基础海草的限制性传播和表型对水深的反应

IF 4.5 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Molecular Ecology Pub Date : 2024-10-30 DOI:10.1111/mec.17565
Erik E Sotka, A Randall Hughes, Torrance C Hanley, Cynthia G Hays
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引用次数: 0

摘要

物种保护和管理得益于对自然扩散模式和遗传变异的精确了解。利用最近在成体植物和散播种子的间接遗传方法方面取得的进展,我们发现一种濒危海洋基础植物(鳗鲡)的平均种子散播距离约为 100-200 米。令人惊讶的是,这一距离与陆生种子随风传播的距离(约 10 到 100 米)相比,更类似于海洋繁殖体通过水流的被动传播距离(约 10 到 100 千米)。由于像 Zostera 这样的近岸海洋植物通常分布在由水深(深度)驱动的强大选择梯度上,即使在这些有限的空间尺度内,种子也能扩散到新的水深,并经历光照、温度和波浪暴露的深刻变化。我们发现,在表型差异和全基因组分化较强的植物中,它们之间的距离大约相当于平均实现扩散的空间尺度。这一结果表明,与深度相关的环境梯度导致的环境遗传隔离是这种模式的一个合理解释。有效规模与普查规模之比(或Ne/Nc)接近0.1%,表明现有植物中的一小部分提供了适应环境变化的遗传变异。我们的研究结果表明,如果不使用大量个体或有针对性地选择基因型进行直接和持续的干预,就很难成功保护能够适应环境条件微观空间和时间变化的海草草甸。
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Restricted Dispersal and Phenotypic Response to Water Depth in a Foundation Seagrass.

Species conservation and management benefit from precise understanding of natural patterns of dispersal and genetic variation. Using recent advances in indirect genetic methods applied to both adult plants and dispersed seeds, we find that the mean seed dispersal in a threatened marine foundation plant (the eelgrass Zostera marina) is approximately 100-200 m. This distance is surprisingly more similar to that of wind-dispersed terrestrial seeds (~10s to 100s of meters) than the passive dispersal of marine propagules via currents (~10s to 100s of kilometres). Because nearshore marine plants like Zostera are commonly distributed across strong selective gradients driven by bathymetry (depth) even within these restricted spatial scales, seeds are capable of dispersing to novel water depths and experiencing profound shifts in light availability, temperature and wave exposure. We documented strong phenotypic variation and genome-wide differentiation among plants separated by approximately the spatial scale of mean realised dispersal. This result suggests genetic isolation by environment in response to depth-related environmental gradients as one plausible explanation for this pattern. The ratio of effective to census size (or Ne/Nc) approximated 0.1%, indicating that a fraction of existing plants provides the genetic variation to allow adaptation to environmental change. Our results suggest that successful conservation of seagrass meadows that can adapt to microspatial and temporal variation in environmental conditions will be low without direct and persistent intervention using large numbers of individuals or a targeted selection of genotypes.

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来源期刊
Molecular Ecology
Molecular Ecology 生物-进化生物学
CiteScore
8.40
自引率
10.20%
发文量
472
审稿时长
1 months
期刊介绍: Molecular Ecology publishes papers that utilize molecular genetic techniques to address consequential questions in ecology, evolution, behaviour and conservation. Studies may employ neutral markers for inference about ecological and evolutionary processes or examine ecologically important genes and their products directly. We discourage papers that are primarily descriptive and are relevant only to the taxon being studied. Papers reporting on molecular marker development, molecular diagnostics, barcoding, or DNA taxonomy, or technical methods should be re-directed to our sister journal, Molecular Ecology Resources. Likewise, papers with a strongly applied focus should be submitted to Evolutionary Applications. Research areas of interest to Molecular Ecology include: * population structure and phylogeography * reproductive strategies * relatedness and kin selection * sex allocation * population genetic theory * analytical methods development * conservation genetics * speciation genetics * microbial biodiversity * evolutionary dynamics of QTLs * ecological interactions * molecular adaptation and environmental genomics * impact of genetically modified organisms
期刊最新文献
Population Genetics and Invasion History of the European Starling Across Aotearoa New Zealand. An Early-Life Disruption of Gut Microbiota Has Opposing Effects on Parasite Resistance in Two Host Species. Genetic Monitoring of a Lethal Control Programme for Wild Canids With Complex Mating Strategies. Elevational Range Impacts Connectivity and Predicted Deme Sizes From Models of Habitat Suitability. Michael C. Whitlock-Recipient of the 2024 Molecular Ecology Prize.
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