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拼凑拼图:对从北大西洋深处到北冰洋的涟虫目(甲壳纲:囊虾总目)多样性和分布模式的见解。

Adding pieces to the puzzle: insights into diversity and distribution patterns of Cumacea (Crustacea: Peracarida) from the deep North Atlantic to the Arctic Ocean.

作者信息

Uhlir Carolin, Schwentner Martin, Meland Kenneth, Kongsrud Jon Anders, Glenner Henrik, Brandt Angelika, Thiel Ralf, Svavarsson Jörundur, Lörz Anne-Nina, Brix Saskia

机构信息

Center of Natural History (CeNak), Universität Hamburg, Hamburg, Germany.

German Center for Marine Biodiversity Research (DZMB), Senckenberg Research Institute, Hamburg, Germany.

出版信息

PeerJ. 2021 Nov 11;9:e12379. doi: 10.7717/peerj.12379. eCollection 2021.

DOI:10.7717/peerj.12379
PMID:34824910
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8590803/
Abstract

The Nordic Seas have one of the highest water-mass diversities in the world, yet large knowledge gaps exist in biodiversity structure and biogeographical distribution patterns of the deep macrobenthic fauna. This study focuses on the marine bottom-dwelling peracarid crustacean taxon Cumacea from northern waters, using a combined approach of morphological and molecular techniques to present one of the first insights into genetic variability of this taxon. In total, 947 specimens were assigned to 77 morphologically differing species, representing all seven known families from the North Atlantic. A total of 131 specimens were studied genetically (16S rRNA) and divided into 53 putative species by species delimitation methods (GMYC and ABGD). In most cases, morphological and molecular-genetic delimitation was fully congruent, highlighting the overall success and high quality of both approaches. Differences were due to eight instances resulting in either ecologically driven morphological diversification of species or morphologically cryptic species, uncovering hidden diversity. An interspecific genetic distance of at least 8% was observed with a clear barcoding gap for molecular delimitation of cumacean species. Combining these findings with data from public databases and specimens collected during different international expeditions revealed a change in the composition of taxa from a Northern Atlantic-boreal to an Arctic community. The Greenland-Iceland-Scotland-Ridge (GIS-Ridge) acts as a geographical barrier and/or predominate water masses correspond well with cumacean taxa dominance. A closer investigation on species level revealed occurrences across multiple ecoregions or patchy distributions within defined ecoregions.

摘要

北欧海域拥有世界上最高的水体多样性之一,但在深海大型底栖动物的生物多样性结构和生物地理分布模式方面仍存在巨大的知识空白。本研究聚焦于北方水域的海洋底栖十足目甲壳动物类群涟虫目,采用形态学和分子技术相结合的方法,首次对该类群的遗传变异性进行了深入研究。总共947个标本被归为77个形态各异的物种,代表了北大西洋所有七个已知科。共对131个标本进行了基因研究(16S rRNA),并通过物种界定方法(GMYC和ABGD)将其分为53个假定物种。在大多数情况下,形态学和分子遗传学界定完全一致,凸显了这两种方法的总体成功和高质量。差异源于八个实例,这些实例导致了物种的生态驱动形态多样化或形态隐秘物种的出现,揭示了隐藏的多样性。观察到种间遗传距离至少为8%,在涟虫目物种的分子界定上有明显的条形码间隙。将这些发现与来自公共数据库的数据以及在不同国际考察中收集的标本相结合,揭示了分类单元组成从北大西洋 - 北方群落向北极群落的变化。格陵兰 - 冰岛 - 苏格兰海脊(GIS海脊)起到了地理屏障的作用,和/或主要水体与涟虫目分类单元的优势分布相吻合。在物种层面的进一步调查揭示了跨多个生态区域的分布情况或在特定生态区域内的零散分布。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d98d/8590803/9f1b0a589734/peerj-09-12379-g013.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d98d/8590803/5c7d1cc58c5e/peerj-09-12379-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d98d/8590803/7837b8182747/peerj-09-12379-g009.jpg
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