Identification and sequence analysis of two related flagellin genes in Rhizobium meliloti.

The genomic region that codes for the flagellin subunits of the complex flagellar filaments of Rhizobium meliloti was cloned and sequenced. Two structural genes, flaA and flaB, that encode 395- and 396-amino-acid polypeptides, respectively, were identified. These exhibit 87% sequence identity. The amino acid sequences of tryptic peptides suggest that both of these subunit proteins are represented in the flagellar filaments. The N-terminal methionine was absent from the mature flagellin subunits. Their derived primary structures show almost no relationship to flagellins from Escherichia coli, Salmonella typhimurium, or Bacillus subtilis but exhibit up to 60% similarity to the N- and C-terminal portions of flagellin from Caulobacter crescentus. It is suggested that the complex flagellar filaments of R. meliloti are unique in being assembled from heterodimers of two related flagellin subunits. The tandemly arranged flagellin genes were shown to be transcribed separately from unusual promoter sequences.     

Three-dimensional reconstruction of the flagellar filament of Caulobacter crescentus. A flagellin lacking the outer domain and its amino acid sequence lacking an internal segment

We obtained a three-dimensional reconstruction of the flagellar filament of Caulobacter crescentus CB15 from electron micrographs of negatively stained preparations. The C. crescentus filament appears, both in negative stain and in the frozen-hydrated state, significantly smoother and narrower than other filaments. Its helical symmetry, and unit cell size, however, are similar to that of other filaments. Although the molecular weight of the C. crescentus flagellin is about half that of other plain flagellins, there is only one monomer per unit cell as indicated by diffraction studies and by linear mass density measurements with the scanning transmission electron microscope. Alignment of the primary amino acid sequences of Salmonella typhimurium (serotype i) and C. crescentus (29,000 Mr) flagellins shows that whereas there is homology at the amino and carboxyterminal ends of the two sequences, the central segment of the S. typhimurium sequence has no homology to that of C. crescentus. A correlated comparison between the three-dimensional reconstructions of the two filaments and primary amino acid sequences of the two flagellins suggests that: (1) the C. crescentus subunit is missing the outer molecular domain but is, otherwise, similar to that of S. typhimurium; (2) the outer molecular domain in S. typhimurium corresponds, therefore, to a central stretch of the primary amino acid sequence; and (3) the outer molecular domain, missing in C. crescentus, is not obligatory for flagellar motility.     

Identification, characterization, and spatial localization of two flagellin species in Helicobacter pylori flagella.

Flagellar filaments were isolated from Helicobacter pylori by shearing, and flagellar proteins were further purified by a variety of techniques, including CsCl density gradient ultracentrifugation, pH 2.0 acid disassociation-neutral pH reassociation, and differential ultracentrifugation followed by molecular sieving with a Sephacryl S-500 column or Mono Q anion-exchange column, and purified to homogeneity by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transfer to an Immobilon membrane. Two flagellin species of pI 5.2 and with apparent subunit molecular weights (Mrs) of 57,000 and 56,000 were obtained. N-terminal amino acid analysis showed that the two H. pylori flagellin species were related to each other and shared sequence similarity with the N-terminal amino acid sequence of Campylobacter coli, Bacillus, Salmonella, and Caulobacter flagellins. Analysis of the amino acid composition of the predominant 56,000-Mr flagellin species isolated from two strains showed that it was comparable to the flagellins of other species. The minor 57,000-Mr flagellin species contained a higher content of proline. Immunoelectron microscopic studies with polyclonal monospecific H. pylori antiflagellin antiserum and monoclonal antibody (MAb) 72c showed that the two different-Mr flagellin species were located in different regions of the assembled flagellar filament. The minor 57,000-Mr species was located proximal to the hook, and the major 56,000-Mr flagellin composed the remainder of the filament. Western immunoblot analysis with polyclonal rabbit antisera raised against H. pylori or Campylobacter jejuni flagellins and MAb 72c showed that the 56,000-Mr flagellin carried sequences antigenetically cross-reactive with the 57,000-Mr H. pylori flagellin and the flagellins of Campylobacter species. This antigenic cross-reactivity did not extend to the flagellins of other gram-negative bacteria. The 56,000-Mr flagellin also carried H. pylori-specific sequences recognized by two additional MAbs. The epitopes for these MAbs were not surface exposed on the assembled inner flagellar filament of H. pylori but were readily detected by immunodot blot assay of sodium dodecyl sulfate-lysed cells of H. pylori, suggesting that this serological test could be a useful addition to those currently employed in the rapid identification of this important pathogen.     

Molecular analyses of the Salmonella g. . . flagellar antigen complex.

Salmonella flagellar filaments are polymers of a highly antigenic protein, termed flagellin. Eight main subfactors have been identified in the Salmonella phase-1 g. . . series flagellar antigen. To determine the molecular basis for expression of the epitopes by which the g. . . family subfactors are distinguished, 10 members of this series were selected and their fliC (the structural gene for phase-1 flagellin) genes were sequenced. Comparative analyses of the inferred primary structures of these flagellins did not allow the identification of linear epitopes responsible for the antigen subfactors. This suggests that conformational aspects are involved in determining the antigenic specificity in these cases. A phylogenetic analysis of the flagellin sequences showed that members of the g. . . series do not form a single coherent unit.     

Comparative analysis of flagellin sequences from Escherichia coli strains possessing serologically distinct flagellar filaments with a shared complex surface pattern.

Escherichia coli morphotype E flagellar filaments have a characteristic surface pattern of short-pitch loops when examined by electron microscopy. Seven of the 50 known E. coli H (flagellar antigen) serotypes (H1, H7, H12, H23, H45, H49, and H51) produce morphotype E filaments. Polymerase chain reaction was used to amplify flagellin structural (fliC) genes from E. coli strains producing morphotype E flagellar filaments and from strains with flagellar filaments representing other morphotypes. A single DNA fragment was obtained from each strain, and the size of the amplified DNA correlated with the molecular mass of the corresponding flagellin protein. This finding and hybridization data suggest that these bacteria are monophasic. fliC genes from three E. coli serotypes (H1, H7, and H12) possessing morphotype E flagellar filaments were sequenced in order to assess the contribution of conserved flagellin primary sequence to the characteristic filament architecture. The H1 and H12 fliC sequences were identical in length (1,788 bp), while the H7 fliC sequence was shorter (1,755 bp). The deduced molecular masses of the FliC proteins were 60,857 Da (H1), 59,722 Da (H7), and 60,978 Da (H12). The H1, H7, and H12 flagellins demonstrated 98 to 99% identity over the amino-terminal region (190 amino acid residues) and 89% (H7) to 99% (H1 and H12) identity in the carboxy-terminal region (100 amino acid residues). The complete primary amino acid sequences for H1 and H12 flagellins differed by only 10 amino acids, accounting for previously reported serological cross-reactions. However, the central region of H7 flagellin had only 38% identity with H1 and H12 flagellins.The characteristic morphology of morphotype E flagellar filaments is therefore not dependent on a highly conserved primary sequence within the exposed central region. Comparison of morphotype E E. coli flagellins with those from E. coli K-12, Serratia marcescens, and several Salmonella serovars supported the established concept of highly conserved terminal regions flanking a variable central region.     

Sequence invariance of the antigen-coding central region of the phase 1 flagellar filament gene (fliC) among strains of Salmonella typhimurium.

Previous studies of the phase 1 flagellar filament protein (flagellin) in strains of five serovars of Salmonella indicated that the central region of the fliC gene encoding the antigenic part of the protein is hypervariable both between and within serovars. To explore the possible use of this variation as a source of information on the phylogenetic relationships of closely related strains, we used the polymerase chain reaction technique to sequence part of the central region of the phase 1 flagellar genes of seven strains of Salmonella typhimurium that were known to differ in chromosomal genotype, as indexed by multilocus enzyme electrophoresis. We found that the nucleotide sequences of the central region were identical in all seven strains and determined that both the previously published sequence of the fliC gene in S. typhimurium LT2 and a report of a marked difference in the amino acid sequence of the phase 1 flagellins of two isolates of this serovar are erroneous. Our finding that the fliC gene is not evolving by sequence drift at an unusually rapid rate is compatible with a model that invokes lateral transfer and recombination of the flagellin genes as a major evolutionary process generating new serovars (antigen combinations) of salmonellae.     

Purification and characterization of a tryptic peptide of Borrelia burgdorferi flagellin, which reduces cross-reactivity in immunoblots and ELISA.

In man the early immune response in Lyme disease is primarily directed against the endoflagellin antigen. Isolated flagellar protein of Borrelia burgdorferi suggests itself as a suitable test antigen. However, cross-reactivity between flagellins of B. burgdorferi, Escherichia coli, Bacillus subtilis, Proteus mirabilis and Salmonella typhimurium was demonstrated by immunoblotting and ELISA with polyclonal rabbit-hyperimmune-sera. Tryptic cleavage of recombinant B. burgdorferi 41 kDa flagellin, expressed in E. coli, produced a peptide fragment which was recognized exclusively by antisera to Borrelia species. This peptide was designated as the 14 kDa fragment due to its migratory behaviour in SDS-PAGE. The fragment is part of the variable region of the flagellin, as proven by amino acid sequencing. The flagellin peptide was employed as an antigen in ELISA and immunoblot assays, testing the polyclonal sera mentioned above. The specificity was superior to that obtained with the intact recombinant flagellin.     

A family of six flagellin genes contributes to the Caulobacter crescentus flagellar filament

The Caulobacter crescentus flagellar filament is assembled from multiple flagellin proteins that are encoded by six genes. The amino acid sequences of the FljJ and FljL flagellins are divergent from those of the other four flagellins. Since these flagellins are the first to be assembled in the flagellar filament, one or both might have specialized to facilitate the initiation of filament assembly.     

N-terminal amino acid sequence of the Borrelia burgdorferi flagellin

Abstract The 41 kDa flagellar protein of Borrelia burgdorferi appears to be an immunodominant antigen producing an early and strong response in most, if not all, individuals during infection in humans. It would represent a very good antigen for serodiagnosis of Lyme disease, if its crossreactivity with flagella of other bacteria was low. To gain information on this point we isolated the B. burgdorferi flagellin by preparative two-dimensional electrophoresis for N-terminal amino acid analysis. By comparing the N-terminal amino acid sequences of flagellar proteins from other eubacteria we found that the first six out of twenty nine amino acids were identical to the Treponema pallidum and Treponema phagedenis 'class B' flagellins. All 29 N-terminal residues exhibited a moderate inter-genus homology (44–55%), in contrast to the high degree (67–95%) of inter-species conservation of the treponemal 'class B' flagellar N-terminal sequences. There was little similarity to other flagellins except the B. subtilis flagellar protein.     

The bvgAS locus negatively controls motility and synthesis of flagella in Bordetella bronchiseptica.

The products of the bvgAS locus coordinately regulate the expression of Bordetella virulence factors in response to environmental conditions. We have identified a phenotype in Bordetella bronchiseptica that is negatively controlled by bvg. Environmental signals which decrease (modulate) the expression of bvg-activated genes lead to flagellum production and motility in B. bronchiseptica. Wild-type (Bvg+) strains are motile and produce peritrichous flagella only in the presence of modulating signals, whereas Bvg- (delta bvgAS or delta bvgS) strains are motile in the absence of modulators. The bvgS-C3 mutation, which confers signal insensitivity and constitutive activation of positively controlled loci, eliminates the induction of motility and production of flagellar organelles. The response to environmental signals is conserved in a diverse set of clinical isolates of both B. bronchiseptica and B. avium, another motile Bordetella species; however, nicotinic acid induced motility only in B. bronchiseptica. Purification of flagellar filaments from B. bronchiseptica strains by differential centrifugation followed by CsCl equilibrium density gradient centrifugation revealed two classes of flagellins of Mr 35,000 and 40,000. A survey of clinical isolates identified only these two flagellin isotypes, and coexpression of the two forms was not detected in any strain. All B. avium strains tested expressed a 42,000-Mr flagellin. Amino acid sequence analysis of the two B. bronchiseptica flagellins revealed 100% identity in the N-terminal region and 80% identity with Salmonella typhimurium flagellin. Monoclonal antibody 15D8, which recognizes a conserved epitope in flagellins in members of the family Enterobacteriaceae, cross-reacted with flagellins from B. bronchiseptica and B. avium. Our results highlight the biphasic nature of the B. bronchiseptica bvg regulon and provide a preliminary characterization of the Bvg-regulated motility phenotype.     

Unique sequences in region VI of the flagellin gene of Salmonella typhi

The H1 (now renamed fliC; lino et al., 1988) alleles specifying antigenically different Salmonella flagellins are identical at their ends but differ greatly towards the middle, where there are two hypervariable segments (regions IV and VI). The flagellar antigen, d, of Salmonella typhi, is found also as phase-1 antigen in many other Salmonella species. We cloned the H1-d gene of a strain of S. typhi and determined the nucleotide sequence of its two hypervariable regions. Comparison with gene H1-d of Salmonella muenchen showed substantial differences in region VI: four scattered amino acid differences and ten adjacent amino acids in the inferred S. typhi sequence, all of which differ from the corresponding nine amino acids in the S. muenchen sequence. The results of polymerase chain reaction amplification indicated the presence of the S. typhi version in all of 18 additional S. typhi strains and the presence of the S. muenchen version in all four non-S. typhi species with flagellar antigen d. The difference in amino acid sequence in segment VI may be responsible for the minor serological differences between antigens d of S. typhi and antigen d of S. muenchen.     

Amino acids responsible for flagellar shape are distributed in terminal regions of flagellin

The shape of the flagellar filaments of the bacterium Salmonella typhimurium under ordinary conditions is a left-handed helix. In addition to the normal wild-type filament, non-helical (i.e. straight), right-handed helical (early), or circular (semi-coiled and coiled) filaments and filament with small amplitude (fl-type) have been found in mutants or in filaments reconstituted in vitro. We analysed wild-type flagellin and flagellins from 17 flagellar-shape mutants (6 with straight filaments, 6 with curly filaments, 4 with coiled filaments and 1 with fl-type filament) by amino acid sequencing to identify the mutational sites. All mutant flagellins except that of the fl-type filament had single mutations; the fl-type flagellin had two mutations in the molecule. The sites of these mutations were localized in alpha-helical segments of the terminal regions of flagellin. A possible mechanism of the polymorphism of the flagellar filament is discussed.     

Isolation and characterization of flagella and flagellin proteins from the Thermoacidophilic archaea Thermoplasma volcanium and Sulfolobus shibatae.

Isolated flagellar filaments of Sulfolobus shibatae were 15 nm in diameter, and they were composed of two major flagellins which have M(r)s of 31,000 and 33,000 and which stained positively for glycoprotein. The flagellar filaments of Thermoplasma volcanium were 12 nm in diameter and were composed of one major flagellin which has an M(r) of 41,000 and which also stained positively for glycoprotein. N-terminal amino acid sequencing indicated that 18 of the N-terminal 20 amino acid positions of the 41-kDa flagellin of T. volcanium were identical to those of the Methanococcus voltae 31-kDa flagellin. Both flagellins of S. shibatae had identical amino acid sequences for at least 23 of the N-terminal positions. This sequence was least similar to any of the available archaeal flagellin sequences, consistent with the phylogenetic distance of S. shibatae from the other archaea studied.     

Flagellin genes of Methanococcus vannielii : amplification by the Polymerase Chain Reaction, demonstration of signal peptides and identification of major components of the flagellar filament

The highly conserved nature of the 5′-termini of all archaeal flagellin genes was exploited by polymerase chain reaction (PCR) techniques to amplify the sequence of a portion of a flagellin gene family from the archaeon Methanococcus vannielii. Subsequent inverse PCR experiments generated fragments that permitted the sequencing of a total of three flagellin genes, which, by comparison with flagellin genes that have been sequenced, from other archaea appear to be equivalent to flaB1, flaB2, and flaB3 of M. voltae. Analysis of purified M. vannielii flagellar filaments by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) revealed two major flagellins (M_r= 30 800 and 28 600), whose N-terminal sequences identified them as the products of the flaB1 and flaB2 genes, respectively. The gene product of flaB3 could not be detected in flagellar filaments by SDS-PAGE. The protein sequence data, coupled with the DNA sequences, demonstrated that both FlaB1 and FlaB2 flagellins are translated with a 12-amino acid signal peptide which is absent from the mature protein incorporated into the flagellar filament. These data suggest that archaeal flagellin export differs significantly from that of bacterial flagellins.     

Biochemical similarity among serologically distinct flagellins of Campylobacter jejuni

Abstract We describe a simplified method for obtaining highly purified flagellin, suitable for biochemical analysis using HPLC-gel permeation. Amino acid composition and N-terminal sequence analyses were performed on flagellins from serologically distinct isolates. The amino acid composition of flagellin from 10 strains was very similar. The N-terminal amino acid sequence is highly conserved. Significant sequence homology was found with flagellin of Bacillus subtilis .     

Flagellin genes of Methanococcus vannielii : amplification by the Polymerase Chain Reaction, demonstration of signal peptides and identification of major components of the flagellar filament

The highly conserved nature of the 5′-termini of all archaeal flagellin genes was exploited by polymerase chain reaction (PCR) techniques to amplify the sequence of a portion of a flagellin gene family from the archaeon Methanococcus vannielii. Subsequent inverse PCR experiments generated fragments that permitted the sequencing of a total of three flagellin genes, which, by comparison with flagellin genes that have been sequenced, from other archaea appear to be equivalent to flaB1, flaB2, and flaB3 of M. voltae. Analysis of purified M. vannielii flagellar filaments by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) revealed two major flagellins (M_r= 30 800 and 28 600), whose N-terminal sequences identified them as the products of the flaB1 and flaB2 genes, respectively. The gene product of flaB3 could not be detected in flagellar filaments by SDS-PAGE. The protein sequence data, coupled with the DNA sequences, demonstrated that both FlaB1 and FlaB2 flagellins are translated with a 12-amino acid signal peptide which is absent from the mature protein incorporated into the flagellar filament. These data suggest that archaeal flagellin export differs significantly from that of bacterial flagellins. Received: 27 November 1997 / Accepted: 19 March 1998     

Conserved N-terminal sequences in the flagellins of archaebacteria

Methanococcus voltae produces two flagellins of molecular weight 31,000 and 33,000. Amino acid analysis as well as peptide mapping with cyanogen bromide, chymotrypsin and Staphylococcus aureus V-8 protease indicates that the two flagellins are distinct. N-terminal sequencing of the 31,000 Mc. voltae flagellin as well as the 24,000 and 25,000 molecular weight flagellins of Methanospirillum hungatei GP1 shows an extensive homology with the reported N-terminus of the flagellins from Halobacterium halobium, deduced from the nucleotide sequence of the cloned genes. However, the N-termini of all three sequenced methanogen flagellins lack a terminal methionine and start at position 13 from the N-terminus of H. halobium flagellins. This initial 12 amino acid stretch may be a leader peptide which is subsequently cleaved to generate the mature flagellin, which could suggest flagellar assembly in archaebacteria occurs by a mechanism distinct from that in eubacteria. The high degree of conservation of the N-terminus of the flagellins from Mc. voltae, Msp. hungatei and H. halobium suggests an important role for this sequence, and that the archaebacteria share a common mechanism for flagellar biosynthesis.     

Recombination of Salmonella phase 1 flagellin genes generates new serovars.

To determine the evolutionary mechanisms generating serotypic diversity in Salmonella strains, we sequenced the central, antigen-determining part of the phase 1 flagellin gene (fliC) in strains of several serovars for which estimates of chromosomal genomic relatedness had been obtained by multilocus enzyme electrophoresis. The nucleotide sequence of this region was identical in several chromosomally divergent strains of Salmonella heidelberg (phase 1 antigen r) but differed by 19% from the corresponding and similarly invariant sequence in strains of the closely related serovar Salmonella typhimurium (phase 1 antigen i). Mutational drift of the sequence present in the common ancestor is unlikely to have generated the difference between the phase 1 flagellins of these two serovars, which we attribute instead to a recombination event. This interpretation is supported by evidence that Salmonella strains of very diverse chromosomal backgrounds but similar phase 1 antigens may have closely similar nucleotide sequences for this highly polymorphic region. We suggest that lateral transfer and recombination of phase 1 flagellin genes is a major evolutionary mechanism generating new Salmonella serovars.     

The flaFIX gene product of Salmonella typhimurium is a flagellar basal body component with a signal peptide for export.

flaFIX, the structural gene for the periplasmic P ring of the flagellar basal body of Salmonella typhimurium, was cloned. Two gene products with apparent molecular weights of 38,000 and 40,000 were identified by minicell analysis. Data from pulse-chase and membrane fractionation experiments and data on the inhibitory effect of the proton ionophore carbonyl cyanide m-chlorophenylhydrazone all indicated that the 40-kilodalton protein was a precursor form which, after export across the cytoplasmic membrane accompanied by cleavage of a signal peptide, gave rise to the mature protein in the periplasm. The N-terminal amino acid sequence of the FlaFIX protein, predicted from the DNA sequence, conformed well to known signal peptide sequences. The results indicate that the P-ring protein of the basal body (unlike flagellin and possible some other external flagellar components) crosses the cytoplasmic membrane in a conventional signal peptide-dependent manner.     

Isolation and characterization of Campylobacter flagellins.

Sequential acid pH dissociation, differential ultracentrifugation, and neutral pH reassociation were used to partially purify serotypically distinct flagella from three strains of Campylobacter jejuni and the two antigenic phases of flagella of Campylobacter coli VC167. Each C. jejuni flagellin and C. coli VC167 antigenic phase 1 flagellin were purified to homogeneity by reverse-phase high-performance liquid chromatography with a C8 Spheri-10 column. C. coli VC167 antigenic phase 2 was purified to homogeneity by ion-exchange chromatography with a Mono-Q column. Amino acid compositional analysis put the C. jejuni flagellin molecular weight in the range 63,200 to 63,800 and the C. coli antigenic phase 1 and 2 flagellins at 61,500 and 59,500, respectively. The amino acid compositions of the C. jejuni were similar to each other and to the C. coli VC167 antigenic phase 1 and phase 2 flagellins. One-dimensional peptide mapping of the C. jejuni flagellins by partial digestion with trypsin or chymotrypsin confirmed the structural similarities of the C. jejuni flagellins and the C. coli VC167 antigenic phase 1 flagellin and showed that C. coli VC167 antigenic phase 2 flagellin was structurally distinct from the phase 1 flagellin. The antigenic phase 2 flagellin was especially sensitive to digestion by chymotrypsin. Amino-terminal sequence analysis showed that the 20 N-terminal amino acids of the Campylobacter flagellins were highly conserved. The Campylobacter flagellins also shared limited sequence homology with the N-terminal sequences reported for Salmonella and Bacillus flagellins.