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沿海潮汐锋面的浮游植物分类和功能多样性模式。

Phytoplankton taxonomic and functional diversity patterns across a coastal tidal front.

机构信息

Sorbonne Université, CNRS-UMR7144-Station Biologique de Roscoff, Place Georges Teissier, 29688, Roscoff, France.

Ifremer-Centre de Brest, DYNECO/Pelagos, Technopôle Brest Iroise, 29280, Plouzané, France.

出版信息

Sci Rep. 2021 Jan 29;11(1):2682. doi: 10.1038/s41598-021-82071-0.

DOI:10.1038/s41598-021-82071-0
PMID:33514820
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7846791/
Abstract

Oceanic physics at fine scale; e.g. eddies, fronts, filaments; are notoriously difficult to sample. However, an increasing number of theoretical approaches hypothesize that these processes affect phytoplankton diversity which have cascading effects on regional ecosystems. In 2015, we targeted the Iroise Sea (France) and evidenced the setting up of the Ushant tidal front from the beginning of spring to late summer. Seawater samples were taken during three sampling cruises and DNA-barcoding allowed us to investigate patterns of eukaryotic phytoplankton diversity across this front. First focusing on patterns of taxonomic richness, we evidenced that the front harbored a hotspot of eukaryotic phytoplankton diversity sustained throughout summer. We then detail the ecological processes leading to the formation of this hotspot by studying shifts in community composition across the Iroise Sea. Physical mixing mingled the communities surrounding the front, allowing the formation of a local ecotone, but it was cycles of disturbances and nutrient inputs over the front that allowed a decrease in competitive exclusion, which maintained a higher diversity of rare phytoplankton taxa. These processes did not select a specific ecological strategy as inferred by a trait approach coupled to our taxonomic approach. Instead the front favored higher richness within widespread strategies, resulting in functional redundancy. We detail how fine-scale ocean physics affect phytoplankton diversity and suppose that this interplay is a major control on regional ecosystems.

摘要

海洋精细物理学;例如,漩涡、锋面、丝状流;这些现象采样非常困难。然而,越来越多的理论方法假设这些过程会影响浮游植物多样性,进而对区域生态系统产生级联效应。2015 年,我们以法国伊罗瓦兹海为研究目标,从春季到夏末,见证了乌尚特潮汐锋的形成。在三次采样航行中采集了海水样本,通过 DNA 条形码技术,我们能够研究整个锋面的真核浮游植物多样性模式。首先,我们重点研究了分类丰富度模式,结果表明,锋面全年维持着一个真核浮游植物多样性热点。然后,我们通过研究伊罗瓦兹海整个海域的群落组成变化,详细阐述了形成这一热点的生态过程。物理混合使锋面周围的群落混合在一起,形成了一个局部生态交错带,但正是锋面的干扰和营养物质输入循环,减少了竞争排斥,从而维持了更多稀有浮游植物类群的多样性。这些过程并没有像我们的分类方法与特征方法相结合所推断的那样,选择一种特定的生态策略。相反,锋面有利于更广泛策略内的更高丰富度,从而产生功能冗余。我们详细说明了海洋精细物理学如何影响浮游植物多样性,并假设这种相互作用是对区域生态系统的主要控制因素。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6235/7846791/fea8a7a9bc71/41598_2021_82071_Fig7_HTML.jpg
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