Structure-function relationship of KaiC around dawn.

IF 1.6 Q4 BIOPHYSICS Biophysics and physicobiology Pub Date : 2023-12-16 eCollection Date: 2024-01-01 DOI:10.2142/biophysico.bppb-v21.0001
Yoshihiko Furuike, Eiki Yamashita, Shuji Akiyama
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Abstract

KaiC is a multifunctional enzyme functioning as the core of the circadian clock system in cyanobacteria: its N-terminal domain has adenosine triphosphatase (ATPase) activity, and its C-terminal domain has autokinase and autophosphatase activities targeting own S431 and T432. The coordination of these multiple biochemical activities is the molecular basis for robust circadian rhythmicity. Therefore, much effort has been devoted to elucidating the cooperative relationship between the two domains. However, structural and functional relationships between the two domains remain unclear especially with respect to the dawn phase, at which KaiC relieves its nocturnal history through autodephosphorylation. In this study, we attempted to design a double mutation of S431 and T432 that can capture KaiC as a fully dephosphorylated form with minimal impacts on its structure and function, and investigated the cooperative relationship between the two domains in the night to morning phases from many perspectives. The results revealed that both domains cooperate at the dawn phase through salt bridges formed between the domains, thereby non-locally co-activating two events, ATPase de-inhibition and S431 dephosphorylation. Our further analysis using existing crystal structures of KaiC suggests that the states of both domains are not always in one-to-one correspondence at every phase of the circadian cycle, and their coupling is affected by the interactions with KaiA or adjacent subunits within a KaiC hexamer.

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黎明前后 KaiC 的结构-功能关系。
KaiC 是一种多功能酶,是蓝藻昼夜节律钟系统的核心:其 N 端结构域具有腺苷三磷酸酶(ATPase)活性,其 C 端结构域具有针对自身 S431 和 T432 的自激酶和自磷酸酶活性。这些多种生化活动的协调是昼夜节律稳健性的分子基础。因此,人们一直致力于阐明这两个结构域之间的合作关系。然而,这两个结构域之间的结构和功能关系仍不清楚,尤其是在黎明阶段,KaiC 通过自身去磷酸化解除了其夜间历史。在这项研究中,我们尝试设计一种 S431 和 T432 的双突变,这种突变可以捕获完全去磷酸化形式的 KaiC,而对其结构和功能的影响最小,并从多个角度研究了这两个结构域在夜间到黎明期的合作关系。结果发现,在黎明阶段,两个结构域通过在结构域之间形成的盐桥进行合作,从而非局部地共同激活了两个事件,即 ATPase 去抑制和 S431 去磷酸化。我们利用现有的 KaiC 晶体结构进行的进一步分析表明,在昼夜节律周期的每个阶段,两个结构域的状态并不总是一一对应的,它们之间的耦合会受到与 KaiA 或 KaiC 六聚体中相邻亚基的相互作用的影响。
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