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模拟热带和亚热带大西洋生态区域内桡足类的α多样性和β多样性。

Modelling the alpha and beta diversity of copepods across tropical and subtropical Atlantic ecoregions.

作者信息

Martínez-Leiva Lorena, Landeira José M, Fernández de Puelles Maria Luz, Hernández-León Santiago, Tuset Víctor M, Fatira Effrosyni

机构信息

Instituto de Oceanografía y Cambio Global, IOCAG, Universidad de Las Palmas de Gran Canaria, Unidad Asociada ULPGC-CSIC, Campus de Taliarte, 35214 Telde, Gran Canaria, Canary Islands, Spain.

Department of Biology, Norwegian University of Science and Technology, Trondhjem Biological Station NO-7491 Trondheim, Trondheim, Norway.

出版信息

NPJ Biodivers. 2025 Jan 31;4(1):3. doi: 10.1038/s44185-025-00073-x.

DOI:10.1038/s44185-025-00073-x
PMID:39890979
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11785948/
Abstract

Copepods, the most abundant individuals of the mesozooplankton, play a pivotal role in marine food webs and carbon cycling. However, few studies have focused on their diversity and the environmental factors influencing it. The objective of the present study is to model the alpha and beta diversity of copepods across the tropical and subtropical ecoregions of Atlantic Ocean using both taxonomic and functional approaches. The study used a dataset of 226 copepod species collected by stratified plankton hauls (0-800 m depth) across the tropical and equatorial Atlantic, from oligotrophic waters close to the Brazilian coast to more productive waters close to the Mauritanian Upwelling. To perform the functional analysis, six traits related to the behaviour, growth, and reproduction of copepods were selected. Several alpha diversities were estimated using taxonomic metrics (SR, Δ+, and Λ+) and functional metrics (FDis, FEve, FDiv, FOri, FSpe), and modelized with GAM model across spatial and environmental gradients, and day/night. The overall and two components of β-diversity (turnover and nestedness) were shared between depth and stations. The surface layers of stations from oligotrophic, equatorial, and Cape Verde ecoregions displayed higher values of taxonomic α-diversity. More unpredictable were the facets of functional α-diversity, although they showed a tendency to be positive with depth during the daytime. The GAM analysis revealed spatial gradients as the key factors modelling the taxonomic α-diversity, whereas depth was the most relevant for functional α-diversity. The turnover component drove taxonomic β-diversity in depth and station, whereas the nestedness component acquired relevance for the functional β-diversity. The taxonomic structure of the copepod community varied spatially across depths and ecoregions, but this was not linked to functional changes of the same magnitude.

摘要

桡足类是中型浮游动物中数量最多的个体,在海洋食物网和碳循环中起着关键作用。然而,很少有研究关注它们的多样性以及影响其多样性的环境因素。本研究的目的是使用分类学和功能学方法,对大西洋热带和亚热带生态区域的桡足类的α多样性和β多样性进行建模。该研究使用了一个数据集,该数据集包含通过分层浮游生物拖网(深度0 - 800米)在热带和赤道大西洋收集的226种桡足类物种,范围从靠近巴西海岸的贫营养水域到靠近毛里塔尼亚上升流的生产力更高的水域。为了进行功能分析,选择了与桡足类行为、生长和繁殖相关的六个特征。使用分类学指标(SR、Δ+和Λ+)和功能指标(FDis、FEve、FDiv、FOri、FSpe)估计了几种α多样性,并通过广义相加模型(GAM)在空间、环境梯度以及白天/黑夜条件下进行建模。β多样性的总体以及两个组成部分(周转和嵌套)在深度和站点之间是共享的。来自贫营养、赤道和佛得角生态区域站点的表层显示出较高的分类学α多样性值。功能α多样性的情况则更难以预测,尽管它们在白天呈现出随深度增加而增加的趋势。GAM分析表明,空间梯度是塑造分类学α多样性的关键因素,而深度对于功能α多样性最为重要。周转部分驱动了深度和站点上的分类学β多样性,而嵌套部分在功能β多样性方面具有重要意义。桡足类群落的分类结构在不同深度和生态区域之间存在空间差异,但这与相同程度的功能变化并无关联。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9cfa/11785948/dfbbc55dcd81/44185_2025_73_Fig7_HTML.jpg
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