广西柳城步氏巨猿牙结石中的植物微体遗存

doi:10.16359/j.1000-3193/AAS.2026.0012

摘要/Abstract

摘要：

步氏巨猿（Gigantopithecus blacki）的食性特征是揭示其演化适应与绝灭机制的关键证据。本文通过分析广西柳城巨猿洞发现的3件巨猿下颌牙结石中的植物残留物，探索步氏巨猿的食性，在尽量保持牙结石完整、避免植物微体损伤的前提下，提取并分析其中的植物微体遗存。本研究共提取8份样本，研究结果表明：5份为牙结石样本，3份为其他沉积物样本；5份牙结石样本共提取出5颗淀粉粒（禾本科草籽、木本植物果实、植物的块根块茎）、4颗植硅体和较多破损植物纤维和管胞遗骸。综上，步氏巨猿食谱兼具禾本科草籽、树冠果实、叶片（裸子植物、蕨类）、茎秆和植物枝条等，丰富的植物纤维和管胞等遗存表明步氏巨猿食性结构中植物粗纤维的高占比，为复原步氏巨猿的食性信息提供了新的生物考古学证据。

关键词: 步氏巨猿, 淀粉粒, 植硅体, 植物管胞, 食性

Abstract:

Gigantopithecus blacki, the largest extinct species within the family Hominidae, provides significant insights into the survival adaptations and extinction of primates. This study focuses on the plant-based dietary evidence of G. blacki from the Gigantopithecus Cave site in Liucheng, Guangxi. Using micro-nano spectral CT analysis, we systematically tested the composition of dental calculus samples attached to the teeth of the only three currently discovered G. blacki mandibles, extracting and analyzing the plant residues within these samples. The results show that the plant microfossils identified in the dental calculus include: starch granules from Poaceae grass seeds, fruits of woody plants, and plant roots and stems; Elongate echinate phytoliths; and tracheary elements from Water Hemlock or fern plants. Additionally, the samples contained ladder-like perforation plates from woody plant stems and reticulate vessels from the phloem of Lardizabalaceae plants. These findings indicate that the diet of G. blacki was highly diverse, covering multiple ecological niches of C₃ plants and providing new evidence for its bamboo consumption behavior. This also suggests its selection of ancient relict plant groups, offering new perspectives on the ecological relationship between large primates and ancient plant communities.

In summary, although the G. blacki specimens from the Liucheng Gigantopithecus Cave site date back approximately 1.2 to 0.9 million years, dental calculus on some of the teeth retained sufficient plant residue information to support further dietary reconstruction. This study combines micro-nano spectral CT and plant residue extraction techniques, enabling rapid compositional assessment of calculus samples, thus providing a novel approach for future research on fossilized dental calculus samples that are difficult to distinguish visually. Future research should expand along both temporal and spatial dimensions: temporally, by analyzing G. blacki dental fossil samples from different geological periods, comparing the differences in plant community composition across these periods, and exploring whether its diet adapted to changes in paleoclimate and paleovegetation, thereby providing dietary evidence for understanding the evolutionary dynamics of G. blacki; spatially, considering the current distribution of G. blacki fossils across Guangxi, Hubei, Chongqing, Guizhou, and Hainan, future comparative studies of regional samples could analyze whether geographical isolation led to regional dietary differentiation, investigate the impact of different regional paleoenvironments on its diet, and refine the study of G. blacki’s ecological distribution and adaptation patterns. This would provide a more comprehensive ecological perspective for exploring the diet and extinction of Gigantopithecus blacki.

Key words: Gigantopithecus blacki, starch granules, phytoliths, plant tracheary elements, diet

中图分类号:

Q981.3

杜瑞妍, 张茂林, 关莹. 广西柳城步氏巨猿牙结石中的植物微体遗存[J]. 人类学学报, 2026, 45(02): 268-279.

DU Ruiyan, ZHANG Maolin, GUAN Ying. Plant micro-remains from dental calculus of Gigantopithecus blacki in Liucheng, Guangxi[J]. Acta Anthropologica Sinica, 2026, 45(02): 268-279.

图/表 5

图1 步氏巨猿下颌骨和采样位置图

Fig.1 Mandible of Gigantopithecus blacki and sampling locations

表1 牙结石残留物分析样品信息

Tab.1 Dental calculus sample information

编号No.	标本Sample	采样齿位 Tooth site	成分Component	植物微体类型Micro-remain Type (n)
编号No.	标本Sample	采样齿位 Tooth site	成分Component	淀粉粒Starch granule	植硅体Phytolith	气孔器Stomata	植物纤维Fiber	表皮细胞Epidermal	合计Total
1	PA77	左下P4-M1	胶	0	0	0	0	6	6
2	PA83	颊侧LM1-LM2	沙砾	0	0	0	0	0	0
3	PA83	右下M3近中侧	沙砾	0	0	0	0	0	0
4	PA83	舌侧	牙结石	1	1	0	4	3	10
5	PA83	颊侧右下M1	牙结石	1	1	1	1	5	9
6	PA78	左下P4-M1	牙结石	0	0	0	4	5	9
7	PA78	左下P4近中侧	牙结石	1	2	1	7	6	17
8	PA78	左下M1-M2	牙结石	2	0	7	3	7	20
牙结石中微体遗存数量合计 Total Count of Microremains in Dental Calculus				5	4	9	19	26	65

图2 微纳能谱CT成分分析谱图左图为测试点位示意图，右图为能量谱图；ROI线为样品能量线，ref线为不同类型成分能量线。The left panel is a schematic diagram of the measurement points, and the right panel shows the corresponding energy spectrum. ROI (region of interest) marks the location of the sample analysis, while ref (reference lines) indicates the characteristic energy lines for different components.

Fig.2 Compositional spectrum from micro-nano spectral CT analysis

图3 牙结石中植物微体 a-e.淀粉粒Starch granules；f-g.刺棒型植硅体Elongate echinate phytoliths；h.孔纹管胞Pitted tracheid；i.网状穿孔板Reticulate perforation plate；j.石细胞A sclereid；k.孔纹导管Pitted vessels；l.腺毛Glandular hair；m.孔纹导管Pitted vessels；n.表皮细胞Epidermal cells

Fig.3 Microscopic images of plant micro-remains from dental calculus samples

图4 现生植物淀粉粒 a.禾本科稗草（种籽）Echinochloa crus-galli (seed)；b.壳斗科厚鳞柯（果实）Lithocarpus pachylepis (fruit)；c.银杏科银杏（果实）Ginkgo biloba (fruit)；d.薯蓣科参薯（根）Dioscorea alata (root)

Fig.4 Starch granules of living plants

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