Functional and phylogenetic β diversities and their link with clustering/overdispersion and uniqueness/redundancy

IF 2.7 3区环境科学与生态学 Q2 ECOLOGY

Ecosphere Pub Date : 2024-11-07 DOI:10.1002/ecs2.70045

Sandrine Pavoine, Carlo Ricotta

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Abstract

In recent decades, research on biodiversity in community ecology has been marked by the consideration of species' evolutionary histories and functional traits. Among the different spatial levels at which functional or phylogenetic (hereafter FP) diversity can be quantified, the definition of the general concept of between-community (β) diversity has been given less attention than that of local, within-community (α) and regional, merged-community (γ) diversities. Here, we develop a new method for partitioning FP β diversity into elementary components to determine how and why FP β diversity differs from species β diversity, with the latter reflecting only differences in species' abundances between communities. As a reference example, we consider two distinct measures of FP β diversity: Rao's dissimilarity coefficient (Q_β), which expresses the average FP dissimilarity between communities, and its transformation (E_β), which expresses the effective number of distinct communities. Through analytical partitioning and simulations, we show that Q_β and E_β are connected differently to typical patterns of community structure. The search for the ecological and evolutionary processes that drive community assembly and the assessment of community resilience and stability have indeed revealed typical community structures: the local clustering of species with similar traits or shared evolutionary histories and the local (α) or regional (γ) presence of functionally or phylogenetically redundant versus unique species. We show that while Q_β and E_β are both increasing functions of species β diversity and FP γ uniqueness, Q_β increases with FP clustering, while E_β increases with FP α redundancy. We also show that the component of FP clustering included in Q_β partitioning formula allows the detection of an overall trend of overdispersion or clustering in a dataset without the need to use null models. To facilitate and secure the selection of an index of β diversity for a given study, we call, through our study, for the development of formal and precise definitions for FP β diversity in light of the concepts of clustering versus overdispersion and redundancy versus uniqueness. In particular, we call for further research on when and why FP β diversity should increase with FP clustering.

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功能和系统发育 β 多样性及其与聚类/过度分散和独特性/冗余的联系

近几十年来，群落生态学中有关生物多样性的研究以考虑物种的进化史和功能特征为标志。在可以量化功能或系统发育（以下简称 FP）多样性的不同空间层次中，与局部、群落内（α）和区域、合并群落（γ）多样性相比，群落间（β）多样性这一一般概念的定义受到的关注较少。在此，我们开发了一种新方法，将 FP β 多样性划分为基本组成部分，以确定 FP β 多样性与物种 β 多样性的不同之处及原因，后者仅反映群落间物种丰度的差异。作为一个参考例子，我们考虑了 FP β 多样性的两种不同测量方法：拉奥异质性系数（Qβ）表示群落间的平均 FP 异质性，其转换系数（Eβ）表示不同群落的有效数量。通过分析划分和模拟，我们发现 Q β 和 E β 与群落结构的典型模式有着不同的联系。对驱动群落组合的生态和进化过程的探索以及对群落恢复力和稳定性的评估确实揭示了典型的群落结构：具有相似性状或共同进化史的物种在局部聚集，功能上或系统发育上冗余的物种与独特的物种在局部（α）或区域（γ）存在。我们发现，虽然 Qβ 和 Eβ 都是物种 β 多样性和 FP γ 唯一性的递增函数，但 Qβ 随 FP 聚类的增加而增加，而 Eβ 则随 FP α 冗余的增加而增加。我们还表明，Qβ 分区公式中包含的 FP 聚类成分可以检测数据集的过度分散或聚类的整体趋势，而无需使用空模型。为了方便和确保为特定研究选择 β 多样性指标，我们呼吁通过我们的研究，根据聚类与过度分散、冗余与唯一性的概念，为 FP β 多样性制定正式而精确的定义。特别是，我们呼吁进一步研究 FP β 多样性何时以及为何会随着 FP 聚类而增加。

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来源期刊

Ecosphere ECOLOGY-

CiteScore

4.70

自引率

3.70%

发文量

378

审稿时长

15 weeks

期刊介绍： The scope of Ecosphere is as broad as the science of ecology itself. The journal welcomes submissions from all sub-disciplines of ecological science, as well as interdisciplinary studies relating to ecology. The journal''s goal is to provide a rapid-publication, online-only, open-access alternative to ESA''s other journals, while maintaining the rigorous standards of peer review for which ESA publications are renowned.