中国南方猩猩化石的研究进展

doi:10.16359/j.1000-3193/AAS.2024.0016

摘要/Abstract

摘要：

在精确年代测定基础上，研究中国南方新发现的猩猩牙齿化石，是近年来猩猩化石研究的特色。中国南方猩猩化石的发现和研究深化了学术界对更新世猩猩分类、大小演化及其与环境变化之间关系的认识。本文梳理了中国南方更新世代表性的含猩猩化石遗址和猩猩化石的最新研究成果。目前发现的猩猩牙齿化石和年代学结果表明，猩猩最早出现于早更新世早期的中国南方，并持续到了晚更新世，以猩猩魏氏种(Pongo weidenreichi)为代表。在中更新世晚期时，猩猩戴氏种(Pongo devosi)可能首次出现在中国南方。猩猩魏氏种与猩猩戴氏种之间的关系还需要更多的化石证据来证实。更新世猩猩牙齿大小演化表现出明显的阶段性，猩猩牙齿变小主要出现在中更新世。猩猩牙齿大小的这种演化关系可能与中国南方草原环境的出现和扩张有关。

关键词: 更新世, 中国南方, 猩猩, 大小演化, 环境变化

Abstract:

The recent studies of newly discovered Pongo fossils with precise absolute age brackets have deepened our understanding of their taxonomy, teeth size evolution and its relationship with environmental changes in southern China during the Pleistocene period. In the present study, we summarize the representative Pleistocene orangutan fossil-bearing sites in southern China and discuss the latest research progress on orangutan fossils. The orangutan fossil found so far and the chronological results indicate that orangutans first appeared in southern China in the early Early Pleistocene and lasted until the Late Pleistocene. From the results of the current studies, at least two species of orangutans may have existed in southern China during the Pleistocene period. One of them is Pongo weidenreichi that is characterized by its overall larger dental size, a high frequency of lingual cingulum remnants and a low frequency of moderate to heavy wrinkling on its molars. P. weidenreichi survived in southern China from the Early Pleistocene to the Late Pleistocene. The other orangutan species, Pongo devosi, may have first appeared in southern China during the late Middle Pleistocene. Compared with P. weidenreichi, P. devosi is distinguished by its relatively smaller overall dental size, relatively lower frequency of lingual cingulum remnants on its molars, the well-developed lingual pillar and lingual cingulum on its incisors and relatively higher frequency of moderate to heavy wrinkling on its molars. More fossil evidences are needed to confirm the relationship between P. weidenreichi and P. devosi in future study. The teeth size evolution of Pleistocene orangutans shows obvious stages. Metric data of orangutan teeth fossils (>1000) from mainland Southeast Asia sites reveal that the reduction in the size of orangutan teeth fossils occurred mainly from the Early Pleistocene to the Middle Pleistocene. And orangutan teeth fossils remained relatively stable in their sizes from the Middle to Late Pleistocene. The stable carbon isotope data of Early to Late Pleistocene mammalian fossil teeth from mainland Southeast Asia can be used to reconstruct changes in the paleoenvironment and could provide some clues to interpret dental size variation of Pongo assemblages in a broader temporal and environmental context. The carbon isotope data show that dental size reduction in orangutan fossils is closely linked to environmental changes. The dental size changes in orangutans appear to coincide with the expansion of savannah biomes and the contraction of forest habitats from the Middle Pleistocene onward.

Key words: Pleistocene, southern China, orangutans, size evolution, environmental change

中图分类号:

Q915.879

廖卫. 中国南方猩猩化石的研究进展[J]. 人类学学报, 2024, 43(02): 199-213.

LIAO Wei. Progress in the study of fossil orangutans in South China[J]. Acta Anthropologica Sinica, 2024, 43(02): 199-213.

图/表 4

图1 猩猩化石和现生猩猩分布修改自文献 [9]/ Modified from the referenc [9]。1.狮子岩; 2.罗坑洞; 3.双岩洞; 4.七星岩洞; 5.下山洞; 6.山背岩;7.独石仔洞; 8.观塘洞; 9.飞树洞;10.黄岩洞; 11.岩灰洞; 12.麻窝口洞; 13.河上洞; 14.仙人洞; 15.仙人二洞; 16.九龙洞;17.磨盘山洞; 18.柳城巨猿洞; 19.通天岩; 20.咁前岩; 21.母鸡山洞; 22.巴马巨猿洞; 23.感仙洞; 24.雾云洞; 25.定模洞;26.大新黑洞; 27.岜仙洞; 28.百孔洞; 29.崇左巨猿洞; 30.三合大洞; 31.缺缺洞; 32.一线天洞; 33.智人洞; 34.双坛洞; 35.渠仔洞;36.宜村洞; 37.新冲洞; 38. Coc Muoi, Vietnam; 39. Tham Khuyen, Vietnam; 40. Keo Leng, Vietnam; 41. Hang Hum, Vietnam; 42. Nguom, Vietnam;43. Duoi U’Oi, Vietnam; 44. Lang Trang, Vietnam; 45. Tham Om, Vietnam; 46. Nam Lot, Laos; 47. Ban Fa Suai I, Thailand;48. Tham Prakai Phet, Thailand; 49. Thum Wiman Nakin, Thailand; 50. Boh Dambang, Thailand; 51. Badak Cave C, Malaysia; 52. Batu Caves, Malaysia;53. Padang Highland Caves, Sumatra; 54. Niah Cave, Borneo; 55. Madai Caves, Borneo; 56. Sangiran, Java; 57. Trinil, Java; 58. Punung, Java

Fig.1 The geographical distribution of the Pleistocene and extant Pongo sites

图2 猩猩魏氏种和猩猩戴氏种下颌门齿比较图 1-3.猩猩魏氏种，来自于感仙洞P. weidenreichi, from Ganxian Cave[8]；4-8.猩猩戴氏种，来自于中山洞P. devosi, from Zhongshan Cave [71]。从图中可见，猩猩魏氏种和戴氏种下颌门齿齿带的发育程度差异很大，猩猩魏氏种下颌门齿齿带不发育或者发育程度很弱，而猩猩戴氏种下颌门齿齿带很发育

Fig.2 Comparison of mandibular incisors of P. weidenreichi and P. devosi The cingulum development of the mandibular incisor of P. weidenreichi and P. devosi varies considerably, with P. weidenreichi being either undeveloped or weakly developed, while the P. devosi is developed very well

图3 东南亚大陆更新世以来猩猩牙齿化石齿冠面积R值分布图 TPP为泰国的Tham Prakai Phet地点。图中R值的分布向右侧偏移时，代表遗址中猩猩牙齿化石整体尺寸较大，而R值的分布向左侧偏移时，代表遗址中猩猩牙齿化石整体尺寸较小。

Fig.3 Dental size (R value) distribution of the orangutan assemblage in Southeast Asia during the Pleistocene period TPP represents the Tham Prakai Phet site in Thailand. The distribution of R-values in the figure is shifted to the right to represent a larger overall size of orangutan teeth fossils at the site, while the distribution of R-values is shifted to the left to represent a smaller overall size of orangutan teeth fossils at the site

图4 东南亚大陆猩猩牙齿化石大小分布与碳同位素分布图 A.晚更新世Late Pleistocene；B.中更新世Middle Pleistocene；C.早更新世Early Pleistocene。修改自Liao et al. (2022)[9]。注：图中猩猩牙齿化石尺寸分布（黑色矩形）向右偏移时，代表猩猩牙齿化石尺寸大，而猩猩猩猩牙齿化石尺寸分布向左偏移时，代表猩猩牙齿化石尺寸偏小。图中碳同位素分布（灰色矩形）向右偏移时，代表开阔的草原环境（以C4植被为主），图中碳同位素分布向左偏移时，代表密闭的森林环境

Fig.4 Comparisons of the dental size distribution of the orangutan assemblage and δ13Cdiet data in mainland Southeast Asia from different periods of the Pleistocene The size distribution of orangutan teeth fossils (black rectangles) shifted to the right in the figure represents large orangutan teeth fossils, while the size distribution of orangutan teeth fossils shifted to the left represents small orangutan teeth fossils. Carbon isotope distribution (grey rectangles) shifted to the right in the figure represents open savannah environments (dominated by C4 vegetation), while carbon isotope distribution shifted to the left represents dense forest environments

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