Temperature-Dependent Self-Splicing Group I Introns in the Flagellin Genes of the Thermophilic Bacillus Species

A previous report described the presence of a self-splicing group I intron in a flagellin gene from a thermophilic Bacillus species. Here, we present evidence that the splicing reaction of the flagellin introns is dependent on temperature. Furthermore, a complementation analysis using a Bacillus subtilis flagellin-deficient mutant indicated that the intron-containing flagellin gene significantly restored the motility of the mutant at higher temperatures.     

The development of a flagellin surface display expression system in a moderate thermophile, <Emphasis Type="Italic">Bacillus halodurans</Emphasis> Alk36

This study relates to the development of an alkaliphilic, thermotolerant, Gram-positive isolate, Bacillus halodurans Alk36, for the over-production and surface display of chimeric gene products. This bacterium continuously over-produces flagellin. To harness this ability, key genetic tools, such as gene targeted inactivation, were developed for this strain. The hag gene, which codes for flagellin, was inactivated on the chromosome giving rise to the B. halodurans BhFC01 mutant. Polylinkers were inserted as in-frame, chimeric, flagellin sandwich fusions to identify the permissive insertion sites corresponding to the variable regions of the flagellin protein. Flagellin expression and motility were evaluated for these constructs. Two sites were identified for possible peptide insertion in the flagellin gene, one of which produced functional flagella and was able to restore the motility phenotype to a non-motile mutant. Peptides encoding a poly-histidine peptide and the HIV-1 subtype C gp120 epitope were, respectively, incorporated into this site as in-frame fusions. The peptides were found to be successfully displayed on the cell surface and functional through metal binding and immunological studies, respectively.     

Analysis of the flagellin (hag) gene of alkalophilic Bacillus sp. C-125.

Motility of the alkalophilic Bacillus sp. C-125, a flagellate bacterium, was demonstrated to be Na(+)- and pH-dependent. Flagellin protein from this strain was purified to homogeneity and the N-terminal sequence determined. Using the hag gene of Bacillus subtilis as a probe, the hag gene of Bacillus sp. C-125 was identified and cloned into Escherichia coli. Sequencing of this hag gene revealed that it encodes a protein of 272 amino acids (M(r) 29,995). The predicted N terminal sequence of this protein was identical to that determined by N-terminal sequencing of the flagellin protein from strain C-125. The alkalophilic Bacillus sp. C-125 flagellin shares homology with other known flagellins in both the N- and C-terminal regions. The middle portion, however, shows considerable differences, even from that of flagellin from the related species, B. subtilis.     

Amino Acid Substitutions and Intragenic Duplications of Bacillus sp. PS3 Flagellin Cause Complementation of the Bacillus subtilis Flagellin Deletion Mutant

Bacillus sp. PS3 produces a glycosylated flagellin. In this study, a number of the glycosylated residues of the flagellin protein were found to be located in the central variable region of this protein. We also report that the motility defect of the Bacillus subtilis flagellin mutant was complemented by Bacillus sp. PS3 flagellin variants without glycosylation, which contained amino acid substitutions and intragenic duplications in the variable region of flagellin.     

Surface-associated flagellum formation and swarming differentiation in Bacillus subtilis are controlled by the ifm locus

Knowledge of the highly regulated processes governing the production of flagella in Bacillus subtilis is the result of several observations obtained from growing this microorganism in liquid cultures. No information is available regarding the regulation of flagellar formation in B. subtilis in response to contact with a solid surface. One of the best-characterized responses of flagellated eubacteria to surfaces is swarming motility, a coordinate cell differentiation process that allows collective movement of bacteria over solid substrates. This study describes the swarming ability of a B. subtilis hypermotile mutant harboring a mutation in the ifm locus that has long been known to affect the degree of flagellation and motility in liquid media. On solid media, the mutant produces elongated and hyperflagellated cells displaying a 10-fold increase in extracellular flagellin. In contrast to the mutant, the parental strain, as well as other laboratory strains carrying a wild-type ifm locus, fails to activate a swarm response. Furthermore, it stops to produce flagella when transferred from liquid to solid medium. Evidence is provided that the absence of flagella is due to the lack of flagellin gene expression. However, restoration of flagellin synthesis in cells overexpressing sigma(D) or carrying a deletion of flgM does not recover the ability to assemble flagella. Thus, the ifm gene plays a determinantal role in the ability of B. subtilis to contact with solid surfaces.     

Cloning and characterization of the gene encoding the z66 antigen of Salmonella enterica serovar Typhi

Z66 antigen-positive strains of Salmonella enterica serovar Typhi change flagellin expression in only one direction from the z66 antigen to the d or j antigen, which is different from the phase variation of S. enterica serovar Typhimurium. In the present study, we identified a new flagellin gene in z66 antigen-positive strains of S. enterica serovar Typhi. The genomic structure of the region containing this new flagellin gene was similar to that of fljBA operon of biphasic S. enterica serovars. A fljA-like gene was present downstream of the new flagellin gene. A rho-independent terminator was located between the new flagellin gene and the fljA-like gene. Hin-like gene was not present upstream of the new flagellin gene. We generated a mutant strain of S. enterica serovar Typhi, which carries a deletion of the new flagellin gene. Western blotting revealed that the 51-kDa z66 antigen protein was absent from the population of proteins secreted by the mutant strain. Southern hybridization demonstrated that the z66 antigen-positive strains of S. enterica serovar Typhi carried the new flagellin gene and fliC on two different genomic EcoRI fragments. When z66 antigen-positive strains were incubated with anti-z66 antiserum, the flagellin expression by S. enterica serovar Typhi changed from z66 antigen to j antigen. The new flagellin gene and the fljA-like gene were absent in the strain with altered flagellin expression. These results suggested that the new flagellin gene is a fljB-like gene, which encodes the z66 antigen of S. enterica serovar Typhi, and that deletion of fljBA-like operon may explain why S. enterica serovar Typhi alters the flagellin expression in only one direction from the z66 antigen to the d or j antigen.     

Cloning of the flagellin gene from Bacillus subtilis and complementation studies of an in vitro-derived deletion mutation.

The flagellin promoter and structural gene from Bacillus subtilis I168 was cloned and sequenced. The amino-terminal protein sequence deduced from the coding sequence of the cloned gene was identical to that of the amino terminus of purified flagellin, indicating that the export of this protein is not directed by a posttranslationally processed N-terminal signal peptide. A sequence that was homologous to that of a consensus sigma 28 RNA polymerase recognition site lay upstream of the proposed translational start site. Amplification of this promoter region on a multicopy plasmid resulted in the formation of long, filamentous cells that accumulated flagellin intracellularly. The chromosomal locus containing the wild-type flagellin allele was replaced with a defective allele of the gene (delta hag-633) that contained a 633-base-pair deletion. Transport analysis of various flagellin gene mutations expressed in the hag deletion strain suggest that the extreme C-terminal portion of flagellin is functionally involved in export of the protein.     

Identification of flagellin associated with the Bacillus subtilis folded chromosome.

We have analyzed the nature and contents of a major protein, P36, in the nucleoid of the Bacillus subtilis wild type and an isogenic mutant devoid of flagella. It appears that deoxyribonucleic acid-P36 complex is flagellin present as membrane-associated flagella.     

Pleiotropic phenomena in autolytic enzyme(s) content, flagellation, and simultaneous hyperproduction of extracellular alpha-amylase and protease in a Bacillus subtilis mutant.

A mutant of Bacillus subtilis 6160 that had been isolated by its hyperproduction of alpha-amylase and protease lacked flagella and motility, and its content of autolytic enzyme(s) was reduced to one-third to one-fourth that of the parent. These phenotypic differences were completely co-transferred by the deoxyribonucleic acid (DNA) of the mutant when five DNA recipient strains of B. subtilis were transformed. The revertants, isolated by motility with a frequency of approximately 10(-7), recovered a normal level of autolytic activity and showed reduced productivity of alpha-amylase and protease. This point mutation allowed normal flagellin synthesis, spore formation, and rate of growth. The comparison of cell envelope of the mutant with that of the parent indicated that there was no significant difference except loss of flagella. Therefore the association at the cell surface of a group of extracellular proteins consisting of alpha-amylase, proteases, flagellin, and autolytic enzymes(s) seem to be coordinately regulated by the gene or seem to be affected coordinately by certain undetected alterations of the cell envelope.     

Role of the flaR gene in flagellar hook formation in Salmonella spp.

Flagellar filaments were reconstituted by polymerization with exogenously supplied flagellin monomers at the tips of normal hooks on Salmonella cells which were missing the filaments because of mutations in either the flaL or flaU gene or the flagellin genes H1 and H2. Reconstitution did not occur at the tips of polyhooks of the flaR mutant cells. Thus, the absence of flagellar filaments in the flaR mutant cells was probably caused by the inability of the polyhooks to work as polymerization nuclei for flagellin. A Phf+ mutant which produced polyhooks with flagellar filaments was isolated from a flaR polyhook mutant. Genetic analysis of the Phf+ mutant showed that it carried an intracistronic suppressor mutation of the original flaR mutation. This result indicated that the flaR gene regulates hook length and initiates flagellin formation.     

Excretion of flagellin by a short-flagella mutant of Salmonella typhimurium.

A nonmotile mutant of Salmonella typhimurium, SJW1254, has very short flagella (less than 0.1 micron long) due to a mutation in the structural gene of flagellin (H2). When ammonium sulfate was added to the culture medium of SJW1254 grown to the late-log phase, a large amount of protein precipitated. Gel electrophoresis and immunodiffusion showed that more than 90% (wt/wt) of the precipitated protein was flagellin. The mutant flagellin appeared to be excreted in the monomeric form, in an amount comparable to the amount in the flagellar filaments of wildtype bacteria. No such precipitate was obtained from the medium of wild-type bacteria. The mutant flagellin had the same apparent molecular weight (55,000) and isoelectric point (5.3) as the wild-type flagellin, but differed in mobility in polyacrylamide gel electrophoresis under nondenaturing conditions. Moreover, the mutant flagellin did not polymerize in vitro under various conditions in which wild-type flagellin polymerized. These results suggested that the mutant bacteria excreted flagellin because the flagellin polymerized poorly and therefore could not be trapped at the tip of the flagellar filament. This short-flagella mutant should be useful for studying the mechanism of flagellin transport.     

A novel factor controlling bistability in Bacillus subtilis: the YmdB protein affects flagellin expression and biofilm formation

Cells of Bacillus subtilis can either be motile or sessile, depending on the expression of mutually exclusive sets of genes that are required for flagellum or biofilm formation, respectively. Both activities are coordinated by the master regulator SinR. We have analyzed the role of the previously uncharacterized ymdB gene for bistable gene expression in B. subtilis. We observed a strong overexpression of the hag gene encoding flagellin and of other genes of the σ(D)-dependent motility regulon in the ymdB mutant, whereas the two major operons for biofilm formation, tapA-sipW-tasA and epsA-O, were not expressed. As a result, the ymdB mutant is unable to form biofilms. An analysis of the individual cells of a population revealed that the ymdB mutant no longer exhibited bistable behavior; instead, all cells are short and motile. The inability of the ymdB mutant to form biofilms is suppressed by the deletion of the sinR gene encoding the master regulator of biofilm formation, indicating that SinR-dependent repression of biofilm genes cannot be relieved in a ymdB mutant. Our studies demonstrate that lack of expression of SlrR, an antagonist of SinR, is responsible for the observed phenotypes. Overexpression of SlrR suppresses the effects of a ymdB mutation.     

Both the extracellular leucine-rich repeat domain and the kinase activity of FSL2 are required for flagellin binding and signaling in Arabidopsis

In Arabidopsis, activation of defense responses by flagellin is triggered by the specific recognition of the most conserved domain of flagellin, represented by the peptide flg22, in a process involving the FLS2 gene, which encodes a leucine-rich repeat serine/threonine protein kinase. We show here that the two fls2 mutant alleles, fls2-24 and fls2-17, which were shown previously to confer insensitivity to flg22, also cause impaired flagellin binding. These features are rescued when a functional FLS2 gene is expressed as a transgene in each of the fls2 mutant plants, indicating that FLS2 is necessary for flagellin binding. The point mutation of the fls2-17 allele lies in the kinase domain. A kinase carrying this missense mutation lacked autophosphorylation activity when expressed in Escherichia coli. This indicates that kinase activity is required for binding and probably affects the stability of the flagellin receptor complex. We further show that overexpression of the kinase-associated protein phosphatase (KAPP) in Arabidopsis results in plants that are insensitive to flagellin treatment, and we show reduced flg22 binding in these plants. Furthermore, using the yeast two-hybrid system, we show physical interaction of KAPP with the kinase domain of FLS2. These results suggest that KAPP functions as a negative regulator of the FLS2 signal transduction pathway and that the phosphorylation of FLS2 is necessary for proper binding and signaling of the flagellin receptor complex.     

Impact of Inactivated Extracellular Proteases on the Modified Flagellin Type III Secretion Pathway of Bacillus halodurans

The flagellin type III secretion pathway of Bacillus halodurans BhFC01 (Δhag) was modified by the inactivation of fliD. An in-frame flagellin gene fusion polypeptide construct was expressed, and the heterologous peptides were secreted as flagellin fusion monomers. The stability of the secreted monomers was significantly enhanced through gene-targeted inactivation of extracellular proteases.