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在雌核发育鱼类墨西哥花鳉中宿主物种来源的微小染色体的稳定遗传。

Stable inheritance of host species-derived microchromosomes in the gynogenetic fish Poecilia formosa.

作者信息

Nanda Indrajit, Schlupp Ingo, Lamatsch Dunja K, Lampert Kathrin P, Schmid Michael, Schartl Manfred

机构信息

Universität Würzburg, Institut für Humangenetik, Biozentrum, D-97074 Würzburg, Germany.

出版信息

Genetics. 2007 Oct;177(2):917-26. doi: 10.1534/genetics.107.076893. Epub 2007 Aug 24.

DOI:10.1534/genetics.107.076893
PMID:17720916
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2034654/
Abstract

B chromosomes are additional, usually unstable constituents of the genome of many organisms. Their origin, however, is often unclear and their evolutionary relevance is not well understood. They may range from being deleterious to neutral or even beneficial. We have followed the genetic fate of B chromosomes in the asexual, all-female fish Poecilia formosa over eight generations. In this species, B chromosomes come in the form of one to three tiny microchromosomes derived from males of the host species that serve as sperm donors for this gynogenetic species. All microchromosomes have centromeric heterochromatin but usually only one has a telomere. Such microchromosomes are stably inherited, while the telomereless are prone to be lost in both the soma and germline. In some cases the stable microchromosome carries a functional gene lending support to the hypothesis that the B chromosomes in P. formosa could increase the genetic diversity of the clonal lineage in this ameiotic organism and to some degree counteract the genomic decay that is supposed to be connected with the lack of recombination.

摘要

B染色体是许多生物体基因组中额外的、通常不稳定的组成部分。然而,它们的起源往往不明,其进化相关性也未得到很好的理解。它们的影响范围可能从有害到中性甚至有益。我们追踪了无性繁殖的全雌鱼墨西哥丽脂鲤中B染色体在八代中的遗传命运。在这个物种中,B染色体以一到三个微小的微染色体形式存在,这些微染色体源自作为该雌核发育物种精子供体的宿主物种的雄性。所有微染色体都有着丝粒异染色质,但通常只有一个有端粒。这样的微染色体能够稳定遗传,而没有端粒的微染色体则容易在体细胞和生殖细胞中丢失。在某些情况下,稳定的微染色体携带一个功能基因,这支持了这样一种假说,即墨西哥丽脂鲤中的B染色体可以增加这种无减数分裂生物体克隆谱系的遗传多样性,并在一定程度上抵消被认为与缺乏重组相关的基因组衰退。

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