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果蝇线粒体遗传学:通过生殖细胞分裂实现异质性的进化。

Drosophila Mitochondrial Genetics: Evolution of Heteroplasmy through Germ Line Cell Divisions.

机构信息

Laboratoire de Biologie et Génétique Evolutives, Centre National de la Recherche Scientifique, F 91190 Gif-sur-Yvette, France.

出版信息

Genetics. 1987 Dec;117(4):687-96. doi: 10.1093/genetics/117.4.687.

DOI:10.1093/genetics/117.4.687
PMID:17246410
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1203241/
Abstract

The mitochondrial genotype of all F(1) female offspring (426 individuals) of a single Drosophila mauritiana female, heteroplasmic for two types of mtDNA (a short and a long genome), was established. All descendants were heteroplasmic. The earliest eggs laid by this female show the cytoplasmic genetic structure of ovariole stem cells at the end of development. Cohorts of females from the eggs laid day after day by this female, throughout the 31 days of its life, provide information on the evolution of the mitochondrial genotypes in the course of successive divisions of stem cells. An increase of the percentage of long DNA in offspring was observed as the female aged. Moreover, the variance of the genotypes increases as rounds of stem cell division progress. These results are supported by observations based on the adults issued from the early and late eggs, for three additional heteroplasmic females.

摘要

对一只携带两种 mtDNA(短基因组和长基因组)异质的毛里求斯果蝇雌蝇的所有 F1 雌性后代(426 只个体)的线粒体基因型进行了鉴定。所有后代均为异质。这只雌蝇最早产下的卵显示了发育末期卵原细胞干细胞的细胞质遗传结构。这只雌蝇每天产下的卵子所产生的雌性群体,在其 31 天的生命周期内,提供了关于线粒体基因型在干细胞连续分裂过程中进化的信息。随着雌蝇年龄的增长,观察到后代中长 DNA 的百分比增加。此外,随着干细胞分裂轮数的增加,基因型的方差也增加。这些结果得到了另外三只异质雌性个体的早期和晚期卵所产生的成虫观察结果的支持。

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