KaiA Protein of Circadian Rhythm

KaiA is one of the essential proteins in the circadian rhythm of cyanobacterias. It can regulate the process of KaiC’s phosphorylation and dephosphorylation together with KaiB and other proteins in our system, and then drive the cyanobacterias into subjective dawn or dusk. We have optimized it in yeast.

Sequence and Features

Biology and Usage

Overview of Cyanobacterias' circadian rhythm

Figure 1. 机理图

Organisms are adapted to the relentless cycles of day and night, because they evolved timekeeping systems called circadian clocks, which regulate biological activities with ~24-hour rhythms. The clock of cyanobacteria is driven by a three-protein oscillator composed of only three protein KaiA, KaiB and KaiC, which together generate a circadian rhythm of KaiC phosphorylation at residues serine 431 and threonine 432 in the CII dimain. KaiA promotes KaiC (auto)phosphorylation during the subjective day, whereas KaiB provides negative feedback to inhibit KaiA and promotes KaiC (auto)dephosphorylation during the subjective night. The 24-h KaiC phosphorylation pattern can be reconstituted in vitro by merely combining the three Kai proteins and ATP, suggesting that the phosphorylation cycle is the fundamental timekeeping mechanism in cyanobacteria. Like KaiA, KaiB is also involved in regulating two antagonistic clock-output proteins--SasA and CikA, which reciprocally control the master regulator of transcription RpaA.

Usage of Life Tik Tok (Cyanobacterias' circadian rhythm in yeast)

About Life Tik Tok

Figure 2. 分子基础+下游应用

Life Tik Tok is a circadian rhythm that is established in yeast by iGEM Tianjin, 2018. It enables to regular the biological activities in yeast under the control of proteins in KaiABC oscillator. Learn more about LTT and click here.

Intereaction between the proteins

Stepwise binding of two KaiA dimers triggers KaiC autophosphorylation at Thr432 and Ser431 (I). These phosphorylation events enable cooperative binding of fold-switched KaiB monomers to the KaiC-CI domain, forming the KaiCB complex (II). KaiCB provides a scaffold for the successive sequestration of KaiA in ternary KaiCBA assemblies, concurring with a rearrangement of the KaiA PsR domains (III). KaiA sequestration promotes KaiC autodephosphorylation, resulting in the regeneration of free KaiC through release of KaiBA subcomplexes (IV).Temporal information from the oscillator is transmitted to downstream genes via the histidine protein kinase SasA (Synechococcus adaptive sensor A), whose autophosphorylation is stimulated by interaction with KaiC. Phosphorylated SasA in turn transfers a phosphoryl group to RpaA (regulator of phycobilisome association A) , a transcription factor that directly regulates the expression of approximately 100 genes. Moreover, RpaA indirectly regulates the expression of nearly all genes in the genome. Disruption of sasA also results in severely damped gene expression rhythms. Surprisingly, the phosphorylation state of RpaA, and subsequently its activity, have been shown to be dependent on CikA, which was primarily thought to be involved in entrainment.

Reconstruction of Life Tik Tok in yeast

Origin of KaiA

Characterization of Life Tik Tok

Reporters' measurement in yeast

Characterization of Life Tik Tok

References