水平基因转移、扩散与嗜盐古菌物种形成
Horizontal gene transfer, dispersal and haloarchaeal speciation.
作者信息
Papke R Thane, Corral Paulina, Ram-Mohan Nikhil, de la Haba Rafael R, Sánchez-Porro Cristina, Makkay Andrea, Ventosa Antonio
机构信息
Department of Molecular and Cell Biology, University of Connecticut, Storrs, CT 06269, USA.
Department of Microbiology and Parasitology, University of Seville, 41004 Seville, Spain.
出版信息
Life (Basel). 2015 May 19;5(2):1405-26. doi: 10.3390/life5021405.
Abstract
The Halobacteria are a well-studied archaeal class and numerous investigations are showing how their diversity is distributed amongst genomes and geographic locations. Evidence indicates that recombination between species continuously facilitates the arrival of new genes, and within species, it is frequent enough to spread acquired genes amongst all individuals in the population. To create permanent independent diversity and generate new species, barriers to recombination are probably required. The data support an interpretation that rates of evolution (e.g., horizontal gene transfer and mutation) are faster at creating geographically localized variation than dispersal and invasion are at homogenizing genetic differences between locations. Therefore, we suggest that recurrent episodes of dispersal followed by variable periods of endemism break the homogenizing forces of intrapopulation recombination and that this process might be the principal stimulus leading to divergence and speciation in Halobacteria.
摘要
嗜盐菌是一个经过充分研究的古菌纲,众多研究正在揭示其多样性在基因组和地理位置之间的分布情况。有证据表明,物种间的重组不断促进新基因的引入,而在物种内部,这种重组频繁到足以使获得的基因在种群中的所有个体间传播。为了创造永久的独立多样性并产生新物种,可能需要重组障碍。数据支持这样一种解释,即进化速率(例如水平基因转移和突变)在产生地理局部变异方面比扩散和入侵在使不同地点间的遗传差异同质化方面更快。因此,我们认为,随后是不同时期地方特有性的反复扩散事件打破了种群内重组的同质化力量,并且这个过程可能是导致嗜盐菌分化和物种形成的主要刺激因素。
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