Antigenic variation of Campylobacter flagella.

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of flagella dissociated from strains of Campylobacter coli and Campylobacter jejuni belonging to the heat-labile serogroup LIO 8 showed that some strains were capable of producing flagellin subunits of two different molecular weights (MrS), 59,500 and 61,500. Immunoelectron microscopy of cultures of the type strain of this serogroup, C. coli VC167, showed the presence of two flagellum filaments of different antigenic specificity. Epitopes on the surface of one of these flagella bound antibodies in LIO 8 typing antiserum, and Western blotting (immunoblotting) and immunoprecipitation showed that the flagellum was composed of flagellin of Mr 61,500. The other flagellum antigenic type did not bind LIO 8 antibodies but did possess serospecific epitopes which bound a second polyclonal antiserum, LAH2. This second antigenic flagellum type was composed of the Mr 59,500 flagellin. Cells producing either of the flagellum antigenic types serotyped as LIO 8, indicating that flagella composed of the Mr 61,500 flagellin do not carry the serological determinants for this serogroup. The ability of C. coli VC167 to produce these flagella of different subunit MrS was shown to represent a bidirectional antigenic variation. When measured in culture medium, the phase 1-to-phase 2 transition occurred at a rate of approximately 2.0 x 10(-5) per cell per generation, and the phase 2-to-phase 1 transition occurred at a rate of 1.2 x 10(-6) per cell per generation.     

M467: a murine IgA myeloma protein that binds a bacterial protein. I. Recognition of common antigenic determinants on Salmonella flagellins.

We have studied the binding of M467, an IgA murine myeloma protein, to flagellin from seven species of Salmonella. It was found that M467 was reacting with antigenic determinants that were common to all the flagellins studied. These determinants were not related to serotypic antigens. Electronmicrographs of unreduced M467 showed a variety of polymeric species bound to flagella in a manner that could produce immobilization as well as agglutination and precipitation through cross-linking of antigenic determinants. Immunodiffusion in agar gel revealed that M467 was recognizing more than one group of peptide determinants on the flagellins studied. Passive hemagglutination inhibition and a solid phase radioimmunoassay provided evidence that there were differences in binding avidities between M467 and the various Salmonella flagellins studied. It was concluded that M467 is binding more than one specific group of antigenic peptide determinants on flagellin molecules. Flagellin from four of the seven species of Salmonella studied were deficient in one or more of these determinants.     

Involvement of tyrosine residues in the protomer-protomer interaction of Proteus mirabilis flagella as studied by spectroscopic methods, chemical modification and aggregation experiments.

Using spectrophotometrical titration, chemical modification, and ultraviolet difference spectral methods, the existence of at least two distinct tyrosine groups in the isolated flagellin of Proteus mirabilis flagella has been established. Three of the five flagellin tyrosines are buried in the protein matrix, whereas the other two seem to lie on the protein surface accessible to perturbants. Also about two tyrosine residues, presumably the latter ones exposed to the environment, can be nitrated with tetranitromethane in the monomeric flagellin with a concomitant loss of the polymerization ability after about one tyrosine per mol flagellin has been nitrated. Nitrated flagellin, homogeneous with respect to molecular weight, degree of nitration and isoelectric point, could be isolated and characterized. On the other hand, it could be shown that in the polymeric flagellum the phenolic groups of all five tyrosine residues are inaccessible to perturbing and modifying reagents. It seems, therefore, that the integrity of the phenolic groups is necessary for the proper folding and aggregation of the flagellin subunits to form the stable helical flagella.     

Archaeal Flagella as Biotemplates for Nanomaterials with New Properties

At the end of 1980s, regions of the polypeptide chain of bacterial flagella subunits (flagellins) responsible for different properties of these protein polymers were identified by structural studies. It was found that the N-and C-terminal regions are responsible for the polymerization properties of subunits, and the central region is responsible for antigenic properties of the flagellum. Soon after that, it was proposed to use variability of the central flagellin domain for directed modification to impart new properties to the flagellum surface. Such studies of flagella and other polymeric structures of bacterial origin thrived. However bacterial polymers have some shortcomings, mainly their instability to dissociating effects. This shortcoming is absent in archaeal flagella. A limiting factor was the lack of the three-dimensional structure of archaeal flagellins. A method was developed that allowed modifying flagella of the halophilic archaeon Halobacterium salinarum in a peptide that connects positively charged ions. Later, corresponding procedures were used that allowed preparing the anode material for a lithiumion battery whose characteristics 4-5-fold exceeded those of batteries commonly used in industrial production. We describe other advantages of archaeal flagella over bacterial analogs when used in nanotechnology.     

Lateral flagellar antigen of Vibrio alginolyticus and Vibrio harveyi: existence of serovars common to the two species

The antigenicity of lateral (L-) flagella of two marine vibrios, Vibrio alginolyticus and V. harveyi, was studied, and the two species were found to have common antigenicity of their flagella. Antisera against L-flagella were prepared by immunizing rabbits with highly purified L-flagellar filaments. H-Agglutination tests with the anti-L-flagella antisera showed that four H-serovars existed in these species and that two of them were shared by the two species. Cross reactivity between H-serovars of these two species and other vibrios having lateral flagella, such as V. parahaemolyticus, V. campbellii, V. proteus, or V. fluvialis, was not observed in the H-agglutination test, although partial common antigenicity was observed in the gel diffusion test with flagellin monomers. These observations suggest that surface antigenic determinants of the lateral flagella of V. alginolyticus and V. harveyi are specific to these two species but internal antigenic determinants buried in the flagellar filaments are partially shared with other vibrio species.     

Caulobacter flagellar organelle: synthesis, compartmentation, and assembly.

In Caulobacter crescentus biogenesis of the flagellar organelle occurs during one stage of its complex life cycle. Thus in synchronous cultures it is possible to assay the sequential synthesis and assembly of the flagellum and hook in vivo with a combination of biochemical and radioimmunological techniques. The periodicity of synthesis and the subcellular compartmentation of the basal hook and filament subunits were determined by radioimmune assay procedures. Unassembled 27,000-dalton (27K) flagellin was preferentially located in isolated membrane fractions, whereas the 25K flagellin was distributed between the membrane and cytoplasm. The synthesis of hook began before that of flagellin, although appreciable overlap of the two processes occurred. Initiation of filament assembly coincided with the association of newly synthesized hook and flagellin subunits. Caulobacter flagella are unusual in that they contain two different flagellin subunits. Data are presented which suggest that the ratio of the two flagellin subunits changes along the length of the filament. Only the newly synthesized 25K flagellin subunit is detected in filaments assembled during the swarmer cell stage. By monitoring the appearance of flagellar hooks in the culture medium, the time at which flagella are released was determined.     

Genetic and molecular characterization of the polar flagellum of Vibrio parahaemolyticus.

Vibrio parahaemolyticus possesses two alternate flagellar systems adapted for movement under different circumstances. A single polar flagellum propels the bacterium in liquid (swimming), while multiple lateral flagella move the bacterium over surfaces (swarming). Energy to rotate the polar flagellum is derived from the sodium membrane potential, whereas lateral flagella are powered by the proton motive force. Lateral flagella are arranged peritrichously, and the unsheathed filaments are polymerized from a single flagellin. The polar flagellum is synthesized constitutively, but lateral flagella are produced only under conditions in which the polar flagellum is not functional, e.g., on surfaces. This work initiates characterization of the sheathed, polar flagellum. Four genes encoding flagellins were cloned and found to map in two loci. These genes, as well as three genes encoding proteins resembling HAPs (hook-associated proteins), were sequenced. A potential consensus polar flagellar promoter was identified by using upstream sequences from seven polar genes. It resembled the enterobacterial sigma 28 consensus promoter. Three of the four flagellin genes were expressed in Escherichia coli, and expression was dependent on the product of the fliA gene encoding sigma 28. The fourth flagellin gene may be different regulated. It was not expressed in E. coli, and inspection of upstream sequence revealed a potential sigma 54 consensus promoter. Mutants with single and multiple defects in flagellin genes were constructed in order to determine assembly rules for filament polymerization. HAP mutants displayed new phenotypes, which were different from those of Salmonella typhimurium and most probably were the result of the filament being sheathed.     

Molecular evolution and subunit structure of cattle lens alpha crystallin

Summary The present studies were based on the premise that any common determinants in homologous proteins must have originated with the common ancestor of all of the taxonomic groups in which that determinant occurs. Cross-reacting antigenic determinants of lens alpha crystallin in various classes of modern vertebrates were used to trace their evolutionary relationships.For quantitation of evolutionarily distinct determinants, equimolar amounts of alpha crystallin or its subunits, in either monomeric or reaggregated form, were bound to a matrix, then saturated with^{1 2 5}I-labeled Fab fragments of anti-cattle alpha crystallin antibodies having phylogenetically restricted specificities. This quantitative procedure has the important advantage of independence from variation in antibody responses to different determinants of the same antigenic molecule. The procedure is not impaired by steric hindrance.Both the SH-containing and SH-free subunits of cattle lens alpha crystallin were found to contain common antigenic determinants with the cyclostomata alpha crystallin. Such determinants originated in evolution with the first vertebrates, the primitive agnatha. Antigenic determinants transferred from ancestral aquatic and land vertebrates to the mammals were found to constitute 93% of all determinants reactive in the monomeric SH-free subunits of cattle alpha crystallin. These determinants constitute only 76.5% of all determinants which are reactive in the SH-containing subunits. The antigenic determinants on both types of subunits were all found to be different. These findings indicate that evolutionary changes must have occurred more slowly in SH-free subunits than in SH-containing subunits.Significant decreases or increases were found in the content of various evolutionarily distinct determinants reactive in the reaggregated subunits as compared to the ones reactive in monomeric subunits. These differences can result from the formation of new conformational antigenic determinants during aggregation as well as from the burial or exposure of other determinants after aggregation.Different amounts of evolutionarily distinct antigenic determinants were found to be reactive in the molecules dissociated into subunits than in the intact molecules one of the reasons being that the intact molecules contain phylogenetically distinct determinants which depend on the quaternary structure of the protein molecule. The data obtained indicate that the quaternary structure of cattle alpha crystallin has, to a large degree, remained unchanged since the origin of vertebrates.     

Physical and antigenic heterogeneity in the flagellins of Listeria monocytogenes and L. ivanovii

Listeria monocytogenes serotypes 4a, 4b and 7, and L. ivanovii, all grown at 20 degrees C, were negatively stained and examined by electron microscopy. Crude extracts of the cell surface of L. monocytogenes serotypes 1/2b, 3b, 3c, 4a, 4b, 4d and 7 and of L. ivanovii (all grown at 20 degrees C) were examined by SDS-PAGE and Western blotting using (i) affinity-purified polyclonal monospecific antibody, and (ii) monoclonal antibody, each raised against 29 kDa flagellin of serotype 4b. No flagella were seen on serotype 7 by electron microscopy and no flagellin was detected in crude cell surface extracts of serotype 7 either in silver-stained gels or in Western blots. The monospecific polyclonal antibody detected flagellins of approximate molecular mass 29 kDa in each of the seven flagellate strains including L. ivanovii. The monoclonal antibody detected 29 kDa flagellin in serotypes 1/2b, 3b, 4a, 4b and 4d, but not the flagellins of serotype 3c or L. ivanovii, which had a slightly lower molecular mass. Following prolonged electrophoresis of crude flagellar extracts the 29 kDa complex was resolved into three closely migrating bands. In a heterologous system using serotype 1/2b crude flagellar extract, all three bands were detected using the polyclonal antibody whereas only two bands were detected by the monoclonal antibody. It is concluded that polyclonal anti-flagellin antibodies are not useful tools with which to distinguish serotypes of L. monocytogenes sensu lato in immunoblotting, but that differences can be determined using a monoclonal antibody directed against particular components of the flagellar complex. These differences did not fully correspond to those anticipated from results of agglutination tests.     

Differences between surface antigenic determinants of polar monotrichous flagella of Vibrio parahaemolyticus and of related species

Polar monotrichous flagella (M-flagella) of Vibrio parahaemolyticus have antigens in common with those of various species of Vibrio including V. cholerae and V. anguillarum, and of Beneckea, revealed by gel diffusion tests with flagelli monomers. However, antiserum against M-flagellin of V. parahaemolyticus did not agglutinate cells of V. cholerae and V. anguillarum, although it did agglutinate cells of V. parahaemolyticus. Agglutination tests after absorption of the antiserum with purified M-flagellar filaments or flagellin monomers and H-agglutination inhibition tests demonstrated that there are two different antigenic determinants in M-flagella as in lateral flagella. One is on the surface of the M-flagella (surface antigenic determinant, SA) and disappears or is buried in dissociated monomers. The other is inside the flagella (internal antigenic determinant, IA) and is exposed when the flagella are dissociated to flagellin monomers. SA of V. parahaemolyticus is different from those of V. cholerae and V. anguillarum, whereas the three species have a common IA.     

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.     

Amino‐terminal residues dictate the export efficiency of the Campylobacter jejuni filament proteins via the flagellum

Bacterial flagella play an essential role in the pathogenesis of numerous enteric pathogens. The flagellum is required for motility, colonization, and in some instances, for the secretion of effector proteins. In contrast to the intensively studied flagella of Escherichia coli and Salmonella typhimurium, the flagella of Campylobacter jejuni, Helicobacter pylori and Vibrio cholerae are less well characterized and composed of multiple flagellin subunits. This study was performed to gain a better understanding of flagellin export from the flagellar type III secretion apparatus of C. jejuni. The flagellar filament of C. jejuni is comprised of two flagellins termed FlaA and FlaB. We demonstrate that the amino‐termini of FlaA and FlaB determine the length of the flagellum and motility of C. jejuni. We also demonstrate that protein‐specific residues in the amino‐terminus of FlaA and FlaB dictate export efficiency from the flagellar type III secretion system (T3SS) of Yersinia enterocolitica. These findings demonstrate that key residues within the amino‐termini of two nearly identical proteins influence protein export efficiency, and that the mechanism governing the efficiency of protein export is conserved among two pathogens belonging to distinct bacterial classes. These findings are of additional interest because C. jejuni utilizes the flagellum to export virulence proteins.     

Specific and general antigenic determinants of flagellin of certain Salmonellae]

As known, in typing of salmonellae H-antigens play an important role. Flagellae bear on their surface specific antigenic determinants, this permitting to differentiate H-antigens serologically. Monomeric form of H-antigens d,a,b,1,2 bear on their surface not only specific, but also common for the given H-antigens determinant group. Common flagellin determinant group in the flagella is screened.     

Comparative ultrastructural and functional studies of Helicobacter pylori and Helicobacter mustelae flagellin mutants: both flagellin subunits, FlaA and FlaB, are necessary for full motility in Helicobacter species.

Helicobacter mustelae causes chronic gastritis and ulcer disease in ferrets. It is therefore considered an important animal model of human Helicobacter pylori infection. High motility even in a viscous environment is one of the common virulence determinants of Helicobacter species. Their sheathed flagella contain a complex filament that is composed of two distinctly different flagellin subunits, FlaA and FlaB, that are coexpressed in different amounts. Here, we report the cloning and sequence determination of the flaA gene of H. mustelae NCTC12032 from a PCR amplification product. The FlaA protein has a calculated molecular mass of 53 kDa and is 73% homologous to the H. pylori FlaA subunit. Isogenic flaA and flaB mutants of H. mustelae F1 were constructed by means of reverse genetics. A method was established to generate double mutants (flaA flaB) of H. mustelae F1 as well as H. pylori N6. Genotypes, motility properties, and morphologies of the H. mustelae flagellin mutants were determined and compared with those of the H. pylori flaA and flaB mutants described previously. The flagellar organizations of the two Helicobacter species proved to be highly similar. When the flaB genes were disrupted, motility decreased by 30 to 40%. flaA mutants retained weak motility by comparison with strains that were devoid of both flagellin subunits. Weakly positive motility tests of the flaA mutants correlated with the existence of short truncated flagella. In H. mustelae, lateral as well as polar flagella were present in the truncated form. flaA flaB double mutants were completely nonmotile and lacked any form of flagella. These results show that the presence of both flagellin subunits is necessary for complete motility of Helicobacter species. The importance of this flagellar organization for the ability of the bacteria to colonize the gastric mucosa and to persist in the gastric mucus remains to be proven.     

Serotype-specific epitope(s) present on the VP8 subunit of rotavirus VP4 protein.

cDNA clones representing the VP8 and VP5 subunits of VP4 of symptomatic human rotavirus strain KU (VP7 serotype 1 and VP4 serotype 1A) or DS-1 (VP7 serotype 2 and VP4 serotype 1B) or asymptomatic human rotavirus strain 1076 (VP7 serotype 2 and VP4 serotype 2) were constructed and inserted into the pGEMEX-1 plasmid and expressed in Escherichia coli. Immunization of guinea pigs with the VP8 or VP5 protein of each strain induced antibodies that neutralized the rotavirus from which the VP4 subunits were derived. In a previous study (M. Gorziglia, G. Larralde, A.Z. Kapikian, and R. M. Chanock, Proc. Natl. Acad. Sci. USA 87:7155-7159, 1990), three distinct serotypes and one subtype of VP4 outer capsid protein were identified among 17 human rotavirus strains that had previously been assigned to five distinct VP7 serotypes. The results obtained by cross-immunoprecipitation and by neutralization assay with antisera to the VP8- and VP5-expressed proteins suggest that the VP8 subunit of VP4 contains the major antigenic site(s) responsible for serotype-specific neutralization of rotavirus via VP4, whereas the VP5 subunit of VP4 is responsible for much of the cross-reactivity observed among strains that belong to different VP4 serotypes.     

Variation in the primary structure of Bacillus subtilis flagellins

The flagella derived from 18 strains Bacillus subtilis were tested for their reaction with antiflagellar filament antibody and antiflagellin antibody. On the basis of their reactivity, at least five serologically distinct classes could be identified. Peptide map analysis of tryptic digests of the subunit proteins were consistent with the immunochemical analysis. Large differences in sequence existed among proteins of the different classes; proteins within an antigenic group differed by only a few peptides. Furthermore, 9 of the 27 tryptic peptides resolved were common to flagellin proteins from all the classes examined. The relationship between antigenic specificity, variability in peptide pattern, and the conformation of the flagellin protein are discussed.     

Giant flagellar bundles ofVibrio alginolyticus (NCMB 1803)

Summary Following swarming ofVibrio alginolyticus on solid medium a large number of giant flagellar bundles appear behind the growth front. The suggested sequence of events leading to bundle formation is as follows. After inoculation from liquid to solid media the short rods with a single polar sheathed flagellum develop peritrichous nonsheathed flagella and elongate into long filamentous swarmers. After division into short rods, some of the cells become spherical in shape with many peritrichous flagella concentrated at one pole in close association with the sheathed polar flagellum. These tufted spherical bodies form the template upon which masses of loose peritrichous flagella spontaneously aggregate.Flagellar bundles formed when bacteria are grown at pH 8.5 are longer than those formed at pH 7.2 and shorter when grown at pH 6.5. In distilled water the flagellar bundles disintegrate into masses of flagellar fragments.     

Differentiation Within the Bacterial Flagellum and Isolation of the Proximal Hook

Purified and crude flagellar isolates from cells of Bacillus pumilus NRS 236 were treated with acid, alcohol, acid-alcohol, or heat, and were examined electron microscopically in negatively stained and shadow-cast preparations. Under certain conditions, each of these agents causes the flagella to break between the proximal hooks and the spiral filaments. In such preparations, filaments are seen in various stages of disintegration, whereas hooks of fairly constant length retain their integrity and morphological identity. When crude isolates of flagella are treated under these conditions, the hooks remain attached to membrane fragments or bear basal material. These findings substantiate previous structural observations that led to the view that the proximal hook is a distinct part of the bacterial flagellum and further confirm that the hook is tightly associated with basal material and the cytoplasmic membrane. It appears that the hook is a polarly oriented structure, and that the interactions between the hook and the basal material or the cytoplasmic membrane are different from those between the hook and the filamentous portion of the organelle. Moreover, both types of interaction apparently differ still from those by which the flagellin subunits are held together in the flagellar filament. Hooks were isolated by exploiting the differences in relative stability shown by the various morphological regions of the bacterial flagellum.     

Flagellin phase‐dependent swimming on epithelial cell surfaces contributes to productive Salmonella gut colonisation

The flagellum is a sophisticated nanomachine and an important virulence factor of many pathogenic bacteria. Flagellar motility enables directed movements towards host cells in a chemotactic process, and near‐surface swimming on cell surfaces is crucial for selection of permissive entry sites. The long external flagellar filament is made of tens of thousands subunits of a single protein, flagellin, and many Salmonella serovars alternate expression of antigenically distinct flagellin proteins, FliC and FljB. However, the role of the different flagellin variants during gut colonisation and host cell invasion remains elusive. Here, we demonstrate that flagella made of different flagellin variants display structural differences and affect Salmonella's swimming behaviour on host cell surfaces. We observed a distinct advantage of bacteria expressing FliC‐flagella to identify target sites on host cell surfaces and to invade epithelial cells. FliC‐expressing bacteria outcompeted FljB‐expressing bacteria for intestinal tissue colonisation in the gastroenteritis and typhoid murine infection models. Intracellular survival and responses of the host immune system were not altered. We conclude that structural properties of flagella modulate the swimming behaviour on host cell surfaces, which facilitates the search for invasion sites and might constitute a general mechanism for productive host cell invasion of flagellated bacteria.     

Characteristics of the hydrodynamic and biological properties of flagellar preparations isolated from submerged cultures of S. typhi]

A study was made of the hydrodynamic and biological properties of the flagella from the S. typhi 4446 cultures, isolated by the methods of differential centrifugation, in crude condition and following depolimerization and denaturing by the action of chemical and physical agents. Molecular parameters of the slow and rapid components of the flagella and subunits of the flagellin were compared. The greatest antigenic activity was possessed by the high molecular fraction of the flagella isolated in the 60% sucrose density gradient.