由聚球藻属蓝细菌染色体压缩赋予的基因转录昼夜节律。
Circadian rhythms in gene transcription imparted by chromosome compaction in the cyanobacterium Synechococcus elongatus.
作者信息
Smith Rachelle M, Williams Stanly B
机构信息
Department of Biology, Life Science Building, University of Utah, 257 South 1400 East, Salt Lake City, UT 84112, USA.
出版信息
Proc Natl Acad Sci U S A. 2006 May 30;103(22):8564-9. doi: 10.1073/pnas.0508696103. Epub 2006 May 17.
Abstract
In the cyanobacterium Synechococcus elongatus (PCC 7942) the kai genes A, B, and C and the sasA gene encode the functional protein core of the timing mechanism essential for circadian clock regulation of global gene expression. The Kai proteins comprise the central timing mechanism, and the sensor kinase SasA is a primary transducer of temporal information. We demonstrate that the circadian clock also regulates a chromosome compaction rhythm. This chromosome compaction rhythm is both circadian clock-controlled and kai-dependent. Although sasA is required for global gene expression rhythmicity, it is not required for these chromosome compaction rhythms. We also demonstrate direct control by the Kai proteins on the rate at which the SasA protein autophosphorylates. Thus, to generate and maintain circadian rhythms in gene expression, the Kai proteins keep relative time, communicate temporal information to SasA, and may control access to promoter elements by imparting rhythmic chromosome compaction.
摘要
在蓝藻聚球藻(集胞藻属细长聚球藻,PCC 7942)中,kai基因A、B和C以及sasA基因编码了对全球基因表达的昼夜节律调控至关重要的计时机制的功能性蛋白质核心。Kai蛋白构成了中央计时机制,而传感激酶SasA是时间信息的主要传感器。我们证明,生物钟也调节染色体压缩节律。这种染色体压缩节律既受生物钟控制,也依赖于kai基因。虽然sasA基因对于全球基因表达节律是必需的,但对于这些染色体压缩节律并非必需。我们还证明了Kai蛋白对SasA蛋白自身磷酸化速率的直接控制。因此,为了在基因表达中产生并维持昼夜节律,Kai蛋白保持相对时间,将时间信息传递给SasA,并可能通过赋予节律性的染色体压缩来控制对启动子元件的访问。
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