Mechanism of sensor kinase CitA transmembrane signaling

Abstract

AbstractMembrane bound histidine kinases (HKs) are ubiquitous sensors of extracellular stimuli in bacteria. Here, we used solid-state NMR in conjunction with crystallography, solution NMR and distance measurements to investigate the transmembrane signaling mechanism of a paradigmatic citrate sensing membrane embedded HK, CitA. Citrate binding in the sensory extracytoplasmic PAS domain (PASp) causes the linker to transmembrane helix 2 (TM2) to adopt a helical conformation. This triggers a piston-like pulling of TM2 and a quaternary structure rearrangement in the cytosolic PAS domain (PASc). Crystal structures of PASc reveal both anti-parallel and parallel dimer conformations. An anti-parallel to parallel transition upon citrate binding agrees with interdimer distances measured in the lipid embedded protein using a site-specific19F label in PASc. These data show how Angstrom scale structural changes in the sensor domain are transmitted across the membrane to be converted and amplified into a nm scale shift in the linker to the phosphorylation subdomain of the kinase.One-Sentence SummaryTransmembrane signal transduction of a PAS-domain containing histidine kinase occurs via a piston-like pulling of a transmembrane helix, and amplification by cytoplasmic PAS domain dimer rearrangement.