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            Rates of Dinosaur Body Mass Evolution Indicate 170 Million Years of Sustained Ecological Innovation on the Avian Stem Lineage

            Introduction Much of extant biodiversity may have arisen from a small number of adaptive radiations occurring on large spatiotemporal scales [1]–[3]. Under the niche-filling model of adaptive radiation, ecological opportunities arise from key innovations, the extinction of competitors, or geographic dispersal [1],[4],[5]. These cause rapid evolutionary rates in ecologically relevant traits, as diverging lineages exploit distinct resources. Rates of trait evolution then decelerate as niches become saturated, a pattern that has been formalised as the “early burst” model (e.g., [6],[7]). Most phylogenetic studies of adaptive radiations focus on small scales such as island radiations and other recently diverging clades, including Anolis lizards, cichlid fishes, and geospizine finches [2],[6],[8]–[10]. Detailed study of these model systems has demonstrated the importance of ecological and functional divergence as drivers of speciation early in adaptive radiations (e.g., [11],[12]). Surprisingly though, early burst patterns of trait evolution receive only limited support from model comparison approaches for these and other adaptive radiations occurring in geographically restricted areas and on short timescales ( 100 Ma, and most have individually targeted either the roots of exceptional modern clades such as birds or mammals (e.g., [19],[27],[28]) or extinct/depauperate clades (e.g., [29]–[31]; studies based on discrete characters). Thus, patterns of morphological evolution in major extinct clades, and their links to successful modern clades, are not well understood. Non-avian dinosaurs are an iconic group of terrestrial animals. They were abundant and ecologically diverse for most of the Mesozoic, and included extremely large-bodied taxa that challenge our understanding of size limits in terrestrial animals [32]. The first dinosaurs appeared more than 230 Ma ago in the Triassic Period, as small-bodied (10–60 kg), bipedal, generalists. By the Early Jurassic (circa 200 Ma), they dominated terrestrial ecosystems in terms of species richness [33],[34], and Cretaceous dinosaurs (145–66 Ma) had body masses spanning more than seven orders of magnitude (Figure 1A). Non-avian dinosaurs became extinct at the catastrophic Cretaceous/Paleogene (K/Pg) boundary event, at or near the peak of their diversity [35],[36]. In contrast, extant dinosaurs (neornithine birds) comprise around 10,000 species and result from one of the most important large-scale adaptive radiations of the Cenozoic [3],[21]. 10.1371/journal.pbio.1001853.g001 Figure 1 Dinosaur body masses. (A) Dinosaur body mass through time (the full set of mass estimates is given in Dataset S1). (B) Box-and-whisker plot showing median (dark line), hinges (box range), and ranges (whiskers) of body masses for major dinosaur groups. Outliers (circles) include the iguanodontians Mochlodon vorosi (31 kg), Elrhazosaurus, and Valdosaurus (both 48 kg), the sauropods Europasaurus (1,050 kg) and Magyarosaurus (746 kg), and the flightless avialan Gargantuavis (180 kg). The proposed drivers of early dinosaur diversification are controversial. Although various causal factors have been suggested to underlie a presumed adaptive radiation, few studies have tested the predictions of niche-filling models, and these have yielded equivocal results. An upright, bipedal gait, rapid growth, and possible endothermy have been proposed as key innovations of Triassic dinosaurs (reviewed by [34]), and mass extinctions during the Triassic/Jurassic boundary interval removed competing clades, perhaps leading to ecological release and rapid rates of body size evolution in Early Jurassic dinosaurs [37] (but see [34]). However, quantitative studies using body size proxies [34] and discrete morphological characters [33] have found only weak support for the niche-filling model during early dinosaur evolution, instead favouring gradualistic evolutionary rates. These studies focussed on the Late Triassic–Early Jurassic, so it is unclear whether Early Jurassic dinosaur evolution differed from later intervals (consistent with radiation following a mass extinction), or how the Middle Jurassic–Cretaceous radiation of birds and their proximate relatives relates to overall patterns of dinosaur diversification. We used phylogenetic comparative methods [6],[14],[38],[39] to analyse rates of dinosaur body mass evolution ( Materials and Methods ; Appendix S1). For this study, we compiled a large dataset of dinosaur body masses (441 taxa; Dataset S1) using the accurate scaling relationship of limb robustness (shaft circumference) derived from extant tetrapods [40] (Appendix S1; Dataset S1). Body mass affects all aspects of organismal biology and ecology (e.g., [41],[42]), including that of dinosaurs (e.g., [43]–[45]). Because of its relationship with animal energetics and first-order ecology, understanding the evolution of body mass is fundamental to identifying the macroevolutionary processes underlying biodiversity seen in both ancient and modern biotas. Therefore, by studying body mass evolution, we assess the broad pattern of niche filling in the assembly of dinosaur diversity through 170 Ma of the Mesozoic. In many hypotheses of adaptive radiation, ecological speciation is an important process generating both morphological and taxonomic diversity (e.g., [2]; but see [46]), according to which ecological differentiation is essentially simultaneous with lineage splitting [12]. In consequence, many large-scale studies of adaptive radiation have focussed on diversification rates (e.g., [17],[21],[47]). A correlation between diversification rates and morphological rates is consistent with adaptive radiation (e.g., [15]). However, even when this can be demonstrated, the occurrence of ecological speciation is difficult (perhaps impossible) to test in clades even only a few Ma old [48]. Methods for estimating diversification rates on non-ultrametric trees (e.g., those including deep time data) have recently become available [49]. However, these methods require accurate estimates of sampling probability during discrete time intervals, and it is not clear that it is possible to obtain such estimates from the dinosaur fossil record, which contains many taxa known only from single occurrences. Therefore, our study focuses on the predictions of niche-filling models of morphological evolution during adaptive radiation, as done in some previous studies (e.g., [6],[13]). Results Most of the earliest dinosaurs weighed 10–35 kg (Figure 1); Herrerasaurus was exceptionally large at 260 kg. Maximum body masses increased rapidly to 1,000–10,000 kg in sauropodomorphs, with especially high masses in early sauropods such as Antetonitrus (5,600 kg; Norian, Late Triassic) and Vulcanodon (9,800 kg; Early Jurassic), whereas minimum body masses of 1–4 kg were attained by Late Triassic ornithischians and theropods (Figure 1). Jurassic Heterodontosauridae (∼0.7 kg [50]), Middle Jurassic and younger Paraves (e.g., Epidexipteryx, 0.4 kg; Anchiornis, 0.7 kg), and Cretaceous Avialae (birds: 13–16 g to 190 kg [51]) extended this lower body size limit (Table 1). Archaeopteryx weighed 0.99 kg (the largest, subadult specimen [52]) and the Cretaceous sauropod Argentinosaurus weighed approximately 90,000 kg (Table 1). Our full set of mass estimates is available in Dataset S1 and a summary is presented in Table 1. 10.1371/journal.pbio.1001853.t001 Table 1 Estimated masses in kilograms of smaller- and larger-bodied adult representatives of major dinosaur groups, given to two significant figures. The standard error of all mass estimates is 0.135 log10(kg) [40]. Clade Smaller masses Larger masses Theropoda Theropoda (non-maniraptoran) Sinosauropteryx prima 0.99 Tyrannosaurus rex 7,700 Procompsognathus triassicus 1.13 Giganotosaurus carolinii 6,100 Maniraptora (non-avialan) Parvicursor remotus 0.14 Suzhousaurus megatherioides 3,100 Rahonavis ostromi 0.58 Gigantoraptor erlianensis 2,000 Avialae Qiliania graffini 0.013 Gargantuavis philoinos 190 Iberomesornis romerali 0.016 Hesperornis crassipes 24 Sauropodomorpha Basal Sauropodomorpha Pampadromaeus barberenai 8.5 Lufengosaurus magnus 2,300 Sauropoda Magyarosaurus dacus 750 Argentinosaurus huinculensis a 90,000 Europasaurus holgeri 1,000 Brachiosaurus altithorax 56,000 Lirainosaurus astibiae 1,800 Turiasaurus riodevensis 51,000 Ornithischia Heterodontosauridae Fruitadens haagarorum 0.73 Tianyulong confuciusi 0.74 Stegosauria Kentrosaurus aethiopicus 1,600 Dacentrurus armatus 7,400 Ankylosauria Saichania chulsanensis 610 Ankylosaurus magniventris 4,800 Pachycephalosauria Stegoceras validum 16 Pachycephalosaurus wyomingensis 370 Basal Ceratopsia Psittacosaurus sinensis 4.1 Leptoceratops gracilis 420 Ceratopsidae Centrosaurus apertus 2500 Triceratops horridus 14,000 Basal Iguanodontia Mochlodon vorosi 31 Iguanodon bernissartensis 15,000 Hadrosauroidea Gilmoreosaurus mongoliensis 1,300 Edmontosaurus regalis 7,600 “Probactrosaurus” mazongshanensis 1,500 Shantungosaurus giganteus 17,000 a Only a referred femur of Argentinosaurus is known: estimating its humeral circumference from the least-squares regression relationship between humeral and femoral circumferences for large sauropods (femoral circumferences >400 mm) yields a mass estimate of 67,400–124,000 kg (95% prediction interval). Our node height tests indicate that evolutionary rate estimates at phylogenetic nodes (standardised phylogenetically independent contrasts [39]) vary inversely with log-transformed stratigraphic age for most phylogenies (Figure 2). This relationship is significant (based on robust regression [14],[53]) for most phylogenies of non-maniraptoran dinosaurs, and for ornithischians and non-maniraptoran theropods when analysed separately (Figure 2B). This result is weakened, and becomes non-significant, when Triassic nodes are excluded (Figure S1). 10.1371/journal.pbio.1001853.g002 Figure 2 Node height test for early burst of rates of dinosaur body mass evolution. (A) Nodal evolutionary rate estimates (standardised independent contrasts [39],[89]) versus node age for data excluding (dashed lowess line) and including (solid lowess line) Maniraptora. (B–C) Box-and-whisker plots detailing results of: (B) robust regression of evolutionary rate on node age: slope (upper plot) and p-value (lower plot); (C) robust regression of evolutionary rate on nodal body mass: slope (upper plot) and p-value (lower plot). In (B–C) dashed lines occur at zero (upper plots) and 0.05 (lower plots: threshold for statistical significance). 1 = Dinosauria; 2 = Ornithischia; 3 = Sauropodomorpha; 4 = Theropoda; and 5 = Maniraptora. Declining evolutionary rates through time are not found in any analyses including maniraptorans. Indeed, when maniraptorans are added to analyses of Dinosauria, a burst of high nodal rate estimates is evident in lowess lines spanning the Middle Jurassic–Early Cretaceous interval of maniraptoran diversification (Figure 2A). Maniraptorans have a weakly positive (non-significant) relationship between evolutionary rates and body mass, and do not show diminishing evolutionary rates through time (Figure 2B–C). This contrasts with non-maniraptoran dinosaurs, in which evolutionary rates vary inversely with body mass (Figure 2C). Maximum-likelihood models [6],[38] were fitted to phylogenies calibrated to stratigraphy using the “equal” and “mbl” (minimum branch length) methods (see Materials and Methods ), and complement the results of our node height tests in showing support for early burst models only in analyses excluding Maniraptora (Table 2; Figure S2). Note, however, that the maximum-likelihood method has less statistical power to detect early burst patterns than does the node height test when even a small number of lineages escape from the overall pattern of declining rates through time [14]. Two models that predict saturation of trait variance through a clade's history were commonly supported in our analyses: the early burst model of exponentially declining evolutionary rates through time, and the Ornstein–Uhlenbeck (OU) model of attraction to a “trait optimum” value. Other models (e.g., Brownian motion, stasis) had negligible AICc weights in all or most (directional trend model) analyses (AICc is Akaike's information criterion for finite sample sizes). 10.1371/journal.pbio.1001853.t002 Table 2 Summary of maximum-likelihood model-fitting approaches, AICc weights (see also Figure S2), and parameter values provided in the form “median (minimum–maximum)” over a set of 60 time-calibrated phylogenies (for AICc weights) or for those phylogenies in which the model received an AICc weight greater than 0.3 (the number of which is given in the column “Number”). Early burst AICc weight Number (weight>0.3) β0 a Dinosauria 0.0000 (0–0.004) 0 NA NA Dinosauria (non-maniraptoran) 0.9615 (0–1) 33 0.043 (0.031–0.064) −0.014 (−0.008–0.016) Ornithischia 0.6445 (0.158–0.999) 50 0.039 (0.020–0.057) −0.010 (−0.005–0.017) Sauropodomorpha 0.6945 (0.002–1) 46 0.033 (0.016–0.081) −0.017 (−0.005–0.017) Theropoda 0.0000 (0–0) 0 NA NA Theropoda (non-maniraptoran) 0.7745 (0.048–0.999) 47 0.049 (0.033–0.085) −0.014 (−0.011–0.021) Maniraptora 0.0000 (0–0.0450) 0 NA NA Trend AICc weight Number (weight>0.3) β μ Dinosauria 0 (0–0) 0 NA NA Dinosauria (non-maniraptoran) 0 (0–0.007) 0 NA NA Ornithischia 0.1065 (0.001–0.357) 2 0.016 (0.016–0.016) 0.006 (0.006–0.006) Sauropodomorpha 0.001 (0–0.080) 0 NA NA Theropoda 0 (0–0) 0 NA NA Theropoda (non-maniraptoran) 0.008 (0–0.051) 0 NA NA Maniraptora 0.001 (0–0.430) 1 0.019 0.011 Ornstein–Uhlenbeck AICc weight Number (weight>0.3) β α Z0 θ Dinosauria 1.000 (0.996–1) 60 0.032 (0.022–0.045) 0.027 (0.016–0.047) 1.207 (−0.181–2.464) 2.349 (2.202–2.513) Dinosauria (non-maniraptoran) 0.037 (0–1) 29 0.025 (0.021–0.029) 0.020 (0.014–0.027) 1.370 (1.007–1.859) 2.722 (2.571–2.838) Ornithischia 0.036 (0–0.486) 9 0.020 (0.020–0.023) 0.010 (0.007–0.012) 1.383 (1.296–1.405) 2.453 (2.339–2.821) Sauropodomorpha 0.733 (0–1) 43 0.025 (0.016–0.058) 0.041 (0.017–0.116) 0.328 (−3.871–1.118) 3.658 (3.283–4.305) Theropoda 1 (1–1) 60 0.0465 (0.030–0.064) 0.039 (0.025–0.053) 1.434 (0.892–1.987) 1.923 (1.687–2.181) Theropoda (non-maniraptoran) 0.189 (0.001–0.940) 27 0.039 (0.028–0.046) 0.037 (0.026–0.044) 1.417 (1.095–1.974) 2.342 (2.226–2.472) Maniraptora 0.998 (0.451–1) 60 0.051 (0.024–0.078) 0.029 (0.009–0.051) 0.357 (−0.067–1.128) 0.907 (0.637–1.348) Parameters: β, Brownian variance (log10kg2/Ma) (∼evolutionary rate; stochastic rate for Ornstein–Uhlenbeck [OU] models; initial rate [β0 ] in early burst models); a, a parameter describing variation in evolutionary rates through time in early burst models; μ, the mean step length (log10kg/Ma), indicating directional evolution in trend models; α, the strength of attraction to a macroevolutionary optimum (θ) in OU models; Z0 , the ancestral node value (log10kg) in OU models; θ, the macroevolutionary optimum (log10kg) in OU models. Early burst models received high AICc weights for analyses of ornithischians, non-maniraptoran theropods, and non-maniraptoran dinosaurs when using the “equal” branch length calibration method (Table 2; Figure S2). Early burst models had comparable AICc weights to Ornstein–Uhlenbeck models for sauropodomorphs when using the “equal” branch length calibration method, and for ornithischians and non-maniraptoran theropods when using the “mbl” method. Early burst models had generally lower AICc weights for non-maniraptoran dinosaurs and for sauropodomorphs when using the “mbl” branch length calibration method (Table 2; Figure S2). Support from some phylogenies for Ornstein–Uhlenbeck models of attraction to a large body size optimum from small ancestral body sizes [54],[55] in ornithischians [56], non-maniraptoran theropods, and especially sauropodomorphs and non-maniraptoran dinosaurs (Table 2; Figure S2), suggests the occurrence of Cope's rule in dinosaurs. All phylogenies provide strong support for this pattern in maniraptorans (Table 2). Exceptionally high rates at individual nodes in our phylogenies were identified as down-weighted datapoints in robust regression analyses [14],[53]. Five sets of exceptional nodes in the Triassic–Early Jurassic represent rapid evolutionary shifts from primitive masses around 10–35 kg to large body masses in derived sauropodomorphs (>1,000 kg), armoured ornithischians (Thyreophora; Figure 1B) and theropods (Herrerasaurus, and derived taxa such as Liliensternus (84 kg) and Dilophosaurus (350 kg)), and to smaller body sizes in heterodontosaurid ornithischians (Figure 3; Table 3). Rapid body size changes were rare in later ornithischians and sauropodomorphs, which each show only one exceptional Jurassic node, marking the origin of body sizes greater than 1,000 kg in derived iguanodontians, and of island dwarfism in the sauropod Europasaurus [57]. By contrast, up to six exceptional Jurassic nodes occur in theropod evolution, with especially high contrasts at the origins of body sizes exceeding 750 kg in Tetanurae, and marking phylogenetically nested size reductions on the line leading to birds: in Coelurosauria (e.g., Ornitholestes, 14 kg; Zuolong, 88 kg) and in Paraves, which originated at very small body masses around 1 kg [58]. 10.1371/journal.pbio.1001853.g003 Figure 3 Dinosaur phylogeny showing nodes with exceptional rates of body size evolution. Exceptional nodes are numbered and indicated by green filled circles with diameter proportional to their down-weighting in robust regression analyses (Appendix S1). Details of these nodes are given in Table 2. The sizes of shapes at tree tips are proportional to log10(mass), and silhouettes are indicative of approximate relative size within some clades. The result from one tree calibrated to stratigraphy by imposing a minimum branch duration of 1 Ma is shown; other trees and calibration methods retrieve similar results. 10.1371/journal.pbio.1001853.t003 Table 3 Details of body size changes at exceptional nodes indicated in Figure 3. Node Description Clade Date Polarity Hypothesis 1 Origin of large body size in the early theropod Herrerasaurus (260 kg) Thero. Triassic Increase Macropredation 2 Origin of large body size in derived theropods such as Liliensternus (84 kg) and Dilophosaurus (350 kg) Thero. Triassic Increase Macropredation 3 Origin of large body size exceeding 1,000 kg in sauropodomorphs such as Plateosauravus (1,300 kg) and sauropods (Table 1) Sauro. Triassic Increase Bulk herbivory 4 Origin of large body size in armoured ornithischian dinosaurs (thyreophorans; Figure 1B) Ornith. Triassic/Jurassic Increase Bulk herbivory 5 Origin of small body size in heterodontosaurid ornithischians (∼0.7 kg; Table 1) Ornith. Triassic/Jurassic Decrease Specialised herbivory 6 Origin of small body size in Paraves, which has very small primitive body mass—around 1 kg (Anchiornis, 0.68 kg; Microraptor, 1.5 kg; Archaeopteryx, 0.97 kg (subadult)) Thero. Jurassic Decrease ? 7 Origin of small body size in Coelurosauria (e.g., Ornitholestes, 14 kg; Zuolong, 88 kg) Thero. Jurassic Decrease ? 8 Origin of large body size in Tetanurae (from 750 kg in Piatnitzkysaurus). Thero. Jurassic Increase Increased macropredation 9 Origin of small body size in compsognathid coelurosaurs (Compsognathus, 1.6–2.3 kg) Thero. Jurassic Decrease ? 10 Origin of large body size in some ceratosaurs (Ceratosaurus, 970 kg) Thero. Jurassic Increase Increased macropredation 11 Origin of small body size in the island dwarf sauropod Europasaurus (1,000 kg) Sauro. Jurassic Decrease Island dwarfing 12 Origin of large body sizes exceeding 1,000 kg in derived iguanodontians such as Camptosaurus Ornith. Jurassic Increase Bulk herbivory 13 Origin of large body size in the ornithuromorph birds Yanornis (1.5 kg) and Yixianornis (0.31 kg), compared with related taxa such as Longicrusavis (0.052 kg) and Hongshanornis (0.031 kg) Thero. Cretaceous Increase ?Wading 14 Origin of large body size in aquatic hesperornithiform birds (e.g., Baptornis, 4.9 kg; Hesperornis, 24 kg) Thero. Cretaceous Increase Aquatic life 15 Origin of large body size in Tianyuraptor (20 kg) compared with other microraptoran paravians (e.g., Graciliraptor, 1.8 kg; Microraptor, 1.5 kg) Thero. Cretaceous Increase ? 16 Origin of large body size in the unenlagiine dromaeosaurids Unenlagia (63 kg) and Austroraptor (519 kg) Thero. Cretaceous Increase Macropredation 17 Origin of large body size in herbivorous therizinosaurian maniraptorans (e.g., Falcarius, 84 kg; Suzhousaurus, 3,000 kg) Thero. Cretaceous Increase Bulk herbivory 18 Origin of large body size in the oviraptorosaur Gigantoraptor (2,000 kg) Thero. Cretaceous Increase ? 19 Origin of small body size in parvicursorine alvarezsauroids.(e.g., Parvicursor, 0.14 kg; Mononykus, 4.7 kg) Thero. Cretaceous Decrease ? 20 Origin of large body size in ornithomimosaurian coelurosaurs (e.g., Shenzhousaurus, 17 kg; Gallimimus, 480 kg; Beishanlong, 620 kg) Thero. Cretaceous Increase ?Herbivory 21 Origin of large body sizes in carcharodontosaurid tetanurans (Giganotosaurus, 6,100 kg; Mapusaurus, 4,100 kg; Carcharodontosaurus, 3,000 kg) Thero. Cretaceous Increase Increased macropredation 22 Origin of small body size in island dwarf rhabdodontid iguanodontians (e.g., Mochlodon vorosi, 31 kg) Sauro. Cretaceous Decrease Island dwarfing 23 Origin of large body size in Ceratopsidae (Figure 1B) Ornith. Cretaceous Increase Bulk herbivory Ornith., Ornithischia; Sauro., Sauropodomorpha; Thero., Theropoda. The contrast between theropods and other dinosaurs is even greater in the Cretaceous, when no exceptional nodes occur in Sauropodomorpha, and only two in Ornithischia: at the origins of large-bodied Ceratopsidae and island dwarf rhabdodontid iguanodontians (e.g., Mochlodon [59]). At least nine shifts occurred during the same interval of theropod evolution, including seven in maniraptorans (Figure 3; Table 3). Discussion Niche-filling Patterns of Dinosaur Body Size Evolution Patterns of dinosaur body size evolution are consistent with the niche-filling model of adaptive radiation [1],[4],[6]. Early dinosaurs exhibit rapid background rates of body size evolution, and a predominance of temporally rapid, order-of-magnitude shifts between body size classes in the Triassic and Early Jurassic. These shifts reflect radiation into disparate ecological niches such as bulk herbivory in large-bodied sauropodomorphs (e.g., [60]) and thyreophoran ornithischians, herbivory using a complex masticating dentition in small-bodied heterodontosaurids (e.g., [61],[62]), and increasing diversity of macropredation in large theropods (Table 3). Subsequently, rates of body size evolution decreased, suggesting saturation of coarsely defined body size niches available to dinosaurs in terrestrial ecosystems, and increasingly limited exploration of novel body size space within clades. The early burst pattern of dinosaurian body size evolution is substantially weakened when Triassic data are excluded (Figure S1). This suggests that key innovations of Triassic dinosaurs (e.g., [63],[64]), and not the Triassic/Jurassic extinction of their competitors [37], drove the early radiation of dinosaur body sizes [34]. Indeed, phylogenetic patterns indicate that many basic ecomorphological divergences occurred well before the Triassic/Jurassic boundary. It is not clear which innovations allowed dinosaurs to radiate [34], or whether the pattern shown here was part of a larger archosaurian radiation [65]. However, the evolution of rapid growth rates may have been important [64], especially in Sauropodomorpha [66], and the erect stance of dinosaurs and some other archosaurs [34] might have been a prerequisite for body size diversification via increased efficiency/capacity for terrestrial weight support [63]. Maniraptoran theropods are an exception to the overall pattern of declining evolutionary rates through time: exhibiting numerous instances of exceptional body size shifts, maintaining rapid evolutionary rates, and generating high ecological diversity [67],[68], including flying taxa. Although a previous study found little evidence for directional trends of body size increase in herbivorous maniraptoran clades [69], this does not conflict with our observation that some body size shifts in maniraptorans (and other coelurosaurs) coincide with the appearance of craniodental, or other, evidence for herbivory (Table 3; e.g., [67],[68],[70]). Much of our knowledge of Late Jurassic and Early Cretaceous maniraptorans comes from a few well-sampled Chinese Lagerstätten, such as the Jehol biota. Without information from these exceptional deposits, we would have substantially less knowledge of divergence dates and ancestral body sizes among early maniraptorans. However, this is unlikely to bias comparisons between maniraptorans and other groups of dinosaurs for two reasons: (1) these deposits provide equally good information on the existence and affinities of small-bodied taxa in other clades, such as Ornithischia; and (2) exceptional information on early maniraptoran history should bias analyses towards finding an early burst pattern in maniraptorans. Inference of high early rates in Maniraptora would be more likely, due either to concentration of short branch durations at the base of the tree (especially using the “mbl” stratigraphic calibration method), or observation of additional body size diversity at the base of the tree that would remain undetected if sampling was poor. We cannot speculate as to the effects on our analyses of finding comparable Lagerstätten documenting early dinosaur history. However, there is currently little positive evidence that the general patterns of body size evolution documented here are artefactual. Many stratigraphically younger dinosaurs, especially non-maniraptorans, exhibit large body size and had slow macroevolutionary rates, possibly due to scaling of generation times (e.g., [71],[72]). Scaling effects are observed across Dinosauria, but show substantial scatter (non-significant; Figure 2C) within Ornithischia and Sauropodomorpha, consistent with previous suggestions that scaling effects should be weak in dinosaurs because of the life history effects of oviparity [73]. Small dinosaurs (10–50 kg) had the highest evolutionary rates, and rates attenuated only weakly, or not at all, at sizes below 10 kg (Figure S3). This might have been key to maniraptoran diversification from small-bodied ancestors, and also explains the origins of fundamentally new body plans and ecotypes from small-bodied ancestors later in ornithischian history (Iguanodontia, Ceratopsidae; Figure 1). Body Size, Ecological Diversity, and Cenozoic Survival Maniraptora includes Avialae, the only dinosaur clade to frequently break the lower body size limit around 1–3 kg seen in other dinosaurs. It is likely that more niches are available to birds (and mammals) around 100 g in mass [41],[74], so obtaining smaller body sizes might have contributed to the ecological radiation of Mesozoic birds (e.g., [27],[75]). If the K/Pg extinction event was ecologically selective, vigorous ecological diversification may have given maniraptoran lineages a greater chance of survival: Avialae was the only dinosaurian clade to survive, perhaps because of the small body sizes of its members. Although the fossil record of birds is inadequate to test hypotheses of K/Pg extinction selectivity, it is clear that smaller-sized squamates and mammals selectively survived this event [76],[77]. Therefore, our results suggest that rapid evolutionary rates within Maniraptora paved the way for a second great adaptive radiation of dinosaurs in the wake of the K/Pg extinction event: the diversification of neornithine birds [21]. Implications for Adaptive Radiation Theory Our findings complement recent studies of diversification rates in the avian crown group [3],[21], and suggest that birds, the most speciose class of tetrapods, arose from a long evolutionary history of continual ecological innovation. Our most striking finding is of sustained, rapid evolutionary rates on the line leading to birds (i.e., in maniraptorans) for more than 150 Ma, from the origin of dinosaurs until at least the end of the Mesozoic. Rates of evolution declined through time in most dinosaurs. However, this early burst pattern, which characterises the niche-filling model of adaptive radiation [6],[7], does not adequately describe evolution on the avian stem lineage. The recovered pattern of sustained evolutionary rates, and the repeated generation of novel ecotypes, suggests a key role for the maintenance of evolvability, the capacity for organisms to evolve, in the evolutionary success of this lineage. Evolvability might have also played a central role in the evolution of other major groups such as crustaceans [78] and actinopterygians [15], supporting its hypothesised importance in organismal evolution [79]. Rapid evolutionary rates observed during the early evolutionary history of Dinosauria, which decelerated through time in most subclades, indicate that much of the observed body size diversity of dinosaurs was generated by an early burst pattern of trait evolution. However, this pattern becomes difficult to detect when data from early dinosaurian history are not included in analyses (Figure S1), consistent with the observation that deep time data improve model inference in simulations [24]. The pruning of lineages by extinction might also overwrite the signals of ancient adaptive radiation in large neontological datasets. For example, Rabosky et al. [15] recovered slow evolutionary rates at the base of the actinopterygian tree, but the fossil record reveals substantial morphological and taxonomic diversity of extinct basal actinopterygian lineages [80],[81]. Although it has not yet been tested quantitatively, this diversity might have resulted from early rapid rates across Actinopterygii, as observed here across Dinosauria. If our results can be generalised, they suggest that the unbalanced distribution of morphological and ecological diversity among clades results from the maintenance of rapid evolutionary rates over vast timescales in key lineages. These highly evolvable lineages may be more likely to lead to successful modern groups such as birds, whereas other lineages show declining evolutionary rates through time. Declining evolutionary rates in dinosaurian lineages off the line leading to birds indicate large-scale niche saturation. This might signal failure to keep pace with a deteriorating (biotic) environment (the Red Queen hypothesis [82],[83]), with fewer broad-scale ecological opportunities than those favouring the early radiation of dinosaurs. There is strong evidence for Red Queen effects on diversification patterns in Cenozoic terrestrial mammals [22], and it is possible that a long-term failure to exploit new opportunities characterises the major extinct radiations of deep time (and depauperate modern clades), whether or not it directly caused their extinctions. Materials and Methods We used phylogenetic comparative methods to analyse rates of dinosaur body mass evolution [6],[14],[38],[39] (Appendix S1). Body mass, accompanied by qualitative observations (Table 3), was used as a general ecological descriptor. Body mass was estimated for all dinosaurs for which appropriate data were available (441 taxa; Dataset S1) using the empirical scaling relationship of limb robustness (stylopodial circumference) with body mass, derived from extant tetrapods [40] (Appendix S1). We analysed log10-transformed data (excluding juveniles), which represent proportional changes in body mass. Stylopodial shaft circumferences are infrequently reported in the literature, so many were taken from our own measurements, or were calculated from shaft diameters (Appendix S1). Previous large datasets of dinosaurian masses were based on substantially less accurate methods, using the relationship between linear measurements (e.g., limb bone lengths) and volumetric models of extinct dinosaurs ([84]–[86]; reviewed by [40]). Quantitative macroevolutionary models were tested on composite trees compiled from recent, taxon-rich cladograms of major dinosaur groups (Appendix S1; Figure S4, Figure S5, Figure S6, Figure S7). Phylogenetic uncertainty was reflected by analysing alternative topologies and randomly resolved polytomies (Appendix S1). Tip heights and branch durations were stratigraphically calibrated, and zero-length branches were “smoothed” using two methods: (1) by sharing duration equally with preceding non-zero length branches (the “equal” method [87]); and (2) by imposing a minimum branch length of 1 Ma (the “mbl” method [88]). We used maximum-likelihood model comparison [6],[38] and “node height” test [14],[39] methods (Appendix S1) to test the prediction of the niche-filling hypothesis: that rates of morphological evolution diminish exponentially through time after an adaptive radiation [1],[2],[4]. The node height test treats standardised independent contrasts [89] as nodal estimates of evolutionary rate [39] and tests for systematic deviations from a uniform rate Brownian model, using regression against log-transformed geological age (robust regression [14],[53]). We also regressed standardised contrasts against nodal body mass estimates (a proxy for generation time and other biological processes that might influence evolutionary rates). As well as testing for a “background” model of declining evolutionary rates through time, robust regression identifies and down-weights single nodes deviating substantially from the overall pattern [14],[53]. These nodes represent substantial, temporally rapid, niche-shift events [14], following the macroecological principle that organisms in different body size classes inhabit different niches and have different energetic requirements [41]. We used lowess lines to visualise non-linear rate variation with time and body mass. Exponentially declining rates of evolution through time, predicted by the niche-filling model of adaptive radiation [1]–[3], were also tested by comparing the fit of an early burst model [6],[7] with other commonly used models: Brownian motion, directional evolution (“trend”), the Ornstein–Uhlenbeck model of evolution attracted to an optimum value, and stasis (“white noise”) [38],[56],[90] (Appendix S1). Explicit mathematical models of trait evolution on our phylogenies were fitted using the R packages GEIGER version 1.99–3 [91] and OUwie version 1.33 [55] (for Ornstein–Uhlenbeck (OU) models only), and compared using AICc [92],[93]. Unlike GEIGER, OUwie allows estimation of a trait optimum (θ) that is distinct from the root value (Z0) in OU models. Values from GEIGER and OUwie are directly comparable: identical log likelihood, AICc, and parameter estimates are obtained for test datasets when fitting models implemented in both packages (Brownian motion in all instances; and OU models when θ = Z0 for ultrametric trees); although note that comparable standard error values entered to the OUwie function of OUwie 1.33 are the square of those entered to the fitContinuous function of Geiger 1.99–3. The algorithm used to fit OU models in GEIGER 1.99–3 is inappropriate for non-ultrametric trees (personal communication, Graham Slater to R. Benson, December 2013). This problem is specific to OU models implemented by GEIGER 1.99–3, and does not affect the other models that we tested. GEIGER 1.99–3 fits models of trait evolution using independent contrasts, after rescaling the branch lengths of the phylogenetic tree according to the model considered [7]. For all models, except the OU model in the case of non-ultrametric trees, the covariance between two taxa i and j can be written as a function of the path length sij shared between the two taxa (e.g., [6],[7]). The tree can thus easily be rescaled by applying this function to the height of each node before computing independent contrasts. In the case of the OU model, the covariance between two taxa i and j is a function of both the shared (pre-divergence) portion of their phylogenetic history and the non-shared (post-divergence) portion [54]. In the case of an ultrametric tree, the non-shared portion can also be written as a function of sij (it is simply the total height T of the tree, minus sij [90],[94]), and the corresponding scaling function can be applied to the tree (this is what is performed in GEIGER 1.99.3). However, in the case of a non-ultrametric tree, the post-divergence portion of the covariance cannot be written as a function of sij, so there is no straightforward scaling function to apply. Instead, it is necessary to fit the model by maximum likelihood after computing the variance–covariance matrix. This is what is implemented in OUwie, and now in GEIGER 2.0 (personal communication, Josef Uyeda to R. Benson, January 2014). Our data and analytical scripts are available at DRYAD [95]. Supporting Information Figure S1 Node height test for early burst of rates of dinosaur body mass evolution excluding Triassic nodes. Results of robust regression of evolutionary rate on node age: (A) slope; (B) p-value. Dashed lines occur at zero (A) and 0.05 (B); 1 = Dinosauria; 2 = Ornithischia; 3 = Sauropodomorpha; 4 = Theropoda; and 5 = Maniraptora. (TIF) Click here for additional data file. Figure S2 AICc weights of maximum likelihood models using different trees and time calibration methods. AICc weights are shown for early burst (1–5), trend (6), and Ornstein–Uhlenbeck (7) models. (A) Trees including the Yates topology for non-sauropodan sauropodomorphs (Figure S6), and calibrated using the “equal” method ( Materials and Methods ). (B) Trees including the Upchurch topology for non-sauropodan sauropodomorphs (Figure S7), and calibrated using the “equal” method. (C) Trees including the Yates topology for non-sauropodan sauropodomorphs, and calibrated using the “mbl” method ( Materials and Methods ). (D) Trees including the Upchurch topology for non-sauropodan sauropodomorphs, and calibrated using the “mbl” method. (TIF) Click here for additional data file. Figure S3 A possible non-linear relationship between macroevolutionary rate and nodal body mass. (A) Based on one phylogeny calibrated using the “equal” method ( Materials and Methods ). (B) Based on one phylogeny calibrated using the “mbl” method ( Materials and Methods ). The (solid) lowess lines suggests that rates decrease with body mass above ∼10−50 kg, but might also decline with a shallower gradient below ∼10−50 kg. The dashed lines show the fitted linear robust regressions. (TIF) Click here for additional data file. Figure S4 Composite tree of ornithischian dinosaur relationships used in the present study. Polytomies were resolved randomly prior to analyses. Details of tree construction are given in Appendix S1. (TIF) Click here for additional data file. Figure S5 Composite tree of theropod dinosaur relationships used in the present study. Polytomies were resolved randomly prior to analyses. Details of tree construction are given in Appendix S1. (TIF) Click here for additional data file. Figure S6 Composite tree of sauropodomorph relationships used in the present study, using the Yates topology for non-sauropodans. Polytomies were resolved randomly prior to analyses. Details of tree construction are given in Appendix S1. (TIF) Click here for additional data file. Figure S7 Composite tree of sauropodomorph relationships used in the present study, using the Upchurch et al. topology for non-sauropodans. Polytomies were resolved randomly prior to analyses. Details of tree construction are given in Appendix S1. (TIF) Click here for additional data file. Table S1 Summary of ordinary least-squares regression relationships between femoral and humeral anteroposterior and mediolateral shaft diameters for groups. N, sample size; R2, coefficient of determination. (DOC) Click here for additional data file. Table S2 Proportions of phylogenies for which data simulated under a constant rate Brownian motion model generated robust regression slopes (node height test) shallower than those observed in the data in fewer than 0.05, 0.10, 0.15, or 0.20 of simulated datasets. Analyses excluding Maniraptora are shaded in grey, and results based only on phylogenies calibrated to stratigraphy different methods (see Materials and Methods ) are additionally presented for Dinosauria. ** indicates cases in which all phylogenies reject the constant rate model at the specified threshold, and * indicates cases in which most phylogenies reject the constant rate model at the specified threshold. Values should not be regarded as p-values, but generally concur with the p-values of our robust regression fits (Figure 2B). (DOC) Click here for additional data file. Appendix S1 Additional methods and results. (DOC) Click here for additional data file. Dataset S1 Complete dataset and mass estimates. (XLS) Click here for additional data file.
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                2019
                November 13 2019
                : 339-404
                10.1007/978-3-030-25865-8_15
                d1b72ba5-7089-456c-a2ec-bbeed67807bc
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