错误蛋白质合成的进化后果。
The evolutionary consequences of erroneous protein synthesis.
作者信息
Drummond D Allan, Wilke Claus O
机构信息
FAS Center for Systems Biology, Harvard University, 52 Oxford Street, Cambridge, MA 02138, USA.
出版信息
Nat Rev Genet. 2009 Oct;10(10):715-24. doi: 10.1038/nrg2662.
Abstract
Errors in protein synthesis disrupt cellular fitness, cause disease phenotypes and shape gene and genome evolution. Experimental and theoretical results on this topic have accumulated rapidly in disparate fields, such as neurobiology, protein biosynthesis and degradation and molecular evolution, but with limited communication among disciplines. Here, we review studies of error frequencies, the cellular and organismal consequences of errors and the attendant long-range evolutionary responses to errors. We emphasize major areas in which little is known, such as the failure rates of protein folding, in addition to areas in which technological innovations may enable imminent gains, such as the elucidation of translational missense error frequencies. Evolutionary responses to errors fall into two broad categories: adaptations that minimize errors and their attendant costs and adaptations that exploit errors for the organism's benefit.
摘要
蛋白质合成错误会破坏细胞适应性,导致疾病表型,并影响基因和基因组进化。关于这一主题的实验和理论结果在神经生物学、蛋白质生物合成与降解以及分子进化等不同领域迅速积累,但各学科之间的交流有限。在此,我们综述了关于错误频率、错误对细胞和生物体的影响以及随之而来的对错误的长期进化反应的研究。我们强调了一些知之甚少的主要领域,例如蛋白质折叠的失败率,此外还强调了一些技术创新可能带来即时进展的领域,例如对翻译错义错误频率的阐明。对错误的进化反应可分为两大类:将错误及其附带成本降至最低的适应性变化,以及利用错误为生物体谋利的适应性变化。
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