As a result the γ-phosphoryl-group of the ATP bound to the P-loop is wedged apart from phosphorylation sites and autophosphorylation is disabled,
accordingly. Unraveling of the A-loop as a result of KaiA-binding breaks the interactions and thereby positions ATP in close proximity to the phosphorylation sites enabling phosphorylation (Egli et al., 2013 and Kim et al., 2008). All KaiC proteins, which show a lower conservation of residues important for interaction with KaiA also display variations in the A-loop sequence and residues important for stabilization of the buried A-loop state. This is most obvious in UCYN-A-KaiC and the additional KaiC proteins from Cyanothece and Crocosphaera as well as MED4-KaiC, which has already been demonstrated to display a kinase activity independent of KaiA ( Axmann et al., 2009). Hence intrinsic 17-AAG datasheet phosphorylation of those proteins might be unaffected by KaiA, as it was also demonstrated for the additional KaiC proteins from the freshwater strain Synechocystis sp. PCC 6803 ( Wiegard et al., 2013). Interestingly, the A-loop as well as the stabilizing residues are highly conserved in Trichodesmium-KaiC but the A-loop lacks I497. It was previously shown that single
mutation of this residue causes exposition of the A-loop ( Kim et al., 2008), which implies that Trichodesmium might display an elevated kinase activity. This finding see more raises the question whether KaiA can further stimulate KaiC’s kinase activity in this organism. In respect to KaiA-binding and A-loop conservation KaiC from S. WH 7803 represents an intermediate GBA3 variant between the highly conserved orthologs of S.elongatus-KaiC and the diverged MED4-KaiC. S. WH 7803 is evolutionary related to the genus
Prochlorococcus but still harbors KaiA. Therefore, future studies should address whether the slight divergence observed in S. WH 7803-KaiC already leads to an elevated kinase activity and whether interaction with KaiA is still possible. From that one could conclude whether modification of KaiC forced loss of KaiA or whether loss of KaiA demanded an adaptation of KaiC in Prochlorococcus. However, cell division is controlled in a circadian fashion in S. WH 7803 ( Sweeney and Borgese, 1989) implying a functional Kai oscillator to be present, including KaiA. Dephosphorylation of KaiC occurs at the same active site as phosphorylation (Egli et al., 2012 and Nishiwaki and Kondo, 2012). All KaiC proteins compared here harbor this active site, which basically enables dephosphorylation. Nonetheless KaiC from MED4 could not be dephosphorylated in the presence of KaiB (Axmann et al., 2009). This is very reasonable because KaiB shifts equilibrium to dephosphorylation by impeding access of KaiA (Kitayama et al., 2003 and Xu et al., 2003) and, hence, might be ineffective for those KaiC proteins whose kinase activity is not triggered by KaiA.
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