利用芥菜基因组探索进化变化的遗传基础。

Using mustard genomes to explore the genetic basis of evolutionary change.

作者信息

Nikolov Lachezar A, Tsiantis Miltos

机构信息

Department of Comparative Development and Genetics, Max Planck Institute for Plant Breeding Research, Cologne 50829, Germany.

出版信息

Curr Opin Plant Biol. 2017 Apr;36:119-128. doi: 10.1016/j.pbi.2017.02.005. Epub 2017 Mar 8.

DOI:10.1016/j.pbi.2017.02.005

PMID:28285128

Abstract

Recent advances in sequencing technologies and gene manipulation tools have driven mustard species into the spotlight of comparative research and have offered powerful insight how phenotypic space is explored during evolution. Evidence emerged for genome-wide signal of transcription factors and gene duplication contributing to trait divergence, e.g., PLETHORA5/7 in leaf complexity. Trait divergence is often manifested in differential expression due to cis-regulatory divergence, as in KNOX genes and REDUCED COMPLEXITY, and can be coupled with protein divergence. Fruit shape in Capsella rubella results from anisotropic growth during three distinct phases. Brassicaceae exhibit novel fruit dispersal strategy, explosive pod shatter, where the rapid movement depends on slow build-up of tension and its rapid release facilitated by asymmetric cell wall thickenings.

摘要

测序技术和基因操作工具的最新进展使芥菜物种成为比较研究的焦点，并为探索进化过程中表型空间提供了有力的见解。有证据表明，转录因子和基因复制的全基因组信号有助于性状分化，例如叶片复杂性中的多胚基因5/7。性状分化通常由于顺式调控差异而表现为差异表达，如在KNOX基因和复杂性降低中，并且可能与蛋白质差异相关联。小花南芥的果实形状源于三个不同阶段的各向异性生长。十字花科植物展现出新颖的果实传播策略，即荚果爆裂，其快速运动取决于张力的缓慢积累以及由不对称细胞壁增厚促进的快速释放。

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利用芥菜基因组探索进化变化的遗传基础。

Using mustard genomes to explore the genetic basis of evolutionary change.

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