Chemical-shift-perturbation mapping of the phosphotransfer and catalytic domain interaction in the histidine autokinase CheA from Thermotoga maritima.

Regulating the activity of the histidine autokinase CheA is a central step in bacterial chemotaxis. The CheA autophosphorylation reaction minimally involves two CheA domains, denoted P1 and P4. The kinase domain (P4) binds adenosine triphosphate (ATP) and orients the gamma phosphate for phosphotransfer to a reactive histidine on the phosphoacceptor domain (P1). Three-dimensional triple-resonance experiments allowed sequential assignments of backbone nuclei from P1 and P4 domains as well as the P4 assignments within a larger construct, P3P4, which includes the dimerization domain P3. We have used nuclear magnetic resonance chemical-shift-perturbation mapping to define the interaction of P1 and P3P4 from the hyperthermophile Thermotoga maritima. The observed chemical-shift changes in P1 upon binding suggest that the P1 domain is bound by interactions on the side opposite the histidine that is phosphorylated. The observed shifts in P3P4 upon P1 binding suggest that P1 is bound at a site distinct from the catalytic site on P4. These results argue that the P1 domain is not bound in a mode that leads to productive phosphate transfer from ATP at the catalytic site and imply the presence of multiple binding modes. The binding mode observed may be regulatory or it may reflect the binding mode needed for effective transfer of the histidyl phosphate of P1 to the substrate proteins CheY and CheB. In either case, this work describes the first direct observation of the interaction between P1 and P4 in CheA.