Circadian rhythms are the endogenous oscillation of biological reactions and behaviors in most organisms on Earth. Circadian clocks are the pacemakers regulating circadian rhythms, and the transcription-translation dependent feedback loop (TTFL) model was supposed to be the sole model of circadian clocks. However, recent years have witnessed rapid progresses in the study of non-TTFL circadian clocks. The cyanobacterial circadian clock consists of three proteins (KaiA, KaiB, and KaiC), and is extensively studied as a non-TTFL circadian clock model. Although containing only three proteins, the molecular mechanism of the KaiABC circadian clock remains elusive. We recently noticed that KaiA has an auto-inhibition conformation during the oscillation, but how this auto-inhibition is regulated is unclear. Here, we started from the design of light modulated KaiAs to investigate this mechanism. We designed different KaiA constructs fused with the light modulable LOV2 protein, and used light-modulated KaiAs to regulate the phosphorylation and dephosphorylation of KaiC. Our data indicated that the N-terminal domain of KaiA is important for KaiA's reversible off/on switching during the unidirectional oscillation of the KaiABC system. This work provides an updated model to explain the molecular mechanism of the KaiABC circadian clock.
Keywords: Circadian rhythm; LOV2; Oscillator; Post-translational circadian clock; Protein design.
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