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.     

SEF14菌毛基因操纵子在肠炎沙门氏菌和D-群沙门氏菌的变异分析

【目的】本文旨在探索SEF14菌毛特异性表达于D-群沙门氏菌,特别是肠炎沙门氏菌以及都柏林沙门氏菌的原因。【方法】应用PCR扩增以及序列测定检测了18株鸡白痢沙门氏菌,11株肠炎沙门氏菌以及1株都柏林沙门氏菌标准株中sefA,sefD和sefR基因序列,并分析比对其序列变异。【结果】以11株肠炎沙门氏菌以及1株都柏林沙门氏菌染色体DNA为模板能成功扩增sefA,sefD以及sefR基因;从18株鸡白痢沙门氏菌中均能成功扩增sefA基因,但只有分离于1980年之前的7株分离菌能成功扩增sefD和sefR基因,而另11株1980年后分离菌PCR扩增sefD和sefR基因却无任何产物。比对PCR扩增产物测序结果发现,11株肠炎沙门氏菌以及1株都柏林沙门氏菌株中sefA,sefD以及sefR基因序列和已发表的序列(GenBank登录号为L11008,U07129和AF233854)100%同源;7株鸡白痢沙门氏菌sefD基因测序结果表明,在196位点处发生碱基缺失,造成移码突变,提前于氨基酸残基71位点处产生终止密码子。优化菌毛表达条件,体外抽提和纯化菌毛并进一步试验证明:肠炎沙门氏菌以及都柏林沙门氏菌体外能很好表达SEF14菌毛,但鸡白痢沙门氏菌在相同培养条件下却无任何表达迹象。【结论】SEF14菌毛操纵子亚单位基因sefA,sefD以及调节基因sefR在不同沙门氏菌中的变异情况可能是SEF14菌毛局限性表达的原因之一。     

The flagellin gene and protein from the brewing spoilage bacteria Pectinatus cerevisiiphilus and Pectinatus frisingensis

Flagellin genes from the anaerobic Gram-negative beer-spoilage bacteria Pectinatus cerevisiiphilus and Pectinatus frisingensis were sequenced and the flagellin proteins initially characterized. Protein microsequencing led to the design of two degenerate PCR primers that allowed the P. cerevisiiphilus flagellin gene to be partially sequenced. A combination of PCR and Bubble PCR was then used to sequence the flagellin genes of three isolates from each species. Cloning and gene expression, followed by immunoblotting, confirmed the gene identities as flagellin. Analysis of the gene sequences revealed proteins similar to other bacterial flagellins, including lengths of 446 or 448 amino acids, putative sigma 28 promoters, and a termination loop. Antibody binding studies with isolated flagella correlated with gene sequence comparisons, with both indicating that the P. cerevisiiphilus isolates studied are very similar but that the P. frisingensis isolates show greater variation. Purified flagellins were found to be glycosylated, probably through an O linkage. Phylogenetic analysis revealed greater diversity within the flagellin sequences than within the 16S rRNA genes. Despite the Gram-negative morphology of Pectinatus, this genus proved most closely related to Gram-positive Firmicutes.     

Molecular evolutionary genetics of the cattle-adapted serovar Salmonella dublin.

An electrophoretic analysis of allelic variation at 24 enzyme loci among 170 isolates of the serovar Salmonella dublin (serotype 1,9,12[Vi]:g,p:-) identified three electrophoretic types (Du 1, Du 3, and Du 4), marking three closely related clones, one of which (Du 1) is globally distributed and was represented by 95% of the randomly selected isolates. All but 1 of 114 nonmotile isolates of serotype 1,9,12:-:- recovered from cattle and swine in the United States were genotypically Du 1. The virulence capsular polysaccharide (Vi antigen) is confined to clone Du 3, which apparently is limited in distribution to France and Great Britain. For all 29 isolates of Du 3, positive signals were detected when genomic DNA was hybridized with a probe specific for the ViaB region, which contains the structurally determinant genes for the Vi antigen; and 23 of these isolates had been serologically typed as Vi positive. In contrast, all 30 isolates of Du 1 tested with the ViaB probe were negative. These findings strongly suggest that the ViaB genes were recently acquired by S. dublin via horizontal transfer and additive recombination. The clones of S. dublin are closely similar to the globally predominant clone (En 1) of Salmonella enteritidis (serotype 1,9,12:g,m:-) in both multilocus enzyme genotype and nucleotide sequence of the fliC gene encoding phase 1 flagellin. Comparative sequencing of fliC has revealed the molecular genetic basis for expression of the p and m flagellar epitopes by which these serovars are distinguished in the Kauffmann-White serological scheme of classification.     

Salmonella enteritidis FliC (flagella filament protein) induces human beta-defensin-2 mRNA production by Caco-2 cells

Antimicrobial peptides are crucial for host defense at mucosal surfaces. Bacterial factors responsible for induction of human beta-defensin-2 (hBD-2) mRNA expression in Caco-2 human carcinoma cells were determined. Salmonella enteritidis, Salmonella typhimurium, Salmonella typhi, Salmonella dublin, and culture supernatants of these strains induced hBD-2 mRNA expression in Caco-2 human carcinoma cells. Using luciferase as a reporter gene for a approximately 2.1-kilobase pair hBD-2 promoter, the hBD-2-inducing factor in culture supernatant of S. enteritidis was isolated. The supernatant factor was heat-stable and proteinase-sensitive. After purification by anion exchange and gel filtration chromatography, the hBD-2-inducing factor was identified as a 53-kDa monomeric protein with the amino-terminal sequence AQVINTNSLSLLTQNNLNK, which is identical to that of the flagella filament structural protein (FliC) of S. enteritidis. Consistent with this finding, the 53-kDa protein reacted with anti-FliC antibody, which prevented its induction of hBD-2 mRNA in Caco-2 cells. In agreement, the hBD-2-inducing activity in culture supernatant was completely neutralized by anti-FliC antibody. In gel retardation analyses, FliC increased binding of NF-kappaB (p65 homodimer) to hBD-2 gene promoter sequences. We conclude that S. enteritidis FliC induces hBD-2 expression in Caco-2 cells via NF-kappaB activation and thus plays an important role in up-regulation of the innate immune response.     

Role of the 25-, 27-, and 29-kilodalton flagellins in Caulobacter crescentus cell motility: method for construction of deletion and Tn5 insertion mutants by gene replacement.

Caulobacter crescentus incorporates two distinct, but related proteins into the polar flagellar filament: a 27-kilodalton (kDa) flagellin is assembled proximal to the hook and a 25-kDa flagellin forms the distal end of the filament. These two proteins and a third, related flagellin protein of 29 kDa are encoded by three tandem genes (alpha-flagellin cluster) in the flaEY gene cluster (S.A. Minnich and A. Newton, Proc. Natl. Acad. Sci. USA 84: 1142-1146, 1987). Since point mutations in flagellin genes had not been isolated their requirement for flagellum function and fla gene expression was not known. To address these questions, we developed a gene replacement protocol that uses cloned flagellin genes mutagenized by either Tn5 transposons in vivo or the replacement of specific DNA fragments in vitro by the antibiotic resistance omega cassette. Analysis of gene replacement mutants constructed by this procedure led to several conclusions. (i) Mutations in any of the three flagellin genes do not cause complete loss of motility. (ii) Tn5 insertions in the 27-kDa flagellin gene and a deletion mutant of this gene do not synthesize the 27-kDa flagellin, but they do synthesize wild-type levels of the 25-kDa flagellin, which implies that the 27-kDa flagellin is not required for expression and assembly of the 25-kDa flagellin; these mutants show slightly impaired motility on swarm plates. (iii) Mutant PC7810, which is deleted for the three flagellin genes in the flaEY cluster, does not synthesize the 27- or 29-kDa flagellin, and it is significantly more impaired for motility on swarm plates than mutants with defects in only the 27-kDa flagellin gene. The synthesis of essentially normal levels of 25-kDa flagellin by strain PC7810 confirms that additional copies of the 25-kDa flagellin map outside the flaEY cluster (beta-flagellin cluster) and that these flagellin genes are active. Thus, while the 29- and 27-kDa flagellins are not absolutely essential for motility in C. crescentus, their assembly into the flagellar structure is necessary for normal flagellar function.     

Epigenetic modification of TLRs in leukocytes is associated with increased susceptibility to Salmonella enteritidis in chickens

Toll-like receptors (TLRs) signaling pathways are the first lines in defense against Salmonella enteritidis (S. enteritidis) infection but the molecular mechanism underlying susceptibility to S. enteritidis infection in chicken remains unclear. SPF chickens injected with S. enteritidis were partitioned into two groups, one consisted of those from Salmonella-susceptible chickens (died within 5 d after injection, n = 6), the other consisted of six Salmonella-resistant chickens that survived for 15 d after injection. The present study shows that the bacterial load in susceptible chickens was significantly higher than that in resistant chickens and TLR4, TLR2-1 and TLR21 expression was strongly diminished in the leukocytes of susceptible chickens compared with those of resistant chickens. The induction of expression of pro-inflammatory cytokine genes, IL-6 and IFN-β, was greatly enhanced in the resistant but not in susceptible chickens. Contrasting with the reduced expression of TLR genes, those of the zinc finger protein 493 (ZNF493) gene and Toll-interacting protein (TOLLIP) gene were enhanced in the susceptible chickens. Finally, the expression of TLR4 in peripheral blood mononuclear cells (PBMCs) infected in vitro with S. enteritidis increased significantly as a result of treatment with 5-Aza-2-deoxycytidine (5-Aza-dc) while either 5-Aza-dc or trichostatin A was effective in up-regulating the expression of TLR21 and TLR2-1. DNA methylation, in the predicted promoter region of TLR4 and TLR21 genes, and an exonic CpG island of the TLR2-1 gene was significantly higher in the susceptible chickens than in resistant chickens. Taken together, the results demonstrate that ZNF493-related epigenetic modification in leukocytes probably accounts for increased susceptibility to S. enteritidis in chickens by diminishing the expression and response of TLR4, TLR21 and TLR2-1.     

Identification of a sequence in human toll-like receptor 5 required for the binding of Gram-negative flagellin

Flagellins from Gram-negative bacteria activate inflammatory cells by a toll-like receptor 5 (TLR5)-dependent signaling pathway. We have examined the interaction between flagellin and TLR5 using an in vitro binding assay. Purified recombinant His-tagged flagellin from Salmonella enteritidis bound to TLR5 in detergent lysates from COS-1 cells transiently transfected with a human TLR5 expression plasmid. Flagellins from Salmonella typhimurium and Escherichia coli also bound to TLR5. The specificity of this interaction was demonstrated by its concentration dependence and lack of TLR5 binding to a biologically inactive form of flagellin or to a His-tagged non-flagellar protein. Flagellin bound to the extracellular domain of TLR5 expressed on the surface of COS-1 cells and to a soluble, monomeric form of the extracellular domain (amino acids 1-636). Although a TLR5 extracellular domain containing amino acids 1-407 retained flagellin binding activity, binding was not evident with a TLR5 peptide encoding residues 1-386. Conversely, a peptide containing amino acid residues 386-636 retained flagellin binding. Thus it is likely that amino acids 386-407 is a binding site for flagellin. This sequence contains a putative leucine-rich repeat. These results support the conclusion that flagellin signaling via TLR5 involves a direct interaction between flagellin and a leucine-rich region in TLR5. We also show that the NH2-terminal 358 amino acids of TLR5 play an important role in its signaling activity. Our results provide, for the first time, a molecular basis for the agonist specificity of a TLR.     

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

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

The flagellin gene of Borrelia miyamotoi sp. nov. and its phylogenetic relationship among Borrelia species

Abstract We have cloned and sequenced the flagellin gene from Borrelia miyamotoi strain HT31 and compared it with previously published flagellin sequences. Sequence similarity analysis demonstrated that strain HT31 is phylogenetically distant from the three species of Lyme disease borreliae and is deeply branched into the relapsing fever borrelia cluster. The result was in full agreement with the classification of Borrelia strains using 16S rRNA sequences. This finding indicates that a phylogenetic analysis using flagellin gene sequences might be useful for classification of Borrelia strains.     

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.     

A new type of flagellin gene in Pseudomonas putida

Previously established PCR amplification and Southern hybridization procedures were developed for the isolation of the 0.8-kb flagellin gene in Pseudomonas putida. The deduced protein sequence has significant homology to the N- and C-terminal sequences of other bacterial flagellins. We propose that P. putida flagellin genes can be divided at least into three size groups: type I (2.0 kb), type II (1.4 kb), and type III (0.8 kb). Type I and type II flagellin genes have been reported. The new 0.8-kb type III gene was expressed in E. coli, and the resulting protein was purified and used to raise polyclonal antibody to study whether this small gene encodes flagellin. The antiserum reacted with purified flagellin monomers from representatives of each flagellin type, as well as proteins of the same sizes in lysates of these organisms, on Western immunoblots. This antiserum was determined to be functional in a motility inhibition assay. Similar results were obtained from antiserum directed against purified type III flagellin, indicating that a new type of flagellin gene in P. putida has been found. Preliminary electron microscopic study revealed that P. putida isolate with the smaller flagellin gene type appeared to have a thinner flagellar filament.     

Expression of a bacterial flagellin gene triggers plant immune responses and confers disease resistance in transgenic rice plants

Flagellin is a component of bacterial flagella and acts as a proteinaceous elicitor of defence responses in organisms. Flagellin from a phytopathogenic bacterium, Acidovorax avenae strain N1141, induces immune responses in suspension-cultured rice cells. To analyse the function of flagellin in rice, we fused the N1141 flagellin gene to the cauliflower mosaic virus 35S promoter and introduced it into rice. Many of the resulting transgenic rice plants accumulated flagellin at various levels. The transgenic rice developed pale spots in the leaves. The expression of a defence-related gene for phenylalanine ammonia-lyase was induced in the transgenic plants, and H(2)O(2) production and cell death were observed in some plants with high levels of gene expression, suggesting that the flagellin triggers immune responses in the transgenic rice. Transgenic plants inoculated with Magnaporthe grisea, the causal agent of rice blast, showed enhanced resistance to blast, suggesting that the flagellin production confers disease resistance in the transgenic rice.     

A novel linear plasmid mediates flagellar variation in Salmonella Typhi

Unlike the majority of Salmonella enterica serovars, Salmonella Typhi (S. Typhi), the etiological agent of human typhoid, is monophasic. S. Typhi normally harbours only the phase 1 flagellin gene (fliC), which encodes the H:d antigen. However, some S. Typhi strains found in Indonesia express an additional flagellin antigen termed H:z66. Molecular analysis of H:z66+ S. Typhi revealed that the H:z66 flagellin structural gene (fljB(z66)) is encoded on a linear plasmid that we have named pBSSB1. The DNA sequence of pBSSB1 was determined to be just over 27 kbp, and was predicted to encode 33 coding sequences. To our knowledge, pBSSB1 is the first non-bacteriophage-related linear plasmid to be described in the Enterobacteriaceae.     

Characterization of six flagellin genes in the H3, H53 and H54 standard strains of Escherichia coli

Six flagellin genes in three H standard Escherichia coli strains for H3, H53 and H54 were characterized. Each strain has two flagellin genes, one of which is expressed as its standard H antigen. A pair of flagellin genes flkA3 (encoding for H3 antigen) and fliC16 (H16) was cloned from Bi7327-41, flkA53 (H53) and fliC-53 from E480-68, and flmA54 (H54) and fliC-54 from E223-69. Two fliC genes, fliC-53 and fliC-54, are nonfunctional owing to the insertions of IS1 and IS1222, respectively. The flkA and flmA regions are located in the 3' end of the rnpB gene and near the nlpA gene, respectively. Each of them is followed by a gene homologous to fljA, which is known to repress the expression of fliC(i) in Salmonella enterica serovar Typhimurium. These results suggest that they are derived from the same origin of the fljBA operon. However, these regions contain neither the hin gene nor the invertible H segment. The four flagellin genes, fliC16, flkA3, flkA53 and flmA54, share high homology in nucleotide and amino-acid sequences with one another and with the S. enterica serovar Typhimurium flagellin genes. The promoter sequence of fliC16 is homologous to that of fliC(i), whereas the promoter sequences of flkA and flmA are homologous to that of fljB. The terminator sequences of the fliC16, fliC-53 and fliC-54 genes are conserved among themselves and identical with that of the E. coli fliC48 gene. Three FljA repressors, FljA3, FljA53 and FljA54, are homologous highly with one another and moderately with FljA of Salmonella. These results indicate that six flagellin genes analyzed are markedly similar to the Salmonella flagellin genes, suggesting their lateral transfer from Salmonella.     

Comparative study of the effectiveness of HBcAg presentation to the immune system using attenuated Salmonella strains, serovars S.enteritidis and S.typhimurium

In this work the results of obtaining HBcAg-producing attenuated Salmonella strains, serovars S. enteritidis and S. typhimurium, and their comparative study is presented. As revealed in this study, attenuated S. enteritidis strain E-23 and S. typhimurium strain T-10, producing HBcAg, induce cell-mediated and humoral immune response to HBcAg after injected into anovals. After injection S. typhimurium strain T-10 induces a much higher titer of specific antibodies than S. enteritidis strain E-23. The level of specific antibodies induced by recombinant HBcAg seems to correlate with the capacity of salmonellae for survival inside macroorganisms.