Nucleotide sequence and characterization of a Bacillus subtilis gene encoding a flagellar switch protein.

The nucleotide sequence of the Bacillus subtilis fliM gene has been determined. This gene encodes a 38-kDa protein that is homologous to the FliM flagellar switch proteins of Escherichia coli and Salmonella typhimurium. Expression of this gene in Che+ cells of E. coli and B. subtilis interferes with normal chemotaxis. The nature of the chemotaxis defect is dependent upon the host used. In B. subtilis, overproduction of FliM generates mostly nonmotile cells. Those cells that are motile switch less frequently. Expression of B. subtilis FliM in E. coli also generates nonmotile cells. However, those cells that are motile have a tumble bias. The B. subtilis fliM gene cannot complement an E. coli fliM mutant. A frameshift mutation was constructed in the fliM gene, and the mutation was transferred onto the B. subtilis chromosome. The mutant has a Fla- phenotype. This phenotype is consistent with the hypothesis that the FliM protein encodes a component of the flagellar switch in B. subtilis. Additional characterization of the fliM mutant suggests that the hag and mot loci are not expressed. These loci are regulated by the SigD form of RNA polymerase. We also did not observe any methyl-accepting chemotaxis proteins in an in vivo methylation experiment. The expression of these proteins is also dependent upon SigD. It is possible that a functional basal body-hook complex may be required for the expression of SigD-regulated chemotaxis and motility genes.     

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.     

Cell cycle-dependent degradation of a flagellar motor component requires a novel-type response regulator

The poles of each Caulobacter crescentus cell undergo morphological development as a function of the cell cycle. A single flagellum assembled at one pole during the asymmetric cell division is later ejected and replaced by a newly synthesized stalk when the motile swarmer progeny differentiates into a sessile stalked cell. The removal of the flagellum during the swarmer-to-stalked cell transition coincides with the degradation of the FliF flagellar anchor protein. We report here that the cell cycle-dependent turnover of FliF does not require the structural components of the flagellum itself, arguing that it is the initial event leading to the ejection of the flagellum. Analysis of a polar development mutant, pleD, revealed that the pleD gene was required for efficient removal of FliF and for ejection of the flagellar structure during the swarmer-to-stalked cell transition. The PleD requirement for FliF degradation was also not dependent on the presence of any part of the flagellar structure. In addition, only 25% of the cells were able to synthesize a stalk during cell differentiation when PleD was absent. The pleD gene codes for a member of the response regulator family with a novel C-terminal regulatory domain. Mutational analysis confirmed that a highly conserved motif in the PleD C-terminal domain is essential to promote both FliF degradation and stalk biogenesis during cell differentiation. Signalling through the C-terminal domain of PleD is thus required for C. crescentus polar development. A second gene, fliL, was shown to be required for efficient turnover of FliF, but not for stalk biogenesis. The possible roles of PleD and FliL in C. crescentus polar development are discussed.     

Ralstonia solanacearum needs motility for invasive virulence on tomato

Ralstonia solanacearum, a widely distributed and economically important plant pathogen, invades the roots of diverse plant hosts from the soil and aggressively colonizes the xylem vessels, causing a lethal wilting known as bacterial wilt disease. By examining bacteria from the xylem vessels of infected plants, we found that R. solanacearum is essentially nonmotile in planta, although it can be highly motile in culture. To determine the role of pathogen motility in this disease, we cloned, characterized, and mutated two genes in the R. solanacearum flagellar biosynthetic pathway. The genes for flagellin, the subunit of the flagellar filament (fliC), and for the flagellar motor switch protein (fliM) were isolated based on their resemblance to these proteins in other bacteria. As is typical for flagellins, the predicted FliC protein had well-conserved N- and C-terminal regions, separated by a divergent central domain. The predicted R. solanacearum FliM closely resembled motor switch proteins from other proteobacteria. Chromosomal mutants lacking fliC or fliM were created by replacing the genes with marked interrupted constructs. Since fliM is embedded in the fliLMNOPQR operon, the aphA cassette was used to make a nonpolar fliM mutation. Both mutants were completely nonmotile on soft agar plates, in minimal broth, and in tomato plants. The fliC mutant lacked flagella altogether; moreover, sheared-cell protein preparations from the fliC mutant lacked a 30-kDa band corresponding to flagellin. The fliM mutant was usually aflagellate, but about 10% of cells had abnormal truncated flagella. In a biologically representative soil-soak inoculation virulence assay, both nonmotile mutants were significantly reduced in the ability to cause disease on tomato plants. However, the fliC mutant had wild-type virulence when it was inoculated directly onto cut tomato petioles, an inoculation method that did not require bacteria to enter the intact host from the soil. These results suggest that swimming motility makes its most important contribution to bacterial wilt virulence in the early stages of host plant invasion and colonization.