The attenuated phenotype of a Salmonella typhimurium flgM mutant is related to expression of FliC flagellin.

The flgM gene of Salmonella typhimurium encodes a negative regulator of flagellin synthesis that acts by inhibiting the flagellum-specific sigma factor FliA (sigma 28), but only when a mutation in a flagellar basal body, hook, or switch gene is present. We previously showed that FlgM is also necessary for the virulence of S. typhimurium in the mouse model of typhoid fever and proposed that FlgM is required to modulate the activity of the FliA sigma factor, which, in turn, regulates a gene involved in virulence. In this investigation, we observed that (i) the in vitro generation times of flgM mutant and wild-type strains of S. typhimurium were indistinguishable, as were the amounts of flagellin produced by the strains; (ii) the 50% lethal doses of fliA mutant and wild-type strains of S. typhimurium were similar in orally infected mice; and (iii) inactivation of the FliA-regulated flagellin gene fliC in an flgM S. typhimurium mutant resulted in a virulent phenotype. Therefore, we now conclude that expression of the FliC flagellin subunit in an flgM strain is responsible for the attenuated phenotype of an flgM mutant and that FliA does not appear to positively regulate virulence genes in S. typhimurium. Our results suggest that the normal regulation of flagellum synthesis appears to be necessary for virulence and that there may be an advantage conferred in vivo by expression of a particular flagellar phenotype of S. typhimurium.     

DegU-phosphate activates expression of the anti-sigma factor FlgM in Bacillus subtilis

The bacterial flagellum is a complex molecular machine that is assembled by more than 30 proteins and is rotated to propel cells either through liquids or over solid surfaces. Flagellar gene expression is extensively regulated to co-ordinate flagellar assembly in both space and time. In Bacillus subtilis, the proteins of unknown function, SwrA and SwrB, and the alternative sigma factor σ(D) are required to activate expression of the flagellar filament protein, flagellin. Here we determine that in the absence of SwrA and SwrB, the phosphorylated form of the response regulator DegU inhibits σ(D) -dependent gene expression indirectly by binding to the P(flgM) promoter region and activating expression of the anti-sigma factor FlgM. We further demonstrate that DegU-P-dependent activation of FlgM is essential to inhibit flagellin expression when flagellar basal body assembly is disrupted. Regulation of FlgM is poorly understood outside of Salmonella, and differential control of FlgM expression may be a common means of coupling flagellin expression to flagellar assembly.     

The Salmonella typhimurium flgM gene, which encodes a negative regulator of flagella synthesis and is involved in virulence, is present and functional in other Salmonella species

Abstract FlgM inhibits the flagella-specific sigma factor FliA and is involved in the mouse-virulence of Salmonella typhimurium . In recent experiments, we observed that: (i) a flgM gene that could function to negatively regulate flagella synthesis was present in a variety of salmonellae; and (ii) the flgM gene derived from Salmonella species that are not normally virulent in mice could complement the S. typhimurium flgM mutant for virulence. Our results suggest that a functional flgM , has been retained in most, and perhaps all, Salmonella species, regardless of the motility or virulence phenotype of the strain.     

Overproduction and characterization of the Bacillus subtilis anti-sigma factor FlgM

FlgM is an anti-sigma factor of the flagellar-specific sigma (sigma) subunit of RNA polymerase in Bacillus subtilis, and it is responsible of the coupling of late flagellar gene expression to the completion of the hook-basal body structure. We have overproduced the protein in soluble form and characterized it. FlgM forms dimers as shown by gel exclusion chromatography and native polyacrylamide gel electrophoresis and interacts in vitro with the cognate sigmaD factor. The FlgM.sigmaD complex is a stable heterodimer as demonstrated by gel exclusion chromatography, chemical cross-linking, native polyacrylamide gel electrophoresis, and isoelectric focusing. sigmaD belongs to the group of sigma factors able to bind to the promoter sequence even in the absence of core RNA polymerase. The FlgM.sigmaD complex gave a shift in a DNA mobility shift assay with a probe containing a sigmaD-dependent promoter sequence. Limited proteolysis studies indicate the presence of two structural motifs, corresponding to the N- and C-terminal regions, respectively.     

FlgM is a primary regulator of sigmaD activity, and its absence restores motility to a sinR mutant.

We have used mini-Tn1O mutagenesis to identify negative regulators of sigmaD activity. Nine independent insertions were mapped to five genes: flgM, flgK, fliD, fliS, and fliT, suggesting that FlgM export is regulated similarly in Bacillus subtilis and Salmonella typhimurium. We show that a deletion of flgM can restore sigmaD activity to a sinR null mutant of B. subtilis, although fla/che operon expression is affected by neither SinR nor FlgM.     

FlgM anti-sigma factors: identification of novel members of the family, evolutionary analysis, homology modeling, and analysis of sequence-structure-function relationships

FlgM proteins, also known as Anti-sigma-28 factor (sigma28), are negative regulators of flagellin synthesis. Recently, a three-dimensional structure of the Aquifex aeolicus sigma28/FlgM complex (PDB code: 1rp3) was determined by X-ray crystallography at 2.3 A resolution. Furthermore, experimental data on bacterial FlgM, including site-directed mutagenesis and structural characterization by NMR are also available. However, an interpretation of the sequence-structure-function relationships combining X-ray and NMR data with the evolutionary information extracted from the increasing number of FlgM-related sequences annotated in databases is not available. In the present study, we combined database sequence searches and sequence-analysis tools to update the multiple sequence alignment of a previously characterized cluster of orthologs (COG2747) and the PFAM classification of protein domains (PF04316) for the FlgM family. A phylogenetic analysis of 77 protein sequences revealed the presence of at least three major sequence clades within the FlgM family. Besides, we predicted functional residues using a SequenceSpace method. We also generated homology models for Bacillus subtilis and Salmonella typhimurium FlgM proteins, for which sequence-structure-function relationship data are available, and used the docking program ClusPro to hypothesize about the dimer association between FlgM proteins. In conclusion, the analysis presented in this work will be useful in designing new experiments to understand better protein-protein interactions between FglM, sigma factors, and putative molecules from the flagellar export apparatus. Electronic Supplementary Material is available in the online version of this article at http://link.springer.de/     

The type III secretion determinants of the flagellar anti-transcription factor, FlgM, extend from the amino-terminus into the anti-σ28 domain

The flagellar-specific anti-sigma factor, FlgM, inhibits the expression of late flagellar genes until the hook–basal body structure is assembled and competent for export of the flagellins and hook-associated proteins (flagellar late proteins). FlgM monitors this assembly checkpoint by being a substrate for export via the hook–basal body structure, which includes a type III protein secretion complex. Amino acid sequence alignment of late-secreted flagellar proteins identified a region of homology present in the amino-terminus of FlgM and the other late flagellar proteins, but not in flagellar proteins secreted earlier during flagellar biosynthesis. Single amino acid substitutions at specific positions within this motif decreased the export of FlgM. Deletion of this region (S3-P11) resulted in lower intracellular FlgM levels, but did not prevent recognition and export by the flagellar-specific secretion system. Mutations were isolated in a second region of FlgM spanning residues K27 to A65 that exhibited increased anti-σ²⁸ activity. These FlgM 'hyperinhibitor' mutants were secreted less than wild-type FlgM. Mutations that interfere with the secretion of FlgM without abolishing anti-σ²⁸ activity have a negative effect upon the secretion of a His-tagged FlgM mutant that lacks anti-σ²⁸ activity. Models are proposed to explain the dominant negative phenotype of the FlgM secretion mutants reported in this study.     

Genetic transplantation: Salmonella enterica serovar Typhimurium as a host to study sigma factor and anti-sigma factor interactions in genetically intractable systems

In Salmonella enterica serovar Typhimurium, sigma(28) and anti-sigma factor FlgM are regulatory proteins crucial for flagellar biogenesis and motility. In this study, we used S. enterica serovar Typhimurium as an in vivo heterologous system to study sigma(28) and anti-sigma(28) interactions in organisms where genetic manipulation poses a significant challenge due to special growth requirements. The chromosomal copy of the S. enterica serovar Typhimurium sigma(28) structural gene fliA was exchanged with homologs of Aquifex aeolicus (an extreme thermophile) and Chlamydia trachomatis (an obligate intracellular pathogen) by targeted replacement of a tetRA element in the fliA gene location using lambda-Red-mediated recombination. The S. enterica serovar Typhimurium hybrid strains showed sigma(28)-dependent gene expression, suggesting that sigma(28) activities from diverse species are preserved in the heterologous host system. A. aeolicus mutants defective for sigma(28)/FlgM interactions were also isolated in S. enterica serovar Typhimurium. These studies highlight a general strategy for analysis of protein function in species that are otherwise genetically intractable and a straightforward method of chromosome restructuring using lambda-Red-mediated recombination.