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一个长达一个世纪的基因记录显示,原生生物的有效种群规模与宏观物种相当。

A century-long genetic record reveals that protist effective population sizes are comparable to those of macroscopic species.

机构信息

Institute of Integrative Biology, University of Liverpool, , Biosciences Building, Liverpool L69 7ZB, UK.

出版信息

Biol Lett. 2013 Nov 27;9(6):20130849. doi: 10.1098/rsbl.2013.0849. Print 2013.

DOI:10.1098/rsbl.2013.0849
PMID:24284562
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3871374/
Abstract

Effective population size (Ne) determines the rate of genetic drift and the relative influence of selection over random genetic changes. While free-living protist populations characteristically consist of huge numbers of cells (N), the absence of any estimates of contemporary Ne raises the question whether protist effective population sizes are comparably large. Using microsatellite genotype data of strains derived from revived cysts of the marine dinoflagellate Pentapharsodinium dalei from sections of a sediment record that spanned some 100 years, we present the first estimates of contemporary Ne for a local population in a free-living protist. The estimates of Ne are relatively small, of the order of a few 100 individuals, and thus are similar in magnitude to values of Ne reported for multicellular animals: the implications are that Ne of P. dalei is of many orders of magnitude lower than the number of cells present (Ne/N ∼ 10(-12)) and that stochastic genetic processes may be more prevalent in protist populations than previously anticipated.

摘要

有效种群大小 (Ne) 决定了遗传漂变的速度和选择对随机遗传变化的相对影响。虽然自由生活的原生动物群体通常由大量的细胞 (N) 组成,但由于缺乏对当代 Ne 的任何估计,这就提出了一个问题,即原生动物的有效种群大小是否相当大。本研究利用从海洋甲藻 Pentapharsodinium dalei 的休眠孢囊衍生的菌株的微卫星基因型数据,这些菌株来自跨越约 100 年的一段沉积物记录的部分,我们首次对自由生活的原生动物的一个本地种群的当代 Ne 进行了估计。Ne 的估计值相对较小,大约为数百个个体,因此与多细胞动物的 Ne 值相似:这意味着 P. dalei 的 Ne 比存在的细胞数量(Ne/N ∼ 10(-12)) 低了许多数量级,而且随机遗传过程在原生动物种群中可能比以前预期的更为普遍。

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