Elevational patterns of bird alpha and beta diversity in Haba Snow Mountain, Southwestern China: Implication for conservation

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Jin-Tao Tang , Shi-Long Liu , Bian-Mu Chunpi , Jun Liu , Peng Liu , Wambura M. Mtemi , Xu Luo , Yu-Bao Duan
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引用次数: 0

Abstract

Understanding environmental patterns of species diversity is essential for nature reserve planning and biodiversity conservation. In this study, we explored the birds’ alpha and beta diversity along the elevational gradients in Haba Snow Mountain Nature Reserve (hereafter, HBSM), a global biodiversity hotspot, and studied which environmental factor is the main driver in explaining alpha and beta diversity patterns. Our results indicated that taxonomic, functional, and phylogenetic alpha diversity consistently exhibited hump-shaped patterns with similar peaks. After controlling for species richness, both functional and phylogenetic alpha diversity increased with elevation, and the peaks at 3400–3700 m. Mean pairwise functional distance remained nearly constant along the elevation band, whereas mean pairwise phylogenetic distance shown hump-shaped pattern, and the predicted MPD peaked at the fifth band (3100–3400 m a.s.l). The functional and phylogenetic structure of bird communities in HBSM were more clustered along the elevation gradients, suggesting environmental filtering likely drove the assembly processes. Additionally, primary productivity (NDVI and/or habitat heterogeneity) and/or precipitation were robust predictors of variation in most diversity metrics. For multiple-site beta diversity, we observed that high turnover component in taxonomic, functional, and phylogenetic dimensions, indicating distinct bird assemblages across various elevational bands. In pairwise beta diversity, the spatial turnover of taxonomic and phylogenetic aspects was higher than nestedness, revealing species replacement occurs relatively frequently between evolutionarily related species with similar niche and functional traits. Overall, our findings highlight the importance of considering both different dimensions and multifaceted diversity when assessing elevational patterns of bird diversity. This study also provides valuable insights into the structuring mechanisms of bird communities and informs conservation planning along elevational gradients in HBSM, and offers a comprehensive case on species richness along elevational gradients.
中国西南哈巴雪山鸟类阿尔法和贝塔多样性的海拔模式:对自然保护的影响
了解物种多样性的环境模式对于自然保护区规划和生物多样性保护至关重要。在这项研究中,我们探讨了全球生物多样性热点地区哈巴雪山自然保护区(以下简称哈巴雪山自然保护区)鸟类沿海拔梯度的α和β多样性,并研究了哪种环境因素是解释α和β多样性模式的主要驱动力。我们的研究结果表明,分类、功能和系统发育α多样性始终呈现出峰值相似的驼峰型模式。在控制了物种丰富度之后,功能和系统发育α多样性都随着海拔的升高而增加,并在3400-3700米处达到峰值。平均成对功能距离沿海拔带几乎保持不变,而平均成对系统进化距离则呈驼峰状,预测的 MPD 在第五带(海拔 3100-3400 米)达到峰值。HBSM中鸟类群落的功能结构和系统发育结构在海拔梯度上更加集群,表明环境过滤可能驱动了群落的集结过程。此外,初级生产力(归一化差异植被指数和/或生境异质性)和/或降水是大多数多样性指标变化的可靠预测因子。在多地点贝塔多样性方面,我们观察到分类学、功能学和系统发生学维度的高周转成分,表明不同海拔带的鸟类组合各不相同。在成对的贝塔多样性中,分类学和系统发生学方面的空间周转率高于嵌套度,这表明具有相似生态位和功能特征的进化相关物种之间的物种替换相对频繁。总之,我们的研究结果强调了在评估鸟类多样性的海拔模式时考虑不同维度和多方面多样性的重要性。这项研究还为鸟类群落的结构机制提供了宝贵的见解,为高海拔梯度生态系统的保护规划提供了信息,并为高海拔梯度物种丰富性提供了一个全面的案例。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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