来自加勒比海和墨西哥湾的灰笛鲷（）亚种群之间的基因流动。

Gene flow between subpopulations of gray snapper () from the Caribbean and Gulf of Mexico.

作者信息

Rosado-Nic Oscar de Jesús, Hogan J Derek, Lara-Arenas José Héctor, Rosas-Luis Rigoberto, Carrillo Laura, Villegas-Sánchez Carmen Amelia

机构信息

Tecnológico Nacional de México/IT de Chetumal, Chetumal, Quintana Roo, Mexico.

Department of Life Sciences, Texas A&M University-Corpus Christi, Corpus Christi, TX, USA.

出版信息

PeerJ. 2020 Feb 10;8:e8485. doi: 10.7717/peerj.8485. eCollection 2020.

DOI:10.7717/peerj.8485

PMID:32095340

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7017790/

Abstract

BACKGROUND

The gray snapper () has a tropical and subtropical distribution. In much of its range this species represents one of the most important fishery resources because of its high quality meat and market value. Due to this, this species is vulnerable to overfishing, and population declines have been observed in parts of its range. In recent decades, it has been established that knowing the level of genetic connectivity is useful for establishing appropriate management and conservation strategies given that genetic isolation can drive towards genetic loss. Presently the level of genetic connectivity between subpopulations of of the southern region of the Gulf of Mexico and the Caribbean Sea remains unknown.

METHODS

In the present study we analyze genetic structure and diversity for seven subpopulations in the southern Gulf of Mexico and the Mexican Caribbean Sea. Eight microsatellite primers of phylogenetically closely related species to were selected.

RESULTS

Total heterozygosity was 0.628 and 0.647 in the southern Gulf of Mexico and the Mexican Caribbean Sea, however, results obtained from AMOVA and indicated a lack of genetic difference between the major basins. We also found no association between genetic difference and geographic distance, and moderately high migration rates ( = > 4.1) suggesting ongoing gene flow among the subpopulations. Gene flow within the southern Gulf of Mexico appears to be stronger going from east-to-west.

CONCLUSIONS

Migration rates tended to be higher between subpopulations within the same basin compared to those across basins indicating some regionalization. High levels of genetic diversity and genetic flow suggest that the population is quite large; apparently, the fishing pressure has not caused a bottleneck effect.

摘要

背景

灰笛鲷分布于热带和亚热带地区。在其大部分分布范围内，由于肉质鲜美且具有市场价值，该物种是最重要的渔业资源之一。正因如此，该物种易受过度捕捞影响，在其部分分布区域已观察到种群数量下降。近几十年来，鉴于基因隔离可能导致基因丧失，了解基因连通性水平对于制定适当的管理和保护策略很有用。目前，墨西哥湾南部地区和加勒比海的灰笛鲷亚种群之间的基因连通性水平仍然未知。

方法

在本研究中，我们分析了墨西哥湾南部和墨西哥加勒比海七个亚种群的遗传结构和多样性。选择了与灰笛鲷系统发育关系密切的物种的八个微卫星引物。

结果

墨西哥湾南部和墨西哥加勒比海的总杂合度分别为0.628和0.647，然而，方差分析（AMOVA）和其他分析结果表明，主要海域之间不存在遗传差异。我们还发现遗传差异与地理距离之间没有关联，且迁移率中等偏高（Nm > 4.1），这表明亚种群之间存在持续的基因流动。墨西哥湾南部内部的基因流动似乎从东向西更强。

结论

与跨海域的亚种群相比，同一海域内亚种群之间的迁移率往往更高，这表明存在一定的区域化现象。高水平的遗传多样性和基因流动表明种群规模相当大；显然，捕捞压力尚未造成瓶颈效应。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/10e2/7017790/099d78a314eb/peerj-08-8485-g001.jpg

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来自加勒比海和墨西哥湾的灰笛鲷（）亚种群之间的基因流动。

Gene flow between subpopulations of gray snapper () from the Caribbean and Gulf of Mexico.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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