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本文引用的文献

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通过晶体学和诱变分析鉴定生物钟蛋白KaiC中的关键磷酸化位点。

Identification of key phosphorylation sites in the circadian clock protein KaiC by crystallographic and mutagenetic analyses.

作者信息

Xu Yao, Mori Tetsuya, Pattanayek Rekha, Pattanayek Sabuj, Egli Martin, Johnson Carl Hirschie

机构信息

Department of Biological Sciences, Vanderbilt University, Nashville, TN 37235, USA.

出版信息

Proc Natl Acad Sci U S A. 2004 Sep 21;101(38):13933-8. doi: 10.1073/pnas.0404768101. Epub 2004 Sep 3.

DOI:10.1073/pnas.0404768101

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC518856/

Abstract

In cyanobacteria, KaiC is an essential hexameric clock protein that forms the core of a circadian protein complex. KaiC can be phosphorylated, and the ratio of phospho-KaiC to non-phospho-KaiC is correlated with circadian period. Structural analyses of KaiC crystals identify three potential phosphorylation sites within a 10-A radius of the ATP binding regions that are at the T432, S431, and T426 residues in the KaiCII domains. When these residues are mutated by alanine substitution singly or in combination, KaiC phosphorylation is altered, and circadian rhythmicity is abolished. These alanine substitutions do not prevent KaiC from hexamerizing. Intriguingly, the ability of KaiC overexpression to repress its own promoter is also not prevented by alanine substitutions at these sites, implying that the capability of KaiC to repress its promoter is not sufficient to allow the clockwork to oscillate. The KaiC structure and the mutational analysis suggest that S431 and T426 may share a phosphate that can shuttle between these two residues. Because the phosphorylation status of KaiC oscillates over the daily cycle, and KaiC phosphorylation is essential for clock function as shown here, daily modulations of KaiC activity by phosphorylation at T432 and S431/T426 seem to be key components of the circadian clockwork in cyanobacteria.

摘要

在蓝细菌中，KaiC是一种必需的六聚体时钟蛋白，构成昼夜节律蛋白复合体的核心。KaiC可以被磷酸化，磷酸化KaiC与非磷酸化KaiC的比例与昼夜节律周期相关。对KaiC晶体的结构分析确定了ATP结合区域半径10埃范围内的三个潜在磷酸化位点，位于KaiCII结构域的T432、S431和T426残基处。当这些残基单独或组合被丙氨酸替代突变时，KaiC的磷酸化发生改变，昼夜节律性被消除。这些丙氨酸替代并不阻止KaiC形成六聚体。有趣的是，这些位点的丙氨酸替代也不会阻止KaiC过表达对其自身启动子的抑制作用，这意味着KaiC抑制其启动子的能力不足以使时钟机制振荡。KaiC的结构和突变分析表明，S431和T426可能共享一个可以在这两个残基之间穿梭的磷酸基团。由于KaiC的磷酸化状态在每日周期中振荡，并且如本文所示KaiC磷酸化对时钟功能至关重要，因此T432和S431/T426处的磷酸化对KaiC活性的每日调节似乎是蓝细菌昼夜节律时钟机制的关键组成部分。