Phylogeography and population structure of the red stingray, Dasyatis akajei inferred by mitochondrial control region.

Mitochondrial Dna Pub Date : 2015-08-01 Epub Date: 2014-01-10 DOI:10.3109/19401736.2013.861423

Ning Li, Xiao Chen, Dianrong Sun, Na Song, Qin Lin, Tianxiang Gao

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引用次数: 11

Abstract

The red stingray Dasyatis akajei is distributed in both marine and freshwater, but little is known about its phylogeography and population structure. We sampled 107 individuals from one freshwater region and 6 coastal localities within the distribution range of D. akajei. Analyses of the first hypervariable region of mitochondrial DNA control region of 474 bp revealed only 17 polymorphism sites that defined 28 haplotypes, with no unique haplotype for the freshwater population. A high level of haplotype diversity and low nucleotide diversity were observed in both marine (h = 0.9393 ± 0.0104, π = 0.0069 ± 0.0040) and freshwater populations (h = 0.8333 ± 0.2224, π = 0.0084 ± 0.0063). Significant level of genetic structure was detected between four marine populations (TZ, WZ, ND and ZZ) via both hierarchical molecular variance analysis (AMOVA) and pairwise FST (with two exceptions), which is unusual for elasmobranchs detected previously over such short geographical distance. However, limited sampling suggested that the freshwater population was not particularly distinct (p > 0.05), but additional samples would be needed to confirm it. Demersal and slow-moving characters likely have contributed to the genetically heterogeneous population structure. The demographic history of D. akajei examined by mismatch distribution analyses, neutrality tests and Bayesian skyline analyses suggested a sudden population expansion dating to upper Pleistocene. The information on genetic diversity and genetic structure will have implications for the management of fisheries and conservation efforts.

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利用线粒体控制区推测红黄貂鱼的系统地理学和种群结构。

红黄貂鱼在海洋和淡水中均有分布，但对其系统地理和种群结构的了解甚少。本研究在赤家鼠分布范围内的1个淡水区和6个沿海地区采集了107只赤家鼠。对线粒体DNA控制区474 bp的第一个高变区进行分析，发现只有17个多态性位点定义了28个单倍型，淡水种群没有独特的单倍型。海洋种群(h = 0.9393±0.0104，π = 0.0069±0.0040)和淡水种群(h = 0.8333±0.2224，π = 0.0084±0.0063)单倍型多样性较高，核苷酸多样性较低。通过层次分子方差分析(AMOVA)和配对FST(2个例外)检测到4个海洋种群(TZ、WZ、ND和ZZ)之间遗传结构的显著水平，这对于以前在如此短的地理距离内检测到的板颌支来说是不寻常的。然而，有限的采样表明淡水种群不是特别明显(p > 0.05)，但需要额外的采样来证实这一点。下沉和缓慢移动的特征可能促成了遗传异质性的种群结构。通过错配分布分析、中性检验和贝叶斯天际线分析等方法研究了赤杨的人口分布历史，表明其种群的突然扩张可追溯到更新世上部。关于遗传多样性和遗传结构的资料将对渔业管理和养护工作产生影响。

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

Mitochondrial Dna 生物-遗传学

自引率

0.00%

发文量

审稿时长

2.4 months

期刊介绍： Previously published under the title DNA Sequence (Vols 1-19.3), Mitochondrial DNA accepts original high-quality reports based on mapping, sequencing and analysis of mitochondrial DNA and RNA. Descriptive papers on DNA sequences from mitochondrial genomes, and also analytical papers in the areas of population genetics, medical genetics, phylogenetics and human evolution that use mitochondrial DNA as a source of evidence for studies will be considered for publication. The editorial board will also consider manuscripts that examine population genetic and systematic theory that specifically address the use of mitochondrial DNA sequences.