrial setting. Thus any argument that the hindlimb feathers would reduce locomotory ability are equally applicable to a terrestrial or an arboreal context. In addition any crouching posture, as seen in theropods at rest  or would occur during climbing , would be hampered by such long feathers.
Extant avian and mammalian climbers reduce the distance between their centre of gravity and the substrate by crouching , , . In this position, the metatarsal feathers of non-avian paravians (some over twice the length of the metatarsus ) would be in constant contact with the surface and at risk of being damaged and interfering with arboreal locomotion if the metatarsus was held at any angle less than upright. In climbing animals an upright distal limb segment is not seen during climbing as it raises the centre of mass away from the substrate (the vertical trunk or along sub horizontal thin branches) and increasing the effort during climbing and the rotational forces during branch walking which leads to increased likelihood of falling . This would be particularly acute in non-avian theropod like Microraptor, given the lack of a reversed hallux to aid in securing a purchase , . Conversely, within extant birds, increased running speed is associated with an increasingly upright stance , . The most cursorial of ratites exhibit a highly extended metatarsus with the distal segment at low angles only when raised during the stride . This mechanical behaviour suggests that the simplest way to ensure that feather damage and locomotory interference is reduced is, paradoxically, to be highly cursorial, which agrees with both the limb proportions and relative leg lengths seen in basal deinonychosaurs , Dececchi and Larsson, unpublished data.
A terrestrial ecology of avian antecedents suggests the flight stroke evolved on the ground. The origin of powered flight is a more difficult question to address (see Introduction). WAIR behaviour has been documented in at least twenty species of extant birds, including both paleognath and neognaths , including their non-volant chicks. This behaviour has been presented as a potential evolutionary narrative for the development of the complex biomechanics that underlie the avian flight stroke with a terrestrial based bird antecedent . WAIR alone cannot be invoked to shore up the trees-down hypothesis because it would only allow limited access to low branches (~5 m ) and does not facilitate movement within or between trees. WAIR also requires a full and powerful flight stroke, with wing force estimates in chukars of up to 220% of body mass and induced velocities comparable to flight . Without modifications to aid in-tree mobility (to permit, for example, prey capture) trees could remain no more than an occasional refuge for non-volant paravians. Although WAIR has been recorded in the Tinamou and some neognaths, the origin of crown Aves (Neornithes) is estimated at approximately 86.5 MYA, using fossils , and 130 MYA, using molecular dating . These dates are minimally 30 million years after the origin of birds . Advanced ornithurans, which have musculoskeletal morphologies indicative of powerful flight comparable to extant birds , ,  occur at least 50 million years before the oldest known neornithine , . This gap indicates a fully developed flight stroke is plesiomorphic for neornithines. Because WAIR is a behavioural trait without osteological specializations, the phylogenetic placement of the flight stroke before the divergence of Neornithes makes it impossible to determine if WAIR is ancestral to the avian flight stroke or derived from it. WAIR is a terrestrial based behaviour to aid in steep incline running and potentially an important step in avian evolution. Yet the uncertainty around its optimization along with its inability to aid with movement along thin diameter substrates (i.e. branches) make WAIR in and of itself insufficient to compensate for the lack of arboreal adaptations seen in non-avian theropods.
Are Tree Kangaroos good analogues for bird antecedents?
Chatterjee and Templin ,  suggested non-avian theropods need not show significant anatomical changes to be arboreal, citing the tree kangaroo (Dendrolagus) as an extant analog, because “adaptation[s are] not apparent in the skeletal features of these animals except for the recurved pedal claws” ( pg.165). This comparison fails on multiple fronts: first tree kangaroos are bipedal on the ground and quadrupedal in the trees ; second, tree kangaroos are highly modified from their terrestrial counterparts , ; and they are herbivorous with few natural predators . Moreover, tree kangaroos do have apparent skeletal differences from there more terrestrial conterparts. Tree kangaroos have a modified calcaneocuboid joint to accommodate increased mediolateral rotation of the ankle –, reduced curial indices (between 80%–55% those of terrestrial kangaroos) and hindlimb lengths , and increased forelimb and axial column flexibility, most notably via highly mobile shoulder and wrist joints , . Arboreal adaptations of Dendrolagus follow similar trends to other arboreal mammals , , ,  and in this analysis clearly distinguish them from their terrestrial counterparts (Figure 1, 2, S1, S2, S3, S4, S5, S6, S7). The folivorous diet and lack of arboreal predators of Dendrolagus might not have supplied adaptive pressures strong enough to evolve the specialized branch-walking or climbing adaptations present in related marsupial predators , . Paravian theropods and most basal birds included in our analysis, in addition to being small , were active hunters and would thus require a more extensive range of morphological adaptations to inhabit the canopy.
Analysis of discrete skeletal characters throughout the body indicates all non-avian theropods examined here have little to no similarity with modern arboreal taxa, regardless if they employ a mammal-like or bird-like locomotion within the branches. Clustering analyses groups all non-avian theropods and Archaeopteryx with terrestrial taxa with a large separation between non-avian theropods and even the more cursorial mammalian scansors (Figure 1, 2, S1, S2, S3, S4, S5, S6, S7). This pattern is repeated using bird specific traits with non-avian theropods clustering closest to ground based birds and far from perching or climbing taxa. Analysis of the hindlimb, as well as the brachial, crural, manual and pedal phalangeal indices all demonstrate none of the expected deviations from the general non-avian theropod condition in putatively “arboreal” non-avian theropods (Figure 3). This lack of change presents no evidence that the undisputed terrestrial locomotion of early theropods was modified for scansorial or arboreal modes of locomotion within non-avian paravians. Nearly all limb metrics have opposing evolutionary trends from what is expected in a clade evolving towards a highly arboreal lifestyle. Unlike non-avian theropods and Archaeopteryx, other early Mesozoic birds cluster with perching birds and have limb indices and hindfoot adaptations that suggest they were adept at perching in trees .
Our results find no anatomical evidence for a scansorial behaviour for non-avian paravians and Archaeopteryx. Instead, these taxa group well with highly cursorial mammals and birds, such as dogs and the ostrich, respectively. Non-avian paravians do not even share the scansorial morphologies of even the least scansorial of mammals, such as the housecat. Although housecats do climb, they have little affinity for movement within the canopy and have particular problems with descent  (pers. obs.). If we only look to avian taxa, Microraptor and Archaeopteryx are morphologically between ratites and galliforms, two avian clades that are definitively ground dwelling. Our results indicate that non-avian, paravian theropods and Archaeopteryx did not have adaptations for quadrupedal nor bipedal arboreal climbing, branch-walking, nor descent. The classic protoavis caricature of Heilmann  or trunk-clinging dromaeosaurs of Chatterjee  and Chatterjee and Templin  can be dismissed.
The oldest known birds with definitive arboreal adaptations lived approximately125 million years ago . The five Cretaceous birds included here all cluster well with the the morphologies of extant generalist, ground foraging birds, such as corvids. In Early Cretaceous times, the trees were full of arboreal mammals and reptiles , , , ,  and probably offered some resistance to a novel arboreal clade. No non-avian theropod had the morphological adaptations present in these extinct or extant arboreal taxa. We find no support for arboreality as an ecological strategy of theropods and, therefore, no evidence for the trees down scenario for the origin of the flight stroke in birds. Our results suggest that the ecological setting for the origin of traits required for powered flight, such as the flight stroke, flight feathers, and small body size, is terrestrial.
A terrestrial origin of birds may differentiate them from the other two known flying vertebrate clades. Bats had arboreal, gliding antecedents  and pterosaurs, whose origins are unknown , are suspected to have also been arboreal gliders , . These alternative ecological pathways may have influenced the evolution of their aerofoils (feathers versus skin membranes), which has implications for wing kinematics, aerodynamics, and body size constraints , . Thus, the differences between how birds and bats fly may be linked to the ecological setting of their evolutionary origins.
Cluster analysis of total data set. A) Correlation setting (score 0.8403). B) Euclidean setting (0.7918). Colour coding: Black = theropods, Light Blue = arboreal birds, Blue –green = Fossil arboreal taxa, Dark Blue = basal birds, Brown = lizards, Gold = ground birds, Green = arboreal mammals and the chameleon, Grey = Climbing birds, Khaki = ground based birds, Pink = Archaeopteryx, Purple = birds of prey, Red = terrestrial mammals, Yellow = scansorial mammals.
Cluster analysis of hindlimb and tail characters from total data set. A) Correlation setting (score 0.8471) B) Euclidean (score 0.824). Colour coding: Black = theropods, Light Blue = arboreal birds, Blue –green = Fossil arboreal taxa, Dark Blue = basal birds, Brown = lizards, Gold = ground birds, Green = arboreal mammals and the chameleon, Grey = Climbing birds, Khaki = ground based birds, Pink = Archaeopteryx, Purple = birds of prey, Red = terrestrial mammals, Yellow = scansorial mammals.
Cluster analysis of characters from quadrupedal data set. A) Correlation setting (score 0.7939) B) Euclidean (score 0.8215). Colour coding: Black = theropods, Light blue = Fossil arboreal taxa, Brown = lizards, Green = arboreal mammals and the chameleon, Pink = Archaeopteryx, Red = terrestrial mammals, Yellow = scansorial mammals.
Cluster analysis of hindlimb and tail characters from quadrupedal data set. A) Correlation setting (score 0.8116) B) Euclidean (score 0.8317). Colour coding: Black = theropods, Light blue = Fossil arboreal taxa, Brown = lizards, Green = arboreal mammals and the chameleon, Pink = Archaeopteryx, Red = terrestrial mammals, Yellow = scansorial mammals.
Correlation box plots for PCO 1. A) all qudrupedial B) qudrupedial hindlimb only and C) Avian only datasets. In A) and B) stars denote the two chameleon data points while fossil climbers are denoted by (‡).
PCO total data set with paravian hips scored as 1 (moderately flexible). A) Correlation setting B) Euclidean setting. Colour coding: Black = theropods, Light Blue = arboreal birds, Blue –green = Fossil arboreal taxa, Dark Blue = basal birds, Brown = lizards, Gold = ground birds, Green = arboreal mammals and the chameleon, Grey = Climbing birds, Khaki = ground based birds, Pink = Archaeopteryx, Purple = birds of prey, Red = terrestrial mammals, Yellow = scansorial mammals.
Cluster analysis of total dataset with paravian hips set at 1 (moderately flexible). (A) Correlation setting (score 0.8358) B) Euclidean setting (0.7832). Colour coding: Black = theropods, Light Blue = arboreal birds, Blue –green = Fossil arboreal taxa, Dark Blue = basal birds, Brown = lizards, Gold = ground birds, Green = arboreal mammals and the chameleon, Grey = Climbing birds, Khaki = ground based birds, Pink = Archaeopteryx, Purple = birds of prey, Red = terrestrial mammals, Yellow = scansorial mammals.
Cluster analysis of avian only data set. A) Correlation setting (score 0.8478) B) Euclidean setting (0.8547). Colour coding: Black = theropods, Light Blue = arboreal birds, Dark Blue = basal birds, Gold = ground birds, Grey = Climbing birds, Khaki = ground based birds, Pink = Archaeopteryx, Purple = birds of prey.
PCO of quadrupedal data set using only forelimb characters. A) correlation setting B) Euclidean (score 0.8317). Colour coding: Black = theropods, Light blue = Fossil arboreal taxa, Brown = lizards, Green = arboreal mammals and the chameleon, Pink = Archaeopteryx, Red = terrestrial mammals, Yellow = scansorial mammals.
Cluster analysis of quadrupedal data set using forelimb only characters. A) Correlation setting (score 0.7169) B) Euclidean (score 0.7843). Colour coding: Black = theropods, Light blue = Fossil arboreal taxa, Brown = lizards, Green = arboreal mammals and the chameleon, Pink = Archaeopteryx, Red = terrestrial mammals, Yellow = scansorial mammals.
The right ilium in lateral aspect of the London specimen of Archaeopteryx lithographica (BMNH 37001). Note the presence of a well developed supra acetabulum crest (sac), contra .
Bivariate plots of metrics used to measure functional morphologies. “Terrestrial” theropods (filled circles), microrpatorines (x's), Archaeopteryx (open squares), avian theropods (crosses), and Scansoriopterygidae (open circles). A) Relative forelimb length (humerus+ulna) to trunk length. LogFL = −0.6642 LogTrunk (+/−0.063783)+2.2913(+/−0.15463), r = −0.76487, P(uncorrelated)<0.001, N = 47. B) Relative hindlimb length to trunk length. LogTL = −0.4968 LogTrunk (+/−0.061771)+2.2919(+/−0.15153), r = −0.52284, P(uncorrelated) = 0.001, N = 49. C) BI regressed against humeral length. LogBI = −0.36873 LogHumerus (+/−0.035123)+1.5559(+/−0.071713), r = −0.48769, P(uncorrelated)<0.001, N = 86. D) CI regressed against log femoral length. LogCI = −0.34557 LogFemur (+/−0.022899)+1.9191(+/−0.052394), r = −0.74601, P(uncorrelated)<0.001, N = 103. E) Manual PI regressed against log metacarpal length. LogPI = −0.7549 LogMetacarpal (+/−0.091001)+0.11887(+/−0.15101), r = −0.16242, P(uncorrelated) = 0.18241, N = 69. F) Pedal PI regressed against log pes length. LogPI = −0.44659 LogPes (+/−0.049735)+2.2501(+/−0.090887), r = −0.5638, P(uncorrelated)<0.001, N = 57.
Boxplots comparing within non-avian theropods and basal birds under hindlimb, tibial, and metatarsal indices.
Cluster analysis of total data. A = Arboreal, A fossil = extinct fossil taxa, An = ankle mobility (0 = anterioposterior only, 1 = moderate movement in all 3 planes, 2 = highly mobile),BB = basal bird, BOP = bird of prey, C = climbing bird, CI = Crural index, C = Claw geometry (0 = straight, 1 = recurved, 2 = highly recurved), Fl = relative forelimb length (Humerus+Ulna/trunk), G = ground forager, GB = ground based, Hal = Hallux orientation (0 = in line with other digits, 1 = divergent, 2 = opposable, 3 = zygodactyl), HFR = Hindfoot reversal (0 = no, 1 = yes), Hip = femoral abduction ability (0 = low, little to no abduction occurs, 1 = moderate, limited abduction ability during locomotion, 2 = highly mobile), HL = relative hindlimb length (femur+tibia/trunk), H/U = Humerus divided by ulna, MPI = Manual phalangeal index(non-ungual phalanges/metacarpal), PPI = Pedal phalangeal index (non-ungual phalanges/metatarsals, in theropods PhIII 2+3/Ph III-1), Pol = Pollex orientation(0 = inline, 1 = capable of securing item with a “scissor grip”, 2 = opposable), Pro = forearm pronation/supination (0 = none, 1 = yes), Scan = Scansorial, SH = Shoulder (humerus-glenoid joint mobility) (0 = limited to anterioposterior movement, 1 = moderate movement in all 3 planes, 2 = highly mobile even cricumduction), ST = Stance (0 = plantigrade, 1 = sub ungaligrade, 2 = digigrade), Terr = Terrestrial, Tail = tail prehensile/support ability (0 = none, 1 = yes). For all extant avians and Sinornis, Confuciusornis and Pengornis, given the horizontal position of the femora CI index was taken as the tarsometatarsus/tibia.
Cluster analysis of bird data. A = arboreal forager, BB = basal birds, Bop = bird of prey, C = climbing birds, Claw = Claw geometry (0 = straight, 1 = recurved, 2 = highly recurved), G = ground forager, GB = ground based, Hallux (hallux 0 = non reversed, 1 = reversed but raised, 2 = reversed), Leg L = relative leg length (F+T+Tmt/mass∧0.33), PPI = Pedal phalangeal index (Ph II+III/PhI), TF = tail feathers show adaption for weight supporting adaptation (0 = absent, present = 1), TL = relative tibia length, TMTL = relative tarsometatarsal length, Zy = zygodactyls = (0 = absent, 1 = present).
PCO loadings for first 3 axes for total dataset. Percentage of variance explained by the first three axes for Euclidean setting: 39.0, 23.9 and 10.3%. For Correlation setting: 35.3, 16.7 and 7.4%. All other axes explain less than 5% of the variance.
PCO loadings for first 3 axes for total dataset using hindlimb characters only. Percentage of variance explained by the first three axes for Euclidean setting: 42.6, 25.3 and 12.6%. For Correlation setting: 40.5, 18.0 and 8.0%. All other axes explain less than 5% of the variance.
PCO loadings for first axes for the quadrupedal only dataset. Percentage of variance explained by the first four axes for Euclidean setting: 47.2, 16.9, 10.2 and 5.2% For Correlation setting the first three axes explained: 39.0, 16.1 and 4.9%. All other axes explain less than 5% of the variance.
PCO loadings for first 3 axes for the quadrupedal only dataset using hindlimb characters only. Percentage of variance explained by the first four axes for Euclidean setting: 50.7, 16.7, 10.5 and 6.4% For Correlation setting the first three axes explained: 47.5, 14.9 and 5.3%. All other axes explain less than 5% of the variance.
PCO loadings for first 3 axes for bipedal (avian) only dataset. Percentage of variance explained by the first three axes for Euclidean setting: 68.0, 14.1 and 7.9%. For Correlation setting: 60.4, 10.5 and 6.7%. All other axes explain less than 5% of the variance.
Forelimb measurements and BI for theropods and basal birds.
Hindlimb measurements and CI for theropods and basal birds.
Bird hindlimb lengths and relative length scores. M = mass, F = femur length, T = tibia length, TMT = tarsometatarsus length, Leg L = leg length (F+T+TMT), Rleg L = (F+T+TMT)/M0.33, TL = T/M0.33, RTL = TL/Avg, TMTL = TMT/M0.33, R TMTL = TMTL/Avg.
Theropod hindlimb lengths and relative length scores. Est C = mass estimate based on femoral circumference from Christiansen and Farina 2004, Est L = estimate based on femoral length from Christiansen and Farina 2004, M = mass used in kg, F = femur length, T = tibia length, Mt = metatarsus length, Leg L = leg length (F+T+Mt), Rleg L = (F+T+TMT)/M0.33, TL = T/M0.33, RTL = TL/Avg, TMTL = TMT/M0.33, R TMTL = TMTL/Avg.
Manual phalangeal indices of non-avian theropods and early avians. A) Digit II B) Digit III.
Pedal phalangeal indices of non-avian theropods and early avians.
Phylogenetic nodal reconstructions across Theropoda into basal birds.
References cited in all supplementary information.
We would like to thank the critical reading of earlier versions of this manuscript by E. Bamforth, L. Harrison, E. Maxwell, K. Padian, and several anonymous reviewers. This work benefited from numerous discussions with R. Carroll, D. Evans, J. Müller and N. Campione. We would also like to thank A. Balanoff, P. Currie, K. Peyer, C. Sullivan, X. Xu and Z. Zhou for providing measurements and the American Museum of Natural History, British Museum of Natural History, Canadian Museum of Nature, Royal Ontario Museum, Royal Tyrrell Museum of Palaeontology, Institute of Vertebrate Paleontology and Paleoanthropology, and Museum für Naturkunde for access to specimens.
Conceived and designed the experiments: HL TAD. Performed the experiments: HL TAD. Analyzed the data: HL TAD. Contributed reagents/materials/analysis tools: HL TAD. Wrote the paper: HL TAD.
- 1. Simpson GG (1944) Tempo and Mode in Evolution. pp. 1–227.
- 2. Chiappe L,Padian K (1998) The origin and early evolution of birds. Biological Review 73: 1–42.
- 3. Huxley TH (1868) On the animals which are most nearly intermediate between birds and reptiles. Geological Magazine 5: 357–365.
- 4. Ostrom JH (1973) Origin of birds. Nature 242: 136.
- 5. Chiappe LM,Dyke GJ (2006) The Early Evolutionary History of Birds. Journal of the Paleontological Society of Korea 22: 133–151.
- 6. Prum RO (2002) Why ornithologists should care about the theropod origin of birds. Auk 119: 1–17.
- 7. Sereno PC (1997) The origin and evolution of dinosaurs. Annual Review of Earth and Planetary Science 25: 435–489.
- 8. Dudley R,Byrnes G,Yanoviak SP,Borrell B,Brown RM,et al. (2007) Gliding and the Functional Origins of Flight: Biomechanical Novelty or Necessity? Annual Review of Ecology, Evolution, and Systematics 38: 179–201.
- 9. Alexander DE,Gong E,Martin LD,Burnham D A,Falk A R (2010) Model tests of gliding with different hindwing configurations in the four-winged dromaeosaurid Microraptor gui. Proceedings of the National Academy of Sciences 1–5.
- 10. Chiappe LM,Burgers P (1999) The wing of Archaeopteryx as a primary thrust generator. Nature 399: 60–62.
- 11. Dial KP (2003) Wing-assisted incline running and the evolution of flight. Science 299: 402–4.
- 12. Norberg UM (1985) Evolution of Vertebrate Flight: An Aerodynamic Model for the Transition from Gliding to active Flight. The American Naturalist 126: 303–327.
- 13. Chatterjee S,Templin RJ (2007) Biplane wing planform and flight performance of the feathered dinosaur Microraptor gui. Proceedings of the National Academy of Sciences of the United States of America 104: 1576–80.
- 14. Chatterjee S,Templin RJ (2004) Feathered coelurosaurs from China: new light on the arboreal origin of avian flight. In: Currie PJ,Koppelhaus MA,Shugar MA,L WJ, editors. Feathered Dragons. Studies on the Transition from Dinosaurs to Birds. Indiana University Press. pp. 251–281.
- 15. Xu X,Zhou Z,Xiaolin W (2000) The smallest known non-avian theropod dinosaur. Nature 408: 705–708.
- 16. Xu X,Zhou Z,Wang X,Zhang F (2003) Four-winged dinosaurs from China. Nature 421: 335–340.
- 17. Zhang F,Zhou Z,Xu X,Wang X (2002) A juvenile coelurosaurian theropod from China indicates arboreal habits. Naturwissenschaften 89: 394–398. doi:10.1007/s00114-002-0353-8.
- 18. Glen CL,Bennett MB (2007) Foraging modes of Mesozoic birds and non-avian theropods. Current biology 17: R911–2.
- 19. Middleton KM (2001) The morphological basis of hallucal orientation in extant birds. J Morphol 250: 51–60.
- 20. Mayr G,Pohl B,Hartman S,Peters DS (2007) The tenth skeletal specimen of Archaeopteryx. Zoological Journal of the Linnean Society 149: 97–116.
- 21. Mayr G,Peters DS (2007) The foot of Archaeopteryx: Response to Feduccia et al. 2007. Auk 124: 1450–1452.
- 22. Padian K (2001) Stages in the origin of bird flight: beyond the arboreal-cursorial dichotomy. In: Gauthier JA,Gall LF, editors. New Perspectives on the Origin and Early Evolution of Birds: Proceedings of the International Symposium in Honor of John H. Ostrom. Peabody Museum of Natural History. pp. 255–274.
- 23. Dial KP,Jackson BE,Segre P (2008) A fundamental avian wing-stroke provides a new perspective on the evolution of flight. Nature 451: 985–9.
- 24. Longrich N (2006) Structure and function of hindlimb feathers in. Paleobiology 32: 417–431.
- 25. Cartmill M (1985) Climbing. In: Hildebrand M,Bramble D,Liem KF,Wake DB, editors. Functional Vertebrate Morphology. Harvard University Press. pp. 73–88.
- 26. Zhang F,Zhou Z,Xu X,Wang X,Sullivan C (2008) A bizarre Jurassic maniraptoran from China with elongate ribbon-like feathers. Nature 455: 1105–8.
- 27. Hu D,Hou L,Zhang L,Xu X (2009) A pre-Archaeopteryx troodontid theropod from China with long feathers on the metatarsus. Nature 461: 640–3.
- 28. Meng J,Hu Y,Wang Y,Wang X,Li C (2006) A Mesozoic gliding mammal from northeastern China. Nature 444: 889–93.
- 29. Renesto S (1994) Megalancosaurus, a possibly arboreal archosauromorph (Reptilia) from the Upper Triassic of Northern Italy. Journal of Vertebrate Paleontology 14: 38–52.
- 30. Ji Q,Luo Z-X,Yuan C-X,Wible JR,Zhang J-P,et al. (2002) The earliest known eutherian mammal. Nature 416: 816–22.
- 31. Wang X,Kellner AW,Zhou Z,Campos DDA (2008) Discovery of a rare arboreal forest-dwelling flying reptile (Pterosauria, Pterodactyloidea) from China. Proceedings of the National Academy of Sciences of the United States of America 105: 1983–7.
- 32. Fröbisch J,Reisz RR (2009) The Late Permian herbivore Suminia and the early evolution of arboreality in terrestrial vertebrate ecosystems. Proceedings of the Royal Society B 276: 3611–8.
- 33. Dial KP,Greene E,Irschick DJ (2008) Allometry of behavior. Trends in ecology & evolution 23: 394–401.
- 34. Kirk EC,Lemelin P,Hamrick MW,Boyer DM,Bloch JI (2008) Intrinsic hand proportions of euarchontans and other mammals: implications for the locomotor behavior of plesiadapiforms. Journal of human evolution 55: 278–99.
- 35. Muzion C de,Argot C (2003) Comparative anatomy of the Tiupampa didelphimorphs; an approach to locomotry habits of early marsupials. In: Jones M,Dickman C,Archer M, editors. Predators with Pouches: The biology of carnivorous marsupials. Collingwood, VIC: CSIRO. pp. 43–63.
- 36. Polly D (2007) Limbs in Mammalian Evolution. In: Hall BK, editor. Fins into Limbs: Evolution, development and transformation. University of Chicago Press. pp. 245–269.
- 37. van Valkenburgh B (1985) Locomotor Diversity Within Past and Present guilds of Large Predatory Mammals. Paleobiology 11: 406–428.
- 38. van Valkenburgh B,Molnar RE (2002) Dinosaurian and mammalian predators compared. Paleobiology 28(4): 527–543.
- 39. Carpenter K (2002) Forelimb biomechanics of nonavian theropod dinosaurs in predation. Senckenbergiana lethaea 82: 59–76.
- 40. Carpenter K (1998) Evidence of predatory behaviour in carnivorous dinosaurs. Gaia 15: 135–144.
- 41. Farrow JO,Holtz TH (2002) The fossil record of predation in dinosaurs. Paleontological Society Papers 8: 251–265.
- 42. Iwaniuk AN,Pellis SM,Whishaw IQ (1999) The relationship between forelimb morphology and behaviour in North American carnivores (Carnivora). Can J Zool 77: 1064–1074.
- 43. Pike AVL,Maitland DP (2004) Scaling of bird claws. Journal of Zoology 262: 73–81.
- 44. Meachen-Samuels J,van Valkenburgh B (2009) Forelimb indicators of prey-size preference in Felidae. Journal of Morphology 270: 729–744.
- 45. Rose KD (1987) Climbing adaptations in the early Eocene mammal Chriacus and the origin of Artiodactyla. Science 236: 314–316.
- 46. Cartmill M,Lemlin P,Schmitt D (2002) Support polygons and symmetrical gaits in mammals. Zoological Journal of the Linnaean Society 136: 401–420.
- 47. Lemlin P,Schmitt D,Cartmill M (2003) Footfall pattern and interlimb co-ordination in opossums (Family Didelphidae): Evidence for the evolution of diagonal-sequence walking gaits in primates. Journal of Zoology 260: 423–429.
- 48. Blob RW,Biewener AA (2001) Mechanics of limb bone loading during terrestrial locomotion in the green iguana (Iguana iguana) and American alligator (Alligator mississippiensis). The Journal of experimental biology 204: 1099–122.
- 49. Russell AP,Bels V (2001) Biomechanics and kinematics of limb-based locomotion in lizards: Review, synthesis and prospectus. Comparative Biochemistry and Physiology Part A 131: 89–112.
- 50. Meiri S (2010) Length-weight allometries in lizards. Journal of Zoology 1–9.
- 51. Turner AH,Pol D,Clarke JA,Erickson GM,Norell MA (2007) A basal dromaeosaurid and size evolution preceding avian flight. Science 317: 1378–81.
- 52. Zani PA (2000) The comparative evolution of lizard claw and toe morphology and clinging performance. Journal of evolutionary biology 13: 316–325.
- 53. Elstrott J,Irschick DJ (2004) Evolutionary correlations among morphology, habitat use and clinging performance in Caribbean Anolis lizards. Biological Journal of the Linnean Society 389–398.
- 54. Russell AP,Higham TE (2009) A new angle on clinging in geckos: incline, not substrate, triggers the deployment of the adhesive system. Proceddings of the Royal Society B 276: 3705–9.
- 55. Pianka ER,Vitt LJ,Greene HW (2003) Lizards: Windows to the Evolution of Diversity. Berkeley: Univeristy of California Press. 346 p.
- 56. Fischer MS,Krause C,Lilje KE (2010) Evolution of chameleon locomotion, or how to become arboreal as a reptile. Zoology 113: 67–74.
- 57. Samuels JX,Valkenburgh BV (2008) Skeletal Indicators of Locomotor Adaptations in Living and Extinct Rodents. Journal of Morphology 269: 1387–1411. doi:10.1002/jmor.10662.
- 58. Gatesy SM (1991) Hind limb scaling in birds and other theropods: Implications for terrestrial locomotion. J Morphol 209: 83–96.
- 59. Farlow JO,Gatesy SM,Holtz TR,Hutchinson JR,Robinson JM (2000) Theropod Locomotion. American Zoologist 40: 640–663.
- 60. Hutchinson JR (2001) The evolution of pelvic osteology and soft tissues on the line to extant birds (Neornithes). Zool J Linn Soc 131: 123–168.
- 61. Norberg ,Ake R (1986) Treecreeper climbing; Mechanics, energetics and structural adaptaions. Ornis Scandinavica 17: 191–209.
- 62. Norberg UM (1979) Morphology of the wings, legs and tail of three coniferous forest tits, the goldcreast and the treecreeper in relation to locomotor pattern and feeding station selection. Philisophical Transaction of the Royal Society of London B 287: 131–165.
- 63. Hopson JA (2001) Ecomorphology of avian and nonavian theropod phalangeal proportions: Implications for the arboreal versus terrestrial origin of bird flight. In: Gauthier JA,Gall LF, editors. New Perspectives on the Origin and Early Evolution of Birds: Proceedings of the International Symposium in Honour of John H. Ostrom. Peabody Museum of Natural History. pp. 211–227.
- 64. Hammer Ø,Harper DAT,Ryan PD (2001) PAST : PAleontological STatistics software package for education and data analysis. Palaeontogia Electronica 4: 1–9.
- 65. Team RDC (2010) R: A Language and Environment for Statistical Computing. Available: http://www.r-project.org.
- 66. Sereno PC,Rao C (1992) Early evolution of avian flight and perching: new evidence from the lower cretaceous of china. Science 255: 845–8.
- 67. Zhou Z,Zhang F (2003) Anatomy of the primitive bird Sapeornis chaoyangensis from the Early Cretaceous of Liaoning, China. Canadian Journal of Earth Sciences 40: 731–747. doi:10.1139/E03-011.
- 68. Zhou Z,Zhang F (2002) A long-tailed, seed-eating bird from the Early Cretaceous of China. Nature 418: 405–409. doi:10.1038/nature00923.1.
- 69. Feeney S (1999) Comparative osteology, myology and locomotor specialization of the fore and hind limbs of the North American foxes Vulpes vulpes and Urocyon cineroargenteuse. Doctoral Dissertation, UMass Amherst.
- 70. Argot C (2002) Functional-Adaptive Analysis of the Hindlimb Anatomy of Extant Marsupials and the Paleobiology of the Paleocene Marsupials Maylestes ferox and Pucadelphys andinus. Journal of Morphology 253: 76–108. doi:10.1002/jmor.1114.
- 71. Callison G,Quimby HM (1984) Tiny Dinosaurs: Are they fully Grown? Journal of Vertebrate Paleontology 3(4): 200–209.
- 72. Bennett MB (2008) Post-hatching growth and development of the pectoral and pelvic limbs in the black noddy, Anous minutus. Comparative biochemistry and physiology. Part A, Molecular & integrative physiology 150: 159–68.
- 73. Kobayashi Y,Lü J (2003) A new ornithomimid dinosaur with gregarious habits from the Late Cretaceous of China. Acta Palaeontologica Polonica 48: 235–259.
- 74. Lemelin P (1999) Morphological correlates of substrate use in didelphid marsupials: implications for primate origins. Journal of Zoology 247: 165–175. doi:10.1017/S0952836999002046.
- 75. Heinrich R,Houde P (2006) Postcranial anatomy of Viveravus (Mammalia, Carnivora) and implications for substrate use in basal Carnivora. Journal of Vertebrate Paleontology 26: 422–435.
- 76. Hutchinson JR,Allen V (2009) The evolutionary continuum of limb function from early theropods to birds. Naturwissenschaften 96: 423–48.
- 77. Senter P (2006) Comparison of forelimb function between Deinonychus and Bambiraptor (Theropoda: Dromaeosauridae). Journal of Vertebrate Paleontology 26: 897–906.
- 78. Hutchinson JR,Gatesy SM (2000) Adductors, abductors, and the evolution of archosaur locomotion. Paleobiology 26: 734–751.
- 79. Hwang SH,Norell MA,Qiang JI,Keqin GAO (2002) New Specimens of Microraptor zhaoianus (Theropoda: Dromaeosauridae) from Northeastern China. American Museum Novitates 1–44.
- 80. Brougham J,Brusatte SL (2010) Distorted Microraptor specimen is not ideal for understanding the origin of avian flight. Proceedings of the National Academy of Sciences of the United States of America 107: E155.
- 81. Xu X,Zhao Q,Norell M,Sullivan C,Hone D,et al. (2009) A new feathered maniraptoran dinosaur fossil that fills a morphological gap in avian origin. Chinese Science Bulletin 54: 430–435.
- 82. Feduccia A (1993) Evidence from Claw Geometry Indicating Arboreal Habits of Archaeopteryx. Science 259: 790–793.
- 83. Manning PL,Margetts L,Johnson MR,Withers PJ,Sellers WI,et al. (2009) Biomechanics of dromaeosaurid dinosaur claws: application of X-ray microtomography, nanoindentation, and finite element analysis. Anatomical Record 292: 1397–405.
- 84. Bin-Jeffery A,Rayfield E (2009) Finite element analysis of pedal claws to determine mode of life in birds, lizards and maniraptoran theropods. Journal of Vertebrate Paleontology 29: 64 A.
- 85. Porfiri JD,Santos DDOS,Calvo JO (2007) New Information on Megaraptor Namunhuaiguii (Theropoda: Tetanurae), Patagonia: Arquivos do Museu Nacional, Rio de Janeiro 65: 545–550.
- 86. Sereno PC,Beck AL,Dutheil DB,Boubacar G,Larsson HCE,et al. (1998) A long-snouted predatory dinosaur from Africa and the evolution of Spinosaurids. Science 282: 1298–1302. doi:10.1126/science.282.5392.1298.
- 87. Azuma Y,Currie PJ (2000) A new carnosaur (Dinosauria: Theropoda) from the Lower Cretaceous of Japan. Canadian Journal of Earth Sciences 37: 1735–1753.
- 88. Perle S (1979) Segnosauridae-A new family of Theropoda from the Lower Cretaceous of Mongolia (In Russian). Transactions(Sestnaya Sovetsko-Mongol'skaya eskpeditsia, Trudy)ovm 45–55.
- 89. Zanno LE (2006) The pectoral girdle and forelimb of the primitive therizinosauroid Falcarius utahensis (Theropoda, maniraptora): Analyzing evolutionary trends within Therizinosauroidea. Journal of Vertebrate Paleontology 26: 636–650.
- 90. Clark JM,Norell IMA,Chiappe LM (1999) An Oviraptorid Skeleton from the Late Cretaceous of Ukhaa Tolgod, Mongolia, Preserved in an Avianlike Brooding Position Over an Oviraptorid Nest. American Museum Novitates 3265: 1–36.
- 91. Sasaki M,Endo H,Derocher AE,Tsubota T,Taru H,et al. (2005) Adaptation of the hindlimbs for climbing in bears. Annals of Anatomy 187: 153–160. doi:10.1016/j.aanat.2004.10.001.
- 92. Sereno PC (1991) Basal Archosaurs: Phylogenetic relationships and functional implications. Memoir(Society of Vertebrate Paleontology) 2: 1–53.
- 93. Alexander RM (2003) Problems of Scale for Walking and Climbing Animals. In: Armada MA,De Gonzalez Santos P, editors. Climbing and Walking Robots. pp. 47–54.
- 94. Jenkins FA,McClearn D (1984) Mechanisms of Hind Foot Reversal in Climbing Mammals. Journal of Morphology 182: 197–219.
- 95. Gebo DL,Rose KD (1993) Skeletal morphology and locomotor adaptation in Prolimnocyon atavus, and Early Eocene Hyaenodontid Creodont. Journal of Vertebrate Paleontology 13: 125–144.
- 96. Sullivan C,Hone DWE,Xu X,Zhang F (2010) The asymmetry of the carpal joint and the evolution of wing folding in maniraptoran theropod dinosaurs. Proceedings of teh Royal Society B 277: 2027–33.
- 97. Taylor ME (1976) The functional anatomy of the hindlimb of Some African Viverridae (Carnivora). J Morphol 148: 227–254.
- 98. Richardson F (1942) Adaptive modifications for tree-trunk foraging in birds. Univ Calif Pubs Zool 46: 317–368.
- 99. Milner ARC,Harris JD,Lockley MG,Kirkland JI,Matthews Na (2009) Bird-like anatomy, posture, and behaviour revealed by an Early Jurassic theropod dinosaur resting trace. PloS one 4: e4591.
- 100. Chatterjee S (1997) The rise of birds. John Hopkins University Press. p.
- 101. Hone DWE,Tischlinger H,Xu X,Zhang F (2010) The extent of the preserved feathers on the four-winged dinosaur Microraptor gui under ultraviolet light. PloS one 5: e9223.
- 102. Reilly SM (2000) Locomotion in the quail (Coturnix japonica): the kinematics of walking and increasing speed. Journal of morphology 243: 173–85.
- 103. Schaller NU,Herkner B,Villa R,Aerts P (2009) The intertarsal joint of the ostrich (Struthio camelus): Anatomical examination and function of passive structures in locomotion. Journal of anatomy 214: 830–47.
- 104. Abourachid A,Renous S (2008) Bipedal locomotion in ratites (Paleognatiform): examples of cursorial birds. Ibis 142: 538–549.
- 105. Tobalske BW,Dial KP (2007) Aerodynamics of wing-assisted incline running in birds. The Journal of experimental biology 210: 1742–51.
- 106. Benton MJ,Donoghue PCJ (2007) Paleontological evidence to date the tree of life. Molecular biology and evolution 24: 26–53.
- 107. Brown JW,Rest JS,García-Moreno J,Sorenson MD,Mindell DP (2008) Strong mitochondrial DNA support for a Cretaceous origin of modern avian lineages. BMC biology 6: 6.
- 108. Clarke J A,Zhou Z,Zhang F (2006) Insight into the evolution of avian flight from a new clade of Early Cretaceous ornithurines from China and the morphology of Yixianornis grabaui. Journal of anatomy 208: 287–308.
- 109. Zhou Z,Zhang F (2006) A beaked basal ornithurine bird (Aves, Ornithurae) from the Lower Cretaceous of China. Zoologica Scripta 35: 363–373.
- 110. Clarke JA,Tambussi CP,Noriega JI,Erickson GM,Ketcham RA (2005) Definitive fossil evidence for the extant avian radiation in the Cretaceous. Nature 433: 305–8.
- 111. You H-L,Lamanna MC,Harris JD,Chiappe LM,O'connor J,et al. (2006) A nearly modern amphibious bird from the Early Cretaceous of northwestern China. Science 312: 1640–3.
- 112. Procter-Gray E,Ganslosser U (1986) The Individual Behaviours of Lumholtz's Tree-Kangaroo: Repertoire and Taxonomic Implications. Journal of Mammology 67: 343–352.
- 113. Grand TI (1990) Body composition and the evolution of the Macropodidae (Potorous, Dendrolagus and Macropus). Anatomy and Embryology 182: 85–92.
- 114. Prideaux GJ (2008) A New Pleistocene Tree-Kangaroo (Diprotodontia: Macropodidae) From The Nullarbor Plain Of South-Central Australia. Journal of Vertebrate Paleontology 225: 1–478. doi:10.1671/0272-4634(2008)28[463:ANPTDM]2.0.CO;2.
- 115. Newell GR (1999) Australia's tree-kangaroos: current issues in their conservation. Biological Conservation 87: 1–12.
- 116. Bishop N (1997) Functional anatomy of the macropodid pes. Proceedings of the Linnean Society, New South Wales 117: 17–50.
- 117. Bassarova M,Janis CM,Archer M (2008) The Calcaneum—On the Heels of Marsupial Locomotion. Journal of Mammalian Evolution 16: 1–23.
- 118. Warburton NM,Prideaux GJ (2010) Functional pedal morphology of the extinct tree-kangaroo Bohra (Diprotodontia: Macropodidae). In: Coulson GM,Eldridge MDB, editors. Macropods: The Biology of Kangaroos, Wallabies and Rat- kangaroos. Melbourne: CSIRO Publishing. pp. 137–151.
- 119. Kear BP,Lee MSY,Gerdtz WR,Flannery TF (2008) Evolution of Hind Limb Proportions in Kangaroos (Marsupialia: Macropodoidea). In: Sagris E,Dagosto M, editors. Mammalian Evolutionary Morphology: A tribute to Frederick S. Szalay. Springer Press. pp. 25–35.
- 120. Iwaniuk AN,Nelson JE,Ivanco TL,Pellis SM,Whishaw IQ (1998) Reaching, grasping and manipulation of food objects by two tree kangaroo species, Dendrolagus lumholtzi and Dendrolagus matschiei. Australian Journal of Zoology 46: 235–248.
- 121. Chen X,Milne N,O'Higgins P (2005) Morphological variation of the thoracolumbar vertebrae in Macropodidae and its functional relevance. Journal of morphology 266: 167–81.
- 122. Heilmann G (1926) The origin of birds. London: H.F. and G. Whiterby. 208 p.
- 123. Li P-peng,Gao K-qin,Hou L-hai,Xu X (2007) A gliding lizard from the Early Cretaceous of China. Proceedings of the National Academy of Sciences of the United States of America 104: 5507–5509.
- 124. Simmons NB,Seymour KL,Habersetzer J,Gunnell GF (2008) Primitive Early Eocene bat from Wyoming and the evolution of flight and echolocation. Nature 451: 818–821.
- 125. Claessens LPAM,O'Connor PM,Unwin DM (2009) Respiratory Evolution Facilitated the Origin of Pterosaur Flight and Aerial Gigantism. PloS one 4: e4497.
- 126. Bennet S C (1997) The arboreal leaping theory of the origin of pterosaur flight. Historical Biology 12: 265–290.
- 127. Hendenstrom A,Johansson LC,Spedding GR (2009) Bird or bat: comparing airframe design and flight performance. Bioinspiration & Biomimetics 4: 1–13.
- 128. Johansson LC,Wolf M,Hendenstrom A (2010) A quantitative comparison of bird and bat wakes. Journal of the Royal Society Interface 7(43): 61–66.