中国特有华溪蟹属淡水蟹多样性格局及其保护空缺

doi:10.17520/biods.2025123

生物多样性

中国特有华溪蟹属淡水蟹多样性格局及其保护空缺

王儒晓, 史博洋, 潘达^*, 孙红英

南京师范大学生命科学学院江苏省生物多样性与生物技术重点实验室, 南京 210023

收稿日期:2025-04-02 修回日期:2025-05-29 接受日期:2025-09-11
通讯作者: 潘达

Biodiversity patterns and conservation gaps of the endemic freshwater crab genus Sinopotamon in China

Ruxiao Wang, Boyang Shi, Da Pan^*, Hongying Sun

Jiangsu Key Laboratory for Biodiversity and Biotechnology, College of Life Sciences, Nanjing Normal University, Nanjing 210023, China

Received:2025-04-02 Revised:2025-05-29 Accepted:2025-09-11
Contact: Da Pan

摘要/Abstract

摘要： 淡水蟹类是底栖大型无脊椎动物代表类群之一, 也是判断生态系统良好的关键指示生物, 这为生物多样性保护研究提供了关键的理想材料。据此, 本研究以中国特有的华溪蟹属(Sinopotamon)淡水蟹类为模型, 基于详尽的野外调查与文献资料汇总, 构建了该类群的物种分布数据库, 利用空间广义线性混合模型来评估影响其物种多样性与遗传多样性的关键环境因素; 通过将物种和遗传多样性格局与现有保护地进行叠加分析, 以识别其多样性热点和保护空缺区域。研究结果表明, 华溪蟹属物种多样性分布中心位于云贵高原东北缘至浙闽丘陵之间的地区, 其物种多样性整体上呈现出由长江流域向南北边缘逐渐稀少的特点; 遗传多样性呈现出空间不均匀分布的特征, 山地区域的遗传多样性相对较高。物种和遗传多样性之间存在显著的正相关关系, 海拔和年平均降水量等环境因子对两者具有显著的正向影响。华溪蟹属物种和遗传多样性格局呈现显著的空间聚集性, 其热点主要分布于中国中南部的山地丘陵地带, 在该地区识别出4个保护空缺区域; 南岭山脉东段被识别为遗传多样性特有的热点区域。本文研究结果显示, 山地生态系统及暖湿气候在华溪蟹属淡水蟹物种和遗传多样性的形成过程中发挥了关键作用。本研究强调了结合物种多样性和遗传多样性来规划自然保护区的必要性, 为中国淡水生态系统的未来生物多样性保护管理与决策提供了数据支撑和科学依据。

关键词: 华溪蟹属, 淡水蟹类, 遗传多样性, 空间分布格局, 保护空缺

Abstract

Aims: Freshwater crabs are one of the representative groups of benthic macroinvertebrates and serve as critical bioindicator of healthy ecosystems, making them ideal model organisms for biodiversity conservation research. The present study uses the freshwater crabs of the endemic Chinese genus Sinopotamon as a model and based on extensive field surveys and literature review aims to investigate a comprehensive species distribution database, assess the key environmental factors influencing both species and genetic diversity, and identify diversity hotspots as well as conservation gaps across its distribution range.

Methods: The distribution data of Sinopotamon species were compiled through field investigations and literature sources. Spatial patterns of diversity were analyzed, and key environmental drivers were evaluated using spatial statistical models. Species and genetic diversity patterns were then overlaid with existing protected area to identify conservation gap regions.

Results: The center of Sinopotamon species diversity lies between the northeastern Yunnan-Guizhou Plateau to the Zhejiang-Fujian hills. Species richness generally declines from the Yangtze River Basin toward the northern and southern margins. Genetic diversity shows strong spatial heterogeneity, with higher levels concentrated in mountainous regions. Species diversity and genetic diversity are significantly positively correlated. Environmental factors such as elevation and mean annual precipitation have significant positive effects on both. Diversity hotspots are spatially clustered, primarily in the mountainous and hill areas of south-central China. Four conservation gaps were identified in these regions, with the eastern section of the Nanling Mountains recognized as a distinctive hotpot for genetic diversity.

Conclusion: Our results indicate that mountainous ecosystems and warm, humid climates have played a critical role in shaping both species and genetic diversity of Sinopotamon. This study highlights the necessity of integrating species and genetic diversity in conservation planning and provides essential data and scientific support for biodiversity conservation and management in China’s freshwater ecosystems.

Key words: Sinopotamon, freshwater crabs, genetic diversity, spatial distribution pattern, conservation gaps

王儒晓, 史博洋, 潘达, 孙红英. 中国特有华溪蟹属淡水蟹多样性格局及其保护空缺. 生物多样性, DOI: 10.17520/biods.2025123.

Ru-Xiao Wang, Boyang Shi, Da Pan, Hongying Sun. Biodiversity patterns and conservation gaps of the endemic freshwater crab genus Sinopotamon in China. Biodiversity Science, DOI: 10.17520/biods.2025123.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2025123

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