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Article

Morphological Disparity of the Humerus in Modern Birds

by
Francisco J. Serrano
1,2,3,*,
Mireia Costa-Pérez
4,
Guillermo Navalón
5,6 and
Alberto Martín-Serra
3
1
Real Academia de Ciencias Exactas, Físicas y Naturales, Calle Valverde, 22, 28004 Madrid, Spain
2
The Dinosaur Institute, Natural History Museum of Los Ángeles County, 900 Exposition Boulevard, Los Ángeles, CA 90007, USA
3
Departamento de Ecología y Geología, Facultad de Ciencias, Universidad de Málaga, Campus Universitario de Teatinos s/n, 29071 Málaga, Spain
4
Departamento de Botánica y Geología, Universidad de Valencia, Calle Doctor Moliner 50, 46100 Burjassot, Valencia, Spain
5
Department of Earth Sciences, University of Oxford, South Parks Road, Oxford OX1 3AN, UK
6
Unidad de Paleontología, Departamento de Biología, Facultad de Ciencias, Universidad Autónoma de Madrid, Calle Darwin 2, Cantoblanco, 28049 Madrid, Spain
*
Author to whom correspondence should be addressed.
Diversity 2020, 12(5), 173; https://doi.org/10.3390/d12050173
Submission received: 1 April 2020 / Revised: 25 April 2020 / Accepted: 26 April 2020 / Published: 28 April 2020
(This article belongs to the Special Issue Origins of Modern Avian Biodiversity)

Abstract

:
From a functional standpoint, the humerus is a key element in the skeleton of vertebrates as it is the forelimb’s bone that connects with the pectoral girdle. In most birds, the humerus receives both the forces exerted by the main flight muscles and the aerodynamical stresses exerted upon the wing during locomotion. Despite this functional preeminence, broad scale studies of the morphological disparity of the humerus in the crown group of birds (Neornithes) are lacking. Here, we explore the variation in shape of the humeral outline in modern birds and its evolutionary relationship with size and the evolution of different functional regimes, including several flight strategies, wing propelled diving and complete loss of wing locomotory function. Our findings suggest that most neornithines evolved repeatedly towards a general humeral morphology linked with functional advantages related with more efficient flapping. Lineages evolving high-stress locomotion such as hyperaeriality (e.g., swifts), hovering (e.g., hummingbirds) and wing-propelled diving (e.g., penguins) greatly deviate from this general trend, each exploring different morphologies. Secondarily flightless birds deviate to a lesser degree from their parent clades in humeral morphology likely as a result of the release from constraints related with wing-based locomotion. Furthermore, these taxa show a different allometric trend that flighted birds. Our results reveal that the constraints of aerial and aquatic locomotion are main factors shaping the macroevolution of humeral morphology in modern birds.

1. Introduction

With more than 10,000 living species occupying almost every habitat over the globe, birds are one of the most speciose and ecologically diverse group of vertebrates [1]. This extraordinary diversity is coupled with a wide range of physiological and morphological adaptations to locomotion, primal among which is aerial locomotion [2,3,4]. Most birds have wings capable of generate the necessary lift and thrust in the air to achieve some kind of flight [4,5]. Some birds have adapted to generate those forces underwater (i.e., wing-propelled diving), what in the case of penguins and some extinct auks have involved the loss of flight capacity [6,7]. Other birds have lost the wing function completely, either in case of species adapted to terrestrial foraging (e.g., ratites, dodo), and those adapted to aquatic foraging through foot-propelling (e.g., flightless cormorant).
Proportions and cross-sections of forelimb bones studied within a phylogenetic context have shown a good correlation with wing-propelled locomotion [8,9,10,11]. During flight and wing-propelled diving the forces from the fluids (i.e., air and water, respectively) are exerted on the wing as bending and torsional moments which are transmitted from distal to proximal skeletal elements [5]. Hence, the humerus—the most proximal element of the forelimb—supports most of the wing stresses ultimatetly transferred through the elbow joint. In addition, the proximal epiphysis of this bone bears the attachment areas for the major flight muscles. Namely, the main muscles of downstroke (i.e., pectoralis) and upstroke (i.e., deltoideus and supracoracoideum) are inserted in the dorsal face of this epiphysis, while the main flexor of the wing (i.e., biceps) is attached to the ventral face [12,13]. All these features indicate that the humerus might be a key element to explore the link between skeletal morphology and locomotion throughout the evolution of the crown birds (i.e., Neornithes).
Our understanding of major morphological transformations over avian macroevolution has significantly improved in the last years with studies targeting several elements across the avian skeleton such as the skull [14,15,16,17,18,19,20], the girdles [20,21], the appendicular skeleton [22,23,24], and specifically the humerus among Mesozoic non-neornithine birds [25]. Despite the functional importance of the humerus and the remarkable morphological disparity displayed by this element in crown birds [26] (Figure 1), studies exploring this issue fall in one of two categories; (1) allometry using linear relationships between bone chord length, midshaft dimensions and body mass [27,28,29,30], or (2) using more complex methods but restricted to a particular clade and/or region of this bone [25,31]. However, a phylogenetically broad study of humeral morphology is lacking. Our study aims to fill this gap shedding light on the morphological transformations underwent by this bone over neornithine evolution.
Here we used geometric morphometrics to explore the morphological disparity of the humerus in birds across all the crown group of modern birds including one outgroup. Geometric morphometrics allows multidimensional analyses of the biological shape including compelling visualization of morphological differences in size and shape of anatomical structures [15,32]. Variations in the humeral morphology are assessed across a well-resolved phylogeny of Neornithes [33], which allows to explore those morphological patterns that are associated with changes in the wing function (i.e., from flight to diving), as well as with the reduction of the function (i.e., from flight to flightless).

2. Material and Methods

2.1. Data Acquisition

Our data includes the humeri of 153 species encompassing 71 families and 23 orders within Neornithes. Species were classified according to the locomotory function of the wing as: (1) flight; (2) flight and diving; (3) diving; (4) and reduced function (Figure 2). Humeri were photographed directly in the collections of Natural History Museum of Los Ángeles County (Los Ángeles, CA, USA) and Burke Museum (Seattle, WA, USA). Photographs were taken from the caudal side of the bone following a standardized protocol for avoiding lens distortion and parallax [34]. The sample includes the cassowary (Casuarius bennetti) but other flightless Paleognathae as Struthio camellus and Rhea americana could not be analyzed because of the impossibility to locate enough landmarks on their humeri as this element is very modified in this taxa. Our sample also includes three recently extinct species: two auks (i.e., Pinguinus impennis and Mancalla milleri) assigned to diving category, and the dodo (i.e., Raphus cucullatus) assigned to the category of reduced wing function. The humeri of P. impennis LACNHM 90052 and M. milleri LACNHM 2813 were photographed from the collection of Natural History Museum of Los Ángeles County (Los Ángeles, CA, USA), while the humerus of R. cucullatus NHMUK PVA u/r was sourced from [35]. Finally, the Late Cretaceous ornithurine Ichthyornis dispar was included as outgroup of Neornithes [36]. The specimen I. dispar MUZ 689 was taken from [37].
We built a phylogenetic tree using the software Mesquite v.3.5 [38] extracting the topology and branch length information [33]. For clades not included in the [33], the information was obtained from specific references given from Timetree.org [39].
Individual values of body mass (Mb) were available for most of the extant birds specimens (n = 140; see Table S1). For those specimens with no individual information we obtained species’ mean values of Mb from online databases [40,41]. We estimated the Mb of I. dispar from the alometric equation of the humeral length in [42]. Mass values for the other extinct birds were obtained from the femur, as this bone correlates better with the Mb than the humerus in flightless species [43]. Mb of M. milleri was estimated using the mean value of femoral lengths provided by [44] and the allometric equation in [42]. Likewise, Mb of P. impennis and R. cucullatus were taken from the mean values given in [43] and [45], respectively.

2.2. Analyses

A series of 19 homologous landmarks and three semilandmark strings (equidistant sliding semilandmarks) were digitized and scaled in each the images of humeri using tpsDig v.2.25 [46]. This was aimed to fully capture the outline shape of this element as well as the relative position and shape of the pneumotricipital fossa (Figure 3, Table S2). The raw X and Y coordinates of these landmarks and semilandmarks were imported into R environment [47] where all downstream analysis were conducted using the package geomorph v.3.1.3 [48].
Generalized Procrustes Analysis was carried out to remove differences in size, translation and rotation in the raw coordinates and extract shape data [49]. Sliding semilandmarks were optimized following a criterion of minimum bending energy [50]. Procrustes coordinates (shape) and log-transformed centroid size (i.e., a geometrically defined proxy of size CS) were obtained from this analysis. The relationship between the CS of the humerus and Mb in birds was explored within a phylogenetic context using a PGLS procedure (procD.pgls) [51], with log-transformed CS as dependent variable and log transformed Mb as independent variable. Two linear measurements traditionally used as estimates of size were calculated: humeral length (HL; L3 to L15) and midshaft width (HW; L11 to L12). The relationship between Mb and the size estimators of humerus, HL and HW, was tested using the same procedure. In addition, a linear model (lm function) was also fitted to calculate the slopes for the total sample of birds, and for flying and flightless subsamples separately. Afterwards, the allometric variation of shape was assessed through two Procrustes ANOVAs within a phylogenetic context using CS and Mb as independent variables, respectively. Differences among flighted and flightless birds were also evaluated. Statistical significance of Procrustes ANOVAs was tested through non-parametric permutation tests (999 iterations) [51]. This non-parametric ANOVA is less likely to result in a type I error for data that violate the parametric assumptions but it might increase the likelihood of a type II error [51].
Finally, the residuals obtained from the Procrustes ANOVA linear regression of shape against centroid size were incorporated as allometric-free shape coordinates in a principal components analysis (PCA; plotTangentSpace) to explore the main directions of morphological change. The morphological changes associated with the PCs were represented using plotRefToTarget function. The phylogeny was also incorporated into PCA visualization by generating phylomorphospaces using functions from phytools package [52]. This reconstructs the ancestral states of humeral shapes using squared-change parsimony [53]. Finally, to inform on the degree in which shape similarity associates with phylogenetic relationships we calculated Kmult using the function physignal also from geomorph. Values of Kmult = 1 represents the value of expected phenotypic similarity under a single-rate Brownian motion model of evolution; therefore, values Kmult > 1 indicate that related taxa are more similar to each other than expected under Brownian motion; while values of Kmult < 1 indicate that related taxa are less similar to each other than expected under a Brownian motion model of evolution.

3. Results

Size metrics of the humerus (i.e., HL, HW and CS) correlate significantly with Mb (Table 1; Figure 4). Bivariate regressions of HL and CS provide almost identical results. Analyses using the three metrics report higher slopes for flying than for flightless birds, although the difference is smaller in the case of HW. Among flying birds, the slopes of HL and CS are higher than the slope provided by HW. Conversely, the slope from HW is steeper in the flightless subsample. PGLS evidences that these differences are highly significant (p < 0.001) and independent from the phylogenetic relationships (Table 1).
Multivariate regressions of shape coordinates on Mb and CS reveal that the allometric variation of humeri is significant but small: Mb explains 2.2% of the total variance, while CS explains 5.8% (Table 2). The morphological variation associated to Mb show that heavier birds tend to have longer and slenderer humeri (i.e., less robust) as compared to lighter birds (Figure 5A). Similarly, the allometric change regarding CS shows that small humeri are more robust than larger humeri (Figure 5B). Differences between flying and flightless birds were not statistically significant (Mb: p = 0.074; CS: p = 0.108). However, visual observations reveal that the allometric pattern associated with Mb seems to be reversed in flightless birds with more robust humeri associated with heavier birds (Figure 5A). Importantly, although swifts and hummingbirds exhibit much stouter humeri than the rest of birds, the results for allometry were the same when these birds were removed from the analyses (Table S3).
The two first principal components (PCs) capture 83.3% of the total morphological variation of the humerus in our sample. Mapping the phylogeny onto our PCA plot shows that Apodiformes (swifts and hummingbirds), Sphenisciformes (penguins) and some Alcidae (e.g., Pinguinus, Mancalla, Uria, and Brachyramphus) are very divergent in humeral shape from the rest of clades (Figure 6A). Shape change along PC1 (55.2% of the variance) depicts variations related with the general robustness of the bone associated with the expansion of both epiphyses and the shortening of the chord length of the diaphysis. Positive scores are associated with short and wide humeri (e.g., swifts and hummingbirds, penguins, swallows) while negative scores are associated with long and slender humeri (e.g., albatross and petrels, O. Procellariformes). PC2 (28.1% of the variance) mainly describes differences in the proximodistal extension of the deltopectoral crest coupled with changes in the extension of the bicipital crest in the proximal epiphysis. Positive scores in PC2 are associated with distally expanded but dorsally shallow deltopectoral crests and a bicipital crest restricted to the proximal end of the humerus like in some penguins and some alcids, including the extinct flightless P. impennis and M. milleri, (Figure 6A). Negative scores along PC2 are associated with shorter and more dorsally projected deltopectoral crests, and more ventrally expanded bicipital crests as shown by hummingbirds (Trochilidae) and, to a lesser degree, by swallows (Hirundinidae) and swifts (Apodidae).
Because the main axes of variation are created by shape differences among outlier taxa (i.e., Apodiformes, Sphenisciformes and Alcidae), we conducted a second PCA excluding these groups in order to observe the variation among the remaining species (Figure 6B). As in the first analysis, the shape captured by the new PC1 is associated with the robustness of the humerus related to the expansion of epiphyses and shortening of the diaphysis, while the new PC2 depicts differences in the length of the deltopectoral crest with respect to the proximal-distal position of the ventral region of the proximal epiphysis (including the bicipital crest). The non-neornithine Ichthyornis dispar scores in the extreme positive axis of the PC2 showing the ventral region located more proximally with respect a long deltopectoral crest (DPC) than the bulk of the other birds (Figure 6B). Compared to Ichthyornis, although there is some disparity between clades, most neornithines tend to increase the dorsoventral symmetry of the proximal epiphysis by restricting both deltopectoral crest and bicipital crest regions proximally. Abundant overlapping of branches within the central region of the morphospace (Figure 6A,B) seems to indicate that these morphologies have been explored several times during neornithine evolution. This is confirmed by a significant value of Kmult = 1.48, indicating overall higher similarity among related taxa than expected (p < 0.001). However, when the most divergent lineages are not considered, a value close to expectations of Brownian motion is recovered (Kmult = 1.04; p = 0.02).
Within Paleognathae, the humerus of the flightless cassowary (Casuarius bennetti) shows a morphological trend close to Ichthyornis, while flying tinamous show morphologies much more similar to other neornithines. Within Neognathae, flightless taxa (i.e., Anas aucklandica, Rapphus cucullatus, Gallirallus owstoni, Hypotaenidya woodfordi, and Nannopterum harrisi) do not seem to follow a common morphological trend though (Figure 6B). Flightless rails (G. owstoni, H. woodfordi) and the Dodo (R. cucullatus) have humeri lesser robust than their flying counterparts from Gruiformes and Columbiformes, respectively. In contrast, the flightless cormorant (N. harrisi) increases the humeral robustness, distally lengthens the DPC and locates the ventral epiphysis more proximal with respect to its closest relatives. The Auckland Teal (A. aucklandica) shows a similar morphology than the flying mallard (Anas platyrhynchos).

4. Discussion

In agreement with previous studies [27,29,30] linear size metrics of the humerus (i.e., humeral length, HL and humeral width, HW) scale with body mass (Mb) according with allometric factors of 0.42 and 0.36, respectively. Meanwhile when only the flying subsample is accounted for, the scaling factors increase slightly (i.e., 0.48 and 0.38), remaining above the expected slope of isometry (i.e., 0.33), that is, humerus dimensions increase faster than body mass and length of the humerus increases faster with body mass than the width of the humeral diaphysis (Table 1, Figure 4) [30]. This entails that as body mass increases the humerus of flying birds tend to be longer and thinner. In flightless birds, however, the slopes for both variables are lower than expected for isometry (HL slope = 0.14; HW slope = 0.29) meaning that body mass increases faster than humeral dimensions and the humerus of flightless birds tends to be shorter and thicker in heavier birds. We also found that centroid size (CS; i.e., the our humeral size proxy) is closely associated with HL, but not with HW, suggesting the CS calculation for birds’ humerus is much more influenced by length than by width, and revealing once again the skewness CS can produce towards certain variations in geometry (e.g., [18,54]).
In agreement with our results on linear allometry, shape allometric variation related with both size proxies, CS and Mb, mainly reflects variations in the robustness of the humerus (i.e., larger humeri or heavier birds are associated with less robust humeri; Figure 5). This is also consistent with previous studies suggesting bone length increases faster than shaft diameter in large birds [27,30,55]. We found that this allometric variation is not a dominant factor of the morphological variability in the humerus of birds as a single group (i.e., 2–6% of bone shape variance), but most of this allometric variation is due to differences in size and shape (e.g., clades with large and slender humeri vs. clades with small and robust humeri) as revealed by the shape variance explained by size variations using non-phylogenetic models (i.e., 25–29%; Table 2). Surprisingly, allometric trends of flightless and flighted birds with CS and Mb were not statistically different (Table 1), although this signification should be taken cautiously, especially in the case of Mb (p = 0.074), as the non-parametric Procrustes ANOVAs might increase the likelihood of a type II error in samples with heterogeneity of within-group variance [51] as ours. In addition, flightless birds seem to follow an opposite tendency in which their humeri become more robust as Mb increases (Figure 5A), which is also consistent with the scaling of HL and HW reported above (Figure 4, Table 1). These results reveal the primal influence of flight adaptation in humeral allometry in modern birds.
However, the link between morphological variations of the humerus and its more specific locomotory functions in birds is intricate. More than 80% of the allometric-free variation reflects changes in the bone robustness associated with the expansion of the epiphyses and shortening of the diaphysis (i.e., PC1), as well as in the relative development of the dorsal and ventral crests in the proximal epiphysis (i.e., PC2). These morphological variations are highly related to the capacity of the bone to bear stresses [8,10] and wing’s mechanics [56,57,58]. The humeral morphology displayed here by the Upper Cretaceous ornithurine Ichthyornis dispar (Figure 6) can be seen in other non-neornithine ornithuromorphs (e.g., [25]). Comparisons of morphological disparity of the humerus in the crown group of birds (i.e., Neornithes) with such pre-neornithine condition illustrate that the humerus of the majority of living bird lineages tended towards a configuration with proximally restricted deltopectoral crests (DPC), that is, closer to the glenoid joint, while more distally located bicipital crests (BC), that is further from the glenoid (Figure 6). Such a configuration implies, on the one hand, a DPC that enhances faster movements of the wing and less contraction length of the pectoralis fibers, and on the other, a biceps closer to elbow and, then with shorter fibers that can exert more force (see [56,59,60]). As a result, we suggest that this morphological transformation of the humerus involved an improvement to flap efficiently in neornithines and likely represents a functional optimum that constrains the evolution of humeral morphology in most neornithines lineages. In addition, developmental constraints could have also played a role in restricting shape variation of the humerus in many neornithine lineages. Quantitative measures of similarity indicate that this constrained pattern is true when all neornithines are considered (Kmult = 1.48), and we found evidence for two functional regimes which deviate from this general morphological trend, which are both the result of a secondary specialization to a highly stressful wing-propelled locomotion in a handful of lineages: intense aerial flapping and underwater wing propulsion. However, when lineages of these two outlier cases are excluded, quantitative measures suggest that within the rest of neornithines, there is significant variation in shape that adjust well to Brownian Motion model of evolution within an specific region of the shape space (Kmult = 1.04).
Apodiformes stand among the lineages which developed an intense aerial flapping activity, as swifts are hyperaerials (i.e., they spend almost their entire life airborne, roosting, mating and foraging) and hummingbirds are the only birds capable of prolonged hovering (i.e., a flight style that requires a very high frequency of flapping because the lift generation comes entirely from the flapping wings) [61,62,63]. These birds display extremely robust humeri (Figure 6A) that allow to deal with the high stresses generated on their wings—that have proportionality very long handwings [62]—from either, hyperariality or prolonged hovering. Their humeri also differ from the remaining of birds in the shape of the proximal epiphysis—DPC is very short and dorsally projected, and the BC lengthens distally—, what is especially conspicuous in hummingbirds (Figure 6A). The shortening of the DPC increases the mechanical advantage of the pectoral and deltoids muscles to achieve faster wing strokes (see [58,60]), while the lengthening of the BC is consistent with a well-developed biceps and the fact of hummingbirds keep the elbow flexed during the full wing cycle [62]. The humeral morphology of hirundinid passerines (i.e., martins and swallows) displays an incipient pattern of homoplasy in the humeral shape with Apodiformes (Figure 6A), which is consistent with other similarities regarding wing shape, wing loading, and hyperaerial habits [64,65,66].
On the other hand, underwater wing propulsion is highly stressful for the wings as the fluid forces (i.e., lift and drag) in the water are four times those undergone in the air at the same Reynolds number [67]. Wing-propelled diving has evolved at least five times within neornithines: in penguins (Sphenisciformes), auks (Alcidae), petrels and shearwaters (Procellariidae), diving-petrels (Pelecanoididae), dippers (Cinclidae), and extinct plotopterids (Plotopteridae). Among them, penguins and plotopterids, which might be closely related [68], are the only clades that lost the flight capacity and fully adapted to underwater foraging [6,43,69]. Compared to close flighted relatives and the bulk of modern birds, penguins have humeri with very long DPCs and reduced BCs (Figure 6A). As pectoralis, supracoracoideus and deltoids muscles are inserted only on the most proximal region of the DPC [70], the length of this crest would not reflect the mechanical advantage of flapping as we have previously described. Meanwhile, the reduced BC reflects the loss of the biceps and the minimal elbow mobility in penguins [69]. The stiffening of the wing of penguins to serve as a flipper have involved the further loss or reduction of forelimb muscles and the movement restriction of the rest of joints [69,70]. Our results support that these modifications to make the wing stiffer are linked to a high robustness of the humerus in the craniocaudal axis (Figure 6A). We therefore suggest that this robust humerus is well-suited to resist the high stresses supported by the wing as a consequence of the high loadings imposed by the fluid forces of water [71]. The extinct species of Alcidae, P. impennis and M. milleri, show seemingly convergent humeral morphologies with penguins (Figure 6A), which is in agreement with another anatomical features indicating they were flightless wing-propelled divers (e.g., [7,43,72,73]). Extant alcids are capable of both wing-propelled flying and diving. Surprisingly, we have identified humeral shape disparity among them, which as far as we know has been previously overlooked. The morphology of genera Uria and Brachyramphus closely approach that of extinct flightless Pinguinnus and Mancalla, showing higher robustness and much longer DPC than genera Fratercula and Cepphus (Figure 1F–G, Figure 6A). Such a divergent pattern within Alcidae could indicate that some species improve flapping capacity in air, while others improve it in the water; although this issue needs to be farther explored on a study focused on alcids. Similarly to Fratercula and Cepphus, the other modern taxa that evolved underwater wing propulsion together with flying capacity (i.e., Procellariidae, Pelecanoididae and Cinclidae) have a humeral morphology that does not differ significantly from the bulk of Neornithes (Figure 6A). Consistently with [6], this result indicate that the aquatic medium imposes extreme selective pressures on the morphology. Hence, the idea that the lineages of alcids and penguins exhibit an aerial-diving functional trade-off of the wing [74] would imply that the transition to a more frequent aquatic wing propelled locomotion would involve greater morphological changes than the transition to a more frequent use of aerial locomotion. However, the flighted species of these lineages should not be viewed as steps of an evolutionary trajectory towards the loss of flight [43].
Our results also show that the loss of wing function in different lineages of neornithines involved divergences in humeral shape from their flying closest relatives (Figure 6B). However, a morphological trend common to all these flightless lineages was not found. The morphological pattern observed in birds that completely loss the wing function responds to three different scenarios: (1) Long-time flightless lineages as the cassowary that show a clear regression to the plesiomorphic morphology with regards to flying relatives. To extend this result to other flightless paleognaths as ostriches and rheas further analysis is necessary, as their humeri are very different from that of the cassowary and could not be analyzed (see material and methods); (2) Terrestrial flightless birds inhabiting small islands without predators, as the extinct dodo (R. cucullatus) and the rails from Pacific Islands (e.g., H. woodfordi, G. owstoni), which tend to decrease the humeral robustness with respect to their relatives; (3) a combination of island isolation and foot-propelling aquatic locomotion, such are cases of the Auckland teal (A. aucklandica) and the flightless cormorant (N. harrisi). The humerus of the former did not greatly diverge from A. platyrrhynchos, its closest relative analyzed, while the humerus of the latter increased its robustness and acquired a more plesiomorphic condition for the proximal epiphysis, with respect to flying cormorants and other close relatives. This might be related with a more recent divergence of the Auckland teal from its flighted counterparts than the flightless cormorant [75,76] although this has not been tested in detail yet.
The absence of a common morphological pattern in birds without locomotory wing function may reflect that the relaxation of functional flight constraints could entail unpredictable morphological variations of the humerus that can lead to different trends including an apparent reversal towards the plesiomorphic condition (as observed for the cassowary, dodo, and flightless cormorant, but not for rails). The release of these functional constraints do not necessarily imply that functional pressures do not affect the morphology of the humerus in these taxa. For instance, while the wing of flightless cormorant is reduced with respect to its flying relatives [77], the humerus increases in robustness (Figure 6B). This change could reflect a skeletal modification to make the bone denser, which would be consistent with the increase of body mass and other anatomical modifications that reduce the buoyancy enhancing its subaquatic performance [77,78,79,80].

5. Conclusions

Our results support that: (1) locomotory adaptation is an important factor shaping the evolution of the morphological disparity of the humerus in Neornithes; (2) allometric variation is unexpectedly low and shows an opposite pattern in flighted birds to that of flightless birds, particularly in relation with the robustness of this bone; (3) considering the humeral morphology of Ichthyornis and other non-neornithine ornithuromorphs [25] as plesiomorphic, we suggest that the transformations in the proximal epiphysis in neornithines would have entailed an improvement in the flapping efficiency in the clade; (4) extreme adaptation to highly stressful wing-propelled locomotion in air (swifts and hummingbirds) and water (penguins and some auks) results in the main morphological divergences observed among neornithines, and in both cases, involves a very robust humeral morphology; (5) the disparity between flighted and flightless wing-propelled divers supports previous hypotheses [6] suggesting that the transition from a “double” wing use (both flying and diving) condition to a fully aquatic use condition involves greater changes than the transition from a purely aerial locomotory condition to a “double” wing use condition; and (6) a common morphological pattern associated with the loss of locomotory function of the wing was not found, what implies the relaxation of the constraints imposed by flapping in fluids on the humerus do not have a predictive effect in the evolution of the architecture of this bone.
Although focused on the two-dimensional shape of the bone and other attributes of morphological variation in the humerus, our study represents one of the first steps towards the understanding of the evolution of postcranial anatomy among the whole extant radiation of birds. In addition, we raise several issues regarding the disparity of the avian humerus and provides a framewrok for future analyses at a broad scale and focuses in clade specific trends which deserve further study (e.g., alcids, paleognaths, and cormorants).

Supplementary Materials

The following are available online at https://www.mdpi.com/1424-2818/12/5/173/s1, Table S1: Birds’ dataset used in this study; Table S2: Anatomical description of the landmarks of the humerus shown in the Figure 3; Table S3: Summary of multivariate regressions for allometric variation of the humeral shape based on Procrustes coordinates (Pcoor) on body mass (Mb) and centroid size (CS) using the subsample that excludes Apodiformes, Sphenisciformes and Alcidae.

Author Contributions

Conceptualization, F.J.S. and M.C.-P.; Methodology, F.J.S. and A.M.-S.; Formal Analysis, F.J.S., M.C.-P. and A.M.-S.; Investigation, F.J.S., M.C.-P. and G.N.; Data Curation, F.J.S., and A.M.-S.; Writing—Original Draft Preparation, F.J.S. and M.C.-P.; Writing—Review & Editing, F.J.S., A.M.-S. and G.N.; Visualization, F.J.S., A.M.-S. and G.N. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Spanish Ministry of Economy and Competitiveness through the Research Project CGL2016-78577-P and the Juan de la Cierva-Incorporación Postdoctoral Fellowship to F.J. Serrano.

Acknowledgments

We thank Daniel J. Field for inviting us and editing the special issue in which this paper is included. We also thank three anonymous reviewers for their insightful comments that improve earlier versions of the manuscript. Thanks to Kimball Garrett (LACNHM, Los Ángeles, CA, USA), Robert Faucett (UWBM, Seattle, WA, USA) and Josefina Barreiro (MNCN, Madrid, Spain) for providing access to collections under their care.

Conflicts of Interest

The authors declare no conflict of interest.

References

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Figure 1. Humeri in caudal view for selected taxa. (A) Oxyura jamaicensis UWBM 33103. Abbreviations: bc, bicipital crest; ch, caput humeri; dc, dorsal condyle; dpc, deltopectoral crest; fpn, fossa pneumotricipital; fp, flexor process; vc, ventral condyle. (B) Haliaeetus leucocephalus UWBM 33937. (C) Macronectes giganteus UWBM 38048. (D) Nannopterum harrisi LACNHM 89910. (E) Hirundapus caudacutus UWBM47345. (F) Uria aalge UWBM 79468. (G) Fratercula corniculata LACNHM 96912. (H) Meleagris gallopavo UWBM 59381. (I) Casuarius bennetti LACNHM 107030. (J) Spheniscus humboldti UWBM 81776. (K) Columba rupestris UWBM 59986. (L) Cinclus mexicanus UWBM 50254. Scale bars equate to 10 mm.
Figure 1. Humeri in caudal view for selected taxa. (A) Oxyura jamaicensis UWBM 33103. Abbreviations: bc, bicipital crest; ch, caput humeri; dc, dorsal condyle; dpc, deltopectoral crest; fpn, fossa pneumotricipital; fp, flexor process; vc, ventral condyle. (B) Haliaeetus leucocephalus UWBM 33937. (C) Macronectes giganteus UWBM 38048. (D) Nannopterum harrisi LACNHM 89910. (E) Hirundapus caudacutus UWBM47345. (F) Uria aalge UWBM 79468. (G) Fratercula corniculata LACNHM 96912. (H) Meleagris gallopavo UWBM 59381. (I) Casuarius bennetti LACNHM 107030. (J) Spheniscus humboldti UWBM 81776. (K) Columba rupestris UWBM 59986. (L) Cinclus mexicanus UWBM 50254. Scale bars equate to 10 mm.
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Figure 2. Time-calibrated phylogeny of the avian species used in this study (based on [33]) and their corresponding wing function categories.
Figure 2. Time-calibrated phylogeny of the avian species used in this study (based on [33]) and their corresponding wing function categories.
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Figure 3. Humerus of Oxyura jamaicensis in caudal view showing the location of the 19 landmarks and the 3 strings of semilandmarks used in this study. Landmarks are described in the Table S2.
Figure 3. Humerus of Oxyura jamaicensis in caudal view showing the location of the 19 landmarks and the 3 strings of semilandmarks used in this study. Landmarks are described in the Table S2.
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Figure 4. Scaling of classic linear measurements of the humerus, length (A) and width at midshaft (B) on body mass. Symbols’ shape corresponds with the function of wings given in Figure 2. Abbreviations: Aco, Archilochus colubris; Apa, Apus pacificus; Bma, Brachyramphus marmoratus; Cbe, Casuarius bennetti; Cme, Cinclus mexicanus; Emi, Eudyptula minor; Fci, Fratercula cirrhata; Gow, Gallirallus owstoni; Hca, Hirundapus caudacutus; Hwo, Hypotaenidya woodfordi; Mgi, Macronectes giganteus; Mmi, Mancalla milleri; Mse, Morus serrator; Nha, Nannopterum harrisi; Ppa, Puffinus pacificus; Pim, Pinguinus impennis; Pur, Pelecanoides urinatrix; Rcu, Rapphus cucullatus; Shu, Spheniscus humboldti.
Figure 4. Scaling of classic linear measurements of the humerus, length (A) and width at midshaft (B) on body mass. Symbols’ shape corresponds with the function of wings given in Figure 2. Abbreviations: Aco, Archilochus colubris; Apa, Apus pacificus; Bma, Brachyramphus marmoratus; Cbe, Casuarius bennetti; Cme, Cinclus mexicanus; Emi, Eudyptula minor; Fci, Fratercula cirrhata; Gow, Gallirallus owstoni; Hca, Hirundapus caudacutus; Hwo, Hypotaenidya woodfordi; Mgi, Macronectes giganteus; Mmi, Mancalla milleri; Mse, Morus serrator; Nha, Nannopterum harrisi; Ppa, Puffinus pacificus; Pim, Pinguinus impennis; Pur, Pelecanoides urinatrix; Rcu, Rapphus cucullatus; Shu, Spheniscus humboldti.
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Figure 5. Allometric scaling of the humeral shape (Procrustes coordinates) on both, body mass (A) and centroid size (B). Shape changes associated with each allometric vector are shown by vector graphs. Symbols’ shape corresponds with the wing function provided in Figure 2. Abbreviations: Aco, Archilochus colubris; Apa, Apus pacificus; Cbe, Casuarius bennetti; Cme, Cinclus mexicanus; Dda, Delichon dasypus; Emi, Eudyptula minor; Gow, Gallirallus owstoni; Hca, Hirundapus caudacutus; Mgi, Macronectes giganteus; Nha, Nannopterum harrisi; Pad, Pygoscelis adeliae; Ppa, Puffinus pacificus; Pim, Pinguinus impennis; Pur, Pelecanoides urinatrix; Rcu, Rapphus cucullatus; Shu, Spheniscus humboldti; Ulo, Uria lomvia.
Figure 5. Allometric scaling of the humeral shape (Procrustes coordinates) on both, body mass (A) and centroid size (B). Shape changes associated with each allometric vector are shown by vector graphs. Symbols’ shape corresponds with the wing function provided in Figure 2. Abbreviations: Aco, Archilochus colubris; Apa, Apus pacificus; Cbe, Casuarius bennetti; Cme, Cinclus mexicanus; Dda, Delichon dasypus; Emi, Eudyptula minor; Gow, Gallirallus owstoni; Hca, Hirundapus caudacutus; Mgi, Macronectes giganteus; Nha, Nannopterum harrisi; Pad, Pygoscelis adeliae; Ppa, Puffinus pacificus; Pim, Pinguinus impennis; Pur, Pelecanoides urinatrix; Rcu, Rapphus cucullatus; Shu, Spheniscus humboldti; Ulo, Uria lomvia.
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Figure 6. Allometric-free variation of humeral shape. (A) Phylomorphospace depicting the two first principal components of the PCA and vector graphs showing the shape changes associated with each of the axes. (B) Phylomorphospace depicted by the two first principal components of the PCA on the subsample excluding Apodiformes, Sphenisciformes and Alcidae, and vector graphs showing the shape changes. Symbols’ shape corresponds with the function of wings given in Figure 2. Abbreviations: Aau, Anas aucklandica; Aco, Archilochus colubris; Apa, Apus pacificus; Apl, Anas platyrhynchos; Bma, Brachyramphus marmoratus; Cbe, Casuarius bennetti; Cli, Columba livia; Cta, Crypturellus tataupa; Dda, Delichon dasypus; Dim, Diomedea inmutabilis; Emi, Eudyptula minor; Fci, Fratercula cirrhata; Gow, Gallirallus owstoni; Hca, Hirundapus caudacutus; Hmy, Hemiprocne mystacea; Hwo, Hypotaenidya woodfordi; Idi, Ichthyornis dispar; Mmi, Mancalla milleri; Mgi, Macronectes giganteus; Mse, Morus serrator; Nha, Nannopterum harrisi; Nma, Nothura maculosa; Pad, Pygoscelis adeliae; Pan, Pygoscelis antarctica; Pim, Pinguinus impennis; Pol, Phalacrocorax olivaceus; Ppa, Puffinus pacificus; Pre, Ptilinopus regina; Psu, Progne subis; Pur, Pelecanoides urinatrix; Rcu, Rapphus cucullatus; Shu, Spheniscus humboldti; Sle, Sula leucogaster; Tbi, Tachycineta bicolor; Uaa, Uria aalge; Ulo, Uria lomvia.
Figure 6. Allometric-free variation of humeral shape. (A) Phylomorphospace depicting the two first principal components of the PCA and vector graphs showing the shape changes associated with each of the axes. (B) Phylomorphospace depicted by the two first principal components of the PCA on the subsample excluding Apodiformes, Sphenisciformes and Alcidae, and vector graphs showing the shape changes. Symbols’ shape corresponds with the function of wings given in Figure 2. Abbreviations: Aau, Anas aucklandica; Aco, Archilochus colubris; Apa, Apus pacificus; Apl, Anas platyrhynchos; Bma, Brachyramphus marmoratus; Cbe, Casuarius bennetti; Cli, Columba livia; Cta, Crypturellus tataupa; Dda, Delichon dasypus; Dim, Diomedea inmutabilis; Emi, Eudyptula minor; Fci, Fratercula cirrhata; Gow, Gallirallus owstoni; Hca, Hirundapus caudacutus; Hmy, Hemiprocne mystacea; Hwo, Hypotaenidya woodfordi; Idi, Ichthyornis dispar; Mmi, Mancalla milleri; Mgi, Macronectes giganteus; Mse, Morus serrator; Nha, Nannopterum harrisi; Nma, Nothura maculosa; Pad, Pygoscelis adeliae; Pan, Pygoscelis antarctica; Pim, Pinguinus impennis; Pol, Phalacrocorax olivaceus; Ppa, Puffinus pacificus; Pre, Ptilinopus regina; Psu, Progne subis; Pur, Pelecanoides urinatrix; Rcu, Rapphus cucullatus; Shu, Spheniscus humboldti; Sle, Sula leucogaster; Tbi, Tachycineta bicolor; Uaa, Uria aalge; Ulo, Uria lomvia.
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Table 1. Summary of bivariate regressions of body mass (Mb) on humeral size metrics.
Table 1. Summary of bivariate regressions of body mass (Mb) on humeral size metrics.
VariableLinear Modeladj R2p-valueslope
CSall birds0.811<0.0010.423
flighted0.907<0.0010.484
flightless0.3290.030.138
HLall birds0.824<0.0010.423
flighted0.915<0.0010.482
flightless0.3400.0270.145
HWall birds0.906<0.0010.365
flighted0.937<0.0010.379
flightless0.4360.0120.291
VariablePGLSadj R2p-value
CSMb0.370<0.001
flighted-flightless0.099<0.001
Mb: flighted-flightless0.259<0.001
HLMb0.387<0.001
flighted-flightless0.092<0.001
Mb: flighted-flightless0.260<0.001
HWMb0.495<0.001
flighted-flightless0.0160.014
Mb: flighted-flightless0.148<0.001
Table 2. Summary of multivariate regressions for allometric variation of humeral shape based on Procrustes coordinates (Pcoor) on body mass (Mb) and centroid size (CS).
Table 2. Summary of multivariate regressions for allometric variation of humeral shape based on Procrustes coordinates (Pcoor) on body mass (Mb) and centroid size (CS).
Linear Modeladj R2p-value
CS0.256<0.001
Mb0.121<0.001
PGLSadj R2p-value
CS0.058<0.001
flighted-flightless0.056<0.001
CS: flighted-flightless0.0120.108
Mb0.0220.016
flighted-flightless0.057<0.001
Mb: flighted-flightless0.0140.074

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Serrano, F.J.; Costa-Pérez, M.; Navalón, G.; Martín-Serra, A. Morphological Disparity of the Humerus in Modern Birds. Diversity 2020, 12, 173. https://doi.org/10.3390/d12050173

AMA Style

Serrano FJ, Costa-Pérez M, Navalón G, Martín-Serra A. Morphological Disparity of the Humerus in Modern Birds. Diversity. 2020; 12(5):173. https://doi.org/10.3390/d12050173

Chicago/Turabian Style

Serrano, Francisco J., Mireia Costa-Pérez, Guillermo Navalón, and Alberto Martín-Serra. 2020. "Morphological Disparity of the Humerus in Modern Birds" Diversity 12, no. 5: 173. https://doi.org/10.3390/d12050173

APA Style

Serrano, F. J., Costa-Pérez, M., Navalón, G., & Martín-Serra, A. (2020). Morphological Disparity of the Humerus in Modern Birds. Diversity, 12(5), 173. https://doi.org/10.3390/d12050173

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