Genetic structure and diversity of the seagrass Zostera marina along a steep environmental gradient, with implications for genetic monitoring

IF 3.3 Q2 ENVIRONMENTAL SCIENCES Frontiers in Climate Pub Date : 2023-12-18 DOI:10.3389/fclim.2023.1303337
Stefanie R. Ries, Ellika Faust, Kerstin Johannesson, Per R. Jonsson, P. Moksnes, R. Pereyra, Marlene Jahnke
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Abstract

Zostera marina (eelgrass) is a foundation species in coastal zones in the northern hemisphere. Eelgrass is declining across its distribution, a trend likely to accelerate under climate change. In Sweden, eelgrass is a species of particular concern in management and conservation. Here, we provide information on genetic variation, an important component for the potential persistence and adaptation of any species in a changing environment. In particular, the steep salinity gradient over which eelgrass is distributed along the Swedish coast (26 psu on the west coast to 5 psu on the east coast) calls for a better understanding of genetic diversity, connectivity, and potential for local adaptation. To assess genetic variation and population genetic structure, we genotyped individuals with 2,138 single nucleotide polymorphisms (SNPs) from 15 eelgrass meadows spanning the whole Swedish distribution. We found a geographic population genetic structure from west to east parallel to the salinity gradient and with a clear genetic break at the entrance to the Baltic Sea. Meadows along the low salinity east coast consisted of a few or only one clone. Eelgrass on the west coast had higher genotypic richness, higher genetic variation, and showed population differentiation on smaller geographic scales. With their low genetic variation, the east coast meadows are especially threatened amidst global changes. Lack of sexual reproduction and the capacity to generate new genotypes is an issue that needs to be seriously considered in management and conservation. In addition, the lack of sexual reproduction renders clonal eelgrass less likely to recover and recolonize after disturbance, and more challenging to restore. The here provided information on genetic clusters, clonality, and genetic variation can be included for prioritizing meadows for conservation and for identifying meadows for restoration purposes. Most importantly, genetic monitoring is urgently needed to assess temporal genetic changes of eelgrass along the Swedish coast and elsewhere facing climate change.
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海草 Zostera marina 在陡峭环境梯度上的遗传结构和多样性及其对遗传监测的影响
鳗草(Zostera marina)是北半球沿海地区的基础物种。黄鳝草在其分布区正逐渐减少,在气候变化的影响下,这一趋势可能会加快。在瑞典,鳗草是管理和保护方面特别关注的物种。在这里,我们提供了有关遗传变异的信息,遗传变异是任何物种在不断变化的环境中持续生存和适应的重要因素。特别是,瑞典沿岸分布着陡峭的盐度梯度(西海岸为 26 psu,东海岸为 5 psu),这就要求我们更好地了解遗传多样性、连通性和本地适应潜力。为了评估遗传变异和种群遗传结构,我们对分布于整个瑞典的 15 个鳗草草甸的 2138 个个体进行了单核苷酸多态性(SNPs)基因分型。我们发现了一个与盐度梯度平行的从西向东的地理种群遗传结构,在波罗的海入口处有一个明显的遗传断裂。盐度较低的东海岸草甸只有几个或一个克隆。西海岸的黄鳝草基因型丰富度较高,遗传变异较大,在较小的地理范围内表现出种群分化。由于遗传变异小,东海岸草地在全球变化中尤其受到威胁。缺乏有性繁殖和产生新基因型的能力是管理和保护中需要认真考虑的问题。此外,由于缺乏有性生殖,克隆性黄鳝草在受到干扰后恢复和重新定殖的可能性较低,恢复起来更具挑战性。本文提供的有关遗传群、克隆性和遗传变异的信息,可用于确定保护草甸的优先次序和确定恢复草甸的目的。最重要的是,迫切需要进行遗传监测,以评估瑞典沿海和其他地区面临气候变化的黄鳝草的时间遗传变化。
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
Frontiers in Climate
Frontiers in Climate Environmental Science-Environmental Science (miscellaneous)
CiteScore
4.50
自引率
0.00%
发文量
233
审稿时长
15 weeks
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