安徽华龙洞遗址大额牛的食性

doi:10.16359/j.1000-3193/AAS.2025.0071

人类学学报 ›› 2025, Vol. 44 ›› Issue (05): 895-905.doi: 10.16359/j.1000-3193/AAS.2025.0071cstr: 32091.14.j.1000-3193/AAS.2025.0071

• 同位素、孢粉、古蛋白 • 上一篇下一篇

安徽华龙洞遗址大额牛的食性

郑明聪¹^,²(), 汪静怡¹^,², 严毅¹^,², 陈逸迎¹^,², 吴妍¹^,³()

1.中国科学院古脊椎动物与古人类研究所，脊椎动物演化与人类起源重点实验室，北京 100044
2.中国科学院大学, 北京 100049
3.旧石器时代人类演化与遗传国家文物局重点科研基地，北京 100044

收稿日期:2025-04-30 修回日期:2025-06-30 出版日期:2025-10-15 发布日期:2025-10-13
通讯作者: 吴妍，研究员，主要研究方向为生物与环境考古。E-mail: wuyan@ivpp.ac.cn
作者简介:郑明聪，硕士研究生，主要研究方向为环境考古与植硅体分析。E-mail: zhengmingcong@ivpp.ac.cn
基金资助:
国家重点研发计划项目(2022YFF0801502);国家自然科学基金项目(42472006);国家自然科学基金项目(41877427)

Dietary ecology of gaur from the Hualongdong site in Anhui Province

ZHENG Mingcong¹^,²(), WANG Jingyi¹^,², YAN Yi¹^,², CHEN Yiying¹^,², WU Yan¹^,³()

1. Key Laboratory of Vertebrate Evolution and Human Origins, Institute of Vertebrate Paleontology and Paleoanthropology, Chinese Academy of Sciences, Beijing 100044
2. University of Chinese Academy of Sciences, Beijing 100049
3. Key Scientific Research Base on Paleolithic Human Evolution and Paleogenetics (IVPP), SACH, Beijing 100044

Received:2025-04-30 Revised:2025-06-30 Online:2025-10-15 Published:2025-10-13

摘要/Abstract

摘要：

为探索安徽华龙洞遗址大额牛的食性以及生态环境背景，本文对遗址中出土的6颗大额牛牙齿化石进行了牙结石植硅体分析及牙釉质稳定同位素分析等研究。结果显示，华龙洞地区的大额牛主要以不同高度的草本植物为食；牙结石中的诊断性植硅体形态鉴定结果表明，姜目和禾本科植物是大额牛饮食的重要组成部分；大额牛牙齿样本的δ¹³C值在-10.3‰~-4.6‰，平均约-8.6‰，指示其食用的植物类型以C₃植物为主，少量C₄植物为辅。综合其食性及其化石常发现的地点，推测华龙洞遗址的大额牛生存于森林较疏朗地带，且食谱中姜目植物的发现也暗示其生存于温暖的气候背景中。本研究结果为了解华龙洞遗址大额牛的食性、栖息地以及气候背景提供了新的植物微体化石与同位素记录，也为重建安徽地区中更新世的古环境提供了依据。

关键词: 更新世, 华龙洞遗址, 大额牛, 植硅体, 饮食

Abstract:

The Hualongdong site in Dongzhi County, Anhui Province, represents the most comprehensive Paleolithic site in China since Zhoukoudian, yielding abundant hominin fossils alongside stone tools and other evidence of human activities. Notably, it has also produced a substantial assemblage of mammalian fossils. As a key species in China's Quaternary mammalian fauna, the Pleistocene gaur [Bos (Bibos) sp.] shares close phylogenetic relationships with its extant counterparts. However, systematic understanding of this fossil Bos (Bibos) sp. species remains limited due to fragmentary fossil materials and methodological constraints. The dental fossils of Bos (Bibos) sp. from Hualongdong site provide crucial materials for investigating its dietary habits, ecological niche, paleoenvironment and ecosystem. This study employs multidisciplinary approaches including CT three-dimensional modeling, phytolith analysis, and stable isotope analysis to systematically investigate Bos (Bibos) sp. dental fossils. CT modeling precisely identified dental calculus locations, enabling subsequent phytolith extraction and morphological characterization from calculus deposits. Concurrently, carbon stable isotope analysis was conducted on tooth enamel. Results reveal that the late Middle Pleistocene Hualongdong site Bos (Bibos) sp. feed on herbaceous plants of varying heights. Carbon isotope data indicate a primary reliance on C₃ plants from the site and surrounding areas, supplemented by limited C₄ plant consumption (δ¹³C values: -10.3‰ to -4.6‰). Phytolith analysis specifically indicates frequent ingestion of Poaceae and Zingiberales species. These findings collectively indicate that Bos (Bibos) sp. primarily foraged in warm environments dominated by C₃ vegetation during the late Middle Pleistocene. The diverse phytolith assemblages and isotopic signatures reflect rich regional vegetation heterogeneity, providing ample food resources. Furthermore, the common occurrence of Pleistocene Bos (Bibos) sp. fossils in alluvial plains, mountain valleys, and karst caves suggests their preference for open forest areas with grassy patches. This ecological pattern aligns with their mixed dietary strategy of feeding on both C₃ and C₄ plants. This research establishes novel phytolith and isotopic records for understanding Bos (Bibos) sp. paleodietary ecology while contributing to Middle-Late Pleistocene paleoclimatic and paleoecological reconstructions in Anhui Province. The integrated methodology demonstrates the efficacy of combining Plant microfossils and geochemical proxies in paleodietary studies, offering insights into herbivore-environment interactions during the Pleistocene.

Key words: Pleistocene, Hualongdong site, Bibos sp., phytoliths, diet

中图分类号:

Q915.86/O615.2

郑明聪, 汪静怡, 严毅, 陈逸迎, 吴妍. 安徽华龙洞遗址大额牛的食性[J]. 人类学学报, 2025, 44(05): 895-905.

ZHENG Mingcong, WANG Jingyi, YAN Yi, CHEN Yiying, WU Yan. Dietary ecology of gaur from the Hualongdong site in Anhui Province[J]. Acta Anthropologica Sinica, 2025, 44(05): 895-905.

图/表 5

图1 本研究选用的6件大额牛牙齿样本

Fig.1 Six tooth samples of Bos sp. for this study

图2 CT扫描结果蓝色部分为牙结石The blue area indicates dental calculus

Fig.2 CT scan results

图3 提取自大额牛牙结石的植硅体形态 a.平滑棒形Elongate entire(from BT5)；b.哑铃形Bilobate(from BT4)；c.鞍形Saddle(from BT5)；d.扇形Bulliform flabellate(from BT5)；e.尖形Acute bulbosus(from BT5)；f.方形Square(from BT5)；g.不规则板状Tabular irregular (from BT5)；h.球形Spheroid psilate(from BT4)；i~j.波状球形Spheroid ornate(from BT2、BT5)；k.延长棒形Elongate attenuate(from BT2)；l.长方形Rectangular(from BT5)；m.块状Blocky(from BT5)，Scale bar: 20 μm。

Fig.3 Phytolith morphotypes in Bos sp. dental calculus in five dental calculus samples

图4 大额牛牙结石中的植硅体百分比图谱 ELO-ENT:平滑棒形Elongate entire; BIL:哑铃形Bilobate; SAD:鞍形Saddle; BUL-FLA:扇形Bulliform flabellate; ACU-BUL:尖形Acute bulbosus; SQU:方形Square; REC:长方形Rectangular; TAB-IRR: 不规则板状Tabular irregular; ELO-ATT:延长棒形Elongate attenuate; SPH-PSI:球形Spheroid psilate; SPH-ORN:波状球形Spheroid ornate; BLO:块状Blocky

Fig.4 Phytolith Percentages in Bos sp. dental calculus

表1 大额牛牙釉质同位素δ13C分析结果

Tab.1 Analysis results of isotopic δ13C in tooth enamel of Bos frontalis

样本编号 Sample No.	BT1	BT2 (m3)	BT3 (M3)	BT4 (M3)	BT5 (m1)	BT6 (m3)
δ¹³C(‰)	-9.8	-9.0	-10.3	-7.5	-4.6	-10.1

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安徽华龙洞遗址大额牛的食性

Dietary ecology of gaur from the Hualongdong site in Anhui Province

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