Abstract
Calcium-dependent protein kinase (CPK), representing a group of typical Ca2+ sensors in plants, has been well characterized in plants. CPK is capable of binding to Ca2+, which sequentially activates CPK. CPK-related kinase (CRK) shows protein structures similar to CPK but only contains degenerative EF-hands, which likely makes the activation of CRK Ca2+ independent. Compared with CPK, CRK is barely functionally analyzed. In this study, we systematically investigated CRK genes in the Arabidopsis genome. We found that CRK appeared to emerge in land plants, suggesting CPK and CRK are divided at very early stages during plant evolution. In Arabidopsis, the detailed analysis of the calmodulin-like domain of CRK indicated the substitutions of key amino acid residues in its EF-hands result in disrupted Ca2+ association. Next, by using a YFP tag, we found that all Arabidopsis CRK proteins were localized at the plasma membrane. After cloning the promoters of all eight CRK genes, we found that CRKs were widely expressed at all stages of Arabidopsis by using GUS staining. Furthermore, the kinase activity of CRK was examined by using phospho-antibody and Pro-Q staining. CRK was shown to possess high autophosphorylation, which was not affected by the presence of Ca2+. Moreover, we analyzed the cis-elements of CRK promoters and discovered that stress signals potentially regulate the expression of CRK genes. Consistently, by using quantitative real-time PCR (qPCR), we found a number of CRK genes were regulated by a variety of biotic and abiotic treatments such as flg22, ABA, drought, salt, and high and low temperatures. Furthermore, by utilizing proteomic approaches, we identified more than 100 proteins that interacted with CRK5 in planta. Notably, RLK and channels/transporters were found in CRK5-containing complexes, suggesting they function upstream and downstream of CRK, respectively.