Skip to main content
PMC home page
Scientific Reports logoLink to Scientific Reports
. 2015 Jul 23;5:12408. doi: 10.1038/srep12408

Possible Signatures of Hominin Hybridization from the Early Holocene of Southwest China

Darren Curnoe 1,a, Xueping Ji 2,b, Paul S C Taçon 3, Ge Yaozheng 4
PMCID: PMC5378881  PMID: 26202835

Abstract

We have previously described hominin remains with numerous archaic traits from two localities (Maludong and Longlin Cave) in Southwest China dating to the Pleistocene-Holocene transition. If correct, this finding has important implications for understanding the late phases of human evolution. Alternative interpretations have suggested these fossils instead fit within the normal range of variation for early modern humans in East Asia. Here we test this proposition, consider the role of size-shape scaling, and more broadly assess the affinities of the Longlin 1 (LL1) cranium by comparing it to modern human and archaic hominin crania. The shape of LL1 is found to be highly unusual, but on balance shows strongest affinities to early modern humans, lacking obvious similarities to early East Asians specifically. We conclude that a scenario of hybridization with archaic hominins best explains the highly unusual morphology of LL1, possibly even occurring as late as the early Holocene.

The hominin fossil records of Europe, West Asia and parts of Africa have long dominated discussions about Late Pleistocene human evolution. Yet, despite its vast size, the East Asian landmass was largely overlooked internationally by palaeoanthropologists for much of the later 20th Century, and was considered to be a backwater with respect to this evolutionary episode1,2. Over the past decade, however, this has begun to change due to several major discoveries that have highlighted the incompleteness of orthodox views. Important among them has been the discovery of the species H. floresiensis3,4 at Liang Bua Cave, Flores, dating between c74 and c17 ka5, with its resemblances to Lower Pleistocene hominins3,4,6.

Yet another enigmatic specimen is the partial mandible recovered from Zhirendong in South China dated >100 ka7. While it was assigned to H. sapiens by its describers7, this designation has been questioned owing to its unusual combination of traits8. Moreover, new research on the early Late Pleistocene Xujiayao specimens from North China shows the presence of a previously undocumented morphological complex that has taxonomic implications for the Chinese later Pleistocene hominin record9,10,11. Finally, several recent finds in South China dated between ~130 ka and ~70 ka have led to the suggestion that modern humans (H. sapiens) may have appeared much earlier in East Asia than conventional wisdom allows12,13,14, raising the possibility of hitherto unknown populations and variation within the species.

Previously, we have reported the discovery of hominin remains dating to the Pleistocene-Holocene transition at Maludong and Longlin (Laomaocao) Cave in Southwest China that exhibit a large number of similarities to archaic hominins15,16. In the most complete cranium, early Holocene age (c11.5 ka15) Longlin 1 (LL1) (Fig. 1), we documented an extensive number of traits that would be unexpected for a modern human, some of them putative plesiomorphies for Late Pleistocene Homo: a finding unseen for any cranium from East Asia during this period and unusual even among Late Pleistocene remains globally15,16, including Australians17. We suggested that two most likely interpretations of the morphology of the Maludong and Longlin Cave fossils were15,16: 1) they represent the remnants of a precociously early and highly plesiomorphic modern human population that migrated to the region and failed to contribute genetically, or did so in a limited way, to recent people, or 2) they sample a late surviving archaic hominin population.

Figure 1. Longlin 1 cranium:

Figure 1

Open in a new tab

(a) anterior view, (b) left lateral view, (c) superior view, and (d) inferior view (Photos taken by the authors).

An alternative interpretation of the affinities of these materials has, however, been offered. Several researchers have questioned our findings and argued that these fossils instead show affinities to either the Late Pleistocene Upper Cave remains from Zhoukoudian18 or Late Pleistocene/early Holocene crania from mainland Southeast Asia19. A recently described mandible from Tam Pa Ling (TPL2) in nearby Laos has also been described as exhibiting archaic hominin features20, although, they are far less numerous than those seen in the Maludong or Longlin remains15,16. The similarly dated TPL1 cranium is evidently modern in its morphology19. Nevertheless, support for the hypothesis that the Maludong and Longlin remains sample a genetically divergent or even late surviving archaic population is growing21,22,23,24,25. Clearly, if they do show affinities to archaic hominins this would have significant implications for understanding the late phases of human evolution.

Our principal aim here is to test three specific questions about the LL1 specimen: 1) Does its cranial shape closely resemble the Late Pleistocene modern humans from Zhoukoudian Upper Cave (UC101 & UC103) (as proposed by Ref. 18) or Liujiang (LNJG), or even early Holocene mainland Southeast Asians (as proposed by Ref. 19), represented here by the Hang Cho Cave26 (HCC) cranium from nearby Northern Vietnam? (2) Alternatively, can the cranial shape of LL1 be accommodated within the range of archaic hominins? (3) Can differences between the morphology of LL1 and modern humans be explained by allometry (i.e. size-scaled shape differences)? To investigate them, bivariate and multivariate methods were applied to craniometric data from LL1. Comparative crania employed were East Asian early modern humans (EMH) represented by UC101, UC103, LNJG and HCC, several European EMH, a putative subspecies of H. sapiens (Herto: H. sapiens idaltu27), several archaic crania and Howells28,29 large global sample of recent modern humans (RMH) (see Table S1). We examined subsets of the data employing nine and four variables, the latter excluding measurements reconstructed by measuring to the median sagittal plane and doubling the value in LL1 (Table 1).

Table 1. Craniometric variables employed in the present study and values for Longlin 1 (LL1).

Variable Abbreviation Value for LL1
Bistephanic breadth STB 103
Frontal chord FRC 108*
Nasion-prosthion height NPH 64
Orbital breadth OBB 44
Orbital height OBH 34
Bizygomatic breadth ZYB (144)
Nasal height NLH 47
Nasal breadth NLB (32)
Biorbital breadth EKB (114)
Open in a new tab

Howells (Ref. 28,29) measurement definitions and abbreviations.

Values in parenthesis reconstructed by measuring to the median sagittal plane and doubling.

*Value different from that originally reported in Ref. 15.

Results

Univariate analysis

First we undertook a univariate examination of the data, which revealed that the value for one raw variable in LL1 (EKB: see Table 1) was outside of (above) the range of 2,524 RMH. The same variable in Herto (HTO) also exceeded the RMH maximum. In Shanidar 1 (SD1) another variable (NPH), and in Shanidar 5 (SD5), two variables (NPH & NLB), were larger than the RMH maximum. In Petralona (PETRA), the value for three variables (ZYB, NPH & EKB) was above the RMH maximum, while the Predmosti 3 (PRD3) cranium exceeded the RMH range for one variable (OBB). Examining size-adjusted variables showed that no measurements in LL1 were outside of RMH range. However, HTO exceeded the global RMH range for one size-adjusted variable (EKB), as did PETRA for a single variable (NPH), while Cro-Magnon 1 (CM1) was below the RMH minimum for one variable (OBH). Finally, values for two variables (NLB & FRC) for the Sima de Los Huesos Cranium 5 (SH5) were above the size-adjusted RMH maximum.

Principal component analysis

Next we used principal component analysis (PCA) to examine the phenetic affinities of LL1. In the first PCA, employing nine size-adjusted variables, the first four PCs explained 84.35% of variance (see Table S2). A scatterplot of object scores for PC1 (36.26%) and PC2 (23.74%) showed that most fossils plotted within the 95% concentration ellipsis for RMH, the exceptions being SH5 and Sangiran 17 (SANG17) (Fig. 2A). There was extensive overlap between EMH and archaic crania on PC1, while PC2 separated these groups (Fig. 2A). PC1 mostly sorted crania on the basis of differences in size-adjusted orbit height (OBH), while PC2 contrasted crania on the basis of posterior frontal breadth (STB) (Table S3). Among all of the fossils included, LL1 exhibited the largest negative object score for PC1, plotting outside of the range of all other fossils (Fig. 2A). For PC2, the object score for LL1 was outside of the range of EMH, although, it was close to UC101 as well as the archaic Dali cranium, being virtually identical to SD1 (Fig. 2A).

Figure 2. Scatterplots of PCA object scores:

Figure 2

Open in a new tab

(a) nine variables, PC1 versus PC2; (b) nine variables, PC3 versus PC4; (c) four variables, PC1 versus PC2; and (d) four variables, PC1 versus PC3 (NB: 95% concentration ellipsis for RMH shown; convex hull for EMH indicated; Key: 1 = LL1, 2 = UC101, 3 = UC103, 4 = LJNG, 5 = HCC, 6 = KEL, 7 = CM1, 8 = PRD3, 9 = PRD4, 10 = OASE 2, 11 = HTO, 12 = SD1, 13 = SD5, 14 = DALI, 15 = SH5, 16 = PETRA & 17 = SANG17; see main text and Table S1 for key to abbreviations).

Although PC3 (14.21%) versus PC4 (10.14%) explained a much lower proportion of variance, a scatterplot of object scores showed interesting contrasts among crania (Fig. 2B). PC3 tended to sort crania largely according to size-adjusted nasal height (NLH) and STB, while PC4 mostly contrasted crania on the basis of size-adjusted bizygomatic breadth (ZYB) (Table S3). On PC3, SD1, SH5 and PETRA were distinguishable from EMH, although, Dali sat within the EMH range (Fig. 2B). On PC4, EMH were characterized by considerable variance, which extended well beyond RMH (positive scores). Thus, this PC highlighted differences between the morphology of non-East Asian EMH and most RMH, with East Asian EMH sitting among RMH (Fig. 2B). PC3 and PC4 clustered LL1 and SANG17 together, both of them exhibiting object scores outside of the range of EMH for both PCs, but within the range of RMH (Fig. 2B).

The second PCA included two additional fossils [Shanidar 5 (SD5) and Oase 2], but used only four size-adjusted variables. Only three PCs were produced and they explained 99.99% of variance (Table S2). A scatterplot of object scores showed that PC1 (53.97%) separated all EMH crania from archaic remains and HTO (Fig. 2C). PC1 was mostly explained by variation in frontal shape: posterior frontal breadth (STB) and frontal length (FRC) (Table S3). PC2 (30.65%) distinguished PETRA, SH5, SD1 and SD5 from EMH, HTO and SANG17 (Fig. 2C). On PC1, LL1 sat within the range of EMH, but on PC2 it was outside of the range of all other fossils (Fig. 2C). Overall, LL1 plotted closest to Oase 2. A scatterplot of object scores for PC1 versus PC3 (15.37%) showed no sorting of groups along the orthogonal axis (Fig. 2D). LL1 sat well within the range of EMH and archaic crania for PC3 (Fig. 2D).

Neighbor joining analysis

The results of neighbor joining (NJ) analysis using RMH sample means, excluding SANG17, and employing SH5 as an outgroup to establish polarities, are provided in Fig. 3. In the first tree, using nine variables, Dali was the most basal branch, followed by LL1, HTO, then a branch containing UC101 and SD1, PETRA, and finally a large branch containing all other EMH and RMH (Fig. 3A). In the NJ tree employing four variables (Fig. 3B), PETRA was the most basal branch, followed by SD5, HTO, SD1 and Dali, and finally a large branch containing all other EMH and RMH (Fig. 3B). In this tree, LL1 was found to reside within the large modern human cluster, within a smaller clade containing recent Australian and Tolai sample means (Fig. 3B).

Figure 3. Neighbor-joining trees from cluster analysis using SH5 as an out-group:

Figure 3

Open in a new tab

(a) nine variables and (b) four variables (RMH represented by sample means; see main text and Table S1 for key to abbreviations).

Discriminant function analysis

With DFA, even if the independent variable has no relationship to the groups as defined by the dependent variables, we should expect classification predictions to be correct a certain proportion of the time owing to chance alone. The two DFA models we employed exhibited an estimated accuracy of 138% (9 variables) and 158% (4 variables), providing an improvement of 38% and 58%, respectively, over chance alone (see Methods). Moreover, when we examined the classification of RMH in our DFA models we found that 7% (9 variables) and 13% (4 variables) of crania were misclassified, unsurprisingly, emphasizing the greater accuracy of the former. The classification results of DFA showing cross-validated assignments and associated posterior probabilities for all fossils are provided in Table 2.

Table 2. Fossil classifications and associated posterior probabilities for cross-validated results from discrimination function analysis using a simple classification scheme (NB: RMH = recent modern human, EMH = early modern human & NM = non-modern).

  9 Variables
 4 Variables
  Highest group p 2nd highest group p Highest group p 2nd highest group p
LL1 NM 0.583 EMH 0.324 EMH 0.744 RMH 0.247
UC101 NM 0.586 RMH 0.411 RMH 0.649 EMH 0.311
UC103 EMH 0.962 RMH 0.036 RMH 0.488 EMH 0.480
LJNG EMH 0.799 RMH 0.189 RMH 0.940 EMH 0.059
HCC RMH 0.975 EMH 0.025 RMH 0.638 EMH 0.361
KEILOR EMH 0.985 NM 0.012 RMH 0.709 EMH 0.248
CM1 EMH 1.000 RMH 0.560 EMH 0.437
PRD3 EMH 0.995 RMH 0.004 RMH 0.535 EMH 0.403
PRD4 EMH 0.998 RMH 0.001 RMH 0.909 EMH 0.090
OASE2 RMH 0.692 EMH 0.302
HTO NM 0.994 EMH 0.006 NM 0.496 RMH 0.451
SD1 RMH 0.930 NM 0.039 RMH 0.634 EMH 0.205
SD5 NM 0.964 RMH 0.023
SH5 NM 1.000 NM 0.845 RMH 0.133
DALI NM 0.659 EMH 0.385 EMH 0.501 RMH 0.447
PETRA EMH 0.769 NM 0.224 NM 0.918 RMH 0.077
SANG17 RMH 0.927 EMH 0.072 NM 0.453 EMH 0.350
Open in a new tab

80.0% of cases were correctly classified.

66.0% of original grouped cases were correctly classified.

The first DFA model classified LL1 as non-modern (NM) with a confidence of 58.3%, the second highest group being early modern human (EMH) with a posterior probability of 32.4% (Table 2). Thus, its classification using this model and the groups we employed was ambiguous. UC101 was also classified as NM with a posterior probability of 58.6%, the second highest group being recent modern humans (RMH) with a probability of 41.1%. The classification of UC101 was also, therefore, considered to be ambiguous. All of the other modern human fossils except HCC were, however, firmly classified as EMH with posterior probabilities ranging from 79.9–100% (Table 2). HCC was classified in RMH with a posterior probability of 97.5% (Table 2). Among the other fossils, HTO, SH5 and Dali were correctly classified as NM (Table 2). SD1 and SANG17 were, however, incorrectly classified as RMH, and PETRA as EMH, with high posterior probabilities (Table 2).

The second (4 variable) DFA model classified LL1 as an EMH with a confidence of 74.4%, the second highest group being RMH with a posterior probability of 24.7% (Table 2). Every other modern human fossil was, however, classified as RMH with posterior probabilities ranging from 48.8% (UC103) to 94% (LJNG) (Table 2). This finding underscores the uniqueness of the morphology of LL1 relative to modern humans. Interestingly, UC103, CM1 and PRD3 were the most ambiguous in their classifications according to posterior probabilities, although, the second highest group in all cases was EMH (Table 2). HTO was ambiguously classified as NM (49.6%), its second highest group being EMH (45.1%); a near 50:50 split between them. SH5 and Dali were correctly classified as NM (Table 2). SD5, SH5, PETRA and SANG17 were also assigned to NM, the latter ambiguously according to posterior probabilities (Table 2). SD1 was classified as RMH, while Dali was ambiguously classified as EMH (Table 2).

Allometry analysis

Size correlated shape (allometric) changes are an important potential source of error in attempts to assess the phenetic affinities of crania using multivariate methods30,31,32,33,34,35. For example, when we compared the average geometric mean of EMH against the average geomean of the RMH sample we found that the difference (65.9 mm v. 63.7 mm) was significant using a 2-way t-test (p0.03). Moreover, the average geomean for our pooled archaic sample was substantially larger (72.0 mm) than RMH (p4.6E-11), and also significantly larger than the EMH average geomean (p0.003). LL1, with a geometric mean of 66.7 mm, was found to be intermediate, and not significantly different to, the EMH and RMH averages (z-scores 0.23 & 1.07), but significantly smaller than archaic hominins (z2.20). Thus, size scaling shape relationships are likely to explain at least some of the differences among crania in our dataset, and although we size-adjusted our data using the geometric mean, this method cannot correct for allometry36,37.

To examine whether scaling relationships between cranial measurements and size might explain differences between LL1 and modern humans we undertook regression analysis of the logged geometric mean versus logged variables. First, we undertook regression on RMH only to assess whether there was an association between size and each variable using a large sample. As there is disagreement in the literature about which regression model is the most appropriate for allometric studies38,39, we undertook ordinary least squares and reduced major axis regression (Table S4). All variables were found to be significantly correlated with the geometric mean in RMH (p < 0.0001), scaling positively with size (Table S4). Correlation coefficients were weak to moderate (r2 0.182–0.714) indicating that cranial size expressed as the geometric mean explained between approximately 18% and 71% of variance in these cranial variables (avg. r2 0.421).

Bivariate plots of logged geometric mean versus cranial variables for RMH and fossils are shown in Fig. 4. Visually, it was clear that LL1 departed substantially from the line of best fit for RMH (solid regression line) and/or EMH (broken regression line) for most variables (Fig. 4). It did, however, sit close to the allometric trend line of EMH for OBB, and near the trend line of RMH for OBH (Fig. 4). To test whether departures from the RMH trend line were significant we calculated externally studentized residuals for LL1 and included all EMH crania (Table S5). Externally studentized residuals were found to be significant for LL1 for FRC, NPH, NLH, NLB and EKB (Table S5). This is far in excess of the EMH range of 0–3 significant residuals (Table S5). Moreover, while most (6 out of 8) EMH crania exhibited significant residuals for OBH, it was lacking in LL1 (Table S5).

Figure 4. Bivariate plots of logged geomean versus logged craniometric variables:

Figure 4

Open in a new tab

(a) STB, (b) FRC, (c) NPH, (d) OBB, (e) OBH, (f) ZYB, (g) NLH, (h) NLB, and (i) EKB (NB: least squares line of best fit for RMH (unbroken line) and EMH (broken line) shown; Key: 1 = LL1, 2 = UC101, 3 = UC103, 4 = LJNG, 5 = HCC, 6 = KEL, 7 = CM1, 8 = PRD3, 9 = PRD4, 10 = HTO, 11 = SD1, 12 = DALI, 13 = SH5, 14 = PETRA & 15 = SANG17; see main text and Table S1 for key to abbreviations).

Discussion

Returning to the central questions of our study we have found that the cranial shape of LL1 was no closer to East Asian EMH than it was to fossil Europeans. In fact, the results of our multivariate studies clearly indicated that LL1 exhibits shape similarities to both EMH and archaic crania. Importantly, LL1 was sometimes found to be on or towards the edge of the range of EMH and RMH in PCA. It clustered basally with archaic hominins in our 9 variable NJ tree, but with EMH + RMH in the dendrogram produced with 4 variables. It was also classified as non-modern by DFA using our 9 variable model, although, ambiguously in terms of the posterior probability, or alone among modern humans in being classified as EMH (along with Dali) in our 4 variable model.

Our analysis of allometry further confirmed that size correlated shape plays a fundamental role in determining phenetic relationships among hominin crania30,31,32,33,34,35,36. Allometry offers the best explanation for the affinities we found between Dali and EMH, the former cranium being small compared to all other archaic remains, and similar in size to EMH. Additionally, the similarities between UC101 and archaic crania, namely Dali and SD1, can also be reconciled in terms of allometry: the Chinese anatomically modern cranium possessing the largest geometric mean of all EMH employed by us. Consistent with these findings is the fact that UC101 failed to exhibit any significant external studentized residuals compared with the allometric line of best fit for RMH.

In contrast, despite its moderate size (geomean 66.7 mm), LL1 was found to show similarities with much larger archaic crania, as well as exhibiting a relatively large number of variables that departed significantly from the size-shape scaling relationship of RMH. Thus, in contrast to UC101, we find that the similarities LL1 shows to archaic crania are much more likely to be of phylogenetic than allometric origin. Therefore, according to our findings, it would simply be incorrect to characterize LL1 as representing a population that is morphologically similar to East Asian EMH18,19. Additionally, in many instances these features are reminiscent of those seen among Lower Pleistocene remains, and contrary to Ref. 18, most of them have not been observed in EMH regardless of their geological age or geographical provenance19,21,22,26,30,31,32,33,34,40,41,42,43,44.

When we put the results of our study together it seems clear that the shape of LL1 is highly unusual within the context of variation seen within Late Pleistocene hominin crania. Its distinctive shape is seemingly the consequence of a large number of morphological features seen in archaic crania superimposed on a modern human “gestalt”. Importantly, this combination of archaic and modern features has simply not been found in any archaic cranium. This helps to explain why a definitive classification has eluded us until now15, especially within the context of the extensive overlap between archaic and modern crania and the confounding effects of size highlighted in the present and previous studies of Late Pleistocene and RMH crania30,31,32,33,34,35. When we took the influences of allometry (size-shape scaling) into account, however, LL1 remained distinctive, as it did across the results of multiple multivariate techniques using size-adjusted data.

The peculiar mixture of features and overall ambiguous affinities of LL1 are evident also in its non-metric traits (Table 3). This seemingly parallels the situation seen in specimens such as Pestera cu Oase 2 from Romania45. The Oase 2 cranium exhibits several hallmarks of modernity, but also possesses a suite of characteristics that distinguish it from Late Pleistocene modern humans45. Yet, when considering both metric and non-metric traits, LL1 is even more distinctive than Oase 2, lacks the putative Neanderthal autapomorphies seen in this European specimen, and importantly also dates from the early Holocene rather than mid-Late Pleistocene.

Table 3. Unusual (mostly archaic) morphological traits of the LL1 cranium (metrical traits based on comparisons in Ref. 15).

1 Cranial sutures mostly obliterated
2 Thick vault (at bregma)
3 Conspicuous supraorbital, with a well developed glabella, and lacking the bipartite form
4 Marked postorbital constriction
5 Broad facial skeleton
6 Mid-face very flat (nasal root and piriform aperture)
7 Nasal bones superiorly very narrow
8 Zygomatic broad, strongly projecting anteriorly (marked alveolar prognathism)
9 Widely flaring zygomatics, angled such that inferior part lies lateral to superior part
10 Anterior masseter attachment marked by broad and deep sulcus
11 Very wide orbits
12 Broad piriform aperture
13 Absence of canine fossa: zygomatic process flat
14 Small zygomatic tubercle
15 Zygomatic tubercle in-line with lateral orbital pillar (anterior view)
16 Interorbital relatively broad
17 Palate broad and shallow, with a prominent anterior shelf
18 Large P4 crown
19 Large M1 crown
Open in a new tab

In attempting to explain the morphology of LL1 from a phylogenetic standpoint, two scenarios seem to offer an explanation for the evidence. The first involves evolutionary reversals relative to the presumed ancestral Middle Pleistocene modern human morphology. In our analyses where LL1 was found to be distinctive from most EMH, it was never especially close to the Middle Pleistocene, and presumably plesiomorphic, HTO specimen. Thus, LL1 is unlikely to simply be an EMH that has reacquired a large number of plesiomorphies. At the same time, it was found to be unusual in reference to all of the fossils we employed, making the establishment of polarities all but impossible, and indicating again that the evolutionary reversal scenario is insufficient to explain its morphology and affinities. Moreover, many of the unusual non-metric features of LL1 are rare or absent from EMH regardless of their geological age19,21,22,26,30,31,32,33,34,40,41,42,43,44, a finding that further undermines such a scenario.

Alternatively, LL1 could descend from a modern population that interbred with one or more archaic groups. This could have resulted in the retention of archaic (plesiomorphic and/or apomorphic) traits as well as the evolution of unique features stemming from novel combinations of genes within the context of modern human gene networks and the disruptive effects of combining genes from divergent gene pools (i.e. hybrid disgenesis). So far, we have been unable to find any trait in LL1 that would be regarded as autapomorphic for H. neanderthalensis or any other Late Pleistocene archaic species (Table 3). The absence of archaic remains from mainland East/Southeast Asia reliably dated to <100 ka, excepting the Early Homo-like H. floresiensis, makes identifying the potential taxon involved in any interbreeding scenario, an important step in identifying hybrids, impossible at present. However, we note that the highly unusual Xujiayao fossils from North China, possibly sampling a novel taxon, could be as young as ~60/70 ka9,10,11. Additionally, DNA evidence suggests that interbreeding with the Neanderthals46 and “Denisovans”47 by modern humans during the Late Pleistocene could have occurred in East Asia independently of hybridization events in West Asia or Europe48, raising the likelihood of multiple pulses of admixture with archaic populations under complex demographic scenarios.

One further clue to the identity of LL1 comes from a recent 3D investigation of the semi-circular canal morphology of a sphenotemporal fragment found along with, and perhaps even belonging to, the LL1 cranium49. This work showed that the LL3 temporal labyrinth was indistinguishable from modern humans, being most similar to Holocene humans, and very dissimilar to Neanderthals49. If correct, this would indicate an affinity to more recent modern humans, inconsistent with the first (evolutionary reversal) scenario, and raising the possibility of very late occurring hybridization. Indeed, given the extent of the unusual morphological features present in LL1 (Table 3), it could even sample an early Holocene hybrid zone, especially within the context of present understanding of the processes involved in extant non-human primate hybridization50 and between Pleistocene modern humans and archaic groups like the Neanderthals and Denisovans46,47,48.

Finally, the morphology of LL1 indicates that just prior to the Neolithic expansions through East Asia human population diversity was unexpectedly large, especially in the region that today includes Southwest China. Moreover, it seems that the evolutionary factors that shaped this diversity were likely to have been highly varied and involved complex demographic scenarios. The distinctiveness of the shape of LL1 forces us to think beyond the usual assumption that hominin crania from the early Holocene must inevitably be fully modern in appearance or ancestry, an observation recently also made for some Late Pleistocene African fossils51,52.

Methods

All measurements of LL1 and a cast of Liujiang were taken by DC following the definitions of Howells28,29. They were blindly checked on multiple occasions across one or more years for accuracy and precision. For example, three estimates of reconstructed ZYB in LL1 – i.e. measured from one side to the median sagittal plane and doubled – taken blindly on separate occasions across two years provided a CV of 0.8%, indicating high precision. Details of the preservation and reconstruction of LL1 can be found in Ref. 15.

The RMH data were downloaded in the form of a Microsoft Excel spreadsheet from The William W. Howells Craniometric Data Set (http://web.utk.edu/~auerbach/HOWL.htm) and were sorted it into geographic samples. Fossil data in addition to those collected by us were taken from the literature (Refs. 26,27,53, 54, 55, 56, 57, 58, 59, 60, 61). Unfortunately, the important Minatogawa crania are not complete enough to have been included in our study. Geological dating information was sourced from Refs. 62, 63, 64, 65, 66.

Prior to PCA, NJ-analysis and DFA, all data were converted to size-adjusted (“shape”) variables by dividing the value for each variable by the geometric mean of all measurements for each cranium36,67. Discriminant function analysis (DFA) using Mahalanobis distances was used to classify crania employing a trichotomous classification (taxonomic free: “recent modern human,” “early modern” and “non-modern”). As very unbalanced matrices may affect the accuracy of the results of this method, we employed a smaller but representative sample of n30 randomly selected RMH (rather than n2,524). We used only males to minimize allometric scaling effects, taking the first male cranium each from all 30 of Howells’ geographic samples (see Table S1). To assess the accuracy of each DFA model, we divided the cross-validated accuracy rate by the proportional by chance accuracy rate (summed squared prior probabilities for each group). We considered the results from our models to be accurate if the cross-validated accuracy rate exceeded the chance accuracy rate by at least 25% (heuristic benchmark).

Additional Information

How to cite this article: Cunoe, D. et al. Possible Signatures of Hominin Hybridization from the Early Holocene of Southwest China. Sci. Rep. 5, 12408; doi: 10.1038/srep12408 (2015).

Supplementary Material

Supplementary Information
srep12408-s1.doc (135KB, doc)

Acknowledgments

The research was funded by the Australian Research Council (under grants DP0877603 & FT120100168), as a key project of Yunnan Institute of Cultural Relics and Archaeology (No. A-201301), the University of New South Wales Australia and Griffith University. Our thanks are extended to Chris Stringer for helpful comments that improved our manuscript. We are also very grateful to Li Changqing for providing additional information about the discovery of the Longlin (Laomaocao) Cave remains, Zhang Jianjun, Institute of Vertebrate Paleontology and Paleoanthropology, Chinese Academy of Sciences, for reconstruction work on LL 1, and Hui Zhongyuan, Jinniushan Museum, and You Pingping, Yunnan Institute of Cultural Relics and Archaeology, for assistance with fossil preparation. We are also grateful to Wang Zhangle, Longlin Museum, for assistance with site investigation conducted by JX in early 2013.

Footnotes

The authors declare no competing financial interests.

Author Contributions All authors made substantial contributions to the conception and design of the research and interpretation of data. D.C. drafted the manuscript while J.X. and P.T. provided critical ideas and additions to the text.

References

  1. Klein R. Anatomy, behavior, and modern human origins. J. World Prehist. 9, 167–198 (1995). [Google Scholar]
  2. Mellars P. The impossible coincidence: A single-species model for the origins of modern human behavior in Europe. Evol. Anthropol. 14, 12–27 10.1002/evan.20037 (2005). [DOI] [Google Scholar]
  3. Brown P., Sutikna T., Morwood M. J. & Soejono R. P. A new small-bodied hominin from the Late Pleistocene of Flores, Indonesia. Nature 431, 1055–1061 10.1038/nature02999 (2004). [DOI] [PubMed] [Google Scholar]
  4. Morwood M. J. et al. Further evidence for small-bodied hominins from the Late Pleistocene of Flores, Indonesia. Nature 437, 1012–1017 10.1038/nature04022 (2005). [DOI] [PubMed] [Google Scholar]
  5. Roberts R. G. et al. Geochronology of cave deposits at Liang Bua and of adjacent river terraces in the Wae Racang valley, western Flores, Indonesia: a synthesis of age estimates for the type locality of Homo floresiensis. J. Hum. Evol. 57, 484–502 10.1016/j.jhevol.2009.01.003 (2009). [DOI] [PubMed] [Google Scholar]
  6. Argue D., Donlon D., Groves C. & Wright R. Homo floresiensis: microcephalic, pygmoid, Australopithecus, or Homo ?  J. Hum. Evol. 51, 360–374 10.1016/j.jhevol.2006.04.013 (2006). [DOI] [PubMed] [Google Scholar]
  7. Liu W. et al. Human remains from Zhirendong, South China, and modern human emergence in East Asia. Proc. Natl. Acad. Sci. 107, 19201–19206 10.1073/pnas.1014386107 (2010). [DOI] [PMC free article] [PubMed] [Google Scholar]
  8. Dennell R. Early Homo sapiens in China. Nature 468, 512–513 10.1038/468512a (2010). [DOI] [PubMed] [Google Scholar]
  9. Wu X. J., Crevecoeur I., Liu W., Xing S. & Trinkaus E. Temporal labyrinths of eastern Eurasian Pleistocene humans. Proc. Natl. Acad. Sci. 111, 10509–10513 10.1073/pnas.1410735111 (2014). [DOI] [PMC free article] [PubMed] [Google Scholar]
  10. Wu X. J. & Trinkaus E. The Xujiayao 14 mandibular ramus and Pleistocene Homo mandibular variation. C. R. Palevol. 13, 333–341 10.1016/j.crpv.2013.10.002 (2014). [DOI] [Google Scholar]
  11. Xing S., Martinón-Torres M., Bermúdez de Castro J. M., Wu X. & Liu W. Hominin teeth from the early late Pleistocene site of Xujiayao, Northern China. Am. J. Phys. Anthropol. 156, 224–240 10.1002/ajpa.22641 (2015). [DOI] [PubMed] [Google Scholar]
  12. Liu W., Wu X. Z., Pei S. W., Wu X. J. & Norton C. J. Huanglong Cave: a Late Pleistocene human fossil site in Hubei Province, China. Quartern. Int. 211, 29–41 10.1016/j.quaint.2009.06.017 (2010). [DOI] [Google Scholar]
  13. Shen G. et al. Mass spectrometric U-series dating of Huanglong Cave in Hubei Province, central China: evidence for early presence of modern humans in eastern Asia. J. Hum. Evol. 65, 162–167 10.1016/j.jhevol.2013.05.002 (2013). [DOI] [PubMed] [Google Scholar]
  14. Bae C. J. et al. Modern human teeth from Late Pleistocene Luna Cave (Guangxi, China). Quatern. Int. 354, 169–183 10.1016/j.quaint.2014.06.051 (2014). [DOI] [Google Scholar]
  15. Curnoe D. et al. Human remains from the Pleistocene-Holocene transition of southwest China suggest a complex evolutionary history for East Asians. PLoS one 7, e31918. 10.1371/journal.pone.0031918 (2012). [DOI] [PMC free article] [PubMed] [Google Scholar]
  16. Ji X. et al. Further geological and palaeoanthropological investigations at the Maludong hominin site, Yunnan Province, Southwest China. Chi. Sci. Bull. 58, 4472–4485 10.1007/s11434-013-6026-5 (2013). [DOI] [Google Scholar]
  17. Curnoe D. A. 150-year conundrum: cranial robusticity and its bearing on the origin of Aboriginal Australians. Int. J. Evol. Biol. 2011 Article ID 632484 10.4061/2011/632484 (2011). [DOI] [PMC free article] [PubMed] [Google Scholar]
  18. Rosenberg K. R. & Wu X. A river runs through it: modern human origins in East Asia. The Origins of Modern Humans: Biology Reconsidered [Smith F. H. & Ahern James C. M. (ed.)] (John Wiley & Sons Inc., Hoboken, N.J., 2013). [Google Scholar]
  19. Demeter F. et al. Anatomically modern human in Southeast Asia (Laos) by 46 ka. Proc. Natl. Acad. Sci. 109, 14375–14380 10.1073/pnas.1208104109 (2012). [DOI] [PMC free article] [PubMed] [Google Scholar]
  20. Demeter F. et al. Early Modern Humans and Morphological Variation in Southeast Asia: Fossil Evidence from Tam Pa Ling, Laos. PLoS One e0121193. 10.1371/journal.pone.0121193 (2015). [DOI] [PMC free article] [PubMed] [Google Scholar]
  21. Boivin N., Fuller D. Q., Dennell R., Allaby R. & Petraglia M. D. Human dispersal across diverse environments of Asia during the Upper Pleistocene. Quatern. Int. 300, 32–47 10.1016/j.quaint.2013.01.008 (2013). [DOI] [Google Scholar]
  22. Dennell R. Smoke and Mirrors: The fossil record for Homo sapiens between Arabia and Australia. Southern Asia, Australia and the Search for Human Origins [Dennell R. & Porr M. (eds.)] (Cambridge University Press, 2014). [Google Scholar]
  23. Bellwood P. First migrants: ancient migration in global perspective. (John Wiley & Sons, 2014). [Google Scholar]
  24. Higham C. Early Mainland Southeast Asia. (River Books, Bangkok, 2014). [Google Scholar]
  25. Wall J. D. Great ape genomics. ILAR Journal 54, 82–90 10.1093/ilar/ilt048(2013) . [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. Matsumura H. et al. Terminal Pleistocene human skeleton from Hang Cho Cave, northern Vietnam: implications for the biological affinities of Hoabinhian people. Anthropol. Sci. 116, 201–217 10.1537/ase.070416 (2008). [DOI] [Google Scholar]
  27. White T. D. et al. Pleistocene Homo sapiens from the Middle Awash, Ethiopia. Nature 423, 742–747 10.1038/nature01669 (2003). [DOI] [PubMed] [Google Scholar]
  28. Howells W. W. Skull Shapes and the Map. Papers of the Peabody Museum of Archaeology and Ethnology. vol. 79, Cambridge, Mass.: Peabody Museum (1989). [Google Scholar]
  29. Howells W. W. Cranial Variation in Man. Papers of the Peabody Museum of Archaeology and Ethnology 67, 1–259 (1973). [Google Scholar]
  30. Bräuer G. A craniological approach to the origin of anatomically modern Homo sapiens in Africa and the implications for the appearance of modern Europeans. The Origins of Modern Humans: A World Survey of the Fossil Evidence [Smith F. H. & Spencer F. (eds.)] (327–410) (Alan R. Liss, New York, 1984). [Google Scholar]
  31. Stringer C. B. Middle Pleistocene hominid variability and the origin of Late Pleistocene humans. Ancestors: The Hard Evidence [Delson E. (ed.)] (289–295) (Alan R. Liss, New York, 1985). [Google Scholar]
  32. Kidder J. H., Jantz R. L. & Smith F. H. Defining modern humans: a multivariate approach. Continuity or Replacement: Controversies in Homo sapiens Evolution. [Bräuer G. & Smith F. H. (Eds.)] (157–177) (Balkema, Rotterdam, 1992). [Google Scholar]
  33. Turbón D., Pérez-Pérez A. & Stringer C. A multivariate analysis of Pleistocene hominids: testing hypotheses of European origins. J. Hum. Evol. 32, 449–468 10.1006/jhev.1996.0119(1997) . [DOI] [PubMed] [Google Scholar]
  34. Schillaci M. A. Human cranial diversity and evidence for an ancient lineage of modern humans. J. Hum. Evol. 54, 814–826 10.1016/jhevol.2007.10.010 (2008). [DOI] [PubMed] [Google Scholar]
  35. McCarthy R. C. & Lucas L. A morphometric re-assessment of BOU-VP-16/1 from Herto, Ethiopia. J. Hum. Evol. 74, 114–117 10.1016/j.jhevol.2014.05.011 (2014). [DOI] [PubMed] [Google Scholar]
  36. Jungers W. L., Falsetti A. B. & Wall C. E. Shape, relative size, and size‐adjustments in morphometrics. Yearb. Phys. Anthropol. 38, 137–161 10.1002/ajpa.1330380608 (1995). [DOI] [Google Scholar]
  37. Jolly C. A proper study for mankind: analogies from the papionin monkeys and their implications for human evolution. Yearbk. Phys. Anthropol. 44, 177–204 10.1002/ajpa.10021 (2001). [DOI] [PubMed] [Google Scholar]
  38. Seim E. & Sæther B. E. On rethinking allometry: which regression model to use ?  J. Theor. Biol. 104, 161–168 10.1016/0022-5193(83)90408-3 (1983). [DOI] [Google Scholar]
  39. Warton D. I., Wright I. J., Falster D. S. & Westoby, Bivariate line‐fitting methods for allometry. Biol. Rev. 81, 259–291 10.1017/S1464793106007007 (2006). [DOI] [PubMed] [Google Scholar]
  40. Wu X. & Bräuer G. Morphological comparison of archaic Homo sapiens crania from China and Africa. Z. Morph. Anthropol. 79, 241–259 (1993). [PubMed] [Google Scholar]
  41. Wood B. & Lonergan N. The hominin fossil record: taxa, grades and clades. J. Anat. 212, 354–376 10.1111/j.1469-7580.2008.00871.x (2008). [DOI] [PMC free article] [PubMed] [Google Scholar]
  42. Schwartz J. H. & Tattersall I. The Human Fossil Record. Terminology and Craniodental Morphology of Genus Homo (Europe) (Vol. 1). John Wiley & Sons (2002). [Google Scholar]
  43. Schwartz J. H. & Tattersall I. The Human Fossil Record, Craniodental Morphology of Genus Homo (Africa and Asia) (Vol. 2). John Wiley & Sons (2003). [Google Scholar]
  44. Trinkaus E., Modern human versus Neandertal evolutionary distinctiveness. Curr. Anthropol. 47, 597–620 10.1086/504165 (2006). [DOI] [Google Scholar]
  45. Trinkaus E. et al. An early modern human from the Peştera cu Oase, Romania. Proc. Natl. Acad. Sci. 100, 11231–11236 10.1073/pnas.2035108100 (2003). [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Prüfer K. et al. The complete genome sequence of a Neanderthal from the Altai Mountains. Nature 505, 43–49 10.1038/nature12886 (2014). [DOI] [PMC free article] [PubMed] [Google Scholar]
  47. Reich D. et al. Denisova admixture and the first modern human dispersals into Southeast Asia and Oceania. Am. J. Hum. Genet. 89, 516–528 10.1016/j.ajhg.2011.09.005 (2011). [DOI] [PMC free article] [PubMed] [Google Scholar]
  48. Kim B. K & Lohmueller K. E. Selection and reduced population size cannot explain higher amounts of Neandertal ancestry in East Asian than in European human populations. Am. J. Hum. Genet. 96, 454–461 10.1016/j.ajhg.2014.12.029 (2015). [DOI] [PMC free article] [PubMed] [Google Scholar]
  49. Ji X., Wu X. J., Wu Y. & Liu W. The temporal bony labyrinthine morphology of Homo Longlin 1 from the Pleistocene-Holocene transition of South China. Chinese Sci. Bull. 59, 3517–3525 10.1360/N972014-00653 (2014). [DOI] [Google Scholar]
  50. Kelaita M. A. & Cortés‐Ortiz L. Morphological variation of genetically confirmed Alouatta Pigra × A. palliata hybrids from a natural hybrid zone in Tabasco, Mexico. Am. J. Phys. Anthropol. 150, 223–234 10.1002/ajpa.22196 (2013). [DOI] [PubMed] [Google Scholar]
  51. Harvati K. et al. The Later Stone Age calvaria from Iwo Eleru, Nigeria: morphology and chronology. PLoS One 6, e24024. 10.1371/journal.pone.0024024 (2011). [DOI] [PMC free article] [PubMed] [Google Scholar]
  52. Tryon C. A. et al. Late Pleistocene age and archaeological context for the hominin calvaria from GvJm-22 (Lukenya Hill, Kenya). Proc. Natl. Acad. Sci. 112, 2682–2687 10.1073/pnas.1417909112 (2015). [DOI] [PMC free article] [PubMed] [Google Scholar]
  53. Kamminga J. & Wright R. V. S. The Upper Cave at Zhoukoudian and the origins of the Mongoloids. J. Hum. Evol. 17, 739–767 10.1016/0047-2484(88)90064-4 (1988). [DOI] [Google Scholar]
  54. Stewart T. D. The Neanderthal skeletal remains from Shanidar Cave, Iraq: A summary of findings to date. Proc. Am. Philos. Soc. 121, 121–165 (1977). [Google Scholar]
  55. Wu X. & Athreya S. A description of the geological context, discrete traits, and linear morphometrics of the Middle Pleistocene hominin from Dali, Shaanxi Province, China. Am. J. Phys. Anthropol. 150, 141–157 10.1002/ajpa.22188 (2013). [DOI] [PubMed] [Google Scholar]
  56. Arsuaga J. L. et al. Sima de los Huesos (Sierra de Atapuerca, Spain). The site. J. Hum. Evol. 33, 109–127 10.1006/jhev.1997.0132 (1997). [DOI] [PubMed] [Google Scholar]
  57. Stringer C. B., Howell F. C. & Melentis J. K. The significance of the fossil hominid skull from Petralona, Greece. J. Archaeo. Sci. 6, 235–253 1016/0305-4403(79)90002-5 (1979). [Google Scholar]
  58. Wu X. & Poirier F.E. Human Evolution in China. Oxford University Press, Oxford. (1995). [Google Scholar]
  59. Kaifu Y., Aziz F., Indriati E., Jacob T., Kurniawan I. & Baba H. Cranial morphology of Javanese Homo erectus: New evidence for continuous evolution, specialization, and terminal extinction. J. Hum. Evol. 55, 551–580 .1016/j.jhevol.2008.05.002 (2008). [DOI] [PubMed] [Google Scholar]
  60. Vandermeesch B. Les Hommes Fossiles De Qafzeh (Israël). Cahiers de Paléontologie (Paléoanthropologie). Paris: Éditions du Centre National de la Recherche Scientifique (1981). [Google Scholar]
  61. Trinkaus E. The Shanidar Neandertals. Academic Press, New York (1983). [Google Scholar]
  62. Thorne A. G. Kow Swamp and Lake Mungo. Ph.D. Dissertation, The Australian National University (1975). [Google Scholar]
  63. Millard A. R. A critique of the chronometric evidence for hominid fossils: I. Africa and the Near East 500-50 ka. J. Hum. Evol. 54, 848–874 10.1016/j.jhevol.2007.11.002 (2008). [DOI] [PubMed] [Google Scholar]
  64. Yin G. et al. ESR/U-series study of teeth recovered from the palaeoanthropological stratum of the Dali Man site (Shaanxi Province, China). Quatern. Geochron. 6, 98–105 10.1016/j.quageo.2010.04.001 (2011). [DOI] [Google Scholar]
  65. Arnold L. J. et al. Luminescence dating and palaeomagnetic age constraint on hominins from Sima de los Huesos, Atapuerca, Spain. J. Hum. Evol. 67, 85–107 10.1016/j.jhevol.2013.12.001 (2014). [DOI] [PubMed] [Google Scholar]
  66. Norton C. J. & Gao X. Zhoukoudian upper cave revisited. Curr. Anthropol. 49, 732–745 10.1086/588637 (2008). [DOI] [Google Scholar]
  67. Darroch J. N. & Mosimann J. E. Canonical and principal components of shape. Biometrika 72, 241–252 10.1093/biomet/72.2.241 (1985). [DOI] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary Information
srep12408-s1.doc (135KB, doc)

Articles from Scientific Reports are provided here courtesy of Nature Publishing Group

RESOURCES