Liao Meimei, Liu Yanqin, Xu Zhancong, Fang Mingxu, Yu Ziqing, Cui Yufan, Sun Zhengda, Huo Ran, Yang Jieyu, Huang Fusheng, Liu Mingming, Zhou Qin, Song Xiaocui, Han Hui, Chen She, Xu Xiaodong, Qin Ximing, He Qun, Ju Dapeng, Wang Tao, Thakkar Nirav, Hardin Paul E, Golden Susan S, Zhang Eric Erquan
National Institute of Biological Sciences, Beijing, China.
Peking University-Tsinghua University-National Institute of Biological Sciences (PTN) Joint Graduate Program, School of Life Sciences, Tsinghua University, Beijing, China.
Nature. 2025 Mar 26. doi: 10.1038/s41586-025-08797-3.
The eukaryotic circadian clock keeps time by using a transcription-translation feedback loop, which exhibits an architecture that is conserved across a diverse range of organisms, including fungi, plants and animals. Despite their mechanistic similarity, the molecular components of these clocks indicate a lack of common ancestry. Our study reveals that RUVBL2, which is a P-loop NTPase enzyme previously shown to affect circadian phase and amplitude as part of mammalian clock super-complexes, influences the circadian period through its remarkably slow ATPase activity, resembling the well-characterized KaiC-based clock in cyanobacteria. A screen of RUVBL2 variants identified arrhythmic, short-period and long-period mutants that altered circadian locomotor activity rhythms following delivery by adeno-associated virus to the murine suprachiasmatic nucleus. Enzymatic assays showed that wild-type RUVBL2 hydrolyses only around 13 ATP molecules a day, a vastly reduced turnover compared with typical ATPases. Notably, physical interactions between RUVBL2 orthologues and core clock proteins in humans, Drosophila and the fungus Neurospora, along with consistent circadian phenotypes of RUVBL2-mutant orthologues across species, reinforce their clock-related function in eukaryotes. Thus, as well as establishing RUVBL2 as a common core component in eukaryotic clocks, our study supports the idea that slow ATPase activity, initially discovered in cyanobacteria, is a shared feature of eukaryotic clocks.
真核生物钟通过转录-翻译反馈回路来计时,这种回路在包括真菌、植物和动物在内的多种生物中展现出保守的结构。尽管这些生物钟在机制上具有相似性,但其分子组成成分显示它们缺乏共同的祖先。我们的研究表明,RUVBL2作为一种P环NTPase酶,先前已被证明作为哺乳动物生物钟超复合体的一部分会影响昼夜节律相位和振幅,它通过其极其缓慢的ATP酶活性影响昼夜节律周期,这类似于蓝细菌中特征明确的基于KaiC的生物钟。对RUVBL2变体的筛选鉴定出了无节律、短周期和长周期突变体,在通过腺相关病毒将其递送至小鼠视交叉上核后,这些突变体会改变昼夜运动活动节律。酶活性测定表明,野生型RUVBL2每天仅水解约13个ATP分子,与典型的ATP酶相比,其周转大大降低。值得注意的是,人类、果蝇和真菌粗糙脉孢菌中RUVBL2直系同源物与核心生物钟蛋白之间的物理相互作用,以及跨物种的RUVBL2突变直系同源物一致的昼夜节律表型,强化了它们在真核生物中与生物钟相关的功能。因此,除了将RUVBL2确立为真核生物钟的一个共同核心成分外,我们的研究还支持了这样一种观点,即最初在蓝细菌中发现的缓慢ATP酶活性是真核生物钟的一个共同特征。
