Structure, function and FliM interaction studies of CheY6 in Rhodobacter sphaeroides

<p>Bacteria control their swimming direction by signalling from chemoreceptors via a small protein, CheY, to the rotary flagellar motor. <em>Rhodobacter sphaeroides</em> has a complex chemosensory network with two pathways, including three different CheYs controlling a stop-start motor. Deletions of these <i>che</i>Ys result in a non-chemotactic phenotype. CheY₆ is essential for chemotaxis, whereas CheY₃ and CheY₄ have some functional redundancies. Although CheY₆ alone can stop the motor, the presence of either CheY₃ or CheY₄ is required for a chemotactic phenotype. To date, little is known about how these three CheY proteins interact with the flagellar motor, or the switch mechanism used between the inactive and active states.</p> <p>Structural studies of CheY₆ using NMR experiments, highlighted a flexible loop region (residues S109-K118) that is not present in CheY₃, CheY₄ or CheYs in other bacterial species. This elongated loop region was deleted (CheY₆-ΔLoop), and <em>in vivo</em> studies were used to investigate its function. CheY₆ ΔLoop is folded, retains the ability to be phosphorylated by CheA₃, localises at the cytoplasmic chemoreceptor cluster, but appears unable to stop the flagellar motor. Circular dichroism and NMR data suggest that CheY₆-ΔLoop is a folded protein that shows similar peak shifts to wild type CheY₆ upon activation. In wild type CheY₆, residues in this loop show chemical shift changes upon addition of the phosphoryl mimic BeF₃^-, suggesting that the loop is involved in the activation mechanism. </p> <p>The switch mechanism of CheY₆ was probed using multidimensional NMR studies. The active state was mimicked using BeF₃^- . Wild type CheY₆ was shown to undergo structural changes upon addition of BeF₃^-. In particular, the β4 α4-loop and residues located near the phosphorylatable D56 show large changes in chemical shift. Superposition of this loop region revealed possible steric clashes with the N-terminus of FliM. S83 shows evidence of involvement in the switch mechanism. Residual dipolar coupling experiments suggest that the published crystal of CheY₆ in complex with CheA₃, is more like the inactive conformation in solution. CheY has been shown to interact with the motor switch protein FliM in other bacterial species. CheY₆-FliM interactions were probed using a combination of <em>in vitro</em> and <em>in vivo</em> studies. Bacterial two hybrid assays and NMR studies suggest that CheY₆ cannot interact with monomeric FliM. Single molecule total internal reflection microscopy revealed CheY₆ does interact with the motor <em>in vivo</em>.</p> <p>The data in combination suggests a model in which CheY₆-P only interacts with FliM when it is part of the switch ring, and structural changes involved in stopping the motor depend on the large conformational changes in the β4-α4-loop.</p>