Motility Protein Complexes in the Bacterial Flagellar Motor

Among the many proteins needed for the assembly and function of bacterial flagella, only five have been suggested to be involved in torque generation. These are MotA, MotB, FliG, FliM and FliN. In this study, we have probed binding interactions among these proteins, by using protein fusions to glutathioneS-transferase or to oligo-histidine, in conjunction with co-isolation assays. The results show that FliG, FliM and FliN all bind to each other, and that each also self-associates. MotA and MotB also bind to each other, and MotA interacts, but only weakly, with FliG and FliM. Taken together with previous genetic, physiological and ultrastructural studies, these results provide strong support for the view that FliG, FliM and FliN function together in a complex on the rotor of the flagellar motor, whereas MotA and MotB form a distinct complex that functions as the stator. Torque generation in the flagellar motor is thus likely to involve interactions between these two protein complexes.     

Regulated underexpression and overexpression of the FliN protein of Escherichia coli and evidence for an interaction between FliN and FliM in the flagellar motor.

The FliN protein of Escherichia coli is essential for the assembly and function of flagella. Here, we report the effects of regulated underexpression and overexpression of FliN in a fliN null strain. Cells that lack the FliN protein do not make flagella. When FliN is underexpressed, cells produce relatively few flagella and those made are defective, rotating at subnormal, rapidly varying speeds. These results are similar to what was seen previously when the flagellar protein FliM was underexpressed and unlike what was seen when the motility proteins MotA and MotB were underexpressed. Overexpression of FliN impairs motility and flagellation, as has been reported previously for FliM, but when FliN and FliM are co-overexpressed, motility is much less impaired. This and additional evidence presented indicate that FliM and FliN are associated in the flagellar motor, in a structure distinct from the MotA/MotB torque generators. A recent study showed that FliN might be involved in the export of flagellar components during assembly (A. P. Vogler, M. Homma, V. M. Irikura, and R. M. Macnab, J. Bacteriol. 173:3564-3572, 1991). We show here that approximately 50 amino acid residues from the amino terminus of FliN are dispensable for function and that the remaining, essential part of FliN has sequence similarity to a part of Spa33, a protein that functions in transmembrane export in Shigella flexneri. Thus, FliN might function primarily in flagellar export, rather than in torque generation, as has sometimes been supposed.     

Function of Proline Residues of MotA in Torque Generation by the Flagellar Motor of Escherichia coli

Bacterial flagellar motors obtain energy for rotation from the membrane gradient of protons or, in some species, sodium ions. The molecular mechanism of flagellar rotation is not understood. MotA and MotB are integral membrane proteins that function in proton conduction and are believed to form the stator of the motor. Previous mutational studies identified two conserved proline residues in MotA (Pro 173 and Pro 222 in the protein from Escherichia coli) and a conserved aspartic acid residue in MotB (Asp 32) that are important for function. Asp 32 of MotB probably forms part of the proton path through the motor. To learn more about the roles of the conserved proline residues of MotA, we examined motor function in Pro 173 and Pro 222 mutants, making measurements of torque at high load, speed at low and intermediate loads, and solvent-isotope effects (D2O versus H2O). Proton conduction by wild-type and mutant MotA-MotB channels was also assayed, by a growth defect that occurs upon overexpression. Several different mutations of Pro 173 reduced the torque of the motor under high load, and a few prevented motor rotation but still allowed proton flow through the MotA-MotB channels. These and other properties of the mutants suggest that Pro 173 has a pivotal role in coupling proton flow to motor rotation and is positioned in the channel near Asp 32 of MotB. Replacements of Pro 222 abolished function in all assays and were strongly dominant. Certain Pro 222 mutant proteins prevented swimming almost completely when expressed at moderate levels in wild-type cells. This dominance might be caused by rotor-stator jamming, because it was weaker when FliG carried a mutation believed to increase rotor-stator clearance. We propose a mechanism for torque generation, in which specific functions are suggested for the proline residues of MotA and Asp32 of MotB.     

Conformational change in the stator of the bacterial flagellar motor.

MotA and MotB are integral membrane proteins of Escherichia coli that form the stator of the proton-fueled flagellar rotary motor. The motor contains several MotA/MotB complexes, which function independently to conduct protons across the cytoplasmic membrane and couple proton flow to rotation. MotB contains a conserved aspartic acid residue, Asp32, that is critical for rotation. We have proposed that the protons energizing the motor interact with Asp32 of MotB to induce conformational changes in the stator that drive movement of the rotor. To test for conformational changes, we examined the protease susceptibility of MotA in membrane-bound complexes with either wild-type MotB or MotB mutated at residue 32. Small, uncharged replacements of Asp32 in MotB (D32N, D32A, D32G, D32S, or D32C) caused a significant change in the conformation of MotA, as evidenced by a change in the pattern of proteolytic fragments. The conformational change does not require any flagellar proteins besides MotA and MotB, as it was still seen in a strain that expresses no other flagellar genes. It affects a cytoplasmic domain of MotA that contains residues known to interact with the rotor, consistent with a role in the generation of torque. Influences of key residues of MotA on conformation were also examined. Pro173 of MotA, known to be important for rotation, is a significant determinant of conformation: Dominant Pro173 mutations, but not recessive ones, altered the proteolysis pattern of MotA and also prevented the conformational change induced by Asp32 replacements. Arg90 and Glu98, residues of MotA that engage in electrostatic interactions with the rotor, appear not to be strong determinants of conformation of the MotA/MotB complex in membranes. We note sequence similarity between MotA and ExbB, a cytoplasmic-membrane protein that energizes outer-membrane transport in Gram-negative bacteria. ExbB and associated proteins might also employ a mechanism involving proton-driven conformational change.     

Domain Analysis of the FliM Protein of Escherichia coli

The FliM protein of Escherichia coli is required for the assembly and function of flagella. Genetic analyses and binding studies have shown that FliM interacts with several other flagellar proteins, including FliN, FliG, phosphorylated CheY, other copies of FliM, and possibly MotA and FliF. Here, we examine the effects of a set of linker insertions and partial deletions in FliM on its binding to FliN, FliG, CheY, and phospho-CheY and on its functions in flagellar assembly and rotation. The results suggest that FliM is organized into multiple domains. A C-terminal domain of about 90 residues binds to FliN in coprecipitation experiments, is most stable when coexpressed with FliN, and has some sequence similarity to FliN. This C-terminal domain is joined to the rest of FliM by a segment (residues 237 to 247) that is poorly conserved, tolerates linker insertion, and may be an interdomain linker. Binding to FliG occurs through multiple segments of FliM, some in the C-terminal domain and others in an N-terminal domain of 144 residues. Binding of FliM to CheY and phospho-CheY was complex. In coprecipitation experiments using purified FliM, the protein bound weakly to unphosphorylated CheY and more strongly to phospho-CheY, in agreement with previous reports. By contrast, in experiments using FliM in fresh cell lysates, the protein bound to unphosphorylated CheY about as well as to phospho-CheY. Determinants for binding CheY occur both near the N terminus of FliM, which appears most important for binding to the phosphorylated protein, and in the C-terminal domain, which binds more strongly to unphosphorylated CheY. Several different deletions and linker insertions in FliM enhanced its binding to phospho-CheY in coprecipitation experiments with protein from cell lysates. This suggests that determinants for binding phospho-CheY may be partly masked in the FliM protein as it exists in the cytoplasm. A model is proposed for the arrangement and function of FliM domains in the flagellar motor.     

Interactions between C ring proteins and export apparatus components: a possible mechanism for facilitating type III protein export

The flagellar switch proteins of Salmonella, FliG, FliM and FliN, participate in the switching of motor rotation, torque generation and flagellar assembly/export. FliN has been implicated in the flagellar export process. To address this possibility, we constructed 10-amino-acid scanning deletions and larger truncations over the C-terminal domain of FliN. Except for the last deletion variant, all other variants were unable to complement a fliN null strain or to restore the export of flagellar proteins. Most of the deletions showed strong negative dominance effects on wild-type cells. FliN was found to associate with FliH, a flagellar export component that regulates the ATPase activity of FliI. The binding of FliM to FliN does not interfere with this FliN-FliH interaction. Furthermore, a five-protein complex consisting of FliG, His-tagged FliM, FliN, FliH and FliI was purified by nickel-affinity chromatography. FliJ, a putative general chaperone, is bound to FliM even in the absence of FliH. The importance of the C ring as a possible docking site for export substrates, chaperones and FliI through FliH for their efficient delivery to membrane components of the export apparatus is discussed.     

Regulated underexpression of the FliM protein of Escherichia coli and evidence for a location in the flagellar motor distinct from the MotA/MotB torque generators.

The FliM protein of Escherichia coli is essential for the assembly and function of flagella. Here, we report the effects of controlled low-level expression of FliM in a fliM null strain. Disruption of the fliM gene abolishes flagellation. Underexpression of FliM causes cells to produce comparatively few flagella, and most flagella built are defective, producing subnormal average torque and fluctuating rapidly in speed. The results imply that in a normal flagellar motor, multiple molecules of FliM are present and can function independently to some degree. The speed fluctuations indicate that stable operation requires most, possibly all, of the normal complement of FliM. Thus, the FliM subunits are not as fully independent as the motility proteins MotA and MotB characterized in earlier work, suggesting that FliM occupies a location in the motor distinct from the MotA/MotB torque generators. Several mutations in fliM previously reported to cause flagellar paralysis in Salmonella typhimurium (H. Sockett, S. Yamaguchi, M. Kihara, V.M. Irikura, and R. M. Macnab, J. Bacteriol. 174:793-806, 1992) were made and characterized in E. coli. These mutations did not cause flagellar paralysis in E. coli; their phenotypes were more complex and suggest that FliM is not directly involved in torque generation.     

Deletion analysis of the FliM flagellar switch protein of Salmonella typhimurium.

The flagellar switch of Salmonella typhimurium and Escherichia coli is composed of three proteins, FliG, FliM, and FliN. The switch complex modulates the direction of flagellar motor rotation in response to information about the environment received through the chemotaxis signal transduction pathway. In particular, chemotaxis protein CheY is believed to bind to switch protein FliM, inducing clockwise filament rotation and tumbling. To investigate the function of FliM and its interactions with FliG and FliN, we engineered a series of 34 FliM deletion mutant proteins, each lacking a different 10-amino-acid segment. We have determined the phenotype associated with each mutant protein, the ability of each mutant protein to interfere with the motility of wild-type cells, and the effect of additional FliG and FliN on the function of selected FliM mutant proteins. Overall, deletions at the N terminus produced a counterclockwise switch bias, deletions in the central region of the protein produced poorly motile or nonflagellate cells, and deletions near the C terminus produced only nonflagellate cells. On the basis of this evidence and the results of a previous study of spontaneous FliM mutants (H. Sockett, S. Yamaguchi, M. Kihara, V. M. Irikura, and R. M. Macnab, J. Bacteriol. 174:793-806, 1992), we propose a division of the FliM protein into four functional regions: an N-terminal region primarily involved in switching, an extended N-terminal region involved in switching and assembly, a middle region involved in switching and motor rotation, and a C-terminal region primarily involved in flagellar assembly.     

Requirements for conversion of the Na(+)-driven flagellar motor of Vibrio cholerae to the H(+)-driven motor of Escherichia coli

Bacterial flagella are powered by a motor that converts a transmembrane electrochemical potential of either H(+) or Na(+) into mechanical work. In Escherichia coli, the MotA and MotB proteins form the stator and function in proton translocation, whereas the FliG protein is located on the rotor and is involved in flagellar assembly and torque generation. The sodium-driven polar flagella of Vibrio species contain homologs of MotA and MotB, called PomA and PomB, and also contain two other membrane proteins called MotX and MotY, which are essential for motor rotation and that might also function in ion conduction. Deletions in pomA, pomB, motX, or motY in Vibrio cholerae resulted in a nonmotile phenotype, whereas deletion of fliG gave a nonflagellate phenotype. fliG genes on plasmids complemented fliG-null strains of the parent species but not fliG-null strains of the other species. FliG-null strains were complemented by chimeric FliG proteins in which the C-terminal domain came from the other species, however, implying that the C-terminal part of FliG can function in conjunction with the ion-translocating components of either species. A V. cholerae strain deleted of pomA, pomB, motX, and motY became weakly motile when the E. coli motA and motB genes were introduced on a plasmid. Like E. coli, but unlike wild-type V. cholerae, motility of some V. cholerae strains containing the hybrid motor was inhibited by the protonophore carbonyl cyanide m-chlorophenylhydrazone under neutral as well as alkaline conditions but not by the sodium motor-specific inhibitor phenamil. We conclude that the E. coli proton motor components MotA and MotB can function in place of the motor proteins of V. cholerae and that the hybrid motors are driven by the proton motive force.     

Torque generation in the flagellar motor of Escherichia coli: evidence of a direct role for FliG but not for FliM or FliN.

Among the many proteins needed for assembly and function of bacterial flagella, FliG, FliM, and FliN have attracted special attention because mutant phenotypes suggest that they are needed not only for flagellar assembly but also for torque generation and for controlling the direction of motor rotation. A role for these proteins in torque generation is suggested by the existence of mutations in each of them that produce the Mot- (or paralyzed) phenotype, in which flagella are assembled and appear normal but do not rotate. The presumption is that Mot- defects cause paralysis by specifically disrupting functions essential for torque generation, while preserving the features of a protein needed for flagellar assembly. Here, we present evidence that the reported mot mutations in fliM and fliN do not disrupt torque-generating functions specifically but, instead, affect the incorporation of proteins into the flagellum. The fliM and fliN mutants are immotile at normal expression levels but become motile when the mutant proteins and/or other, evidently interacting flagellar proteins are overexpressed. In contrast, many of the reported fliG mot mutations abolish motility at all expression levels, while permitting flagellar assembly, and thus appear to disrupt torque generation specifically. These mutations are clustered in a segment of about 100 residues at the carboxyl terminus of FliG. A slightly larger carboxyl-terminal segment of 126 residues accumulates in the cells when expressed alone and thus probably constitutes a stable, independently folded domain. We suggest that the carboxyl-terminal domain of FliG functions specifically in torque generation, forming the rotor portion of the site of energy transduction in the flagellar motor.     

Rhodospirillum centenum utilizes separate motor and switch components to control lateral and polar flagellum rotation

Rhodospirillum centenum is a purple photosynthetic bacterium that is capable of differentiating from vibrioid swimming cells that contain a single polar flagellum into rod-shaped swarming cells that have a polar flagellum plus numerous lateral flagella. Microscopic studies have demonstrated that the polar flagellum is constitutively present and that the lateral flagella are found only when the cells are grown on solidified or viscous medium. In this study, we demonstrated that R. centenum contains two sets of motor and switch genes, one set for the lateral flagella and the other for the polar flagellum. Electron microscopic analysis indicated that polar and lateral flagellum-specific FliG, FliM, and FliN switch proteins are necessary for assembly of the respective flagella. In contrast, separate polar and lateral MotA and MotB motor subunits are shown to be required for motility but are not needed for the synthesis of polar and lateral flagella. Phylogenetic analysis indicates that the polar and lateral FliG, FliM, and FliN switch proteins are closely related and most likely arose as a gene duplication event. However, phylogenetic analysis of the MotA and MotB motor subunits suggests that the polar flagellum may have obtained a set of motor genes through a lateral transfer event.     

Mutations inmotBSuppressible by Changes in Stator or Rotor Components of the Bacterial Flagellar Motor

Five proteins (MotA, MotB, FliG, FliM and FliN) may be involved in energizing flagellar rotation inEscherichia coli. To study interactions between the Mot proteins, and between them and the three Fli proteins of the switch-motor complex, we have isolated extragenic suppressors of dominant and partially dominantmotBmissense mutations. Four of the 13motBmutations yielded partially allele-specific suppressors. Of the suppressing mutations, 57 are in themotAgene, eight are infliG, and one is infliM; no suppressor was identified infliN. The prevalence of suppressors infliGsuggests that FliG interacts rather directly with the Mot proteins. The behaviour of cells in tethering and swarm assays indicates that themotAsuppressors are more efficient than thefliGorfliMsuppressors. Some of the suppressing mutations themselves confer distinctive phenotypes inmotB⁺cells. We propose a model in which mutations affecting residues in or near the putative peptidoglucan-binding region of MotB misalign the stator relative to the rotor. We suggest that most of the suppressors restore motility by introducing compensatory realignments in MotA or FliG.     

Mutational analysis of the flagellar protein FliG: sites of interaction with FliM and implications for organization of the switch complex

The switch complex at the base of the bacterial flagellum is essential for flagellar assembly, rotation, and switching. In Escherichia coli and Salmonella, the complex contains about 26 copies of FliG, 34 copies of FliM, and more then 100 copies of FliN, together forming the basal body C ring. FliG is involved most directly in motor rotation and is located in the upper (membrane-proximal) part of the C ring. A crystal structure of the middle and C-terminal parts of FliG shows two globular domains connected by an alpha-helix and a short extended segment. The middle domain of FliG has a conserved surface patch formed by the residues EHPQ(125-128) and R(160) (the EHPQR motif), and the C-terminal domain has a conserved surface hydrophobic patch. To examine the functional importance of these and other surface features of FliG, we made mutations in residues distributed over the protein surface and measured the effects on flagellar assembly and function. Mutations preventing flagellar assembly occurred mainly in the vicinity of the EHPQR motif and the hydrophobic patch. Mutations causing aberrant clockwise or counterclockwise motor bias occurred in these same regions and in the waist between the upper and lower parts of the C-terminal domain. Pull-down assays with glutathione S-transferase-FliM showed that FliG interacts with FliM through both the EHPQR motif and the hydrophobic patch. We propose a model for the organization of FliG and FliM subunits that accounts for the FliG-FliM interactions identified here and for the different copy numbers of FliG and FliM in the flagellum.     

Charged residues in the cytoplasmic loop of MotA are required for stator assembly into the bacterial flagellar motor

MotA and MotB form a transmembrane proton channel that acts as the stator of the bacterial flagellar motor to couple proton flow with torque generation. The C-terminal periplasmic domain of MotB plays a role in anchoring the stators to the motor. However, it remains unclear where their initial binding sites are. Here, we constructed Salmonella strains expressing GFP-MotB and MotA-mCherry and investigated their subcellular localization by fluorescence microscopy. Neither the D33N and D33A mutations in MotB, which abolish the proton flow, nor depletion of proton motive force affected the assembly of GFP-MotB into the motor, indicating that the proton translocation activity is not required for stator assembly. Overexpression of MotA markedly inhibited wild-type motility, and it was due to the reduction in the number of functional stators. Consistently, MotA-mCherry was observed to colocalize with GFP-FliG even in the absence of MotB. These results suggest that MotA alone can be installed into the motor. The R90E and E98K mutations in the cytoplasmic loop of MotA (MotA(C) ), which has been shown to abolish the interaction with FliG, significantly affected stator assembly, suggesting that the electrostatic interaction of MotA(C) with FliG is required for the efficient assembly of the stators around the rotor.     

Structures of bacterial flagellar motors from two FliF-FliG gene fusion mutants

Flagella purified from Salmonella enterica serovar Typhimurium contain FliG, FliM, and FliN, cytoplasmic proteins that are important in torque generation and switching, and FliF, a transmembrane structural protein. The motor portion of the flagellum (the basal body complex) has a cytoplasmic C ring and a transmembrane M ring. Incubation of purified basal bodies at pH 4.5 removed FliM and FliN but not FliG or FliF. These basal bodies lacked C rings but had intact M rings, suggesting that FliM and FliN are part of the C ring but not a detectable part of the M ring. Incubation of basal bodies at pH 2.5 removed FliG, FliM, and FliN but not FliF. These basal bodies lacked the C ring, and the cytoplasmic face of the M ring was altered, suggesting that FliG makes up at least part of the cytoplasmic face of the M ring. Further insights into FliG were obtained from cells expressing a fusion protein of FliF and FliG. Flagella from these mutants still rotated but cells were not chemotactic. One mutant is a full-length fusion of FliF and FliG; the second mutant has a deletion lacking the last 56 residues of FliF and the first 94 residues of FliG. In the former, C rings appeared complete, but a portion of the M ring was shifted to higher radius. The C-ring-M-ring interaction appeared to be altered. In basal bodies with the fusion-deletion protein, the C ring was smaller in diameter, and one of its domains occupied space vacated by missing portions of FliF and FliG.     

Deletion analysis of MotA and MotB, components of the force-generating unit in the flagellar motor of Salmonella

MotA and MotB are cytoplasmic membrane proteins that form the force-generating unit of the flagellar motor in Salmonella typhimurium and many other bacteria. Many missense mutations in both proteins are known to cause slow motor rotation (slow-motile phenotype) or no rotation at all (non-motile or paralysed phenotype). However, large stretches of sequence in the cytoplasmic regions of MotA and in the periplasmic region of MotB have failed to yield these types of mutations. In this study, we have investigated the effect of a series of 10-amino-acid deletions in these phenotypically silent regions. In the case of MotA, we found that only the C-terminal 5 amino acids were completely dispensable; an adjacent 10 amino acids were partially dispensable. In the cytoplasmic loop region of MotA, deletions made the protein unstable. For MotB, we found that two large segments of the periplasmic region were dispensable: the results with individual deletions showed that the first consisted of six deletions between the sole transmembrane span and the peptidoglycan binding motif, whereas the second consisted of four deletions at the C-terminus. We also found that deletions in the MotB cytoplasmic region at the N-terminus impaired motility but did not abolish it. Further investigations in MotB were carried out by combining dispensable deletion segments. The most extreme version of MotB that still retained some degree of function lacked a total of 99 amino acids in the periplasmic region, beginning immediately after the transmembrane span. These results indicate that the deleted regions in the MotA cytoplasmic loop region are essential for stability; they may or may not be directly involved in torque generation. Part of the MotA C-terminal cytoplasmic region is not essential for torque generation. MotB can be divided into three regions: an N-terminal region of about 30 amino acids in the cytoplasm, a transmembrane span and about 260 amino acids in the periplasm, including a peptidoglycan binding motif. In the periplasmic region, we suggest that the first of the two dispensable stretches in MotB may comprise part of a linker between the transmembrane span of MotB and its attachment point to the peptidoglycan layer, and that the length or specific sequence of much of that linker sequence is not critical. About 40 residues at the C-terminus are also unimportant.     

The Agrobacterium tumefaciens motor gene,motA, is in a linked cluster with the flagellar switch protein genes,fliG, fliM and fliN

We report the sequence of 3978 bp of the Agrobacterium tumefaciens chromosome which contains a putative operon encoding the homologues of the transmembrane proton channel protein MotA, and the flagellar switch proteins FliM, FliN and FliG. Two transposon insertions in fliG result in a non-flagellate phenotype, indicating that this gene at least is required for flagellar assembly.© 1997 Elsevier Science B.V. All rights reserved.     

Insertional inactivation of genes encoding components of the sodium-type flagellar motor and switch of Vibrio parahaemolyticus

Vibrio parahaemolyticus possesses two types of flagella, polar and lateral, powered by distinct energy sources, which are derived from the sodium and proton motive forces, respectively. Although proton-powered flagella in Escherichia coli and Salmonella enterica serovar Typhimurium have been extensively studied, the mechanism of torque generation is still not understood. Molecular knowledge of the structure of the sodium-driven motor is only now being developed. In this work, we identify the switch components, FliG, FliM, and FliN, of the sodium-type motor. This brings the total number of genes identified as pertinent to polar motor function to seven. Both FliM and FliN possess charged domains not found in proton-type homologs; however, they can interact with the proton-type motor of E. coli to a limited extent. Residues known to be critical for torque generation in the proton-type motor are conserved in the sodium-type motor, suggesting a common mechanism for energy transfer at the rotor-stator interface regardless of the driving force powering rotation. Mutants representing a complete panel of insertionally inactivated switch and motor genes were constructed. All of these mutants were defective in sodium-driven swimming motility. Alkaline phosphatase could be fused to the C termini of MotB and MotY without abolishing motility, whereas deletion of the unusual, highly charged C-terminal domain of FliM disrupted motor function. All of the mutants retained proton-driven, lateral motility over surfaces. Thus, although central chemotaxis genes are shared by the polar and lateral systems, genes encoding the switch components, as well as the motor genes, are distinct for each motility system.     

Structure of Flagellar Motor Proteins in Complex Allows for Insights into Motor Structure and Switching

The flagellar motor is one type of propulsion device of motile bacteria. The cytoplasmic ring (C-ring) of the motor interacts with the stator to generate torque in clockwise and counterclockwise directions. The C-ring is composed of three proteins, FliM, FliN, and FliG. Together they form the “switch complex” and regulate switching and torque generation. Here we report the crystal structure of the middle domain of FliM in complex with the middle and C-terminal domains of FliG that shows the interaction surface and orientations of the proteins. In the complex, FliG assumes a compact conformation in which the middle and C-terminal domains (FliG_MC) collapse and stack together similarly to the recently published structure of a mutant of FliG_MC with a clockwise rotational bias. This intramolecular stacking of the domains is distinct from the intermolecular stacking seen in other structures of FliG. We fit the complex structure into the three-dimensional reconstructions of the motor and propose that the cytoplasmic ring is assembled from 34 FliG and FliM molecules in a 1:1 fashion.     

Interactions of the chemotaxis signal protein CheY with bacterial flagellar motors visualized by evanescent wave microscopy

The chemotaxis signal protein CheY of enteric bacteria shuttles between transmembrane methyl-accepting chemotaxis protein (MCP) receptor complexes and flagellar basal bodies [1]. The basal body C-rings, composed of the FliM, FliG and FliN proteins, form the rotor of the flagellar motor [2]. Phosphorylated CheY binds to isolated FliM [3] and may also interact with FliG [4], but its binding to basal bodies has not been measured. Using the chemorepellent acetate to phosphorylate and acetylate CheY [5], we have measured the covalent-modification-dependent binding of a green fluorescent protein-CheY fusion (GFP-CheY) to motor assemblies in bacteria lacking MCP complexes by evanescent wave microscopy [6]. At acetate concentrations that cause solely clockwise rotation, GFP-CheY molecules bound to native basal bodies or to overproduced rotor complexes with a stoichiometry comparable to the number of C-ring subunits. GFP-CheY did not bind to rotors lacking FIiM/FliN, showing that these subunits are essential for the association. This assay provides a new means of monitoring protein-protein interactions in signal transduction pathways in living cells.