Abstract
The histidine protein kinase CheA plays an essential role in stimulus-response coupling during bacterial chemotaxis. The kinase is a homodimer that catalyzes the reversible transfer of a gamma-phosphoryl group from ATP to the N-3 position of one of its own histidine residues. Kinetic studies of rates of autophosphorylation show a second order dependence on CheA concentrations at submicromolar levels that is consistent with dissociation of the homodimer into inactive monomers. The dissociation was confirmed by chemical cross-linking studies. The dissociation constant (CheA2<==>2CheA; KD = 0.2-0.4 microM) was not affected by nucleotide binding, histidine phosphorylation, or binding of the response regulator, CheY. The turnover number per active site within a dimer (assuming 2 independent sites/dimer) at saturating ATP was approximately 10/min. The kinetics of autophosphorylation and ATP/ADP exchange indicated that the dissociation constants of ATP and ADP bound to CheA were similar (KD values approximately 0.2-0.3 mM), whereas ATP had a reduced affinity for CheA approximately P (KD approximately 0.8 mM) compared with ADP (KD approximately 0.3 mM). The rates of phosphotransfer from bound ATP to the phosphoaccepting histidine and from the phosphohistidine back to ADP seem to be essentially equal (kcat approximately 10 min-1).
Highlights
The histidine protein kinase CheA plays an essential role in stimulus-response coupling during bacterial chemotaxis
The protein purified from Escherichia coli or Salmonella typhimurium catalyzes the transfer of the ␥-phosphoryl group from ATP to one of its own histidine residues, His48 [3,4,5]
The kinase domain is homologous to corresponding domains in a large family of histidine protein kinases that function in signal transduction to provide phosphoryl groups for a second family of proteins with regulator domains that are homologous to CheY [15, 16]
Summary
The histidine protein kinase CheA plays an essential role in stimulus-response coupling during bacterial chemotaxis. The kinase is a homodimer that catalyzes the reversible transfer of a ␥-phosphoryl group from ATP to the N-3 position of one of its own histidine residues. The dissociation constant (CheA2 7 2CheA; KD ؍0.2– 0.4 M) was not affected by nucleotide binding, histidine phosphorylation, or binding of the response regulator, CheY. CheA forms a 2:2:2 complex with an 18,000 molecular weight protein, CheW, and the signaling domain of membrane chemoreceptors [6] Within this complex CheA autophosphorylation is regulated by the signaling state of the receptor [7, 8]. Whether CheA is in a complex with CheW and receptor or alone in solution, the phosphoryl group is rapidly transferred from His to an aspartate residue, Asp, in the chemotaxis response regulator protein, CheY [4, 9, 10]. Our results are consistent with the notion that dimer formation is an essential feature of CheA function in bacterial chemotaxis
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