细胞转变的承诺先于全基因组转录变化。
Commitment to a cellular transition precedes genome-wide transcriptional change.
机构信息
Department of Applied Physics, Stanford University, Stanford CA 94305, USA.
出版信息
Mol Cell. 2011 Aug 19;43(4):515-27. doi: 10.1016/j.molcel.2011.06.024.
Abstract
In budding yeast, commitment to cell division corresponds to activating the positive feedback loop of G1 cyclins controlled by the transcription factors SBF and MBF. This pair of transcription factors has over 200 targets, implying that cell-cycle commitment coincides with genome-wide changes in transcription. Here, we find that genes within this regulon have a well-defined distribution of transcriptional activation times. Combinatorial use of SBF and MBF results in a logical OR function for gene expression and partially explains activation timing. Activation of G1 cyclin expression precedes the activation of the bulk of the G1/S regulon, ensuring that commitment to cell division occurs before large-scale changes in transcription. Furthermore, we find similar positive feedback-first regulation in the yeasts S. bayanus and S. cerevisiae, as well as human cells. The widespread use of the feedback-first motif in eukaryotic cell-cycle control, implemented by nonorthologous proteins, suggests its frequent deployment at cellular transitions.
摘要
在出芽酵母中,细胞分裂的决定对应于激活由转录因子 SBF 和 MBF 控制的 G1 细胞周期蛋白的正反馈环。这对转录因子有超过 200 个靶标,这意味着细胞周期的决定与转录的全基因组变化同时发生。在这里,我们发现这个调控子内的基因具有明确的转录激活时间分布。SBF 和 MBF 的组合使用导致基因表达的逻辑“或”功能,并部分解释了激活时间。G1 细胞周期蛋白表达的激活先于 G1/S 调控子的大部分激活,确保在大规模转录变化之前进行细胞分裂的决定。此外,我们还在酵母 S. bayanus 和 S. cerevisiae 以及人类细胞中发现了类似的正反馈优先调控。这种非同源蛋白在真核细胞周期控制中广泛使用的反馈优先模式表明,它在细胞转变中经常被使用。
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