Ligand-induced conformational changes in the Bacillus subtilis chemoreceptor McpB determined by disulfide crosslinking in vivo.

Previously, we characterized the organization of the transmembrane (TM) domain of the Bacillus subtilis chemoreceptor McpB using disulfide crosslinking. Cysteine residues were engineered into serial positions along the two helices through the membrane, TM1 and TM2, as well as double mutants in TM1 and TM2, and the extent of crosslinking determined to characterize the organization of the TM domain. In this study, the organization of the TM domain was studied in the presence and absence of ligand to address what ligand-induced structural changes occur. We found that asparagine caused changes in crosslinking rate on all residues along the TM1-TM1' helical interface, whereas the crosslinking rate for almost all residues along the TM2-TM2' interface did not change. These results indicated that helix TM1 rotated counterclockwise and that TM2 did not move in respect to TM2' in the dimer on binding asparagine. Interestingly, intramolecular crosslinking of paired substitutions in 34/280 and 38/273 were unaffected by asparagine, demonstrating that attractant binding to McpB did not induce a "piston-like" vertical displacement of TM2 as seen for Trg and Tar in Escherichia coli. However, these paired substitutions produced oligomeric forms of receptor in response to ligand. This must be due to a shift of the interface between different receptor dimers, within previously suggested trimers of dimers, or even higher order complexes. Furthermore, the extent of disulfide bond formation in the presence of asparagine was unaffected by the presence of the methyl-modification enzymes, CheB and CheR, or the coupling proteins, CheW and CheV, demonstrating that these proteins must have local structural effects on the cytoplasmic domain that is not translated to the entire receptor. Finally, disulfide bond formation was also unaffected by binding proline to McpC. We conclude that ligand-binding induced a conformational change in the TM domain of McpB dimers as an excitation signal that is likely propagated within the cytoplasmic region of receptors and that subsequent adaptational events do not affect this new TM domain conformation.

Receptor conformational changes enhance methylesterase activity during chemotaxis by Bacillus subtilis.

Addition and removal of the attractant asparagine causes methanol formation as a consequence of methylation and demethylation of conserved glutamate residues in the Bacillus subtilis chemotaxis receptor McpB C-terminal domain. We found that methanol was released on both addition and removal of asparagine even when the response regulator domain of CheB was removed (to produce CheB(141-357)). Thus, in undergoing the transition from unbound receptor to ligand-bound adapted receptor, the receptor must pass through a state of heightened susceptibility to demethylation by CheB that is independent of phosphorylation. The same result occurred when the aspartate phosphorylation site of CheB, Asp54, had been mutated to an asparagine residue, provided the enzyme was sufficiently induced. However, no methanol release was observed for an active site point mutant, cheB(S173C), in response to addition or removal of asparagine even when induced. Finally, methanol release was observed only for attractant addition in a mutant background lacking the coupling proteins, CheW and CheV, provided CheB(141-357) was present. Thus, on attractant addition, methanol must arise from a transient conformation of the receptor C-terminal domain that is an intrinsic property of the receptor; on attractant removal, however, methanol must arise from a different transient conformation, one dependent on the presence of coupling proteins.

Bacillus subtilis hydrolyzes CheY-P at the location of its action, the flagellar switch.

In this report we show that in Bacillus subtilis the flagellar switch, which controls direction of flagellar rotation based on levels of the chemotaxis primary response regulator, CheY-P, also causes hydrolysis of CheY-P to form CheY and Pi. This task is performed in Escherichia coli by CheZ, which interestingly enough is primarily located at the receptors, not at the switch. In particular we have identified the phosphatase as FliY, which resembles E. coli switch protein FliN only in its C-terminal part, while an additional N-terminal domain is homologous to another switch protein FliM and to CheC, a protein found in the archaea and many bacteria but not in E. coli. Previous E. coli studies have localized the CheY-P binding site of the switch to FliM residues 6-15. These residues are almost identical to the residues 6-15 in both B. subtilis FliM and FliY. We were able to show that both of these proteins are capable of binding CheY-P in vitro. Deletion of this binding region in B. subtilis mutant fliM caused the same phenotype as a cheY mutant (clockwise flagellar rotation), whereas deletion of it in fliY caused the opposite. We showed that FliY increases the rate of CheY-P hydrolysis in vitro. Consequently, we imagine that the duration of enhanced CheY-P levels caused by activation of the CheA kinase upon attractant binding to receptors, is brief due both to adaptational processes and to phosphatase activity of FliY.

Transmembrane organization of the Bacillus subtilis chemoreceptor McpB deduced by cysteine disulfide crosslinking.

The Bacillus subtilis chemoreceptor McpB is a dimer of identical subunits containing two transmembrane (TM) segments (TM1, residues 17-34: TM2, residues 280-302) in each monomer with a 2-fold axis of symmetry. To study the organization of the TM domains, the wild-type receptor was mutated systematically at the membrane bilayer/extracytoplasmic interface with 15 single cysteine (Cys) substitutions in each of the two TM domains. Each single Cys substitution was capable of complementing a null allele in vivo, suggesting that no significant perturbation of the native tertiary or quaternary structure of the chemoreceptor was introduced by the mutations. On the basis of patterns of disulfide crosslinking between subunits of the dimeric receptor, an alpha-helical interface was identified between TM1 and TM1' (containing residues 32, 36, 39, and 43) and between TM2 and TM2' (containing residues 276, 277, 280, 283 and 286). Pairs of cysteine substitutions (positions 34/280 and 38/273) in TM1 and TM2 were used to further elucidate specific contacts within a monomer subunit, enabling a model to be constructed defining the organization of the TM domain. Crosslinking of residues that were 150-180 degrees removed from position 32 (positions 37, 41, and 44) suggested that the receptors may be organized as an array of trimers of dimers in vivo. All crosslinking was unaffected by deletion of cheB and cheR (loss of receptor demethylation/methylation enzymes) or by deletion of cheW and cheV (loss of proteins that couple receptors with the autophosphorylating kinase). These findings indicate that the organization of the transmembrane region and the stability of the quaternary complex of receptors are independent of covalent modifications of the cytoplasmic domain and conformations in the cytoplasmic domain induced by the coupling proteins.