跳跃基因与表观遗传学：迈向新物种。

Jumping genes and epigenetics: Towards new species.

机构信息

CNRS, UMR558, Laboratoire de Biométrie et Biologie Evolutive, Université Lyon 1, Villeurbanne, France.

出版信息

Gene. 2010 Apr 1;454(1-2):1-7. doi: 10.1016/j.gene.2010.01.003. Epub 2010 Jan 25.

DOI:10.1016/j.gene.2010.01.003

PMID:20102733

Abstract

Transposable elements (TEs) are responsible for rapid genome remodelling by the creation of new regulatory gene networks and chromosome restructuring. TEs are often regulated by the host through epigenetic systems, but environmental changes can lead to physiological and, therefore, epigenetic stress, which disrupt the tight control of TEs. The resulting TE mobilization drives genome restructuring that may sometimes provide the host with an innovative genetic escape route. We suggest that macroevolution and speciation might therefore originate when the host relaxes its epigenetic control of TEs. To understand the impact of TEs and their importance in host genome evolution, it is essential to study TE epigenetic variation in natural populations. We propose to focus on recent data that demonstrate the correlation between changes in the epigenetic control of TEs in species/populations and genome evolution.

摘要

转座元件 (TEs) 通过创建新的调控基因网络和染色体结构重排，导致了基因组的快速重塑。TEs 通常受到宿主通过表观遗传系统的调控，但环境变化会导致生理和因此的表观遗传应激，从而破坏 TEs 的紧密控制。由此产生的 TE 动员推动了基因组结构重排，这有时可能为宿主提供了一种创新的遗传逃逸途径。因此，我们认为当宿主放松对 TEs 的表观遗传控制时，宏观进化和物种形成可能就会产生。为了了解 TEs 的影响及其在宿主基因组进化中的重要性，研究自然种群中 TE 的表观遗传变异至关重要。我们建议将重点放在最近的数据上，这些数据表明了物种/种群中 TE 表观遗传调控变化与基因组进化之间的相关性。

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跳跃基因与表观遗传学：迈向新物种。

Jumping genes and epigenetics: Towards new species.

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