跳跃叉在反向重复序列处结合。
Leaping forks at inverted repeats.
机构信息
Fondazione IFOM, Istituto FIRC di Oncologia Molecolare, 20139 Milan, Italy.
出版信息
Genes Dev. 2010 Jan 1;24(1):5-9. doi: 10.1101/gad.1884810.
Abstract
Genome rearrangements are often associated with genome instability observed in cancer and other pathological disorders. Different types of repeat elements are common in genomes and are prone to instability. S-phase checkpoints, recombination, and telomere maintenance pathways have been implicated in suppressing chromosome rearrangements, but little is known about the molecular mechanisms and the chromosome intermediates generating such genome-wide instability. In the December 15, 2009, issue of Genes & Development, two studies by Paek and colleagues (2861-2875) and Mizuno and colleagues (pp. 2876-2886), demonstrate that nearby inverted repeats in budding and fission yeasts recombine spontaneously and frequently to form dicentric and acentric chromosomes. The recombination mechanism underlying this phenomenon does not appear to require double-strand break formation, and is likely caused by a replication mechanism involving template switching.
摘要
基因组重排通常与癌症和其他病理紊乱中观察到的基因组不稳定性有关。不同类型的重复元件在基因组中很常见,并且容易不稳定。S 期检查点、重组和端粒维持途径已被牵涉到抑制染色体重排,但对于产生这种全基因组不稳定性的分子机制和染色体中间体知之甚少。在 2009 年 12 月 15 日的《基因与发育》杂志上,Paek 及其同事的两项研究(2861-2875)和 Mizuno 及其同事的研究(第 2876-2886 页)表明,出芽酵母和裂殖酵母中附近的反向重复序列会自发且频繁地重组,形成双中心和无着丝粒染色体。这种现象的重组机制似乎不需要双链断裂的形成,很可能是由涉及模板转换的复制机制引起的。
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本文引用的文献
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2
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