Cells of the yeast Saccharomyces cerevisiae are delayed in the G2 phase of the cell cycle following chromosomal DNA damage. This arrest is RAD9-dependent and suggests a signaling mechanism(s) between chromosomal lesions and cell cycling. We examined the global nature of growth inhibition caused by an HO endonuclease-induced double-strand break (DSB) at a 45-bp YZ sequence (from MAT YZ) in a non-yeast region of a dispensable single-copy plasmid. The presence of an unrepaired DSB results in cellular death even though the plasmid is dispensable. Loss of cell viability is partially dependent on the RAD9 gene product. Following induction of the DSB, 40% of RAD+ and 49% of rad9 delta cells [including both unbudded (G1) and budded (S plus G2) cells] did not progress further in the cell cycle. The remaining RAD+ cells progressed to form microcolonies (< 30 cells) containing aberrantly shaped inviable cells. For the rad9 delta mutant, the majority of the remaining cells produced viable colonies accounting for the greater survival of the rad9 delta strain. Based on the profound effects of a single nonchromosomal DNA lesion, this system provides a convenient means for studying the signaling effects of a DNA lesion, as well as for designing strategies for modulating cell proliferation.
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机译:酵母酿酒酵母的细胞在染色体DNA损伤后在细胞周期的G2期被延迟。这种逮捕是RAD9依赖的,并建议染色体损伤和细胞周期之间的信号传导机制。我们检查了由HO内切酶诱导的双链断裂(DSB)在可分配单拷贝质粒的非酵母区域中的45 bp YZ序列(来自MAT YZ)引起的生长抑制的整体性质。即使质粒是可有可无的,未修复的DSB的存在也会导致细胞死亡。细胞活力的丧失部分取决于RAD9基因产物。诱导DSB之后,40%的RAD +和49%的rad9 delta细胞[包括未预算的(G1)和萌芽的(S加G2)细胞]在细胞周期中没有进一步发展。其余的RAD +细胞逐渐形成含有异常形状的存活细胞的微菌落(<30个细胞)。对于rad9 delta突变体,其余大多数细胞会产生活菌落,这说明rad9 delta菌株的存活率更高。基于单个非染色体DNA损伤的深远影响,该系统为研究DNA损伤的信号传导作用以及设计调节细胞增殖的策略提供了方便的方法。
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