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.     

The Flag-2 locus, an ancestral gene cluster, is potentially associated with a novel flagellar system from Escherichia coli

Escherichia coli K-12 possesses two adjacent, divergent, promoterless flagellar genes, fhiA-mbhA, that are absent from Salmonella enterica. Through bioinformatics analysis, we found that these genes are remnants of an ancestral 44-gene cluster and are capable of encoding a novel flagellar system, Flag-2. In enteroaggregative E. coli strain 042, there is a frameshift in lfgC that is likely to have inactivated the system in this strain. Tiling path PCR studies showed that the Flag-2 cluster is present in 15 of 72 of the well-characterized ECOR strains. The Flag-2 system resembles the lateral flagellar systems of Aeromonas and Vibrio, particularly in its apparent dependence on RpoN. Unlike the conventional Flag-1 flagellin, the Flag-2 flagellin shows a remarkable lack of sequence polymorphism. The Flag-2 gene cluster encodes a flagellar type III secretion system (including a dedicated flagellar sigma-antisigma combination), thus raising the number of distinct type III secretion systems in Escherichia/Shigella to five. The presence of the Flag-2 cluster at identical sites in E. coli and its close relative Citrobacter rodentium, combined with its absence from S. enterica, suggests that it was acquired by horizontal gene transfer after the former two species diverged from Salmonella. The presence of Flag-2-like gene clusters in Yersinia pestis, Yersinia pseudotuberculosis, and Chromobacterium violaceum suggests that coexistence of two flagellar systems within the same species is more common than previously suspected. The fact that the Flag-2 gene cluster was not discovered in the first 10 Escherichia/Shigella genome sequences studied emphasizes the importance of maintaining an energetic program of genome sequencing for this important taxonomic group.     

A genomic islet mediates flagellar phase variation in Escherichia coli strains carrying the flagellin-specifying locus flk

The occurrence of unilateral flagellar phase variation was previously demonstrated in Escherichia coli strains carrying the non-fliC flagellin-specifying locus flk. In this study, we investigated the mechanism involved in this process. By using sequencing and sequence analysis, the flk region between the chromosomal genes yhaC and rnpB was characterized in all described flk-positive E. coli strains, including the H35 strain identified in this study (the other strains used are H3, H36, H47, and H53 strains), and this region was found to contain a putative integrase gene and flanking direct repeats in addition to the flk flagellin-specifying gene flkA and a fliC repressor gene, flkB, indicating that there is a typical genomic islet (GI), which was designated the flk GI. The horizontal transfer potential of the flk GI was indicated by detection of the excised extrachromosomal circular form of the flk GI. By generating fliC-expressing variants of H3 and H47 strains, unilateral flagellar phase variation in flk-positive strains was shown to be mediated by excision of the flk GI. The function of the proposed integrase gene was confirmed by deletion and a complementation test. The potential integration sites of the flk GI were identified. A general model for flagellar phase variation in flk-positive E. coli strains can be expressed as fliC(off) + flkA(on) --> fliC(on) + flkA(none). This is the first time that a molecular mechanism for flagellar phase variation has been reported for E. coli.     

Different alleles of the flagellin gene hagB in Escherichia coli standard H test strains

Abstract The genes determining flagellar antigen specificities H36, H47 and H53 in the respective E. coli standard H test strains were found to be alleles of the flagellin gene hagB . Until now, only the allele encoding the flagellar antigen H3 has been identified. The chromosomal regions of flagellin genes hagB in E. coli and H2 in Salmonella were non-homologous as these genes integrated at different sites in the E. coli K-12 chromosome and were unable to replace each other. The hagA allele encoding E. coli flagellar antigen H48 was insensitive to the repressor produced by Salmonella gene rhl or by its putative analog in E. coli .     

Genes for the hook-basal body proteins of the flagellar apparatus in Escherichia coli.

Of the more than 30 genes required for flagellar function, 6 are located between pyrC and ptsG on the Escherichia coli genetic man. This cluster of genes is called flagellar region I. Four-point transductional crosses were used to establish the position and order of the region I flagellar genes with respect to the outside markers ptsG and pyrC. Bacteriophage lambda-E. coli hybrids that contained most of the genes necessary for flagellar formation were constructed. The properties of specific hybrids that carried the region I fla genes were examined by genetic complementation and by measuring the capacity of the hybrids to direct the synthesis of specific polypeptides. The results of these tests with lambda hybrids and with a series of deletion mutations derived from the lambda hybrids demonstrated the existence of at least six flagellar-specific cistrons. These directed the synthesis of polypeptides with the following apparent molecular weights: flaV, 11,000; flaK, 42,000; flaL, 30,000 and 27,000; flaM, 38,000; flS, 60,000; and flaT, 35,000. Plasmid ColE1-E. coli hybrids with region I flagellar genes were also used to program the synthesis of polypeptides in minicell-producing strains. The polypeptides synthesized in these experiments were identical to polypeptides of the hook-basal body structure and helped to confirm the assignment of genes to specific polypeptides. The synthesis of all of these polypeptides was regulated by the same mechanism that regulates the synthesis of other flagellar-related structural components.     

Isolation of Helicobacter pylori genes that modulate urease activity

Helicobacter pylori urease, a nickel-requiring metalloenzyme, hydrolyzes urea to NH3 and CO2. We sought to identify H. pylori genes that modulate urease activity by constructing pHP8080, a plasmid which encodes both H. pylori urease and the NixA nickel transporter. Escherichia coli SE5000 and DH5alpha transformed with pHP8080 resulted in a high-level urease producer and a low-level urease producer, respectively. An H. pylori DNA library was cotransformed into SE5000 (pHP8080) and DH5alpha (pHP8080) and was screened for cotransformants expressing either lowered or heightened urease activity, respectively. Among the clones carrying urease-enhancing factors, 21 of 23 contained hp0548, a gene that potentially encodes a DNA helicase found within the cag pathogenicity island, and hp0511, a gene that potentially encodes a lipoprotein. Each of these genes, when subcloned, conferred a urease-enhancing activity in E. coli (pHP8080) compared with the vector control. Among clones carrying urease-decreasing factors, 11 of 13 clones contained the flbA (also known as flhA) flagellar biosynthesis/regulatory gene (hp1041), an lcrD homolog. The LcrD protein family is involved in type III secretion and flagellar secretion in pathogenic bacteria. Almost no urease activity was detected in E. coli (pHP8080) containing the subcloned flbA gene. Furthermore, there was significantly reduced synthesis of the urease structural subunits in E. coli (pHP8080) containing the flbA gene, as determined by Western blot analysis with UreA and UreB antiserum. Thus, flagellar biosynthesis and urease activity may be linked in H. pylori. These results suggest that H. pylori genes may modulate urease activity.     

Evolutionary divergence of enterobacterial genes coding for the glucose phosphotransferase system components

Abstract The DNA relatedness of 64 enterobacterial species to Escherichia coli genes pts I, pts H, crr , pts G, and pts LPM, was determined by quantitative filter hybridization. DNA relatedness was expressed relative to E. coli K-12 DNA. Enterobacterial DNAs were 0 to 100% related to E. coli genes and the level of relatedness (except for crr data) reflected the known taxonomic (phylogenetic) position of species with respect to E. coli . When pts I relatedness data were plotted against pts H data, correlation was excellent. In pts G versus pts LPM plots, the data points (species) were scattered along the diagonal with a large gap separating E. coli strains (80–100% relatedness to both probes) from the 63 other species (1 to 40% relatedness to E. coli genes). Serratia (9 species), Buttiauxella agrestis , and Klebsiella planticola gave higher relatedness values with crr probe than with the other probes tested.     

Subdivision of flagellar region III of the Escherichia coli and Salmonella typhimurium chromosomes and identification of two additional flagellar genes.

The many genes involved in flagellar structure and function in Escherichia coli and Salmonella typhimurium are located in three major clusters on the chromosome: flagellar regions I, II and III. We have found that region III does not consist of a contiguous set of flagellar genes, as was thought, but that in E. coli there is almost 7 kb of DNA between the filament cap gene, fliD, and the next known flagellar gene, fliE; a similar situation occurs in S. typhimurium. Most of this DNA is unrelated to flagellar function, since a mutant in which 5.4 kb of it had been deleted remained fully motile and chemotactic as judged by swarming on semi-solid agar. We have therefore subdivided flagellar region III into two regions, IIIa and IIIb. The known genes in region IIIa are fliABCD, all of which are involved in filament structure and assembly, while region IIIb contains genes fliEFGHIJKLMNOPQR, all of which are related to formation of the hook (basal-body)-complex or to even earlier assembly events. We have found that fliD, the last known gene in region IIIa, is immediately followed by two additional genes, both necessary for flagellation, which we have designated fliS and fliT. They encode small proteins with deduced molecular masses of about 15 kDa and 14 kDa, respectively. The functions of FliS and FliT remain to be determined, but they do not appear to be members of the axial family of structural proteins to which FliD belongs.     

Norwegian sheep are an important reservoir for human-pathogenic Escherichia coli O26:H11

A previous national survey of Escherichia coli in Norwegian sheep detected eae-positive (eae(+)) E. coli O26:H11 isolates in 16.3% (80/491) of the flocks. The purpose of the present study was to evaluate the human-pathogenic potential of these ovine isolates by comparing them with E. coli O26 isolates from humans infected in Norway. All human E. coli O26 isolates studied carried the eae gene and shared flagellar type H11. Two-thirds of the sheep flocks and 95.1% of the patients harbored isolates containing arcA allele type 2 and espK and were classified as enterohemorrhagic E. coli (EHEC) (stx positive) or EHEC-like (stx negative). These isolates were further divided into group A (EspK2 positive), associated with stx(2-EDL933) and stcE(O103), and group B (EspK1 positive), associated with stx(1a). Although the stx genes were more frequently present in isolates from patients (46.3%) than in those from sheep flocks (5%), more than half of the ovine isolates in the EHEC/EHEC-like group had multiple-locus variable number of tandem repeat analysis (MLVA) profiles that were identical to those seen in stx-positive human O26:H11 isolates. This indicates that EHEC-like ovine isolates may be able to acquire stx-carrying bacteriophages and thereby have the possibility to cause serious illness in humans. The remaining one-third of the sheep flocks and two of the patients had isolates fulfilling the criteria for atypical enteropathogenic E. coli (aEPEC): arcA allele type 1 and espK negative (group C). The majority of these ovine isolates showed MLVA profiles not previously seen in E. coli O26:H11 isolates from humans. However, according to their virulence gene profile, the aEPEC ovine isolates should be considered potentially pathogenic for humans. In conclusion, sheep are an important reservoir of human-pathogenic E. coli O26:H11 isolates in Norway.     

Genetic analysis of chromosomal resistance to trimethoprim derived from clinical isolates of Escherichia coli

Chromosomal genes conferring resistance to trimethoprim were transferred from three independently isolated thy+ clinical strains of Escherichia coli to Escherichia coli K12 by using P1 transduction. Trimethoprim-resistant transductants were obtained less frequently than transductants of other chromosomal markers, suggesting that there were problems related to the expression of the trimethoprim resistance genes in E. coli K12. Mapping studies revealed that one of the resistance determinants was located at a similar position on the chromosome (1 min) to the fol-type mutations previously described in E. coli K12. The two remaining resistance determinants mapped at separate positions between 2.5 and 3 min on the chromosome. The presence of one of these determinants reduced the efficiency with which either donor or recipient cells carrying it could participate in conjugation mediated by the sex factor F and also resulted in phenotypic interaction with the azi gene. The mechanisms of trimethoprim resistance in the three clinical E. coli isolates studied were more complex and diverse than was expected from previous studies of E. coli K12 mutants.     

Bacterial flagellar diversity in the post-genomic era

Flagellar biosynthesis has been studied most thoroughly in laboratory strains of Escherichia coli and Salmonella enterica. However, genome sequencing has uncovered flagellar loci in distantly related bacteria. We have used homology searches to determine how far the E. coli/S. enterica paradigm can be generalised to other flagellar systems. Numerous previously unrecognized homologues of flagellar components were discovered, including novel FlgM, FlgN, FliK and FliO homologues. Homology was found between the FliK proteins and a molecular ruler, YscP, from a virulence-associated type-III secretion system. Also described is a new family of flagellar proteins, the FlhX proteins, which resemble the cytoplasmic domain of FlhB.     

Expressed and cryptic flagellin genes in the H44 and H55 type strains of Escherichia coli

Bacterial H antigens are specified by flagellin molecules, which constitute the flagellar filament. Escherichia coli 781-55 and E2987-73 are the type strains for H44 and H55 antigens, respectively. Unlike E. coli K-12, they possess two flagellin genes, fliC and fllA, on their chromosomes. However, they are monophasic, expressing exclusively the fllA genes, which specify the type antigens. In this study, the flagellin genes were cloned from these strains and their structure and expression were analyzed. It was found that the fliC genes encode apparently intact flagellin subunits but possess inefficient sigma28-dependent promoters, which may result in these genes being silent. The chromosomal locations of the fllA genes are approximately, but not exactly, identical with that of the phase-2 flagellin gene, fljB, of diphasic Salmonella strains. However, unlike the Salmonella fljB gene, the invertible H segment and the fljA gene responsible for the control of flagellar phase variation are both absent from the fllA loci. The fllA genes are highly homologous to the E. coli fliC gene but distantly related to the Salmonella fljB gene. These results suggest a hypothesis that the fllA genes may have emerged by an intra-species lateral transfer of the fliC gene. This hypothesis is further supported by the observation that the fllA genes are flanked by several IS elements and located within cryptic prophage elements.     

Genetic Analysis of Flagellar Mutants in Escherichia coli

Flagellar mutants in Escherichia coli were obtained by selection for resistance to the flagellotropic phage chi. F elements covering various regions of the E. coli genome were then constructed, and, on the basis of the ability of these elements to restore flagellar function, the mutations were assigned to three regions of the E. coli chromosome. Region I is between trp and gal; region II is between uvrC and aroD; and region III is between his and uvrC. F elements carrying flagellar mutations were constructed. Stable merodiploid strains with a flagellar defect on the exogenote and another on the endogenote were then prepared. These merodiploids yielded information on the complementation behavior of mutations in a given region. Region III was shown to include at least six cistrons, A, B, C, D, E, and F. Region II was shown to include at least four cistrons, G, H, I, and J. Examination of the phenotypes of the mutants revealed that those with lesions in cistron E of region III produce "polyhooks" and lesions in cistron F of region III result in loss of ability to produce flagellin. Mutants with lesions in cistron J of region II were entirely paralyzed (mot) mutants. Genetic analysis of flagellar mutations in region III suggested that the mutations located in cistrons A, B, C, and E are closely linked and mutations in cistrons D and F are closely linked.     

Cloning and characterization of three fatty alcohol oxidase genes from Candida tropicalis strain ATCC 20336

Candida tropicalis (ATCC 20336) converts fatty acids to long-chain dicarboxylic acids via a pathway that includes among other reactions the oxidation of omega-hydroxy fatty acids to omega-aldehydes by a fatty alcohol oxidase (FAO). Three FAO genes (one gene designated FAO1 and two putative allelic genes designated FAO2a and FAO2b), have been cloned and sequenced from this strain. A comparison of the DNA sequence homology and derived amino acid sequence homology between these three genes and previously published Candida FAO genes indicates that FAO1 and FAO2 are distinct genes. Both genes were individually cloned and expressed in Escherichia coli. The substrate specificity and K(m) values for the recombinant FAO1 and FAO2 were significantly different. Particularly striking is the fact that FAO1 oxidizes omega-hydroxy fatty acids but not 2-alkanols, whereas FAO2 oxidizes 2-alkanols but not omega-hydroxy fatty acids. Analysis of extracts of strain H5343 during growth on fatty acids indicated that only FAO1 was highly induced under these conditions. FAO2 contains one CTG codon, which codes for serine (amino acid 177) in C. tropicalis but codes for leucine in E. coli. An FAO2a construct, with a TCG codon (codes for serine in E. coli) substituted for the CTG codon, was prepared and expressed in E. coli. Neither the substrate specificity nor the K(m) values for the FAO2a variant with a serine at position 177 were radically different from those of the variant with a leucine at that position.     

DNA sequence analysis, gene product identification, and localization of flagellar motor components of Escherichia coli.

The Escherichia coli operon designated flaA contains seven flagellar genes; among them are two switch protein genes whose products are believed to interface with the motility and chemotaxis machinery of the cell. Complementation analysis using several plasmids carrying different portions of the flaA operon and analysis of expression of these plasmids in minicells allowed the identification of two flagellar gene products. The MotD (now called FliN) protein, a flagellar switch protein, was determined to have an apparent molecular weight of 16,000, and the FlaAI (FliL) protein, encoded by a previously unidentified gene, had an apparent molecular weight of 17,000. DNA sequence analysis of the motD gene revealed an open reading frame of 414 base pairs. There were two possible initiation codons (ATG) for motD translation, the first of which overlapped with the termination codon of the upstream gene, flaAII (fliN). The wild-type flaAI gene on the chromosome was replaced with a flaAI gene mutated in vitro. Loss of the flaAI gene product resulted in a nonmotile and nonflagellated phenotype. The subcellular location for both the MotD and FlaAI proteins was determined; the FlaAI protein partitioned exclusively in the insoluble fraction of a whole minicell sonic extract, whereas the MotD protein remained in both the soluble and insoluble fractions. In addition, we subcloned a 2.2-kilobase-pair DNA fragment capable of complementing the remaining four genes of the flaA operon (flbD [fliO], flaR [fliP], flaQ [fliQ], and flaP [fliR]).