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Variation in Craniomandibular Morphology and Sexual Dimorphism in Pantherines and the Sabercat Smilodon fatalis

Abstract

Sexual dimorphism is widespread among carnivorans, and has been an important evolutionary factor in social ecology. However, its presence in sabertoothed felids remains contentious. Here we present a comprehensive analysis of extant Panthera and the sabertoothed felid Smilodon fatalis. S. fatalis has been reported to show little or no sexual dimorphism but to have been intraspecifically variable in skull morphology. We found that large and small specimens of S. fatalis could be assigned to male and female sexes with similar degrees of confidence as Panthera based on craniomandibular shape. P. uncia is much less craniomandibularly variable and has low levels of sexual size-dimorphism. Shape variation in S. fatalis probably reflects sexual differences. Craniomandibular size-dimorphism is lower in S. fatalis than in Panthera except P. uncia. Sexual dimorphism in felids is related to more than overall size, and S. fatalis and the four large Panthera species show marked and similar craniomandibular and dental morphometric sexual dimorphism, whereas morphometric dimorphism in P. uncia is less. Many morphometric-sexually dimorphic characters in Panthera and Smilodon are related to bite strength and presumably to killing ecology. This suggests that morphometric sexual dimorphism is an evolutionary adaptation to intraspecific resource partitioning, since large males with thicker upper canines and stronger bite forces would be able to hunt larger prey than females, which is corroborated by feeding ecology in P. leo. Sexual dimorphism indicates that S. fatalis could have been social, but it is unlikely that it lived in fusion-fission units dominated by one or a few males, as in sub-Saharan populations of P. leo. Instead, S. fatalis could have been solitary and polygynous, as most extant felids, or it may have lived in unisexual groups, as is common in P. leo persica.

Introduction

Sexual dimorphism is common among mammals and strong sexual dimorphism is usually present in species with a polygynous social ecology, and is thought to reflect increased male-male competition for access to breeding females [1][6]. Among carnivores, sexual dimorphism in the size of the skull, canine and carnassial teeth is widespread and appears to be most pronounced in felids; this is also thought to be related to breeding ecology and not to diet, habitat or activity patterns [7], [8]. Felids contrast with other well-studied mammal groups, such as primates, where diurnal species are generally more sexually dimorphic than nocturnal species, probably because of increased importance of sexual agonistic display during the day [1], and terrestrial species tend to be more strongly sexual dimorphic than arboreal species, probably as a result of increased predation in terrestrial habitats [6], [9], [10].

Sexual size-dimorphism is common among extant felids, and male traits are on average usually significantly larger than those of females on the basis of the cranial, mandibular, and dental measurements [7], [11][17]. Such sexual dimorphism of craniodental and mandibular size-traits is a common feature of carnivorans in general [6][8], [18][26]. Sexual size-dimorphism is an intrinsic feature of carnivoran evolutionary morphology and ecology. However, extant felids are only one of two large subgroups within the Felidae. The Machairodontinae or sabertoothed felids were a widespread and common group of often large species, which were in most cases highly specialised for large-vertebrate predation [27][32]. Sexual dimorphism has been invoked as explanation for morphological differences in the geographically widespread Megantereon, but purported sexual differences are likely to reflect species differences instead [17]. Most sabertoothed felids are found in far too low numbers to allow analysis of sexual dimorphism but its widespread presence across the entire Carnivora, and the usually strongly pronounced sexual dimorphism in extant felids relative to most other carnivorans would indicate that it was probably present.

The sabertoothed felid Smilodon fatalis from the Late Pleistocene is the only machairodont taxon hitherto recovered in sufficient numbers to allow inferences of sexual dimorphism, although a recent surge of Amphimachairodus giganteus specimens from China implies that analyses of this species will also be possible in the near future. The largest known sample of S. fatalis hails from various excavation pits at Rancho La Brea, now a 23 acre park in the western part of the City of Los Angeles. Miller [33] estimated the sample size of this species to be 2100 individuals based on the Hancock Collection specimens that were recovered in 1913-15. That collection contains approximately 650 crania in various states of completeness. Subsequent excavations have recovered cranial parts of a further 79 individuals from Pit 91, and 28 individuals from Project 23; neither excavation has yet been completed. S. fatalis is the second-most abundant taxon at Rancho La Brea next to the dire wolf (Canis dirus) [34].

There is disagreement as to whether or not S. fatalis shows sexual dimorphism. An often cited feature of the La Brea assemblage of S. fatalis skulls supposedly indicating a lack of sexual dimorphism is that the size-distribution of adult skulls does not fall into two distinct (bimodal) size-clusters, supposedly indicating merging of two normally distributed samples with different sample averages [33], [35], [36]. However, it has not yet been established that bimodal size-clusters is a species-level characteristic of sexually size-dimorphic felids. Based on cranial and carnassial size, a low degree of sexual dimorphism has been inferred in S. fatalis [8], which is corroborated by analyses of postcranial material [35]. Both studies concluded that sexual dimorphism in S. fatalis was less than in extant large felids, notably the lion (Panthera leo). In contrast, a study of mandible size [36] found no evidence of sexual dimorphism. If S. fatalis truly was sexually non-dimorphic this would likely have had implications for its social ecology and would have exemplified a distinctly atypical socioevolutionary trait among the Felidae.

Even if this suggestion might sound unlikely it is not inconceivable given that the Machairodontinae shared a last common ancestor with the Felinae at no less than 13 MYA, as indicated by the approximate ages of primitive sabercats such as Nimravides, Machairodus, or Miomachairodus [30], [32]. Additionally, the predatory ecology of most machairodonts probably differed substantially from those of extant felids in a number of ways [30], [37][49]. Against such a notion in terms of the phylogenetic bracket [50] stands the fact that sexual dimorphism is widespread across not only the entire Carnivora but the Vertebrata, even Animalia. Sexual dimorphism has been documented in a variety of other mammals [6], [51], as well as other vertebrate groups, such as pterosaurs [52], dinosaurs [53][55], birds [56][58], reptiles [59][62], and fish [63][66]. Sexual dimorphism is also widespread and often strongly expressed in a wide variety of insect groups [67][74]. In most cases male-male competition for access to resources and/or breeding females is considered to have been a prominent evolutionary selective parameter.

It has also been noted that crania of S. fatalis from Rancho La Brea collectively show marked intraspecific variation [75], which some [34] have even considered equivalent to the degree of interspecific morphological differentiation among extant felids. This has hitherto not been tested and, if true, could potentially influence inferences of sexual dimorphism depending on sample size and from where the specimens were selected. Intraspecifc morphological diversity, if present, could be accounted for in terms of sexual dimorphism of morphological traits, not merely size. Analysing this would likely require greater samples sizes than the 10–20 individuals used in previous studies [8], [35], [36]. Alternatively, elevated morphological variation could be a function of increased interspecific competition among an unusually rich, varied fauna of large, powerful predators [76].

In studies of sexual dimorphism, it is often overlooked that at least some extant felids, notably the more well-studied pantherines, are not merely sexually dimorphic with respects to trait size, but appear to show genuine sexual differences in certain aspects of craniodental morphology, as originally recognised by Reginald Pocock [77]. Accordingly, males appear not to be simply scaled-up versions of females, but in certain traits appear to be morphologically different, graphically demonstrated by the once widely held but erroneous notion that skulls of Asian male leopards belonged to a different species than the smaller skulls from the so-called panther [78], [79], but which later turned out to be from females. Other great cats also show pronounced morphological differences between the sexes [16]. Accordingly, if S. fatalis was sexually dimorphic, it is conceivable that it too would show distinct morphological differences between males and females, and that size-analyses may be only one way of approaching this issue.

Materials and Methods

Data samples

Collectively, the excavation pits of Rancho La Brea cover an estimated age span of ∼55-9 KYA [80][83]. The fact that many recovered skulls are fragmentary may in part be due to the movement of the asphaltum. Complete skulls are generally well preserved with little, if any, distortion, but the enormous upper canines are usually missing or broken [34]. For the purpose of this analysis it was required that specimens were fully adult, as evidenced by closure of cranial, particularly basicranial, sutures and in near complete and undistorted condition. Some have suggested that the body size in S. fatalis may have fluctuated slightly across time [81], [84] and, accordingly, we chose to restrict analyses to Pit 61 and Pit 67 which were, in all likelihood, one assemblage and contain a large sample of adult S. fatalis skulls and mandibles in good condition, of which a total of 79 crania and 61 mandibles were deemed suitable for analysis.

Field notes on file at the Page Museum indicate that Pit 61 was located in and on the bank of a small pond adjacent to Pit 4 and under the spoil pile from Pit 4. Excavation commenced on September 17 1914 and continued through June 5 1915 to a depth of 20 feet. Pit 61 was interpreted as a series of connected pockets of bone ranging in size from half a cubic yard to ten or more cubic yards rather than as one continuous deposit as in, e.g., Pits 3, 4, 9, or 16. Catalogued skulls comprised 64 Smilodon fatalis; 99 dire wolf (Canis dirus); 7 coyote (C. latrans); 2 large and one small ground sloth (Paramylodon harlani and Nothrotheriops shastensis), and one each of horse (Equus occidentalis), deer (Odocoileus sp.), and lion-like cat, Panthera atrox [85].

Field notes on file at the Page Museum indicate that Pit 67 was located on the north edge of the pond adjacent to Pit 4 and north of Pit 61. It was excavated from October 28 1914 through June 21 1915. The location next to the pond and an unusually wet winter made excavation difficult and slumping of the excavation walls was frequent, which was unfortunate since a number of archaeological artefacts were recovered from Pits 61 and 67, and their association with extinct elements of the fauna are uncertain. The excavators decided that Pits 61 and 67 were parts of the same fossil deposit; in support of this, parts of an American mastodon (Mammut americanum) skeleton were recovered from both localities that appear to belong to the same individual. Pit 67 was also excavated to a depth of 20 feet. Catalogued skulls from Pit 67 included 120 S. fatalis; 118 C. dirus; 13 C. latrans; six large and six small ground sloth skulls (P. harlani and N. shastensis); three horses (E. occidentalis); three bison (Bison antiquus); and one P. atrox. Dates from Pits 61–7 include one of 4,450 radiocarbon years (5,063 calendar years) for an atlatl shaft, but five S. fatalis femora dates range from 11,130 radiocarbon years (13,025 calendar years BP) to 12,200 radiocarbon years (14,304 calendar years) [83].

For comparison with S. fatalis we used all five extant Panthera or great cats, the lion (Panthera leo); jaguar (P. onca); leopard (P. pardus); tiger (P. tigris); and snow leopard (P. uncia). For comparisons of overall cranial and mandible size, we measured condylobasal and mandibular length, respectively, in a sample of 931 specimens comprising: P. leo (crania: n = 247, 140♂, 107♀; mandibles: n = 189, 103♂, 86♀); P. onca (crania: n = 93, 55♂, 38♀; mandibles: n = 70, 42♂, 28♀); P. pardus (crania: n = 303, 198♂, 105♀; mandibles: n = 247, 153♂, 94♀); P. tigris (crania: n = 192, 96♂, 96♀; mandibles: n = 165, 81♂, 84♀); and P. uncia (crania: n = 43, 17♂, 26♀; mandibles: n = 32, 13♂, 19♀). For morphometric and geometric morphometric (shape) comparisons we used a slightly smaller database of 686 specimens (Table S1): P. leo (crania: n = 247, 144♂, 103♀; mandibles: n = 177, 102♂, 75♀); P. onca (crania: n = 71, 42♂, 29♀; mandibles: n = 49, 27♂, 22♀); P. pardus (crania: n = 152, 102♂, 50♀; mandibles: n = 132, 83♂, 49♀); P. tigris (crania: n = 183, 101♂; 82♀; mandibles: n = 119, 69♂, 50♀); and P. uncia (crania: n = 33, 13♂, 20♀; mandibles: n = 27, 13♂, 14♀). All specimens were fully adult as evidenced by closure of cranial sutures.

Several of the included pantherines vary in size and morphology across their biogeographic ranges, and to ensure adequate representation of the morphological variation characteristic of the species and not merely populations within it, specimens were sampled from a comprehensive portion of the known biogeographic range and purported subspecies. Historically, the proposed nature of intraspecific variation and subsequent proposition of subspecies varies widely in the included species. The number of apparently valid lion subspecies appears not to be greatly different from the traditionally proposed eight [86], [87], although the actual number and biogeographic distribution is still debated [88][91]; all of the traditionally proposed lion subspecies were included (azandica, bleyenberghi, krugeri, leo, melanochaita, nubica, persica, senegalensis). Although a number of subspecies of jaguar have traditionally been proposed, most often eight [92], [93], but occasionally even twice as many [94], recent studies of morphological and molecular diversity have failed to find convincing evidence for subspecies division [95], [96]. Of the traditionally proposed eight subspecies five were included (centralis, hernandesii, onca, paraguensis, peruviana).

The number of traditionally proposed subspecies of leopards varies greatly but is often around 30 [97][101], undoubtedly owing to its large biogeographic distribution and superficial differences in overall size and coat morphology. However, this has long been regarded as excessive [102], and recent studies have proposed that only eight or nine are valid [101], [103] but see [104]; 16 of the traditionally proposed subspecies were included, covering most of the leopard's vast biogeographic range (antinorii, delacouri, fusca, iturensis, japonensis, leopardus, melanotica, melas, orientalis, panthera, pardus, reichenowi, saxicolor, shortridgei, sindica, suahelicus). More work has been done on tiger subspecies differentiation than any other extant felid [77], [105][113], but the number of valid subspecies remains a subject of debate; all of the traditionally proposed eight subspecies (altaica, amoyensis, balica, corbetti (including 7 specimens of jacksoni), sondaica, sumatrae, tigris, virgata) were included in this study.

In marked contrast to other Panthera, no division into subspecies has been proposed within the snow leopard, despite the fact that the historical biogeographic range of this species covered several million square kilometres across numerous countries in Central Asia [15], [76], [98], [99], [102], [114], [115]. This could be due to a true lack of evolutionary subdivision in this species, known to be able to cover large geographic distances [15], [102], but could also be due to lack of scientific knowledge, since it is the least well known of all the great cats, in large part owing to the remote and difficult terrain and low population densities [15], [116][119]. Comparatively few studies have historically been made on this species [120], including its evolutionary relationships, none of which are recent [76], [98], [99], [114], [115].

For comparative purposes with felids, we also analysed cranial morphometry and sexual dimorphism in 464 ursids: the giant panda (Ailuropoda melanoleuca, 16♂, 8♀); spectacled bear (Tremarctos ornatus, 18♂, 12♀); sloth bear (Ursus ursinus, 35♂, 17♀); American black bear (U. americanus, 39♂, 14♀); brown bear (U. arctos, 100♂, 71♀); and polar bear (U. maritimus, 78♂, 56♀).

Size division of Smilodon fatalis

We gauged the nature and degree of sexual dimorphism in S. fatalis and Panthera by analyzing their size-distribution (condylobasal length, CBL; and mandibular ramus length, ML) by plotting the specimens into size-categories. We also analysed the size-distribution for departure in kurtosis and skewness from a normal distribution using the g-moment statistics [121]. We computed the sexual dimorphism quotient from the sample means (S = ((mean–mean)/mean)*100) [20], [122], and the coefficient of variation (v = (SD*100)/mean) was computed from the sample means and standard deviations (SD).

Morphological variation in Smilodon fatalis appears not to be random, and large and small specimens appear to be morphologically different in several respects. For analysis, we attempted to separate S. fatalis into probable male and female specimens based on size. S. fatalis is comparable in skull and body size to P. leo and the mainland populations of P. tigris, and in our samples, there is a clear sexual division of sizes, as noted below. Of 247 P. leo crania, only 2 of 107 females exceed a CBL of 300 mm, and only barely so; both are of the large, East and South African subspecies (P. l. krugeri, BM19.7.7.94.2, 301.3 mm; P. l. nubica CN2113, 301.1 mm); in contrast 102 of 107 had a CBL of <290 mm, and 91 had CBL<280 mm. For males, only 11 of 147 had CBL<290 mm, whereas 115 had CBL>300 mm; below a CBL of 280 mm, only a single specimen out of 92 was male. Tigers vary considerably in size biogeographically [105] regardless of whether these constitute actual subspecies or not, and our sample encompassed 81 specimens of the large mainland populations (traditionally referred to P. t. altaica, tigris, and virgata); no female had a CBL of more than 290 mm, the largest being two P. t. tigris females (BM32.8.19.1, 282.3 mm; and BM10.7.21.1, 284.8 mm).

Accordingly, it would appear reasonable to suppose that such a size division could be applied to S. fatalis as well. For the purpose of morphometric analyses, we assumed that all S. fatalis with a CBL≥300.0 were male and those with a CBL≤285.0 mm were female. We decided to omit the middle group (285.1–299.9 mm; n = 31), since this group shows sexual size-overlapping in P. leo. Our sample of P. leo encompassed 30 specimens in the size-range of 285.1–299.9 mm of which 22 were males and 8 were females. Omitting this size-category in S. fatalis should ensure that the specimens analysed should have been allocated to their proper sex with some degree of confidence; this implies a sample of 21 females and 27 males.

The sample of 186 P. leo mandibles were used to separate the 61 S. fatalis mandibles into sexes. Out of 86 P. leo females, 85 had ML<215 mm, and 82 were <205 mm; the largest female was CN2113 (P. l. nubica, ML: 215.9 mm). Of 103 males, 93 had ML>210 mm, and 85 were >215 mm; every specimen with ML≥216.0 mm was male. Accordingly, the S. fatalis mandibles were divided into inferred females with a ML≤205.0 mm, and males with a ML≥215.0 mm; this implied 22 males and 21 females. The middle group (ML of 205.1–214.9 mm; n = 18) were not included in the morphometric analyses. Significantly, all included Pit 67 specimens with an associated mandible (n = 10; of which 6 had been sexed as males for CBL) were also sexed as males independently based on their ML sizes.

Morphometric analysis

We compared the morphology of S. fatalis crania and mandibles to those of Panthera using a combination of traditional morphometric analysis on measured variables and geometric morphometric (shape) analysis. For morphometric studies using measured variables we took 32 linear measurements in lateral, ventral and dorsal perspective on each skull and mandible (Fig. S1) using digital callipers. Although it is universally recognised that extant felids and many other carnivores are sexually dimorphic, analysis of sexual dimorphism nearly always refers to simple size-dimorphism; however, there is reason to assume that at least some felids are not merely size-dimorphic but morphometrically dimorphic as well, as noted above. Accordingly, we used the above craniomandibular linear measurements in analysis of morphometry, standardizing each measurement to CBL or ML, as appropriate. We statistically compared the resulting ratios in male and female samples by means of one-way ANOVA's, following arcsine transformation of the ratios to restore normality [121].

We also compared S. fatalis to Panthera using geometric morphometrics, scoring 25 landmarks on each skull and 17 on each mandible (Fig. 1) using TpsDig [123]. For morphometric analysis, specimens were photographed in high resolution from a distance to ensure that they only occupy the central portion of focal space to avoid peripheral image distortion or parallax [124], [125]. In several S. fatalis specimens, the tips of the nasals are missing, thus causing difficulty in the placement of landmark 21, but in such cases the nasal apex was restored by graphically overlaying the specimen with another of the same CBL, and noting the inferred position of the nasal apex. For geometric morphometric analysis we used the Thin Plate Splines (TPS) function decomposed by its Partial Warps, which is a 2D model for analysing shape deformations of structures compared to a predefined reference shape configuration [126][128]. The reference configuration is non-arbitrary and non-local, and is computed by a generalized orthogonal least squares Procrustes superimposition as a mean reference shape of the included specimens [127], [129][132]. The reference configuration defines the point of tangency between shape space and approximating tangent space in the computation of the thin plate splines and is oriented by its principal component axis.

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Figure 1. Landmarks scored on crania and mandibles for analyses of intraspecific cranial morphological shape diversity.

Shown here is Smilodon fatalis LACMHC2001-2 and LACMHC2002-2(L2), associated skull and mandible from pit 67; scale bar equals 5 cm. Landmarks on the cranium are: 1, top of cranium at the junction of sagittal and nuchal crests; 2, top of occipital condyle; 3, dorsal extent of the mastoid musculature; 4, apex of paroccipital process; 5, apex of mastoid process; 6, centre of external auditory meatus; 7, posterior base of zygomatic arch; 8, ventral junction of jugal-squamosal suture; 9, centre of mandibular cotyle; 10, base of postorbital process (jugal portion); 11, apex of postorbital process (frontal portion); 12, centre of orbital aperture; 13, junction of jugal-maxilla suture; 14, posterior, and 15, anterior edge of P4; 15, posterior, and 16, anterior edge of P3; 17, posterior, and 18, anterior edge of C1; 19, anterior edge of premaxilla at incisor alveolus; 20, ventral edge of external narial aperture; 21, apex of nasal; 22, dorsal, and 23, ventral edge of infraorbital foramen; 24, dorsal edge of maxilla-frontal suture; 25, dorsal profile at beginning of temporal fossa. Landmarks on the mandible are: 1, apex of mandibular condyle; 2, posterior and, 3, anterior base of coronoid process; 4, apex of coronoid process; 5, posterior, and 6, anterior extent of retroarticular process; 7, anterior extent of mandibular (for m. temporalis) fossa; 8, posterior, and 10, anterior edge of M1; 10, posterior, and 12, anterior edge of P4; 14, transition of horizontal ramus to ascending portion towards symphysis; 15, posterior, and 16, anterior edge of C1 at the alveolar border; 17, ventral edge of mandibular symphysis; and the depth of the horizontal mandibular ramus posterior to M1 (8, 9), at the M1/P4 junction (10, 11); and anterior to P4 (12, 13).

https://doi.org/10.1371/journal.pone.0048352.g001

Geometric morphometrics studies structural shape and have the advantage of separating morphological shape differences from differences resulting from size [129], [130]. The TPS function interpolates a surface which is fixed at the landmarks, and is computed so as to minimize overall bending energy, which is a function of the distance between individual landmarks of the reference configuration and a given specimen [127], [128], [131][133]. We performed Partial Warp analyses in tpsRelw [134]. The Partial Warps were used in a step-wise Discriminant Function Analysis (DA), which is effective in evaluating separation among pre-defined groups, emphasizing variation among groups relative to within groups, by identifying canonical axes of the form ∑λiXi, which are linear functions of the included variables, where λi represents coefficients and Xi represents variables [121], [128], [135], [136]. The multiple regression derived from DA yields the best least squares predictor of group assignment, facilitating post hoc assignments of individual specimens to the defined groups. We also conducted post hoc classification analyses to evaluate the percentage of specimens correctly allocated to each species and sex.

Results

Panthera are strongly sexually size-dimorphic in cranium (Fig. 2) and mandible size (Fig. 3). P. leo appears to be the most sexually size-dimorphic species and P. uncia the least so, as evidenced by the sexual dimorphism (S) quotients, which range from 7.77 in P. uncia to 18.92 in P. leo for CBL; S coefficients are slightly higher for ML, ranging from 9.41 in P. uncia to 21.23 in P. leo. Accordingly, in all species the average male CBL is highly significantly larger than the average female CBL (Fig. 2C–G) as is the case with average ML (Fig. 3B–F). Despite the sizes of the samples and the great divergence in mean values and size distributions, the coefficients of variation for the total samples (sexes pooled) are not greatly above those of the individual samples of males and females separately (Fig. 2, 3), ranging from around 2/3 in most cases to around one half in P. leo (CBL, ML) and P. tigris (ML). The coefficients of variation for the S. fatalis samples are lower (5.21 and 5.36 for CBL and ML, respectively), and generally correspond to single-sex samples in the strongly size-dimorphic Panthera species (P. leo, P. onca, P. pardus, and P. tigris), but are comparable to mixed-sample values in the less size-dimorphic P. uncia. Accordingly, based on size-distribution and variation in CBL and ML, the notion that S. fatalis shows a low-moderate degree of sexual size-dimorphism [8], [35] is warranted.

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Figure 2. Size distribution of condylobasal skull lengths (CBL) in Smilodon fatalis and Panthera spp. along with the average CBL±SD and the coefficient of variation (v) for each sample.

A, Smilodon fatalis (pit 61 only); B. S. fatalis (pit 61+67); C, Panthera leo; D, P. onca; E, P. pardus; F, P. tigris; G, P. uncia. All Panthera are strongly sexually size-dimorphic and in all species the average male CBL is highly significantly larger than the average female CBL: P. leo (F = 643.485, p<0.0001); P. onca (F = 66.168, p<0.0001); P. pardus (F = 162.098, p<0.0001); P. tigris (F = 296.848, p<0.0001); and P. uncia (F = 47.124, p<0.0001). The sexual dimorphism quotient (S) and intersexual coefficient of variation for the samples are P. leo (S = 18.92; v = 9.97); P. onca (S = 13.04; v = 8.64); P. pardus (S = 17.15; v = 10.12); P. tigris (S = 15.24; v = 9.09); and P. uncia (S = 7.77; v = 4.82). In comparison the coefficient of variation for the S. fatalis samples are: pit 61 (v = 5.03); pit 67 (v = 5.03); and pit 61+67 (v = 5.21).

https://doi.org/10.1371/journal.pone.0048352.g002

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Figure 3. Size distribution of mandible lengths (ML) in Smilodon fatalis and Panthera spp. along with the average ML±SD and the coefficient of variation (v) for each sample.

A, Smilodon fatalis; B, Panthera leo; C, P. onca; D, P. pardus; E, P. tigris; E, P. uncia. All Panthera are strongly sexually size-dimorphic and in all species the average male ML is highly significantly larger than the average female ML: P. leo (F = 483.091, p<0.0001); P. onca (F = 48.483, p<0.0001); P. pardus (F = 374.975, p<0.0001); P. tigris (F = 256.669, p<0.0001); and P. uncia (F = 37.904, p<0.0001). The sexual dimorphism quotient (S) and intersexual coefficient of variation for the samples are P. leo (S = 21.23; v = 11.19); P. onca (S = 13.51; v = 9.56); P. pardus (S = 19.81; v = 11.04); P. tigris (S = 16.72; v = 9.91); and P. uncia (S = 9.41; v = 6.05). In comparison the coefficient of variation for the S. fatalis samples are: pit 61 (v = 5.02); and pit 61+67 (v = 5.36).

https://doi.org/10.1371/journal.pone.0048352.g003

The size-distribution curves for S. fatalis appear to show a normal distribution for both CBL (Fig. 2A, B) and ML (Fig. 3A) instead of a clear division of larger males and smaller females. However, the notion that a random sample of males and females in a sexually size-dimorphic species will show a near-bimodal distribution, and using this as a gauge for inferences of presence or absence of sexual dimorphism in extinct species, is not supported by cranium and mandible size-distribution in Panthera. Simple visual inspection of the CBL size-distribution curves (Fig. 2) indicate that some species appear to be normally distributed (P. onca, P. pardus), others show varying tendencies of kurtosis (P. tigris, P. uncia), whereas only P. leo indicates a pooling of two normally distributed single-sex samples (Fig. 2C). For mandible size the pattern is slightly different and only P. tigris shows a near-bimodal distribution (Fig. 3F), whereas P. onca and P. pardus show more normal size-distribution curves (Fig. 3D, E).

The moment statistic for skewness (g1; Table 1) indicates that for CBL size-distribution, four of five Panthera species are normally distributed even if the curves appear to deviate slightly from a normal distribution (P. onca: ts = 1.63311, 0.10<p<0.20 ns; P. pardus: ts = 1.61790, 0.10<p<0.20 ns; and P. uncia: ts = 1.59028, 0.10<p<0.20 ns). Even the sample of P. leo, which shows a somewhat bimodal size-distribution is actually normally distributed (ts = 0.33864, 0.70<p<0.80 ns), and only P. tigris shows a non-normal size distribution, which is significantly skewed to the right (ts = 2.54087, 0.02<p<0.01; elongate right shoulder and tail). CBL size-distributions are, in fact, skewed to the right in three of the four other Panthera species, despite non-significance, as is evident from Fig. 2; the exception is P. uncia, which is skewed to the left. For comparison, the S. fatalis samples are also normally distributed (Pit 61, Fig. 2A: ts = 0.72595, 0.40<p<0.50 ns; and Pit 61+67, Fig. 2B: ts = 0.05222, p<0.90 ns). The total sample (Pit 61+67) is slightly skewed to the right, as in Panthera, and the sub-sample of Pit 61 is slightly skewed to the left. The above pattern is mirrored in analyses of ML size-distribution (Fig. 3). No sample shows a size-distribution that departs significantly from normality (P. leo: ts = 0.4007, 0.60<p<0.70 ns; P. onca: ts = 0.20591, 0.80<p<0.90 ns; P. pardus: ts = 1.48444, 0.10<p<0.20 ns; P. uncia: ts = 0.23318, 0.80<p<0.90 ns), except P. tigris, where the right skewness is significantly different from a normally distributed sample (ts = 2.48304, 0.02<p<0.01). The other samples show very slight right (P. leo, P. onca) or left (P. pardus, P. uncia) skewness. The S. fatalis sample (Fig. 3A) shows a near perfect normal distribution (ts = 0.02964, p<0.90 ns).

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Table 1. Values of the moment (g) statistics in analysis of normal distribution for size-distribution of condylobasal length (CBL) and mandibular length (ML) in samples of extant Panthera and Smilodon fatalis.

https://doi.org/10.1371/journal.pone.0048352.t001

It is the pattern of sample kurtosis that causes some curves to appear to deviate from a normal distribution. This is corroborated by a visual inspection of the curves and the moment statistic for kurtosis (g2; Table 1) which indicate that CBL distribution in P. leo and P. tigris (Fig. 2C, F) show a moderate platykurtic distribution ( = greater sample frequency around curve shoulders and less in the middle and along the tails), whereas it shows a moderate leptokurtic distribution ( = greater sample frequency around the middle and along curve tails than around curve shoulders) in P. onca, P. pardus, and P. uncia (Fig. 2D, E, G). Both S. fatalis samples (Pit 61, Fig. 2A; and Pit 61+67, Fig. 2B) show a moderately leptokurtic size-distribution. For ML the distribution-frequency pattern is similar but kurtosis deviation from a normal distribution is occasionally slightly stronger than for CBL, as also indicated by the greater moment statistic (g2) values (Table 1). P. leo and P. tigris (Fig. 3B, E) show a quite pronounced and moderate, respectively, platykurtic distribution, and P. pardus and P. uncia (Fig. 3D, F) show a weakly and moderate, respectively, leptokurtic distribution. In P. onca, however, the distribution is different for the mandible, since it shows a quite pronounced platykurtic frequency distribution (Fig. 3C) compared to the slightly leptokurtic distribution for CBL. The frequency distribution of S. fatalis mandible sizes (Fig. 3A) is slightly platykurtic.

Shape analysis demonstrates that Smilodon and Panthera are distinctly different in cranial and mandibular shape, and Discriminant Analysis of the Partial Warps result in very large Mahalanobis distances between the two genera (Table 2, 3). Cranial shape results in Mahalanobis distances between S. fatalis and Panthera that are around 3–27 times greater than interspecific distances among Panthera spp. (Table 2). A plot of the first two canonical variables (Fig. 4) graphically shows the great distance, in particular along variable 1. Plotting the first two canonical variables for Panthera only results in a clear separation of the species (Fig. S2; Table S2). Similarly, for the mandible the Mahalanobis distances between S. fatalis and Panthera are around 15–330 times greater than interspecific distances among Panthera spp. (Table 3). The Mahalanobis Distances between the sexes in Panthera spp. are, expectedly, much lower than the interspecific distances, but for the mandible, the species distances between P. leo ♀ and P. pardus are comparable to sexual distances (Table 3). Significantly, the Mahalanobis Distances between large and small specimens of S. fatalis are comparable to the sexual distances in Panthera spp. and it is noteworthy that the Mahalanobis Distance between large and small specimens of S. fatalis for cranial shape is intermediate between those of strongly sexually size-dimorphic Panthera (leo, onca, pardus, and tigris), and the less markedly size-dimorphic P. uncia.

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Figure 4. Plots of the first two canonical axes based on Discriminant Analysis of the Ppartial Warp scores from a Thin Plate Splines analysis on cranial shape in Panthera spp. and Smilodon fatalis.

The first canonical variable explains 66.7% of sample variation and the second canonical variable explains 18.7% of sample variation.

https://doi.org/10.1371/journal.pone.0048352.g004

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Table 2. Mahalanobis distance F-matrix of species and sexes based on the Partial Warp scores from a Thin Plate Splines analysis of cranial shape in Panthera spp. and Smilodon fatalis.

https://doi.org/10.1371/journal.pone.0048352.t002

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Table 3. Mahalanobis distance F-matrix of species and sexes based on the Partial Warp scores from a Thin Plate Splines analysis of mandible shape in Panthera spp. and Smilodon fatalis.

https://doi.org/10.1371/journal.pone.0048352.t003

Post hoc classification analyses identified all species with high accuracy for cranial (S. fatalis, P. leo, and P. uncia: 100%; P. pardus, P. tigris: 99%; and P. onca: 97%) and mandibular (S. fatalis, P. tigris, and P. uncia: 100%; P. pardus: 98%; P. leo and P. onca: 97%) Partial Warp scores. When dividing species-samples into males and females, the sexes were also identified with high levels of accuracy in all Panthera for cranial (Table 4; 76–94% correct) and mandible (Table 5; 74–100% correct) shape. For cranial shape, the misidentified specimens were nearly always misclassified as the other sex and in only four cases were a specimen erroneously misclassified as another species (Table 4). One specimen each of P. onca ♀ and ♂ were misclassified as P. pardus ♂; one P. pardus ♂ was misclassified as a P. onca ♂; and one P. tigris ♀ was misclassified as a P. leo ♀. For mandible shape (Table 5), seven specimens of P. leo ♂ were misclassified as P. pardus ♂; five P. pardus ♂ were misclassified as P. leo ♀: and two P. tigris ♂ were misclassified as P. onca ♂. Large and small specimens of S. fatalis were identified with similar high levels of accuracy for cranla (85% for large specimens, and 95% for small specimens) and mandible (91% and 76%, respectively) shape. This indicates that cranial and mandible shape is equally distinguishable in large and small specimens of S. fatalis as in males and females of Panthera spp.

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Table 4. Post hoc classification matrix of species and sexes based on the Partial Warp scores from a Thin Plate Splines analysis of cranial shape in Panthera spp. and Smilodon fatalis.

https://doi.org/10.1371/journal.pone.0048352.t004

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Table 5. Post hoc classification matrix of species and sexes based on the Partial Warp scores from a Thin Plate Splines analysis of mandible shape in Panthera spp. and Smilodon fatalis.

https://doi.org/10.1371/journal.pone.0048352.t005

Morphometric analyses corroborate the notion of pronounced sexual dimorphism in Panthera and Smilodon fatalis. Most ratio variables were normally distributed prior to arcsine transformation, although transformation generally resulted in a greater percentage of specimens falling within ±1SD of the mean (Table S3). Panthera spp. are not merely dimorphic with respects to size; a number of cranial proportions relative to CBL are significantly different in males and females. Interestingly, most of the same ratios also differ significantly in small vs. large specimens of S. fatalis, corroborating the notion that large specimens are, in fact, males and small specimens are females. Among Panthera the proportional differences between the sexes are much more pronounced in the strongly sexually size-dimorphic species, P. leo, P. onca, P. pardus, and P. tigris, whereas P. uncia males and females differ less from each other. Relative to CBL, in the four great Panthera species, length of the sagittal crest (Fig. 5A); facial length (Fig. 5B); width across the postorbital constriction (Fig. 5C; also in P. uncia, Table S8); width of the palate at the carnassials (Fig. 5D); width across the occipital condyles (Fig. 5E); and length of the carnassial (Fig. 5F) are all (p<0.001) statistically significantly different in males vs. females. To this can be added a large number of other cranial features which differ between the sexes in all five species (width across the braincase; Tables S4, S5, S6, S7, S8); or which differ between the sexes in P. leo, P. onca, P. pardus, and P. tigris (Table S4, S5, S6, S7) such as dorsoventral skull height at the junction of P3/P4; width of the palate across the P3 paracone or across the pterygoids; or the length of the P3 crown. Additionally, a number of other variables are significantly different between the sexes in one or several of the species (Tables S4, S5, S6, S7, S8).

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Figure 5. Box-plots of statistically significant differences in cranial proportions in male (blue) and female (red) extant Panthera spp.

Values are expressed as percentages of CBL, along with the sample averages±SD, coefficients of variation (v) and the sexual dimorphism coefficient (S). The length of each box indicates the central 50% range of the values, and the box hinges denote the first and third quantiles. The whiskers indicate the range of values that fall within the inner fences, and values between the inner and outer fences are indicated with an asterisk. A, length of sagittal crest (differences between male and female samples: P. leo: F = 60.791, p<0.001; P. onca: F = 32.949, p<0.001; P. pardus: F = 175.843, p<0.001; P. tigris: F = 80.551, p<0.001); B, length of premaxilla+maxilla along alveolar series (P. leo: F = 69.761, p<0.001; P. onca: F = 8.246, p<0.001; P. pardus: F = 13.941, p<0.001; P. tigris: F = 27.230, p<0.001); C, width across postorbital constriction (P. leo: F = 58.315, p<0.001; P. onca: F = 19.669, p<0.001; P. pardus: F = 100.793, p<0.001; P. tigris: F = 89.657, p<0.001); D, palatal width across carnassial notch of P4 (P. leo: F = 92.652, p<0.001; P. onca: F = 13.554, p<0.001; P. pardus: F = 28.241, p<0.001; P. tigris: F = 11.177, p<0.001); E, width across occipital condyles (P. leo: F = 104.219, p<0.001; P. onca: F = 14.421, p<0.001; P. pardus: F = 89.402, p<0.001; P. tigris: F = 30.128, p<0.001); F, length of P4 (P. leo: F = 162.110, p<0.001; P. onca: F = 10.482, p<0.001; P. pardus: F = 46.672, p<0.001; P. tigris: F = 72.386, p<0.001).

https://doi.org/10.1371/journal.pone.0048352.g005

A number of the same features also differ significantly in large vs. small specimens of S. fatalis, and notably they differ in the same fashion, such that small specimens have higher or lower ratios, depending on the variable, relative to large specimens in the same way that females have higher or lower ratios than males in Panthera. These include the width of the palate at the carnassials (Fig. 6E); width across the postorbital constriction (Fig. 6H); width across the incisors (Fig. 6D; significant in P. leo (Table S4); P. pardus (Table S6); and P. tigris (Table S7)); or the anteroposterior distance from the preglenoid process to the occipital condyles (Fig. 6A; significant in P. pardus (Table S6); and P. tigris (Table S7)); all of which are relatively greater in small S. fatalis specimens. To this may be added braincase width, which is significantly (n = 43; F = 7.309, p = 0.010) narrower relative to CBL in large (0.432±0.019; v = 4.37) than in small (0.449±0.021; v = 4.60) specimens, exactly as in all five species of Panthera (Tables S4, S5, S6, S7, S8). Some features differ slightly in Panthera and S. fatalis, such as the length of the face (from tip of premaxilla to posterior edge of maxilla along the alveolar line). This statistic is significantly different between the sexes in P. leo, P. onca, P. pardus and P. tigris (Fig. 5B) but not in S. fatalis. However, the distance from the infraorbital foramen to the tip of the premaxilla is significantly longer relative to CBL in large S. fatalis (Fig. 6C), but shows no sexual difference in Panthera; in contrast, in Panthera relative facial length is higher in females.

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Figure 6. Box-plots of statistically significant differences in cranial proportions between large (black; CBL≥300.0 mm) and small (grey; CBL≤285.0 mm) Smilodon fatalis specimens from pits 61+67.

Values are expressed as percentages of CBL, along with the sample averages±SD and coefficients of variation (v). The length of each box indicates the central 50% range of the values, and the box hinges denote the first and third quantiles. The whiskers indicate the range of values that fall within the inner fences, and values between the inner and outer fences are indicated with an asterisk. A, distance from anterior rim of preglenoid process to posterior edge of occipital condyle (large-small specimen samples: combined n = 47; F = 9.742, p = 0.003); B, mastoid height (n = 48; F = 24.806, p<0.001); C, distance from anterior edge of infraorbital fenestra to tip of premaxilla (n = 48; F = 31.977, p<0.001); D, width across the incisor arcade (n = 48; F = 21.535, p<0.001); E, palatal width across carnassial notch of P4 (n = 48; F = 20.093, p<0.001); F, P3 crown length (n = 48; F = 33.740, p<0.001); G, P4 crown length (n = 48; F = 66.530, p<0.001); H, postorbital constriction width (n = 43; F = 28.322, p<0.001).

https://doi.org/10.1371/journal.pone.0048352.g006

The mastoid process is relatively gigantic in S. fatalis compared even to other derived sabercats, and is significantly dorsoventrally higher relative to CBL in large specimens (Fig. 6B). Panthera spp. shows no significant differences between the sexes in this metric but males in certain groups of other carnivores, in this case ursids, also have very large mastoid processes; in fact, mastoid process height relative to CBL is one of the most distinguishing sexual differences in male vs. female ursine ursids, whereas the primitive ursids (Ailuropoda, Tremarctos) are not sexually dimorphic on this ratio (Table S9, variable 4). Despite their greatly different overall skull morphology from those of felids, ursids also show some of the same sexually dimorphic differences in skull proportions as felids (Table S9), for instance relatively wider palate but narrower zygomatic arches and more slender canines in females, indicating their widespread occurrence in the Carnivora. This supports the notion that large S. fatalis specimens really are males, which are morphometrically different from the smaller females. As with Panthera, CBL in all ursids is strongly sexually size-dimorphic (Fig. S3).

The sexual dimorphism quotients for the above morphometric ratios are generally similar in S. fatalis and Panthera (Fig. 5,6; Tables S4, S5, S6, S7, S8), for instance, anteroposterior distance from the preglenoid process to the occipital condyles (S. fatalis, S = 4.06; compared to P. pardus, S = 3.32; and P. tigris, S = 2.33); width across the incisors (S. fatalis, S = 6.05; compared to P. leo, S = 5.47; P. pardus, S = 5.41; and P. tigris, S = 2.36); postorbital constriction width (S. fatalis, S = 10.68; compared to 4.09–12.93 in Panthera); braincase width (S. fatalis, S = 3.89; compared to 3.39–9.25 in Panthera); or width of the palate across the carnassials (S. fatalis, S = 3.78; compared to 1.67–4.3 in Panthera). This indicates similar levels of sexual morphology-dimorphism in S. fatalis to Panthera. However, for other ratios, the sexual dimorphism quotients in S. fatalis are higher than in Panthera, such as the relative sizes of P3 and P4, which are 10.68 and 10.57, respectively, in S. fatalis, compared to 4.46–8.33 and 2.49–7.90, respectively, in Panthera (Fig. 5F; and Tables S4, S5, S6, S7, S8, respectively). Relative mastoid height also has a high sexual dimorphism quotient in S. fatalis (8.33). Accordingly, S. fatalis may show a smaller degree of sexual size-dimorphism than Panthera, but it appears to be comparable to Panthera in terms of cranial sexual morphometric dimorphism.

The mandible proved to be less morphometrically sexually dimorphic in Panthera than the cranium. Of the analyzed mandibular morphometric ratio variables, only the dental ratios (crown lengths of P4 and M1) are sexually dimorphic in Panthera; both are significantly different between the sexes in all species (Fig. 7) except P. uncia, where no ratio variables proved different between the sexes. Solely among Panthera, P. tigris also proved sexually dimorphic on the ratio of MAM (moment arm of m. masseter)/ML (mean±SD and v (♂): 0.237±0.017, 7.34; mean±SD, and v (♀): 0.223±0.013, 5.81; F = 10.751, p<0.001; S = 5.63). S. fatalis is also dimorphic on the above two dental ratios (Fig. 7), and the coefficients of variation within each sample of small and large specimens are similar to those in single-sex Panthera, but the coefficients in M1/mandible length are in the lower range of those observed in Panthera. The sexual dimorphism quotients for S. fatalis are 11.27 (P4) and 7.17 (M1), which are similar to those in Panthera. As with the above cranial ratio variables, S. fatalis varies in the same fashion as Panthera, in that small specimens of S. fatalis have higher dental ratios, as in female Panthera, whereas those of large specimens are significantly lower, as in male Panthera.

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Figure 7. Box-plots of P4 and M1 crown lengths in male (blue) and female (red) extant Panthera spp. and large (black) and small (grey) specimens of Smilodon fatalis.

Values are expressed as percentages of ML, along with the sample averages±SD, coefficients of variation (v) and the sexual dimorphism coefficient (S) for Panthera spp. The length of each box indicates the central 50% range of the values, and the box hinges denote the first and third quantiles. The whiskers indicate the range of values that fall within the inner fences, and values between the inner and outer fences are indicated with an asterisk. A, length of P4 crown (differences between male and female samples: P. leo: F = 19.162, p<0.001; P. onca: F = 8.484, p = 0.002; P. pardus: F = 33.237, p<0.001; P. tigris: F = 26.071, p<0.001); B, length of M1 crown (P. leo: F = 8.820, p<0.001; P. onca: F = 12.703, p<0.001; P. pardus: F = 9.462, p<0.001; P. tigris: F = 14.946, p<0.001). In Smilodon fatalis, the ratio variables are also highly significantly different between large vs. small specimens (P4: F = 35.363, p<0.001; M1: F = 20.327, p<0.001).

https://doi.org/10.1371/journal.pone.0048352.g007

Discussion

Smilodon fatalis was sexually dimorphic, but levels of size-dimorphism are less than morphometric dimorphism, and also less than in most extant Panthera. However, morphologically, large specimens of S. fatalis, inferred to have been males, appear to have differed from small specimens, inferred to have been females, in largely the same craniodental and mandibular proportions and in the same fashion that males differ from females in Panthera. The similarity of these morphological differences in a distantly-related clade of carnivores, the ursids, with markedly different craniomandibular and dental morphologies as well as feeding and killing ecologies from those of felids, indicate that this pattern is widespread in the Carnivora. We suggest that previous assertions [34], [75] of high morphological variation in S. fatalis skulls is due to morphological differences between the sexes.

Among Panthera, size-differences are of course an immediate and easily recognisable difference between males and females, since males usually cover a size-range that is somewhat overlapping and outside that of females. Some species vary geographically in size, such as the P. onca, P. pardus, and P. tigris, and small males from small-sized populations, whether or not they constitute actual subspecies, may be no larger than large females from populations where the modal size is larger. However, as shown in this paper, the sexes are morphologically distinct, so size is but one parameter with which to gauge sexual dimorphism. We would argue that anyone familiar with leopard cranial morphology can easily tell apart a small male from a large female, providing that they be fully adult.

S. fatalis appears to follow the same pattern, and when visually comparing large and small specimens, morphological differences are readily apparent (Fig. 8); they simply have the distinct appearance of males and females in the same way that a mixed-sex assemblage of skulls from modern felids would. Large specimens of S. fatalis have a larger (albeit not anteroposteriorly longer, as in Panthera) sagittal crest; a more well-developed mastoid process; a longer face and often more prognatheous incisors, which would appear to be a result of a more horizontally drawn-out naseoalveolar basin; as well as a more abbreviated posterior part of the skull, as indicated by a shorter distance from the preglenoid process to the occipital condyle. Large specimens also have relatively narrower incisor arcades and palatal widths across the P4, but they do not merely have a more elongate overall skull shape compared to small specimens, since most other relative widths are not different, e.g., width between the upper canine alveoli, palatal width across the centre of the P3, zygomatic width, or width across the mastoid processes and occipital condyles.

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Figure 8. Comparative morphology of some Smilodon fatalis skulls from Pits 61 and 67, all to scale.

A–D are inferred to potentially be males and E–H are inferred to potentially be females; note that D and H have complete upper canines, which have been cropped in this image. A, LACMHC2001-261 (Pit 61); B, LACMHC2001-151 (Pit 67); C, LACMHC2001-215 (Pit 61); D, LACMHC2001-2 (Pit 67); E, LACMHC2001-401 (Pit 61); F, LACMHC2001-408 (Pit 61); G, LACMHC2001-434 (Pit 61); H, LACMHC2001-231 (Pit 67). Scale bar equals 10 cm.

https://doi.org/10.1371/journal.pone.0048352.g008

Among the identified significant evolutionary advantages of selection for increased male size is intrasexual competition among males for reasons of maximizing fecundity, intersexual resource partitioning, and antipredator defence [137], [138]. Other than size-dimorphism, it is evident that several of the identified sexual morphometric-dimorphic traits in skulls in Panthera, ursids (Fig. S4; Table S9), and S. fatalis are related to the feeding/killing apparatus, such as more massive upper canines, larger sagittal crests, larger mastoid processes, and in some species more widely flaring zygomatic arches, implying more strongly developed mandibular adductor (primarily m. temporalis) musculature in males. This suggests a correlation of sexual morphometric- and size-dimorphism and raises the possibility of differences in predatory ecology. Certainly, the marked sexual morphometric dimorphism of S. fatalis reported in this study is suggestive of evolutionary selection for male-male competition, as in other felids.

A strong correlation between predator size and maximal prey size has been established for a wide variety of animals including carnivoran mammals [139][147]. As a consequence, males often prefer larger prey than females in strongly size-dimorphic species since they are physically larger [144]. However, large predators not only take larger prey than smaller predators, they are also able to exploit a wider range of different prey sizes, which again has been documented for a variety of different animals [141], [144]. Hypercarnivores like felids have a preferred size-range of prey body masses, and they are usually not very successful in catching prey outside their preferred size-class [148], [149]. Strong bite forces are an important part of predator adaptations for a large-prey feeding ecology [142], [150], and in felids, the robusticity of the canines is related to specialization for large-prey predation [147].

The above indicates that among Panthera and Smilodon, males have not only larger body sizes as adaptations for intrasexual competition for mating access, and stronger bite forces because they are physically larger than females; they also have more well-developed craniomandibular traits in precisely those areas that relate to bite forces, and this could imply evolutionary adaptations for reducing intersexual resource competition. Owing to their larger body sizes, males could be expected to generally prefer larger prey than females, in which case stronger bite forces would imply a further selective advantage. This has been demonstrated in P. leo, where all-male groups kill large prey like buffalo (Syncerus caffer) much more frequently than females do, and such differences in sexual size and strength dimorphism has lead to intraspecific, sexually determined resource partitioning [151], [152]. Among derived sabercats, the head-depressing muscles associated with the mastoid process were important components of the killing bite [30], [38][40], [46], so a larger mastoid process would be expected in S. fatalis males but not in Panthera males. This is in accordance with our results. In an environment of fierce predator competition, like the La Brea fauna [76] ecological pressure for resource partitioning could have been a strong selective component of morphometric sexual dimorphism in S. fatalis.

The social ecology of S. fatalis has been a subject of decades of debate. The sheer volume of recovered specimens would seem to favour group living like P. leo [153], and S. fatalis numbers are exceeded only by those of Canis dirus, about which there is a general consensus that they were pack-living much like their extant relative, C. lupus [8], [82] but see [154]. Recent analysis of the faunal composition of the La Brea pits compared to the numbers of carnivores actively seeking out sounds made by dying herbivores in Africa have also suggested that the abundance of S. fatalis and C. dirus are indicative of their having lived in social groups [82]. However, Merriam & Stock [34] ascribed the abundance in La Brea of S. fatalis compared to the other great felid, Panthera atrox, to a behavioural tendency of S. fatalis to remain in close proximity with the asphalt traps and their bounty of trapped herbivores, but they thought that its smaller brain size compared to those of extant great felids was indicative of a solitary ecology; this was supported and further elaborated upon by Radinsky [155], [156]. Subsequent studies on relative brain size and social ecology in Panthera have called such inferences into question [157].

Others have ascribed group living to S. fatalis based on healed injuries in some of the bones, supposedly requiring the nurture of group members for survival and recovery [158], [159]. However, other studies have considered this inconclusive, since the number of pathological specimens is low, and extant felids show a remarkable potential for recovery from even severe bone fractures [160]. For wild felids availability of water appears to be a much more critical factor than availability of food brought home by other group members [160]. As such, these authors concluded that S. fatalis had probably not lived in social groups.

Sexual dimorphism analyses have also been used to assess possible social ecology in S. fatalis. Based on their finding of no sexual size-dimorphism in S. fatalis mandibles, Meachen-Samuels & Binder [36] concluded that it probably had not lived in groups, and may have been less polygynous than most extant felids, perhaps monogamous. Van Valkenburgh & Sacco [8] found that the low variability in cranial size was indicative of a non-social ecology, since group living, as in P. leo, would likely have favoured selection for large male body size, which would have been advantageous in intrasexual agonistic behaviours. They ascribed the large number of S. fatalis at La Brea to a possible sharing of carcasses by the resident females of a given area, i.e., a social ecology similar to those of most extant felids with a dominant male and several females in any one area. Among primates, levels of sexual dimorphism have been found to covary with mating systems, but also with habitat, diet, and with differences in body size [2], [9], [10], [161][163]. However, in carnivorans, levels of sexual selection for canine size-dimorphism appears have been simpler and primarily restricted to one ecological parameter, breeding ecology [7]. This indicates that, in contrast to primates, analyses of sexual dimorphism should provide information about social ecology in fossil species as well.

The current study found that S. fatalis shows a lower degree of intraspecific size-variation than Panthera, except P. uncia; however, when comparing samples of probable male and female specimens, they were every bit as morphometrically different in the same traits as males and females in Panthera. Significantly, among the four great Panthera species levels of size- and morphometric dimorphism, as well as sex identification based on shape analysis, are comparable, and the social P. leo is not different from the other species. Additionally, even strongly size-dimorphic felids may or may not show a bimodal or normal distribution. As such, our results indicate that size- and morphometric-dimorphism may not be as reliable predictors of social ecology in Panthera as has been advocated, and should be used with caution in extinct felids. Absence of a bimodal size-distribution is also not necessarily indicative of low or absent sexual size-dimorphism.

In terms of sexual size- and morphometric dimorphism, the aberrant Panthera species is not the social P. leo but P. uncia. P. uncia is often not included in analyses of felid morphology owing to the scarcity of specimens in museums, but the current study suggested that sexual dimorphism (size, morphometry) in Panthera has a phylogenetic component. P. uncia is the most basal of the known Panthera species [164], and it is decidedly less dimorphic than the other species; yet, P. uncia is solitary like P. onca, P. pardus, and P. tigris. Previous hypotheses of P. uncia living in monogamous pairs have not been supported by radiotracking studies, which have indicated a typical solitary lifestyle for both sexes [117].

Social ecology in P. uncia is not well understood, and it is not known with certainty if it shares the social ecology typical of most extant felids, with females having adjacent and often somewhat overlapping territories, and with one dominant male overlapping the territories of the resident females either singularly or with partial overlaps from another, adjacent male as well [15]. Male felids usually actively defend their territories from other males by marking (scent, scraping, dung), vocalizations, and, if necessary, direct physical intimidation and combat. Observations that P. uncia call for mates during the breeding season in early spring [165], [166] is similar to behaviours of other solitary and polygynous felids, e.g., Neofelis spp., P. pardus, or P. tigris, where females call and scent-mark to announce their receptiveness [167][169]. This indicates that social ecology in P. uncia is probably similar to those of most other felids.

However, P. uncia usually maintain very large homeranges, where territorial defence by marking appears to be much less than in other Panthera, since individuals visit any given place much less frequently [15]. This indicates that intraspecific aggressive encounters are less frequent than in other Panthera, if they occur at all. This is corroborated by the virtual absence of evidence of intrasexual (male) agonistic behaviour in P. uncia in the wild. Behavioural ecology also strongly suggests that this species is decidedly less aggressive than other Panthera [15], [102], [165], [170]. The above could potentially be the cause of the low level of sexual dimorphism in this species, apparently not favouring selection for increased male size and agonistic traits to the same extent as in other Panthera. Having huge territories with relatively few available prey, there would also be less selective advantage in evolving craniomandibular adaptations for intersexual resource partitioning. In contrast, S. fatalis appears to have been highly aggressive, as indicated by dramatic finds of skulls and other bones with deeply penetrating canine bite marks from other specimens [34], [159]; such fossils are also known of the South American S. populator (pers. obs.).

There are few exceptions among extant felids to the basic polygynous social ecology, the two most notable are the cheetah (Acinonyx jubatus) and P. leo, the only truly social felid. In A. jubatus females are solitary with extensively overlapping territories, and males are either solitary or live in small groups of 2–3, which may or may not be related, and mate with as many willing females as they encounter; these typically pass through the males' territories [171]. Numerous field ecology studies have been made on the social ecology of P. leo, primarily in East Africa [172][187]. In inferences of social ecology in S. fatalis, P. leo is usually the baseline for comparison. However, it is often overlooked that the typical fusion-fission social structure of resident females and offspring with dominant males migrating in and taking over the pride at regular intervals, is not ubiquitously present in all lions, but is primarily characteristic of the well-studied sub-Saharan/East African populations. The sub-Saharan lions may or may not constitute several distinct subspecies, but there is a widespread consensus that they are evolutionarily younger than the Asiatic lion (P. l. persica) and the North African Barbary lion (P. l. leo) [86], [87][91], [188].

Studies have indicated that basal lions form different kinds of social structures than the sub-Saharan lions. Social structure in P. l. persica is very varied, and single individuals, single pairs, and separate male and female groups are found, whereas true family groups of adult males, females, and juveniles are less common [189][193]. All-male and all-female groups are common and usually only associate at large kills or during mating. Male pride territories overlap those of female prides, but each favour different habitats, females primarily patrol riverine forest areas whereas males occupy more arid, hilly areas deeper inside the forest [192], [193]. For P. l. leo, only anecdotal evidence for natural ecology exists, since it became extirpated in the wild in the 1940s, and now only exists in a few captive populations [188]. However, it appears to have frequented mountainous forest tracts and to have lived largely solitarily except during the mating season, where there was association between the sexes; apparently these lions did not form prides [194], [195].

Using the P. leo sample from this study, the sub-Saharan African lions (i.e., excluding P. l. leo and P. l. persica; n = 232 of a total n = 247) showed the same sexual differences in CBL size and morphometric ratios reported for the total sample (Fig. 2,5; Table S4). The sub-sample of P. l. persica (n = 13, 7♂, 6♀), however, is different. P. l. persica is much less strongly sexually size-dimorphic than African lions (♂: 295.75±20.43 mm, v = 6.93; ♀: 270.73±12.41 mm, v = 6.93; F = 7.656, p = 0.018; S = 8.84). However, of the 16 morphometric ratios which differed significantly between the sexes in the total sample and in the sub-Saharan African lion sub-sample, only seven are significantly different in the P. l. persica sub-sample: sagittal crest length (♂: 0.398±0.028, v = 7.04; ♀: 0.365±0.025, v = 6.98; F = 5.468, p = 0.039; S = 9.11); facial length (♂: 0.370±0.011, v = 3.07; ♀: 0.391±0.015, v = 3.88; F = 8.690, p = 0.013; S = 5.36); intraorbital width (♂: 0.264±0.010, v = 3.69; ♀: 0.249±0.012, v = 4.92; F = 6.372, p = 0.028; S = 5.95); width across the incisor arcade (♂: 0.142±0.006, v = 4.26; ♀: 0.148±0.004, v = 2.86; F = 4.848, p = 0.049; S = 4.12); palatal width across P4 (♂: 0.407±0.009, v = 2.19; ♀: 0.419±0.008, v = 1.82; F = 6.475, p = 0.027; S = 2.68); crown length of P3 (♂: 0.080±0.004, v = 4.76; ♀: 0.085±0.003, v = 3.59; F = 7.514, p = 0.019; S = 5.90); and crown length of P4 (♂: 0.121±0.004, v = 2.92; ♀: 0.127±0.002, v = 1.39; F = 18.740, p = 0.001; S = 5.07). Sample size may have played a factor in a few cases, such as palatal width across P3, which is significant at the 10% level (F = 3.556, p = 0.086), but all other morphometric ratios are so far from being significantly different that even a much greater sample size would probably not have changed the results, unless the present sample is not representative of P. l. persica morphology.

The above has important implications for inferences of possible social ecology in S. fatalis, because the current study does not indicate markedly greater morphometric or size-dimorphism in the social P. leo vs. the solitary and polygynous Panthera species (except P. uncia). Other studies have also found that P. pardus, a close relative of P. leo [164], also has a high degree of cranial and canine size-dimorphism [8]; this is corroborated in this study. Accordingly, S. fatalis may well have lived in groups despite its moderate cranial and mandibular size-dimorphism. Group-living would have facilitated safer and easier killing of the great variety of large herbivores which were dominant in the La Brea fauna [34]. It would also have been advantageous in defence of prey in a fauna incorporating by an unusually great diversity of large, powerful carnivores with presumed strong resource competition [76], [177].

The composition, if any, of a social group of S. fatalis is of course unknown, but it is unlikely that it lived in female coalitions dominated by one or, at most, a few males, like sub-Saharan lions. Such a social ecology would likely have had an impact on the inferred sex-ratio in recovered specimens, since females would probably be overrepresented in the asphalt when becoming mired in attempts to reach a trapped prey animal, since they would have been more numerous than males within a group's territory. In contrast, inferred males appear to be slightly more numerous than females in the Pit61+67 samples. Among Asiatic and African lions, adult females typically outnumber males by 2:1 owing to high mortality among juvenile males [191], [192], [196], [197]. We filtered out the medium-sized S. fatalis specimens prior to analysis, but were left with cranial and mandible samples in which large and small specimens were quite evenly matched (inferred male/female ratios are 1:1.29 and 1:1.05 for CBL and ML, respectively), as in P. atrox [36]. Unless the sex-distribution of the medium-sized specimens is strongly skewed towards one sex, this does not suggest a multi-female social ecology dominated by a few males, but is in accordance with a random trapping of non-social individuals or monogamous pairs. However, if S. fatalis was social, the numbers would also be in accordance with a social ecology of all-male and all-female groups, as in P. leo persica.

Supporting Information

Figure S1.

Skull of Asiatic lion (Panthera leo persica; ♂, BM31.1.5.1) in lateral, dorsal and ventral views; and mandible of leopard (P. pardus melas; ♂, CN26), illustrating the 27 of the 32 measurements taken for morphometric analysis.

https://doi.org/10.1371/journal.pone.0048352.s001

(DOC)

Figure S2.

Plot of the first two canonical axes from a Discriminant Analysis on the Partial Warp scores from a Thin Plate Splines analysis on cranial shape in Panthera spp.

https://doi.org/10.1371/journal.pone.0048352.s002

(DOC)

Figure S3.

Box-plots of sexual size-dimorphism of cranial condylobasal length in 464 specimens of extant ursids representing six species (males in blue, females in red), along with the sample averages±SD, coefficients of variation (v) and the sexual dimorphism coefficient (S).

https://doi.org/10.1371/journal.pone.0048352.s003

(DOC)

Figure S4.

Skulls of female (CN4543; live body mass 203 kg) and male (CN4532; 496 kg) of the Kodiak brown bear (Ursus arctos middendorffi) showing not only the marked size-dimorphism characteristic of all extant ursids but also distinctive morphological differences, such as the taller, more robust overall skull proportions of the male; the much larger mastoid process; more robust upper canine; larger sagittal crest; and the shorter facial region.

https://doi.org/10.1371/journal.pone.0048352.s004

(DOC)

Table S1.

List of specimens of Smilodon fatalis and Panthera spp. used in the analysis, along with museum numbers and explanation of museum codes.

https://doi.org/10.1371/journal.pone.0048352.s005

(NTS)

Table S2.

Table of Mahalanobis distances and post hoc classification matrix of Panthera species and sexes based on the Partial Warp scores from a Thin Plate Splines analysis of cranial shape.

https://doi.org/10.1371/journal.pone.0048352.s006

(DOC)

Table S3.

Normality distribution of cranial ratios in Panthera spp. and Smilodon fatalis , all divided by condylobasal length.

https://doi.org/10.1371/journal.pone.0048352.s007

(DOC)

Table S4.

Sexual proportional dimorphism in cranial morphology in the lion ( Panthera leo ssp.), all expressed as percentages of condylobasal skull length.

https://doi.org/10.1371/journal.pone.0048352.s008

(DOC)

Table S5.

Sexual proportional dimorphism in cranial morphology in the jaguar ( Panthera onca ssp.), all expressed as percentages of condylobasal skull length.

https://doi.org/10.1371/journal.pone.0048352.s009

(DOC)

Table S6.

Sexual proportional dimorphism in cranial morphology in the leopard ( Panthera pardus ssp.), all expressed as percentages of condylobasal skull length.

https://doi.org/10.1371/journal.pone.0048352.s010

(DOC)

Table S7.

Sexual proportional dimorphism in cranial morphology in the tiger ( Panthera tigris ssp.), all expressed as percentages of condylobasal skull length.

https://doi.org/10.1371/journal.pone.0048352.s011

(DOC)

Table S8.

Sexual proportional dimorphism in cranial morphology in the snow leopard ( Panthera uncia ), all expressed as percentages of condylobasal skull length.

https://doi.org/10.1371/journal.pone.0048352.s012

(DOC)

Table S9.

Ratio comparisons of male and female cranial proportions in six species of extant ursids, along with the sample averages±SD, coefficients of variation ( v ) and the sexual dimorphism coefficient (S).

https://doi.org/10.1371/journal.pone.0048352.s013

(DOC)

Acknowledgments

We are indebted to the staff at the Los Angeles County Museum, Los Angeles, and to the Natural History Museum in London; the Zoological Museum in Copenhagen; the Museo Nacional de Ciencias Naturales in Madrid; the Museum National d'Histoire Naturelle in Paris; Naturhistoriska riksmusset in Stockholm; the National Museum of Natural History in Leiden; the Naturmuseum Senckenberg in Frankfurt; Staatliches Museum fûr Naturkunde in Stuttgart; and the department of zoology at the Museum für Naturkunde in Berlin for hospitality and helpful assistance during our frequent visits. Two anonymous reviewers provided many insightful comments on an earlier draft of this manuscript.

Author Contributions

Conceived and designed the experiments: PC JH. Performed the experiments: PC. Analyzed the data: PC. Contributed reagents/materials/analysis tools: PC JH. Wrote the paper: PC JH.

References

  1. 1. Harvey PH, Kavanagh M, Clutton-Brock TH (1978) Sexual dimorphism in primate teeth. J Zool Lond 186: 475–487.
  2. 2. Cheverud JM, Dow MM, Leutenegger W (1985) The quantitative assessment of phylogenetic constraints in comparative analyses: Sexual dimorphism in body weight among primates. Evolution 39: 1335–1351.
  3. 3. Kay RF, Plavcan JM, Glander GE, Wright PC (1988) Sexual selection and canine dimorphism in New World monkeys. Am J Phys Anthropol 77: 385–397.
  4. 4. Plavcan JM, van Schaik CP, Kappeler PM (1995) Competition, coalitions, and canine size in primates. J Human Evol 28: 245–276.
  5. 5. Short RV, Balaban E (1994) The differences between the sexes. Cambridge: Cambridge Univ Press.
  6. 6. Weckerly FW (1998) Sexual-size dimorphism: Influence of mass and mating systems in the most dimorphic mammals. J Mammal 79: 33–52.
  7. 7. Gittleman JL, Van Valkenburgh B (1997) Sexual dimorphism in the canines and skulls of carnivores: Effects of size, phylogeny and behavioural ecology. J Zool Lond 242: 97–117.
  8. 8. Van Valkenburgh B, Sacco T (2002) Sexual dimorphism, social behavior, and intrasexual competition in large Pleistocene carnivorans. J Vert Paleontol 22: 164–169.
  9. 9. Leutenegger W (1982) Scaling of sexual dimorphism in body weight and canine size in primates. Folia Primatol 37: 163–176.
  10. 10. Leutenegger W, Cheverud JM (1982) Correlates of sexual dimorphism in primates: ecological and size variables. Intl J Primatol 3: 387–402.
  11. 11. Kurtén B (1973) Geographic variation in size in the puma (Felis concolor). Comm Biol 63: 1–8.
  12. 12. Turner A (1984) Dental sex dimorphism in European lions (Panthera leo L.) of the UpperPleistocene: Palaeoecological and palaeoethological implications. Ann Zool Fennici 21: 1–8.
  13. 13. Wiig Ø, Andersen T (1986) Sexual size dimorphism in the skull of Norwegian Lynx. Acta Theriol 31: 147–155.
  14. 14. Dayan T, Simberloff D, Tchernov E, Yom-Tov Y (1990) Feline canines: Community-wide character displacement among the small cats of Israel. Am Nat 136: 39–60.
  15. 15. Sunquist M, Sunquist F (2002) Wild cats of the World. Chicago: Univ Chicago Press.
  16. 16. Mazak JH (2004) On the sexual dimorphism in the skull of the tiger (Panthera tigris). Mamm Biol 69: 392–400.
  17. 17. Palmquist P, Torregrosa V, Pérez-Claros JA, Martínez-Navarro B, Turner A (2007) A re-evaluation of the diversity of Megantereon (Mammalia, Carnivora, Machairodontinae) and the problem of species identification in extinct carnivores. J Vert Paleontol 27: 160–175.
  18. 18. Kurtén B (1955) Sex dimorphism and size trends in the cave bear Ursus spelaeus Rosenmüller and Heinroth. Acta Zool Fennica 90: 1–48.
  19. 19. Larsen T (1971) Sexual dimorphism in the molar rows of the polar bear. J Wildl Managm 35: 374–377.
  20. 20. Lynch JM, O'Sullivan WM (1993) Cranial form and sexual dimorphism in the Irish otter (Lutra lutra). Biol. & Environm. Proc R Ir Acad 93: 97–105.
  21. 21. Dayan T, Simberloff D, Tchernov E, Yom-Tov Y (1989) Inter-and intraspecific character displacement in mustelids. Ecology 70: 1526–1539.
  22. 22. Dayan T, Simberloff D, Tchernov E, Yom-Tov Y (1993) Canine carnassials: Character displacement in the wolves, jackals and foxes of Israel. Biol J Linn Soc 45: 315–331.
  23. 23. Dayan T, Simberloff D (1994) Character displacement, sexual dimorphism, and morphological variation among British and Irish mustelids. Ecology 75: 1063–1073.
  24. 24. Dayan T, Simberloff D (1996) Patterns of size separation in carnivore communities. In: Gittleman JL, ed. Carnivore Behavior, Ecology, and Evolution, Vol. II. New York: Cornell Univ Press. pp 243–266.
  25. 25. Loy A, Spinosi O, Carlini R (2004) Cranial morphology of Martes foina and M. martes (Mammalia, Carnivora, Mustelidae): the role of size and shape in sexual dimorphism and interspecific differentiation. Ital J Zool 71: 27–35.
  26. 26. Meiri S, Dayan T, Simberloff D (2005) Variability and sexual size dimorphism in carnivores: testing the niche variation hypothesis. Ecology 86: 1432–1440.
  27. 27. Emerson SB, Radinsky LB (1980) Functional analysis of sabertooth cranial morphology. Paleobiol 6: 295–312.
  28. 28. Martin LD (1980) Functional morphology and the evolution of cats. Trans Nebraska Acad Sci 8: 141–154.
  29. 29. Martin LD (1998) Felidae. In: Janis CM, Scott KM, Jabobs LL, eds. Evolution of Tertiary Mammals of North America, vol. I: Terrestrial Carnivores, Ungulates and Ungulatelike Mammals. Cambridge: Cambridge Univ Press. pp 236–242.
  30. 30. Turner A, Antón M (1997) The big cats and their fossil relatives. An illustrated guide to their evolution and natural history. New York: Columbia Univ Press.
  31. 31. Christiansen P (2006b) Sabertooth characters in the clouded leopard (Neofelis nebulosa Griffith, 1821). J Morphol 267: 1186–1198.
  32. 32. Werdelin L, O'Brien SJ, Johnson WE, Yamaguchi N (2010) Phylogeny and evolution of cats (Felidae). In: Macdonald DW, Loveridge AJ, eds. Biology and Conservation of Wild Felids. Oxford University Press. pp 60–82.
  33. 33. Miller GJ (1968) On the age distribution of Smilodon californicus Bovard from Rancho la Brea. Contr Sci Nat Hist Mus Los Angeles County 131: 1–17.
  34. 34. Merriam JC, Stock C (1932) The Felidae of Rancho La Brea. Carnegie Inst Washington Publ 422: 1–232.
  35. 35. Kurtén B, Werdelin L (1990) Relationships between North and South American Smilodon.. J Vert Paleontol 10: 158–169.
  36. 36. Meachen-Samuels J, Binder WJ (2010) Sexual dimorphism and ontogenetic growth in the American lion and sabertoothed cat from Ranho La Brea. J Zool Lond 280: 271–279.
  37. 37. Akersten WA (1985) Canine function in Smilodon (Mammalia; Felidae; Machairodontinae). Contr Sci Nat Hist Mus Los Angeles County 356: 1–22.
  38. 38. Antón M, Galobart A (1999) Neck function and predatory behavior in the scimitar toothed cat Homotherium latidens (Owen). J. Vert Paleontol 19: 771–784.
  39. 39. Antón M, Salesa MJ, Pastor JF, Sánchez IM, Fraile S, et al. (2004) Implications of the mastoid anatomy of larger extant felids for the evolution and predatory behaviour of sabretoothed cats (Mammalia, Carnivora, Felidae). Zool J Linn Soc 140: 207–221.
  40. 40. Salesa MJ, Antón M, Turner A, Morales J (2005) Aspects of the functional morphology in the cranial and cervical skeleton of the sabre-toothed cat Paramachairodus ogygia (Kaup, 1832) (Felidae: Machairodontinae) from the Late Miocene of Spain: implications for the origins of the machairodont killing bite. Zool J Linn Soc 144: 363–377.
  41. 41. Therrien F (2005) Feeding behaviour and bite force of sabretoothed predators. Zool J Linn Soc 145: 393–426.
  42. 42. Wroe S, McHenry C, Thomason JJ (2005) Bite club: comparative biteforce in big biting mammals and the prediction of predatory behaviour in fossil taxa. Proc Royal Soc Lond B 272: 619–625.
  43. 43. McHenry CH, Wroe S, Clausen PD, Moreno K, Cunningham E (2007) Supermodeled sabrecat, predatory behaviour in Smilodon fatalis revealed by high-resolution 3D computer simulation. Proc Natl Acad Sci 104: 16010–16015.
  44. 44. Christiansen P (2007) Comparative biteforces and canine bending strengths in feline and sabretooth felids: implications for predatory ecology. Zool J Linn Soc 151: 423–437.
  45. 45. Christiansen P (2008a) Evolution of skull and mandible shape in cats (Carnivora: Felidae). PLoS ONE 3: 1–8.
  46. 46. Christiansen P (2011) A dynamic model for the evolution of sabrecat predatory bite mechanics. Zool J Linn Soc 162: 220–242.
  47. 47. Slater GJ, Van Valkenburgh B (2008) Long in tooth: evolution of sabertooth cat cranial shape. Paleobiol 34: 403–419.
  48. 48. Meachen-Samuels J, Van Valkenburgh B (2010) Radiographs reveal exceptional forelimb strength in the sabertooth cat, Smilodon fatalis. PLoS ONE 5: 1–6.
  49. 49. Prevosti FJ, Turazzini GF, Chemisquy AM (2010) Cranial morphology in sabertooth cats: Allometry, function and phylogeny. Ameghiniana 47: 239–256.
  50. 50. Witmer LM (1995) The extant phylogenetic bracket and the importance of reconstructing soft tissues in fossils. In: Thomason J, ed. Functional morphology in vertebrate paleontology. Cambridge: Cambridge Univ Press Cambridge. pp 19–33.
  51. 51. Ralls K (1977) Sexual dimorphism in mammals: avian models and un-answered questions. Am Nat 111: 917–938.
  52. 52. Bennett SC (1992) Sexual dimorphism of Pteranodon and other pterosaurs, with comments on cranial crests. J Vert Paleontol 12: 422–434.
  53. 53. Dodson P (1976) Quantitative aspects of relative growth and sexual dimorphism in Protoceratops. J Palaeontol 50: 929–940.
  54. 54. Chapman RE, Weishampel DB, Hunt G, Rasskin-Gutman D (1997) Sexual dimorphism in dinosaurs. In: Wolberg DL, Stump E, Rosenberg GD, eds. Dinofest International. Proceedings of a symposium held at Arizona State University. Philadelphia: Acad Natl Sci. pp 83–93.
  55. 55. Galton PM (1997) Comments on sexual dimorphism in the prosauropod dinosaur Plateosaurus engelhardtii (Upper Triassic, Tossingen). N Jahrb Geol Palaeontol Mh 11: 674–682.
  56. 56. Selander RK (1966) Sexual dimorphism and differential niche utilization in birds. Condor 68: 113–151.
  57. 57. Owens IPF, Hartley IR (1998) Sexual dimorphism in birds: why are there so many different forms of dimorphism? Proc Royal Soc Lond B 265: 397–407.
  58. 58. Figuerola J (1999) A comparative study on the evolution of reversed size dimorphism in monogamous waders. Biol J Linn Soc 67: 1–18.
  59. 59. Shine R (1978) Sexual size dimorphism and sexual selection in turtles (order Testudines). Oecologia 33: 269–277.
  60. 60. Gibbons JV, Lovich JE (1990) Sexual dimorphism in turtles with emphasis on the slider turtle (Trachemys scripta). Herpetol Monogr 4: 1–29.
  61. 61. Schwaner TD, Sarre SD (1990) Body size and sexual dimorphism in mainland and island tiger snakes. J Herpetol 24: 320–322.
  62. 62. Janzen FJ, Paukstis GL (1991) A preliminary test of the adaptive significance of environmental sex determination in reptiles. Evolution 45: 435–440.
  63. 63. Parker GA (1992) The evolution of sexual size dimorphism in fish. J Fish Biol 41 (Suppl B): 1–20.
  64. 64. Filiz H, Taskavak E (2006) Sexual dimorphism in the head, mouth, and body morphology of the smallspotted catshark, Scyliorhinus canicula (Linnaeus, 1758) (Chondrichthyes: Scyliorhinidae) from Turkey. Acta Adriat 47: 37–47.
  65. 65. Johnson GD, Paxton JR, Sutton TT, SatohTP SadoT, et al. (2009) Deep-sea mystery solved: astonishing larval transformations and extreme sexual dimorphism unite three fish families. Biol Lett 5: 235–239.
  66. 66. Herler J, Kerschbaumer M, Mitteroecker P, Post L, Sturmbauer C (2010) Sexual dimorphism and population divergence in the Lake Tanganyika cichlid fish genus Tropheus. Front Zool 7: 1–10.
  67. 67. Otte D (1979) Historical development of sexual selection theory. In: Blum MS, Bulm NA, eds. Sexual Reproduction and Reproductive Competition in Insects. New York: Academic Press. pp 1–18.
  68. 68. Cook D (1987) Sexual selection in dung beetles I. A multivariate study of the morphological variation in two species of Onthophagus (Scarabaeidae: Onthophagini). Austr J Zool 35: 123–132.
  69. 69. Conner J (1988) Field measurements of natural and sexual selection in the fungus beetle, Bolitotherus cornutus. Evolution 42: 736–749.
  70. 70. Emlen DJ, Nijhout HF (2000) The development and evolution of exaggerated morphologies in insects. Ann Rev Entomol 45: 661–708.
  71. 71. Kawano K (2003) Character displacement in the stag beetles (Coleoptera: Lucanidae). Ann Entomol Soc Am 94: 503–511.
  72. 72. Kawano K (2004) Developmental stability and adaptive variability of male genitalia in sexually dimorphic beetles. Am Nat 163: 1–15.
  73. 73. Christiansen P (2006a) Somatic proportions in the genus Megasoma (Scarabaeidae: Dynastinae): Megasoma actaeon. Ann Entomol Soc Am 99: 342–351.
  74. 74. Gidaszewski NA, Baylac M, Klingenberg CP (2009) Evolution of sexual dimorphism of wing shape in the Drosophila melanogaster subgroup. BMC Evol Biol 9: 110.
  75. 75. Slaughter BH (1963) Some observations concerning the genus Smilodon with special reference to Smilodon fatalis. Texas J Sci 55: 68–81.
  76. 76. Van Valkenburgh B, Hertel F (1993) Tough times at La Brea: Tooth breakage in large carnivores of the Late Pleistocene. Science 261: 456–459.
  77. 77. Pocock RI (1939a) The fauna of British India including Ceylon and Burma. Mammalia Vol. I: Primates and Carnivora (in part): Families Felidæ and Viverridæ. London: Taylor and Francis Ltd.
  78. 78. Jerdon TC (1867) The mammals of India: a natural history of all the animals known to inhabit continental India. Rorkee: Thomason College Press.
  79. 79. Sterndale RA (1884) Natural history of the Mammalia of India and Ceylon. Calcutta: Thacker & Spink.
  80. 80. Marcus LF, Berger R (1984) The significance of radiocarbon dates for Rancho La Brea. In: Martin PS, Klein RG, eds. Quaternary extinctions. Tucson: Univ Arizona Press. pp 159–188.
  81. 81. Shaw CA, Tejada-Flores AE (1985) Biomechanical implications of the variation in Smilodon ectocuneiforms from Rancho la Brea. Contr Sci Nat Hist Mus Los Angeles County 359: 1–8.
  82. 82. Carbone C, Maddox T, Funston PJ, Mills MGL, Grether GF, et al. (2009) Parallels between playbacks and Pleistocene tar seeps suggest sociality in an extinct sabretooth cat, Smilodon. Biol Lett 5: 81–85.
  83. 83. O'Keefe FR, Fet EV, Harris JM (2009) Compilation, calibration, and synthesis of faunal and floral radiocarbon dates, Rancho La Brea, California. Contr Sci Nat Hist Mus Los Angeles County 518: 1–16.
  84. 84. Menard HW Jr (1947) Analysis of measurements in length of the metapodials of Smilodon. Bull Southern Calif Acad Sci 46: 127–135.
  85. 85. Christiansen P, Harris JM (2009) Craniomandibular morphology and phylogenetic affinities of Panthera atrox: implications for the evolution and paleobiology of the lion lineage. J Vert Paleontol 29: 934–945.
  86. 86. Hemmer H (1974) Untersuchungen zur Stammesgeschichte der Pantherkatzen (Pantherinae). Teil III. Zur Artsgeschichte des Löwen Panthera (Panthera) leo (Linnaeus 1758). Veröff Zool Staatssaml München 17: 167–280.
  87. 87. Haas SK, Hayssen V, Krausman PR (2005) Panthera leo. Mamm Spec 762: 1–11.
  88. 88. Burger J, Rosendahl W, Loreille O, Hemmer H, Ericksson T, et al. (2004) Molecular phylogeny of the extinct cave lion Panthera leo spelaea. Mol Phyl Evol 30: 841–849.
  89. 89. Dubach J, Patterson BD, Briggs MB, Venzke K, Flamand J, et al. (2005) Molecular genetic variation across the southern and eastern geographic ranges of the African lion, Panthera leo. Cons Gen 6: 15–24.
  90. 90. Christiansen P (2008b) On the distinctiveness of the Cape lion (Panthera leo melanochaita Smith, 1842) and a possible new specimen from the Zoological Museum, Copenhagen. Mamm Biol 73: 58–65.
  91. 91. Mazak JH (2010) Geographical variation and phylogenetics of modern lions based on craniometric data. J Zool Lond 281: 194–209.
  92. 92. Pocock RI (1939b) The races of jaguar (Panthera onca). Novit Zool 41: 406–422.
  93. 93. Seymour KL (1989) Panthera onca. Mamm Spec 340: 1–9.
  94. 94. Nelson EW, Goldman EA (1933) Revision of the jaguars. J Mammal 14: 221–240.
  95. 95. Larson SE (1997) Taxonomic re-evaluation of the jaguar. Zoo Biol 16: 107–120.
  96. 96. Eizirik E, Kim J-H, Menotti-Raymond M, Crawshaw PG Jr, O'Brien SJ, et al. (2001) Phylogeography, population history and conservation genetics of jaguars (Panthera onca, Mammalia, Felidae). Mol Ecol 10: 65–79.
  97. 97. Pocock RI (1909) On the skulls of leopards. Proc Zool Soc Lond 1909: 204–209.
  98. 98. Pocock RI (1930a) The panthers and ounces of Asia. J Bombay Nat Hist Soc 34: 63–82.
  99. 99. Pocock RI (1930b) The panthers and ounces of Asia. Part II. The panthers of Kashmir, India and Ceylon. J Bombay Nat Hist Soc 34: 307–336.
  100. 100. Pocock RI (1932) The leopards of Africa. Proc Zool Soc Lond 1932: 543–591.
  101. 101. Uphyrkina O, Johnson WE, Quigley H, Miquelle D, Marker L, et al. (2001) Phylogenetics, genome diversity and origin of modern leopard, Panthera pardus. Mol Ecol 10: 2617–2633.
  102. 102. Guggisberg CAW (1975) Wild cats of the world. London: David & Charles Holdings.
  103. 103. Miththapala S, Seidensticker J, O'Brien SJ (1996) Phylogeographic subspecies recognition in leopards (Panthera pardus): Molecular genetic variation. Cons Biol 10: 1115–1132.
  104. 104. Khorozyan IG, Baryshnikov GF, Abramov AV (2006) Taxonomic status of the leopard, Panthera pardus (Carnivora, Felidae) in the Caucasus and adjacent areas. Russ J Theriol 5: 41–52.
  105. 105. Mazák V (1983) Der Tiger. Neue Brehm-Bücherei 356. Wittenberg, Lutherstadt: A. Ziemsen Verlag.
  106. 106. Cracraft J, Feinstein J, Vaughn J, Helm-Bychowski K (1998) Sorting out tigers (Panthera tigris): mitochondrial sequences, nuclear inserts, systematics and conservation genetics. Anim Cons 1: 139–150.
  107. 107. Pocock RI (1929) Tigers. J Bombay Nat Hist Soc 33: 505–541.
  108. 108. Hendrickson SL, Mayer GC, Wallen EP, Quigley K (2000) Genetic variability and geographic structure of three subspecies of tigers (Panthera tigris) based on MHC class I variation. Anim Cons 3: 135–143.
  109. 109. Kitchener AC, Dugmore AJ (2000) Biogeographical change in the tiger, Panthera tigris. Anim Cons 3: 113–124.
  110. 110. Luo S-J, Kim J-H, Johnson WE, van der Walt J, Martenson J, et al. (2004) Phylogeography and genetic ancestry of tigers (Panthera tigris). PLoS Biol 2: 2275–2293.
  111. 111. Luo S-J, Kim J-H, Johnson WE, Miquelle DG, Huang S-Q, et al. (2006) Proceedings in phylogeography and genetic ancestry of tigers (Panthera tigris) in China and across their range. Zool Res 27: 441–448.
  112. 112. Mazak JH, Groves CP (2006) A taxonomic revision of the tigers (Panthera tigris) of Southeast Asia. Mamm Biol 71: 268–287.
  113. 113. Driscoll CA, Yamaguchi N, Bar-Gal GK, Roca AL, Luo S, et al. (2009) Mitochondrial phylogeography illuminates the origin of the extinct Caspian tiger and its relationships to the Amur tiger. PloS ONE 4: e4125.
  114. 114. Hemmer H (1968) Untersuchungen zur Stammesgeschichte der Pantherkatzen (Pantherinae). Teil II. Studien zur Ethologie des Nebelparders Neofelis nebulosa (Griffith 1821) und des Irbis Uncia uncia (Schreber 1775). Veröff Zool Staatssamlung München 12: 155–247.
  115. 115. Hemmer H (1972) Uncia uncia. Mamm Spec 20: 1–5.
  116. 116. Oli MK (1994) Snow leopards and blue sheep in Nepal: densities and predator:prey ratio. J Mammal 75: 998–1004.
  117. 117. Jackson RM (1996): Home range, movements and habitat use of snow leopard (Uncia uncia) in Nepal. Unpubl. Ph.d. dissertation. Univ. London, England.
  118. 118. Jackson R, Hunter DO (1996) Snow leopard survey and conservation handbook. Seattle: Intl Snow Leopard Trust.
  119. 119. McCarthy TM, Chapron G (2003) Snow leopard survival strategy. Seattle: Snow Leopard Trust & Snow Leopard Network.
  120. 120. Rieger I (1980) Some aspects of the history of ounce knowledge. Intl Pedigree Book of Snow Leopards 2: 1–36.
  121. 121. Sokal RR, Rohlf FJ (1995) Biometry. New York: WH Freeman and Co.
  122. 122. Rossolimo OL, Pavlinov IJ (1974) Sexual dimorphism in the development, size and proportions of the skull in the pine-marten (Martes martes L.: Mammalia, Mustelidae). Bull Moscow Soc Naturalists (Biol.) 79: 23–25.
  123. 123. Rohlf FJ (2004a) tpsDig, digitize landmarks and outlines, ver. 2.0. Department of Ecology and Evolution, State University of New York at Stony Brook (computer program and documentation).
  124. 124. Jacobshagen B, Berghaus G, Knussmann R, Sperwien A, Zeltner H (1988) Fotogrammetrische Methoden. In: Knussmann R, ed. Anthropologie. Handbuch der vergleichenden Biologie des Menschen, volume 1. Springer Verlag, Stuttgart. pp. 328–345
  125. 125. Friess M (1997) Analyses de formes crâniennes fondées sur la photogrammétrie. Biom Hum Ety Anthropol 15: 19–22.
  126. 126. Bookstein FL (1989) Principal warps: thin-plate splines and the decomposition of deformation. IEEE Trans Pattern Anal Mach Intell 11: 567–585.
  127. 127. Bookstein FL (1991) Morphometric Tools for Landmark Analysis: Geometry and Biology. New York: Cambridge Univ Press.
  128. 128. Zelditch ML, Swiderski DL, Sheets HD, Fink WL (2004) Geometric Morphometrics for Biologists. A Primer. San Diego: Elsevier Acad Press.
  129. 129. Gower JC (1975) Generalized Procrustes analysis. Psychometrika 40: 33–51.
  130. 130. Rohlf FJ, Slice DE (1990) Extensions of the Procrustes method for the optimal superimposition of landmarks. Syst Biol 39: 40–59.
  131. 131. Zelditch ML, Bookstein FL, Lundrigan BL (1992) Ontogeny of integrated skull shape in the cotton rat, Sigmodon. Evolution 46: 1164–1180.
  132. 132. Rohlf FJ (1993) Relative warp analysis and an example of its application to mosquito wings. In: Marcus LF, Bello E, Garcia-Valdecasas A, eds. Contributions to morphometrics, vol 8. Madrid: Museo Nacional de Ciencias Naturales (CSIC). pp 131–159.
  133. 133. Zelditch ML, Swiderski DL, Fink WL (2000) Discovery of phylogenetic characters in morphometric data. 37–83. In: Wiens JJ, ed. Phylogenetic analysis of morphological data Washington: Smithsonian Inst Press. pp 37–83.
  134. 134. Rohlf FJ (2004b) tpsRelw, ver. 1.39. Department of Ecology and Evolution, State University of New York at Stony Brook (computer program and documentation).
  135. 135. Bookstein FL (1996) Combining the tools of geometric morphometrics. In: Marcus LF, Corti M, Loy A, Naylor GJP, Slice DE, eds. Advances in Morphometrics. Proceedings of the 1993 NATO Advanced Studies Institute on Morphometrics, IL Ciocco, Italy. New York: Plenum Publ. Corp. pp 131–151.
  136. 136. Fowler J, Cohen L, Jarvis P (2003) Practical statistics for field biology. Chichester: Wiley.
  137. 137. Hedrick AV, Temeles ET (1989) The evolution of sexual dimorphism in animals hypotheses and tests. Trends Ecol Evol 4: 136–138.
  138. 138. Shine R (1989) Ecological causes for the evolution of sexual dimorphism: a review of the evidence. Q Rev Biol 64: 419–461.
  139. 139. Brodie ED Jr, Formanowicz DR Jr (1983) Prey size preference of predators: differential vulnerability of larval anurans. Herpetologica 39: 67–75.
  140. 140. Vézina AF (1985) Empirical relationships between predator and prey size among terrestrial vertebrate predators. Oecologia 67: 555–565.
  141. 141. Scharf FS, Juanes F, Roundtree RA (2000) Predator size - prey size relationships of marine fish predators: interspecific variation and effects of ontogeny and body size on trophic-niche breadth. Marine Ecol Progr Ser 208: 229–248.
  142. 142. Meers MB (2002) Maximum bite force and prey size of Tyrannosaurus rex and their relationships to the inference of feeding behavior. Hist Biol 16: 1–12.
  143. 143. Emmerson MC, Raffaelli D (2004) Predator–prey body size, interaction strength and the stability of a real food web. J Anim Ecol 73: 399–409.
  144. 144. Radloff FGT, du Toit JT (2004) Large predators and their prey in a southern African savanna: a predator's size determines its prey size range. J Anim Ecol 73: 410–423.
  145. 145. Carbone C, Teacher A, Rowcliffe JM (2007) The costs of carnivory. PLoS Biol 5: e22.
  146. 146. Owen-Smith N, Mills MG (2008) Predator-prey size relationships in an African large-mammal food web. J Anim Ecol 77: 173–183.
  147. 147. Meachen-Samuels J, Van Valkenburgh B (2009) Craniodental indicators of prey size preference in the Felidae. Biol J Linn Soc 96: 784–799.
  148. 148. Sinclair ARE, Mduma S, Brashares JS (2003) Patterns of predation in a diverse predator-prey system. Nature 425: 288–290.
  149. 149. Hayward MW, Kerley GIH (2005) Prey preferences of the lion (Panthera leo). J Zool Lond 267: 309–322.
  150. 150. Christiansen P, Wroe SM (2007) Bite forces and evolutionary adaptations to feeding ecology in carnivores. Ecology 88: 347–358.
  151. 151. Funston PJ, Mills MGL, Biggs HC, Richardson PRK (1998) Hunting by male lions ecological influences and socioecological implications. Anim Behav 56: 1333–1345.
  152. 152. Funston PJ, Mills MGL, Richardson PRK, van Jaarsveld AS (2003) Reduced dispersal and opportunistic territory acquisition in male lions (Panthera leo). J Zool Lond 259: 131–142.
  153. 153. Gonyea WJ (1976) Behavioral implications of saber-toothed felid morphology. Palaeobiol 2: 332–342.
  154. 154. Kurtén B, Anderson E (1980) Pleistocene mammals of North America. New York: Columbia Univ Press.
  155. 155. Radinsky LB (1975) Evolution of the felid brain. Brain Behav Ecol 11: 214–254.
  156. 156. Radinsky LB (1978) Evolution of brain size in carnivores and ungulates. Am Nat 112: 815–831.
  157. 157. Yamaguchi N, Kitchener AC, Gilissen E, MacDonald DW (2009) Brain size of the lion (Panthera leo) and the tiger (P. tigris): implications for intrageneric phylogeny, intraspecific differences and the effects of captivity. Biol J Linn Soc 98: 85–93.
  158. 158. Heald F (1989) Injuries and diseases in Smilodon californicus. J Vert Paleontol Suppl 9: 24A.
  159. 159. Mestel R (1993) Saber-toothed tales. Discover 14: 50–59.
  160. 160. McCall S, Naples V, Martin LD (2003) Assessing behavior in extinct animals: Was Smilodon social? Brain Behav Evol 61: 159–164.
  161. 161. Lindenfors P, Tullberg BS (1998) Phylogenetic analysis of primate size evolution: The consequences of sexual selection. Biol J Linn Soc 64: 413–447.
  162. 162. Plavcan JM (2001) Sexual dimorphism in primate evolution. Am J Phys Anthropol 33: 25–53.
  163. 163. Thorén S, Lindenfors P, Kappeler PM (2006) Phylogenetic analysis of dimorphism in primates: Evidence for stronger selection on canine size than on body size. Am J Phys Anthropol 130: 50–59.
  164. 164. Christiansen P (2008c) Phylogeny of the great cats (Felidae Pantherinae), and the influence of fossil taxa and missing characters. Cladistics 24: 977–992.
  165. 165. Schaller GM (1977) Mountain monarchs. Chicago: Univ Chicago Press.
  166. 166. Mallon DP (1984) The snow leopard, Panthera uncia, in Mongolia. Intl Pedigree Book on Snow Leopards 4: 3–9.
  167. 167. Sunquist ME (1981) The social organisation of tigers (Panthera tigris) in Royal Chitawan National Park, Nepal. Smithsonian Contr Zool 336: 1–98.
  168. 168. Smith JLD, McDougal C, Miquelle D (1989) Scent marking in free-ranging tigers, Panthera tigris. Anim Behav 37: 1–10.
  169. 169. Bailey TN (1993) The African leopard. New York: Columbia Univ Press.
  170. 170. Bagchi S, Mishra C (2006) Living with large carnivores predation on livestock by the snow leopard (Uncia uncia). J Zool Lond 268: 217–224.
  171. 171. Caro TM (1994) Cheetahs of the Serengeti Plains. Group living in an asocial Species. Chicago: Univ Chicago Press.
  172. 172. Wright B (1960) Predation on big game in East Africa. J Wildl Managm 24: 1–15.
  173. 173. Schaller GM (1972) The Serengeti lion: a study of predator-prey relations. Chicago: Univ Chicago Press.
  174. 174. Elliott JP, Cowan IM (1977) Territoriality, density, and prey of the lion in Ngorongoro Crater, Tanzania. Can J Zool 56: 1726–1734.
  175. 175. Hanby JP, Bygott JD (1979) Populations changes in lions and other predators. In: Sinclair ARE, Norton-Griffiths M, eds. Serengeti: Dynamics of an ecosystem. Chicago: Univ Chicago Press. pp. 249–262.
  176. 176. Hanby JP, Bygott JD (1987) Emigration of subadult lions. Anim Behav 35: 161–169.
  177. 177. Packer C, Scheel D, Pusey AE (1990) Why lions form groups: Food is not enough. Am Nat 136 1–19.
  178. 178. Gilbert DA, Packer C, Pusey AE, Stephens JC, O'Brien SJ (1991) Analytical DNA fingerprinting in lions: Parentage, genetic diversity, and kinship. J Heredity 82: 378–386.
  179. 179. Stander PE (1991) Foraging dynamics of lions in a semi-arid environment. Can J Zool 70: 8–21.
  180. 180. Stander PE (1992) Cooperative hunting in lions: the role of the individual. Behav Ecol Sociobiol 29: 445–454.
  181. 181. Grinnell J, Packer C, Pusey AE (1995) Cooperation in male lions: kinship, reciprocity or mutualism? Anim Behav 49: 95–105.
  182. 182. Heinsohn R, Packer C (1995) Complex cooperative strategies in group-territorial African lions. Science 269: 1260–1262.
  183. 183. Packer C, Pusey AE (1997) Divided we fall: Cooperation among lions. Sci Am 276: 32–39.
  184. 184. Kays RW, Patterson BD (2002) Mane variation in African lions and its social correlations. Can J Zool 80: 471–478.
  185. 185. Spong G, Stone J, Creel S, Björklund M (2002) Genetic structure of lions (Panthera leo L.) in the Selous Game Reserve: implications for the evolution of sociality. J Evol Biol 15: 945–953.
  186. 186. Bauer H, de Iongh HH, di Silvestre I (2003) Lion (Panthera leo) social behaviour in the West and Central African savannah belt. Mamm Biol 68: 239–243.
  187. 187. Kissui BM, Packer C (2004) Top-down population regulation of a top predator lions in the Ngorongoro Crater. Proc Royal Soc Lond B 271: 1867–1874.
  188. 188. Burger J, Hemmer H (2006) Urgent call for further breeding of the relic zoo population of the critically endangered Barbary lion (Panthera leo leo Linnaeus 1758). Eur J Wildl Res 52: 54–58.
  189. 189. Dharmakumarsinhji KS, Wynter-Blyth MA (1950) The Gir Forest and its lions, part III. J Bombay Nat Hist Soc 49: 685–694.
  190. 190. Wynter-Blyth MA, Dharmakumarsinhji KS (1950) The Gir Forest and its lions, part II. J Bombay Nat Hist Soc 49: 456–470.
  191. 191. Joslin P (1984) The environmental limitations and future of the Asiatic lion. J Bombay Nat Hist Soc 81: 648–664.
  192. 192. Chellam R, Johnsingh AJT (1993) Management of Asiatic lions in the Gir Forest, India. Symp Zool Soc Lond 65: 409–424.
  193. 193. Divyabhanusinh (2005) The story of Asia's lions. Mumbai: Marg Publ.
  194. 194. Cabrera A (1932) Los mamiferos de Marruecos. Trabajos del Museo Nacional de Ciencias Naturales Ser Zool 57: 1–361.
  195. 195. Werner F (1939) Von den letzten Berberlöwen und anderen Groβkatzen. Zool Garten Leipzig NF 10: 224–227.
  196. 196. Smuts GL (1978) Effects of population reduction on the travels and reproduction of lions in Kruger National Park. Carnivore 1: 61–72.
  197. 197. Van Orsdol KG, Hanby JP, Bygott JD (1985) Ecological correlations of lion social organisation (Panthera leo). J Zool Lond 206: 97–112.