古DNA揭示中国西北地区史前人类对野生动物资源的利用

doi:10.16359/j.1000-3193/AAS.2024.0031

人类学学报 ›› 2025, Vol. 44 ›› Issue (01): 117-131.doi: 10.16359/j.1000-3193/AAS.2024.0031

古DNA揭示中国西北地区史前人类对野生动物资源的利用

宋光捷¹^,²(), 蔡大伟¹^,²(), 朱存世³, 胡松梅⁴^,⁵(), 周静⁶, 任晓燕⁷

1.吉林大学生物考古实验室，长春 130012
2.吉林大学考古学院，长春 130012
3.宁夏回族自治区文物考古研究所，银川 750001
4.山东大学科技考古教育部重点实验室，青岛 266237
5.山东大学文化遗产研究院，青岛 266237
6.甘肃省文物考古研究所，兰州 730000
7.青海省文物考古研究所，西宁 810007

收稿日期:2023-11-07 修回日期:2023-12-27 出版日期:2025-02-15 发布日期:2025-02-13
通讯作者: 蔡大伟，教授，主要从事分子考古学研究。E-mail: wycdw@sina.com;胡松梅，教授，主要从事动物考古学研究。E-mail: 940779538@qq.com
作者简介:宋光捷，博士研究生，主要从事分子考古学研究。E-mail: songgj21@mails.jlu.edu.cn
基金资助:
国家社科基金重大项目“古动物DNA视角下的丝路文化交流研究”(17ZDA221)

Ancient DNA reveals the utilization of wild animal resources by prehistoric humans in Northwest China

SONG Guangjie¹^,²(), CAI Dawei¹^,²(), ZHU Cunshi³, HU Songmei⁴^,⁵(), ZHOU Jing⁶, REN Xiaoyan⁷

1. Bioarchaeology Laboratory, Jilin University, Changchun 130012
2. School of Archaeology, Jilin University, Changchun 130012
3. Ningxia Institute of Cultural Relics and Archaeology, Yinchuan 750001
4. Key Laboratory of Archaeological Sciences and Technology, Ministry of Education, Shandong University, Qingdao 266237
5. Institute of Cultural Heritage, Shandong University, Qingdao 266237
6. Institute of Cultural Relics and Archaeology of Gansu Province, Lanzhou 730000
7. Institute of Cultural Relics and Archaeology of Qinghai Province, Xining 810007

Received:2023-11-07 Revised:2023-12-27 Online:2025-02-15 Published:2025-02-13

摘要/Abstract

摘要：

进行古代野生动物遗存的研究，有助于我们了解古代居民的饮食结构、狩猎活动、经济模式等问题，在此基础上应用古DNA技术，则有利于区分家养动物与野生动物。本研究对中国西北地区长宁、磨沟、泉护村、打石沟4个遗址的9例形态学鉴定为“绵羊”或“山羊”的动物样本进行古DNA研究，通过古DNA提取、建库和高通量测序，成功获得了这9例样本的线粒体全基因组序列。根据比对分析、系统发育分析、主成分分析和遗传距离计算，鉴定出这些样本分别为牛科和鹿科动物下的4个不同野生种属，说明古DNA技术可以弥补形态学在鉴定动物遗存方面的不足。结合4个遗址的相关资料，从分子角度证实了中国西北地区史前时期先民在肉食来源、殉葬和骨器原料等方面，普遍存在将野生动物作为动物资源的补充的情况。

关键词: 古DNA, 物种鉴定, 中国西北, 野生动物资源

Abstract:

Genomic analysis of ancient wild animal remains is of not only great significance for the conservation and utilization of genetic resources of wild animal species but also crucial for helping us understand the diet compositions and hunting activities of ancient human beings as well as their social-economic development patterns. Ancient DNA technology has been widely employed in archaeological research. Among its numerous strengths, its potential to decipher the genetic information carried by biological samples at the molecular level has been widely acknowledged, and many researchers have utilized ancient DNA analysis to distinguish between domestic and wild animals. Moreover, when combined with historical and archaeological evidence, it offers us robust scientific and technological support, enabling us to comprehensively understand ancient human societies, including their origins and evolutionary processes.

In this study, the ancient DNA of nine animal samples, which were excavated from the Changning, Mogou, Quanhucun, and Dashigou sites in Northwest China and morphologically identified as either “sheep” or “goats”, was investigated using ancient DNA technology. Ancient DNA extraction, library construction, and high-throughput sequencing were carried out, and the mitochondrial genome sequences of the nine samples were successfully obtained. Alignment analysis was performed between the genomic sequences of these samples and the 146 mitochondrial genomic sequences of Cervidae and Bovidae (used as reference data). The results of the alignment analysis indicated that these nine samples were identified as belonging to four different wild animal species within the families of Cervidae and Bovidae: the Siberian roe deer (Capreolus pygargus) of the genus Capreolus within the subfamily Odocoileinae; the Przewalski’s gazelle (Procapra przewalskii) and Tibetan gazelle (Procapra picticaudata) of the genus Procapra within the subfamily Antilopinae; and the Sumatran serow (Capricornis sumatraensis) of the genus Capricornis within the subfamily Caprinae.

Two phylogenetic analyses were conducted on the mitochondrial genome data extracted from the Odocoileinae, Caprinae, and Antilopinae subfamilies. Bayesian phylogenetic trees and Maximum Likelihood phylogenetic trees were constructed. It was demonstrated that each of the nine samples clustered with the corresponding species identified by the alignment analysis, which was consistent with the results of the principal component analysis on the same data set, where the nine samples were assigned to the corresponding species identified in the alignment analysis. Genetic distance calculations between individuals based on ancient and modern samples revealed that each of the nine samples was genetically closest to the specific species identified.

All of the above results emphasize that ancient DNA technology can overcome the limitations of morphological methods in the species identification of ancient animals. Considering other wild animal bone remains excavated from the four sites, it can be concluded that the ancient people in prehistoric Northwest China used wild animals as a supplement to domestic animal resources for food, sacrificial offerings, and bone tool manufacture. This study is of great significance as it provides new evidence at the molecular level and corroborates the findings of previous archaeological research on animals in prehistoric times.

Key words: ancient DNA, species identification, Northwest China, wild animal resources

中图分类号:

Q915

宋光捷, 蔡大伟, 朱存世, 胡松梅, 周静, 任晓燕. 古DNA揭示中国西北地区史前人类对野生动物资源的利用[J]. 人类学学报, 2025, 44(01): 117-131.

SONG Guangjie, CAI Dawei, ZHU Cunshi, HU Songmei, ZHOU Jing, REN Xiaoyan. Ancient DNA reveals the utilization of wild animal resources by prehistoric humans in Northwest China[J]. Acta Anthropologica Sinica, 2025, 44(01): 117-131.

图/表 7

图1 长宁、磨沟、泉护村和打石沟遗址的地理位置图

Fig.1 Geographic location of the Changning, Mogou, Quanhucun and Dashigou sites

图2 本文所用的9个古代遗骸

Fig.2 Specimens of 9 ancient remains analyzed in this study

表1 实验结果信息表

Tab.1 Information of experimental results

遗址名称Sites	实验编号Experimental Code	原始Reads数 Number of Raw Reads	经比对最匹配的物种The Most Matched Species after Alignment	覆盖度(X)Coverage(X)	比对上的Reads数Number of Aligned Reads	覆盖比例Coverage Ratio	比对位点数Number of Sites	参考序列位点数Number of Sites in the Reference	比对率Rate of Alignment
长宁Changning	CNS6*	1305844	Procapra przewalskii	39.2565	52162	97.32%	16105	16548	53.21%
长宁Changning	CNS21*	656078	Capreolus pygargus	75.9312	43931	64.80%	10599	16357	49.67%
	CNS22*	4238200	Procapra przewalskii	255.7252	528914	100%	16548	16548	53.79%
	CNS23*	2476308	Procapra przewalskii	125.2455	293503	99.99%	16547	16548	53.89%
磨沟Mogou	MG08S*	3159946	Procapra picticaudata	1639.2262	473981	100%	16620	16620	59.44%
	MG09S*	11438866	Capreolus pygargus	130.4001	3230898	99.04%	16200	16357	48.74%
泉护村Quanhucun	QHS1	19397604	Procapra przewalskii	6.2310	1779	75.42%	12480	16548	46.25%
泉护村Quanhucun	QHS3*	3263926	Capricornis sumatraensis	49.8297	12753	87.35%	14361	16441	46.23%
打石沟Dashigou	DSG04Y	15218412	Capreolus pygargus	4.8947	878	97.29%	15914	16357	32.38%

图3 基于羚羊亚科、羊亚科和空齿鹿亚科线粒体全基因组构建的最大似然树

Fig.3 ML phylogenetic tree of Antilopinae, Caprinae and Odocoileinae species based on mitochondrial genome

图4 基于羚羊亚科、羊亚科和空齿鹿亚科线粒体全基因组构建的贝叶斯树

Fig.4 Bayesian phylogenetic tree of Antilopinae, Caprinae and Odocoileinae species based on mitochondrial genome

图5 古代样本和羚羊亚科、羊亚科和空齿鹿亚科线粒体基因组的主成分分析图

Fig.5 PCA of mitochondrial genome for ancient samples and modern Antilopinae, Caprinae and Odocoileinae species

图6 古代样本和羚羊亚科、羊亚科和空齿鹿亚科线粒体基因组的遗传距离聚类热图

Fig.6 Pairwise distances heatmap of mitochondrial genome for ancient samples and modern Antilopinae, Caprinae and Odocoileinae specie

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古DNA揭示中国西北地区史前人类对野生动物资源的利用

Ancient DNA reveals the utilization of wild animal resources by prehistoric humans in Northwest China

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