超螺旋敏感性的稳态调节协调细菌基因组的转录。
Homeostatic regulation of supercoiling sensitivity coordinates transcription of the bacterial genome.
作者信息
Blot Nicolas, Mavathur Ramesh, Geertz Marcel, Travers Andrew, Muskhelishvili Georgi
机构信息
International University Bremen, Campus Ring 1, 28759 Bremen, Germany.
出版信息
EMBO Rep. 2006 Jul;7(7):710-5. doi: 10.1038/sj.embor.7400729. Epub 2006 Jun 16.
Abstract
Regulation of cellular growth implies spatiotemporally coordinated programmes of gene transcription. A central question, therefore, is how global transcription is coordinated in the genome. The growth of the unicellular organism Escherichia coli is associated with changes in both the global superhelicity modulated by cellular topoisomerase activity and the relative proportions of the abundant DNA-architectural chromatin proteins. Using a DNA-microarray-based approach that combines mutations in the genes of two important chromatin proteins with induced changes of DNA superhelicity, we demonstrate that genomic transcription is tightly associated with the spatial distribution of supercoiling sensitivity, which in turn depends on chromatin proteins. We further demonstrate that essential metabolic pathways involved in the maintenance of growth respond distinctly to changes of superhelicity. We infer that a homeostatic mechanism organizing the supercoiling sensitivity is coordinating the growth-phase-dependent transcription of the genome.
摘要
细胞生长的调控意味着基因转录在时空上的协调程序。因此,一个核心问题是基因组中的全局转录如何协调。单细胞生物大肠杆菌的生长与细胞拓扑异构酶活性调节的全局超螺旋度变化以及丰富的DNA结构染色质蛋白的相对比例变化有关。通过基于DNA微阵列的方法,将两种重要染色质蛋白基因的突变与DNA超螺旋度的诱导变化相结合,我们证明基因组转录与超螺旋敏感性的空间分布紧密相关,而超螺旋敏感性又依赖于染色质蛋白。我们进一步证明,参与维持生长的基本代谢途径对超螺旋度的变化有明显不同的反应。我们推断,一种组织超螺旋敏感性的稳态机制正在协调基因组的生长阶段依赖性转录。
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