Transposon Tn917lacZ mutagenesis of Bacillus subtilis: identification of two new loci required for motility and chemotaxis

Components of the Legionella pneumophila flagellar regulon contribute to multiple virulence traits, including lysosome avoidance and macrophage death

Legionella pneumophila is a motile intracellular pathogen of macrophages and amoebae. When nutrients become scarce, the bacterium induces expression of transmission traits, some of which are dependent on the flagellar sigma factor FliA (sigma(28)). To test how particular components of the L. pneumophila flagellar regulon contribute to virulence, we compared a fliA mutant with strains whose flagellar construction is disrupted at various stages. We find that L. pneumophila requires FliA to avoid lysosomal degradation in murine bone marrow-derived macrophages (BMM), to regulate production of a melanin-like pigment, and to regulate binding to the dye crystal violet, whereas motility, flagellar secretion, and external flagella or flagellin are dispensable for these activities. Thus, in addition to flagellar genes, the FliA sigma factor regulates an effector(s) or regulator(s) that contributes to other transmissive traits, notably inhibition of phagosome maturation. Whether or not the microbes produced flagellin, all nonmotile L. pneumophila mutants bound BMM less efficiently than the wild type, resulting in poor infectivity and a loss of contact-dependent death of BMM. Therefore, bacterial motility increases contact with host cells during infection, but flagellin is not an adhesin. When BMM contact by each nonmotile strain was promoted by centrifugation, all the mutants bound BMM similarly, but only those microbes that synthesized flagellin induced BMM death. Thus, the flagellar regulon equips the aquatic pathogen L. pneumophila to coordinate motility with multiple traits vital to virulence.

MotPS is the stator-force generator for motility of alkaliphilic Bacillus, and its homologue is a second functional Mot in Bacillus subtilis

The stator-force generator that drives Na+-dependent motility in alkaliphilic Bacillus pseudofirmus OF4 is identified here as MotPS, MotAB-like proteins with genes that are downstream of the ccpA gene, which encodes a major regulator of carbon metabolism. B. pseudofirmus OF4 was only motile at pH values above 8. Disruption of motPS resulted in a non-motile phenotype, and motility was restored by transformation with a multicopy plasmid containing the motPS genes. Purified and reconstituted MotPS from B. pseudofirmus OF4 catalysed amiloride analogue-sensitive Na+ translocation. In contrast to B. pseudofirmus, Bacillus subtilis contains both MotAB and MotPS systems. The role of the motPS genes from B. subtilis in several motility-based behaviours was tested in isogenic strains with intact motAB and motPS loci, only one of the two mot systems or neither mot system. B. subtilis MotPS (BsMotPS) supported Na+-stimulated motility, chemotaxis on soft agar surfaces and biofilm formation, especially after selection of an up-motile variant. BsMotPS also supported motility in agar soft plugs immersed in liquid; motility was completely inhibited by an amiloride analogue. BsMotPS did not support surfactin-dependent swarming on higher concentration agar surfaces. These results indicate that BsMotPS contributes to biofilm formation and motility on soft agar, but not to swarming, in laboratory strains of B. subtilis in which MotAB is the dominant stator-force generator. BsMotPS could potentially be dominant for motility in B. subtilis variants that arise in particular niches.

Isolation of human plasma-inducible, growth phase- and temperature-regulated gene fusions in Streptococcus pyogenes using a Tn917-lacZ transposon

Streptococcus pyogenes is capable of causing a variety of human diseases ranging from superficial or deep tissue infections to non-infectious post-streptococcal infection sequelae. In this paper, we report the use of a Tn917-lacZ transposon to isolate random lacZ transcription fusions in the S. pyogenes chromosome. Libraries of random Tn917-lacZ mutants were generated in a representative opacity factor positive strain CS101 (M49) and an opacity factor negative strain 1881 (M1). Several different mutant phenotypes were isolated. These included: temperature-regulated promoters, growth phase/cell density-regulated promoters and a human plasma-inducible promoter. Expression of the temperature-regulated fusions was 5-10-fold higher when grown at 30 degrees C compared to growth at 37 degrees C. The growth phase-regulated fusions were induced 30-fold at late exponential phase and were repressed by a diffusible S. pyogenes factor(s). Expression of the human plasma-inducible fusion was induced 10-15-fold by human plasma or sera, 4-fold by rabbit sera and was repressed by horse and mouse sera. In addition, hemolysin negative and capsule over expression mutants were isolated. These results demonstrate the utility of Tn917-lacZ mutagenesis for the identification of S. pyogenes promoters.

Dual promoters are responsible for transcription initiation of the fla/che operon in Bacillus subtilis

The fla/che region contains more than 30 genes required for flagellar synthesis and chemotaxis in Bacillus subtilis, including the gene for the flagellum-specific sigmaD factor, sigD. Sequence and primer extension data demonstrate that a PA promoter immediately upstream of flgB, henceforth referred to as the fla/che PA, and the PD-3 promoter are active in vivo. Transcription from the PD-3 element is dependent on sigmaD activity and is regulated by the flagellum-specific negative regulator, FlgM. In a strain containing a deletion of fla/che PA (PADelta), sigmaD protein was not detected, demonstrating that the fla/che PA is necessary for wild-type expression of the sigD gene. Thus, sigD is part of the >26-kb fla/che operon. Consistent with a lack of detectable sigmaD protein, the PADelta strain grows as long filaments and does not express a sigmaD-dependent hag::lacZ reporter construct. These phenotypes are indicative of a lack of sigD expression or complete inhibition of sigmaD activity by FlgM. However, sigmaD activity is found in a double mutant containing the PADelta and a null mutation in flgM. The double mutant no longer grows as long filaments, and expression of hag::lacZ is partially restored. These data demonstrate that a low level of sigmaD activity does exist in the PADelta mutant but can be detected only in the presence of a null mutation in flgM. Therefore, normal expression of sigD may also involve another promoter(s) within the fla/che operon.

Rhizobium leguminosarum contains a group of genes that appear to code for methyl-accepting chemotaxis proteins

Methyl-accepting chemotaxis proteins (MCPs) play important roles in the chemotactic response of many bacteria. Oligonucleotide primers designed to amplify the conserved signalling domain of MCPs by PCR were used to identify potential MCP-encoding genes in Rhizobium leguminosarum. Using a PCR-derived probe created from these primers a genomic library of R. leguminosarum VF39SM was screened; at least five putative MCP-encoding genes (termed mcpB to mcpF) were identified and isolated from the library. One of these putative genes (mcpC) is located on one of the indigenous plasmids of VF39SM. Fifteen different cosmids showing homology to an mcpD probe were also isolated from a genomic library. The complete DNA sequences of mcpB, mcpC and mcpD were obtained. All three genes code for proteins with characteristics typical of MCPs. However, the protein encoded by mcpB has a relatively large periplasmic domain compared to that in other MCPs. Partial DNA sequences of mcpE and mcpF had strong similarity to sequences from the methylation domains of known MCPs. Mutants defective in mcpB, mcpC, mcpD or mcpE were created using insertional mutagenesis strategies. Mutation of mcpB resulted in impairment of chemotaxis to a wide range of carbon sources on swarm plates; phenotypes for the other three mutants have yet to be elucidated. The mcpB, mcpC and mcpD mutants were tested for loss of nodulation competitiveness. When co-inoculated with the wild-type, the mcpB and mcpC mutants formed fewer nodules than the wild-type, whereas the mcpD mutant was just as competitive as the wild-type. The results overall suggest that R. leguminosarum possesses mcp-like genes, and that at least some of these play a role in early steps in the plant-microbe interaction.

Functional and genetic characterization of mcpC, which encodes a third methyl-accepting chemotaxis protein in Bacillus subtilis

A 3135 bp DNA segment downstream of the spl gene on the Bacillus subtilis chromosome was cloned and its nucleotide sequence determined. An open reading frame capable of encoding a putative protein of 654 amino acids with a calculated molecular mass of 72.1 kDa was identified. The deduced amino acid sequence was similar to the McpA and McpB proteins of B. subtilis. McpA and McpB encode different methyl-accepting chemotaxis proteins (MCPs). A mutant strain containing an antibiotic resistance DNA cassette inserted into the region containing the MCP-like reading frame suffered a complete loss of taxis to the amino acids cysteine, proline, threonine, glycine, serine, lysine, valine and arginine. The open reading frame was designated mcpC. The wild-type and an mcpC mutant strain were analysed for their content of methylated proteins and it was found that mcpC encodes a methylated membrane protein that has previously been designated H3. These results show that mcpC encodes a third MCP in B. subtilis. The transcription start site upstream of the mcpC gene was determined by primer extension analysis and it was found to be preceded by a potential promoter sequence that is recognized by the sigma D form of RNA polymerase. The level of beta-galactosidase expressed from a transcriptional mcpC-lacZ fusion was increased threefold when cells entered the stationary phase. No beta-galactosidase could be detected in a sigD genetic background.

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.

Role of FlgM in sigma D-dependent gene expression in Bacillus subtilis

The alternative sigma factor sigma D directs transcription of a number of genes involved in chemotaxis, motility, and autolysis in Bacillus subtilis (sigmaD regulon). The activity of SigD is probably in contrast to that of FlgM, which acts as an antisigma factor and is responsible for the coupling of late flagellar gene expression to the assembly of the hook-basal body complex. We have characterized the effects of an in-frame deletion mutation of flgM. By transcriptional fusions to lacZ, we have shown that in FlgM-depleted strains there is a 10-fold increase in transcription from three different sigmaD-dependent promoters, i.e., Phag, PmotAB, and PfliDST. The number of flagellar filaments was only slightly increased by the flgM mutation. Overexpression of FlgM from a multicopy plasmid under control of the isopropyl-beta-D-thiogalactopyranoside-inducible spac promoter drastically reduced the level of transcription from the hag promoter. On the basis of these results, we conclude that, as in Salmonella typhimurium, FlgM inhibits the activity of SigD, but an additional element is involved in determining the number of flagellar filaments.

Catabolite repression in Bacillus subtilis: a global regulatory mechanism for the gram-positive bacteria?

Three components involved in catabolite repression (CR) of gene expression in Bacillus have been identified. The cis-acting catabolite responsive element (CRE), which is present in many genes encoding carbon catabolic enzymes in various species of the Gram-positive bacteria, mediates CR of several genes in Bacillus subtilis, Bacillus megaterium, and Staphylococcus xylosus. CR of most genes regulated via CRE is also affected by the trans-acting factors CcpA and HPr. Similarities between CcpA and Lac and Gal repressors suggest binding of CcpA to CRE. HPr, a component of the phosphoenolpyruvate:sugar phosphotransferase system, undergoes regulatory phosphorylation at a serine residue by a fructose-1,6-diphosphate-activated kinase. A mutant of HPr, which is not phosphorylatable at this position because of an exchange of serine to alanine, lacks CR of several catabolic activities. This mutant phenotype is similar to the one exhibited by a ccpA mutant. Direct protein-protein interaction between CcpA and HPr(Ser-P) was recently demonstrated and constitutes a link between metabolic activity and CR.

MotX, the channel component of the sodium-type flagellar motor

Thrust for propulsion of flagellated bacteria is generated by rotation of a propeller, the flagellum. The power to drive the polar flagellar rotary motor of Vibrio parahaemolyticus is derived from the transmembrane potential of sodium ions. Force is generated by the motor on coupling of the movement of ions across the membrane to rotation of the flagellum. A gene, motX, encoding one component of the torque generator has been cloned and sequenced. The deduced protein sequence is 212 amino acids in length. MotX was localized to the membrane and shown to interact with MotY, which is the presumed stationary component of the motor. Overproduction of MotX, but not that of a nonfunctional mutant MotX, was lethal to Escherichia coli. The rate of lysis caused by induction of motX was proportional to the sodium ion concentration. Li+ and K+ substituted for Na+ to promote lysis, while Ca2+ did not enhance lysis. Protection from the lethal effects of induction of motX was afforded by the sodium channel blocker amiloride. The data suggest that MotX forms a sodium channel. The deduced protein sequence for MotX shows no homology to its ion-conducting counterpart in the proton-driven motor; however, in possessing only one hydrophobic domain, it resembles other channels formed by small proteins with single membrane-spanning domains.

Motility and chemotaxis in Bacillus sphaericus. Dependence upon stage of growth

Chemotaxis and motility of B. sphaericus 2362 were monitored as the function of a batch culture age. It was found that both functions changed independently during growth of the culture. Motility was low until the late logarithmic stage ensued, whereafter it increased sharply. The ability of cells to respond to chemoeffectors peaked at the mid-logarithmic phase. A major methyl-accepting chemotaxis protein (P53, M(r) = 53 kDa) was identified. The extent of label incorporation in this protein from L-[methyl-3H]methionine was maximal in mid- and late logarithmic phases of the growth. Cells in stationary cultures incorporated very low amounts of the label. At any stage, the labeling was maximal in starved cells; it was almost abolished in cells pre-incubated with amino acids. Although extents of P53 labeling in mid- and late logarithmic cells were similar, late logarithmic cells demonstrated a considerably impaired chemotaxis. Supermotile sporulating cells were practically insensitive to environmental stimuli. The difference in development of sensory and locomotive functions may be interpreted as an adaptive response. A well developed sensory apparatus would allow vegetative cells to adapt efficiently to fluctuating attractant gradients. Insensitive sporulating cells would tend to disperse randomly from the nutrient-exhausted area. Thus, spore formation would occur in larger volume of the habitat, increasing the chance of the microbial population to survive.

Identification of flagellar synthesis regulatory and structural genes in a sigma D-dependent operon of Bacillus subtilis

The sigma D form of RNA polymerase from Bacillus subtilis has been shown previously to direct the synthesis of several transcription units bearing genes for flagellin, motility proteins, and autolysins. In this report, we describe an operon of genes transcribed from the sigma D-dependent promoter PD-1. We have identified three complete open reading frames and one partial one downstream of this promoter; immediately upstream is the previously identified comF locus. The PD-1 operon encodes the presumptive B. subtilis homologs of two Salmonella typhimurium late flagellar genes, flgM and flgK. Also present in this operon are two genes of unknown function, orf139 and orf160, whose products show similarities to the eukaryotic cytoskeletal proteins myosin and vimentin, respectively. orf139 and orf160 may encode proteins that form extended alpha-helical secondary structures and coiled-coil quaternary structures which may be filamentous components of the gram-positive bacterial flagellum. We have characterized the B. subtilis flgM gene further by constructing an in-frame deletion mutation, flgM delta 80, and creating strains of B. subtilis in which this allele has replaced the wild-type copy. By primer extension analysis of cellular RNA, we have shown that the flgM delta 80 mutation relieves the block to transcription of two other sigma D-dependent operons imposed by an unlinked mutation in a gene directing early flagellar synthesis. We conclude that, as in the case of S. typhimurium, early flagellar synthesis in B. subtilis is coupled to late flagellar synthesis through repression of sigma D-dependent transcription by the flgM gene product.

Motility and chemotaxis in Bacillus sphaericus. Dependence upon stage of growth

Chemotaxis and motility of Bacillus sphaericus 2362 were monitored as a function of the batch culture age. It was found that both functions changed independently during growth of the culture. Motility was low until the late logarithmic stage ensued, whereafter it increased sharply. The ability of cells to respond to chemo-effectors peaked at the mid-logarithmic phase. A major methyl-accepting chemotaxis protein (P53, M(r) = 53 kDa) was identified. The extent of label incorporation in this protein from L-[methyl-3H]methionine was maximal in mid- and late-logarithmic phases of the growth. Cells in stationary cultures incorporated very low amounts of the label. At any stage, the labeling was maximal in starved cells; it was almost abolished in cells pre-incubated with amino acids. Although extents of P53 labeling in mid- and late logarithmic cells were similar, late logarithmic cells demonstrated a considerably impaired chemotaxis. Supermotile sporulating cells were practically insensitive to environmental stimuli. The difference in development of sensory and locomotive functions may be interpreted as an adaptive response. A well developed sensory apparatus would allow vegetative cells to adapt efficiently to fluctuating attractant gradients. Insensitive sporulating cells would tend to disperse randomly from the nutrient-exhausted area. Thus, spore formation would occur in larger volume of the habitat, increasing the chance of microbial population to survive.

The Bacillus subtilis sigma D-dependent operon encoding the flagellar proteins FliD, FliS, and FliT

During a genetic screen to identify metalloregulated loci in Bacillus subtilis, we isolated a Tn917-lacZ insertion in the second gene of an operon downstream of the flagellin (hag) gene. Sequence analysis indicates that this gene encodes a homolog of the enteric flagellar filament cap protein FliD. The fliD gene is followed by homologs of the fliS and fliT genes. Transcription of the fliD-lacZ fusion is sigma D dependent, with peak expression at the end of logarithmic-phase growth. Like other sigma D-dependent genes, expression of fliD-lacZ is greatly reduced by mutations in genes essential for assembly and function of the basal body and hook complex (class II functions). These results suggest that B. subtilis flagellar genes are organized in a hierarchy of gene expression similar to that found in enteric bacteria with hag and fliD as class III genes. Expression from the fliD operon promoter, but not the hag promoter, is repressed by iron, which suggests that the target of metalloregulation is the promoter rather than the sigma D protein.

Dual chemotaxis signaling pathways in Bacillus subtilis: a sigma D-dependent gene encodes a novel protein with both CheW and CheY homologous domains

The alternative sigma factor, sigma D, activates the expression of genes required for chemotaxis and motility in Bacillus subtilis, including those encoding flagellin, hook-associated proteins, and the motor proteins. The sigma D protein is encoded in a large operon which also encodes the structural proteins for the basal body and homologs of the enteric CheW, CheY, CheA, and CheB chemotaxis proteins. We report the identification and molecular characterization of a novel chemotaxis gene, cheV. The predicted CheV gene product contains an amino-terminal CheW homologous domain linked to a response regulator domain of the CheY family, suggesting that either or both of these functions are duplicated. Transcription of cheV initiates from a sigma D-dependent promoter element both in vivo and in vitro, and expression of a cheV-lacZ fusion is completely dependent on sigD. Expression is repressed by nonpolar mutations in structural genes for the basal body, fliM or fliP, indicating that cheV belongs to class III in the B. subtilis flagellar hierarchy. The cheV locus is monocistronic and is located at 123 degrees on the B. subtilis genetic map near the previously defined cheX locus. A cheV mutant strain is motile but impaired in chemotaxis on swarm plates. Surprisingly, an insertion in the CheW homologous domain leads to a more severe defect than an insertion in the CheY homologous domain. The presence of dual pathways for chemotactic signal transduction is consistent with the residual signaling observed in previous studies of cheW mutants (D. W. Hanlon, L. Márques-Magaña, P. B. Carpenter, M. J. Chamberlin, and G. W. Ordal, J. Biol. Chem. 267:12055-12060, 1992).

Characterization of the sigD transcription unit of Bacillus subtilis

The sigma D factor of Bacillus subtilis is required for the transcription of the flagellin and motility genes as well as for wild-type chemotaxis. Southern blot and sequence analyses demonstrate that the structural gene for sigma D, sigD, is located immediately downstream of a region of DNA originally identified as the chemotaxis (che) locus and now renamed the fla/che region. In fact, sigD appears to be part of a very large operon (> 26 kb) containing genes which encode structural proteins that form the hook-basal body complex as well as regulatory proteins required for chemotaxis. Transposon insertions up to 24 kb upstream of sigD, within several of the genes for the hook-basal body components, give rise to only a moderate decrease in sigD expression. The transposon insertions, however, block sigma D activity as demonstrated by the lack of flagellin expression in strains bearing these insertions. These effects appear to arise from two types of regulation. In cis the transposon insertions appear to introduce a partial block to transcription of sigD from upstream promoter elements; in trans they disrupt genes whose gene products are required for sigma D activity. It appears that sigD transcription is initiated, at least in part, by a promoter many kilobases upstream of its translation start site and that transcription of the flagellin gene by sigma D is dependent on the formation of a functional hook-basal body complex. The possibility that sigD is part of the fla/che operon was further tested by the integration of an insertion plasmid, containing strong transcription terminators, 1.6 and 24 kb upstream of the sigD gene. In both cases, the introduction of the terminators resulted in a greater decrease of sigD expression than was caused by the plasmid sequences alone. These results indicate that wild-type transcription of sigD is dependent on promoter sequences > 24kb upstream of its structural gene and that the entire fla/che region forms a single operon.

Characterization of two putative Listeria monocytogenes genes encoding polypeptides homologous to the sensor protein CheA and the response regulator CheY of chemotaxis

The nucleotide sequence of a region located downstream of the Listeria monocytogenes flagellin gene, flaA, has been determined. DNA sequence analysis revealed the presence of two open reading frames with a potential to encode polypeptides of 13.1 and 68.7 kDa, respectively. The deduced polypeptides show a high degree of identity to the chemotactic proteins, CheY and CheA, respectively, from Bacillus subtilis and Escherichia coli. Moreover, significant features of CheY and CheA are conserved in the L. monocytogenes homologues. The high degree of conservation suggests that the polypeptides are involved in signal transduction controlling chemotaxis in L. monocytogenes and consequently the putative genes are named cheY and cheA. Northern blot and primer extension analysis suggested that cheY and cheA are transcribed as a bicistronic unit and that the transcription is thermoregulated.

Bacillus subtilis FlhA: a flagellar protein related to a new family of signal-transducing receptors

The Bacillus subtilis flhA gene lies in the major che/fla operon, a transcription unit that spans 26 kilobases (kb) of DNA. flhA encodes a 677-amino-acid polypeptide that is a strong candidate for an integral membrane protein. The sequence of FlhA displays substantial homology to a newly identified family of putative signal-transducing receptors that have been implicated in diverse cellular processes. FlhA is the first member of this family to be described from a Gram-positive bacterium. We demonstrate that flhA is a flagellar gene and that FlhA is required in trans for the formation of products from some, but not all, B. subtilis motility-related operons that are regulated by the sigma D form of RNA polymerase. We suggest that FlhA is a component of a signalling system that is involved with the formation of some flagellar gene products during the biosynthesis of the flagellum.

flhF, a Bacillus subtilis flagellar gene that encodes a putative GTP-binding protein

We describe the sequence and characterization of the Bacillus subtilis flhF gene. flhF encodes a basic polypeptide of 41 kDa that contains a putative GTP-binding motif. The sequence of FlhF reveals a structural relationship to two Escherichia coli proteins, Ffh and FtsY, as well as to other members of the SRP54 family, in a domain presumed to bind GTP. flhF is located in a large operon consisting of chemotaxis and flagellar genes. Cells deficient in flhF are nonmotile. Through the use of anti-flagellar antibodies we have established that flhF is a flagellar (fla) gene. Thus, flhF is a unique flagellar gene in that it encodes a GTP-binding protein with similarities to members of the SRP54 family of proteins. These data suggest that flagellar biosynthesis in B. subtilis requires GTP.

An operon of Bacillus subtilis motility genes transcribed by the sigma D form of RNA polymerase

Two genes controlling motility functions in Bacillus subtilis were identified by DNA sequence analysis of a chromosomal fragment containing a strong promoter for sigma D RNA polymerase. Previous studies had shown that this sigma D-dependent promoter controls synthesis of a 1.6-kb transcript in vivo and in vitro. Sequence analysis revealed that the 1.6-kb transcript contains two open reading frames coding for protein sequences homologous to the Escherichia coli motA and motB gene products, respectively, and ends in a rho-independent termination site. Direct evidence linking these genes to motility functions in B. subtilis was obtained by precise localization by polymerase chain reaction of Tn917 transposon insertion mutations of Mot- strains, isolated by Zuberi et al. (A. R. Zuberi, C. Ying, H. M. Parker, and G. W. Ordal, J. Bacteriol. 172:6841-6848, 1990), to within this mot. operon. Replacement of each wild-type gene by in-frame deletion mutations yielded strains possessing paralyzed flagella and confirmed that both motA and motB are required for the motility of B. subtilis. These current findings support our earlier suggestions that sigma D in B. subtilis plays a central role in the control of gene expression for flagellar assembly, chemotaxis, and motility functions. Sigma F, the enteric homolog of sigma D, controls similar functions in E. coli and Salmonella typhimurium, and these factors appear to be representative of a family of factors implicated in flagellar synthesis in many bacterial species, which we propose to designate the sigma 28 family.

Restoration of motility to an Escherichia coli fliA flagellar mutant by a Bacillus subtilis sigma factor

The activation of additional promoter sites by production of an alternative sigma subunit for RNA polymerase is a common strategy for the coordinate regulation of gene expression. Many alternative sigma factors control genes for specialized, and often narrowly distributed, functions. For example, most of the alternative sigma factors in Bacillus subtilis control genes necessary for endospore formation. In contrast, the B. subtilis sigma D protein controls the expression of genes important for flagellar-based motility and chemotaxis, a form of locomotion very broadly distributed in the eubacteria. A homologous sigma factor, sigma F, controls a similar group of motility genes in the enteric bacteria. The conservation of both promoter specificity and genetic function in these two regulons allowed us to test the ability of a B. subtilis sigma factor to function within an Escherichia coli host. We demonstrate that expression of the B. subtilis sigD gene restores motility to an E. coli strain mutant in the fliA locus encoding the sigma F factor. This result suggests that the B. subtilis sigma D protein can bind to the E. coli core RNA polymerase to direct transcription initiation from at least four of the late operon promoters, thereby leading to the synthesis of flagellin, motor, and hook-associated proteins. Conversely, expression of sigma D protein in a normally chemotactic strain of E. coli (fliA+) leads to a hyperflagellated, nonchemotactic phenotype.

Alternative sigma factors and the regulation of flagellar gene expression

Synthesis of bacterial flagella and the accompanying array of chemotaxis receptors and transducers represents a major commitment of energy and resources for a growing bacterial cell and is subject to numerous levels of regulation. Genes for flagellar and chemotaxis proteins are expressed in a complex transcriptional cascade. This regulatory hierarchy acts to ensure that the highly expressed filament structural protein, flagellin, is synthesized only after a prerequisite set of structural proteins has been expressed and properly assembled. Recent evidence suggests that many bacteria utilize an alternative sigma (sigma) subunit, similar in specificity to the Bacillus subtilis sigma 28 protein, to direct transcription of flagellin, chemotaxis and motility genes. In Caulobacter crescentus and Campylobacter spp., both a sigma 54-like factor and a sigma 28-like factor participate in the transcription of flagellar and chemotaxis genes. Conversely, a sigma 28-like factor controls non-motility functions in at least one non-flagellated organism.

Properties of the Bacillus subtilis chemotaxis protein CheF, a homolog of the Salmonella typhimurium flagellar protein FliJ

The nucleotide sequence of Bacillus subtilis cheF was corrected. It encodes an 18-kDa protein that is homologous to FliJ, a protein required for formation of basal bodies in Escherichia coli and Salmonella typhimurium. Methanol release is abnormal in cheF mutants, suggesting that the morphology and functioning of the motor affects methanol formation.

Genetic analysis of the flaA locus of Bacillus subtilis

We isolated two clones of recombinant lambda bacteriophage with overlapping inserts of Bacillus subtilis chromosomal DNA corresponding to part of the flaA locus. The flaA4 and flaA15 mutations were localized on the physical map by marker rescue experiments. The flaA locus and the flaB (sigD) gene were mapped in transduction crosses, and the order glnA polC flaB flaA was determined. FlaB was linked to polC in transformation crosses.

Gene-protein relationships in the flagellar hook-basal body complex of Bacillus subtilis: sequences of the flgB, flgC, flgG, fliE and fliF genes

The nucleotide sequence of five genes from the major Bacillus subtilis chemotaxis locus has been determined. Four of these genes encode proteins that are homologous to the Salmonella typhimurium FlgB, FlgC, FlgG and FliF proteins. One gene encodes a protein that is homologous to the Escherichia coli FliE protein. The data from S. typhimurium and E. coli suggest that all of these proteins form part of the hook-basal body (HBB) complex of the bacterial flagella. The FlgB, FlgC and FlgG proteins are components of the proximal and distal rods. The FliF protein forms the M-ring that anchors the rod assembly to the membrane. The role of the FliE protein within the HBB complex has not yet been determined. The similarity between the B. subtilis and S. typhimurium proteins suggests that the structure of the M-ring and the rod may be similar in the two species. However, we observed some differences in size and amino acid composition between some of the corresponding homologues that suggest the basal body proteins may be organized slightly differently within B. subtilis.

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.