Essential thioredoxin-dependent peroxiredoxin system from Helicobacter pylori: genetic and kinetic characterization.

Helicobacter pylori, an oxygen-sensitive microaerophile, contains an alkyl hydroperoxide reductase homologue (AhpC, HP1563) that is more closely related to 2-Cys peroxiredoxins of higher organisms than to most other eubacterial AhpC proteins. Allelic replacement mutagenesis revealed ahpC to be essential, suggesting a critical role for AhpC in defending H. pylori against oxygen toxicity. Characterization of the ahpC promoter region divulged two putative regulatory elements and identified the transcription initiation site, which was mapped to 96 and 94 bp upstream of the initiation codon. No homologue of ahpF, which encodes the dedicated AhpC reductase in most eubacteria, was found in the H. pylori genome. Instead, homologues of Escherichia coli thioredoxin (Trx) reductase (TrxR, HP0825) and Trx (Trx1, HP0824) formed a reductase system for H. pylori AhpC. A second Trx homologue (Trx2, HP1458) was identified but was incapable of AhpC reduction, although Trx2 exhibited disulfide reductase activity with other substrates [insulin and 5,5'-dithiobis(2-nitrobenzoic acid)]. AhpC interactions with each substrate, Trx1 and hydroperoxide, were bimolecular and nonsaturable (infinite V(max) and K(m) values) but rapid enough (at 1 x 10(5) to 2 x 10(5) M(-1) s(-1)) to suggest an important role for AhpC in cellular peroxide metabolism. AhpC also exhibited a wide specificity for hydroperoxide substrates, which, taken together with the above results, suggests a minimal binding site for hydroperoxides composed of little more than the cysteinyl (Cys49) active site. H. pylori AhpC was not reduced by Salmonella typhimurium AhpF and was slightly more active with E. coli TrxR and Trx1 than was S. typhimurium AhpC, demonstrating the specialized catalytic properties of this peroxiredoxin.

Metronidazole activation is mutagenic and causes DNA fragmentation in Helicobacter pylori and in Escherichia coli containing a cloned H. pylori RdxA(+) (Nitroreductase) gene.

Much of the normal high sensitivity of wild-type Helicobacter pylori to metronidazole (Mtz) depends on rdxA (HP0954), a gene encoding a novel nitroreductase that catalyzes the conversion of Mtz from a harmless prodrug to a bactericidal agent. Here we report that levels of Mtz that partially inhibit growth stimulate forward mutation to rifampin resistance in rdxA(+) (Mtz(s)) and also in rdxA (Mtz(r)) H. pylori strains, and that expression of rdxA in Escherichia coli results in equivalent Mtz-induced mutation. A reversion test using defined lac tester strains of E. coli carrying rdxA(+) indicated that CG-to-GC transversions and AT-to-GC transitions are induced more frequently than other base substitutions. Alkaline gel electrophoretic tests showed that Mtz concentrations near or higher than the MIC for growth also caused DNA breakage in H. pylori and in E. coli carrying rdxA(+), suggesting that this damage may account for most of the bactericidal action of Mtz. Coculture of Mtz(s) H. pylori with E. coli (highly resistant to Mtz) in the presence of Mtz did not stimulate forward mutation in E. coli, indicating that the mutagenic and bactericidal products of Mtz metabolism do not diffuse significantly to neighboring (bystander) cells. Our results suggest that the widespread use of Mtz against other pathogens in people chronically infected with H. pylori may stimulate mutation and recombination in H. pylori, thereby speeding host-specific adaptation, the evolution of virulence, and the emergence of resistance against Mtz and other clinically useful antimicrobials.

Helicobacter pylori with separate beta- and beta'-subunits of RNA polymerase is viable and can colonize conventional mice.

The genes encoding the beta- and beta'-subunits of RNA polymerase (rpoB and rpoC respectively) are fused as one continuous open reading frame in Helicobacter pylori and in other members of this genus, but are separate in other bacterial taxonomic groups, including the closely related genus Campylobacter. To test whether this beta-beta' tethering is essential, we used polymerase chain reaction-based cloning to separate the rpoB and rpoC moieties of the H. pylori rpoB-rpoC fusion gene with a non-polar chloramphenicol resistance cassette containing a new translational start, and introduced this construct into H. pylori by electro-transformation. H. pylori containing these separated rpoB and rpoC genes in place of the native fusion gene produced non-tethered beta and beta' RNAP subunits, grew well in culture and colonized and proliferated well in conventional C57BL/6 mice. Thus, the extraordinary beta-beta' tethering is not essential for H. pylori viability and gastric colonization.

Genotypes of Helicobacter pylori in Lithuanian families.

BACKGROUND: Infection by Helicobacter pylori is very common in Eastern Europe, but the genotypes of predominant strains and prevalence of single vs. multiple infection in this geographic region have not been much studied. MATERIALS AND METHODS: H. pylori was cultured from 13 Lithuanians belonging to six families, and characterized by arbitrarily primed PCR (RAPD) DNA fingerprinting, and by hybridization and PCR tests for polymorphic virulence-associated and neutral genetic markers. RESULTS: Eleven distinct strains were identified: seven carried the cag pathogenicity island (PAI) and the s1 (generally toxigenic) allele of the vacuolating cytotoxin gene (vacA); the other four were cag- and carried the vacA s2 (nontoxigenic) allele; five of the seven vacA s1 strains carried an m1 middle region allele of vacA, whereas all other strains carried m2 alleles, which are generally less toxigenic; four strains carried the virulence-associated iceA1 gene, and the other seven carried the completely unrelated iceA2 gene at the same locus. Insertion sequences IS605 and IS606 and a plasmid replication gene (repA) were also found in some strains. RAPD fingerprinting identified a mixed infection in just one of the 13 persons. In two families, two of the members harbored the same strain, whereas in the other four families each member tested carried a different strain. Resistance to metronidazole (Mtz) was found in two persons; each of them also carried MtzS strains that were indistinguishable from the coresident MtzR strain by RAPD fingerprinting, and that were thus closely related in overall genotype. CONCLUSION: The distribution of genotypes of Lithuanian H. pylori strains resembles that seen in Western Europe. This finding has important implications for understanding modes of H. pylori transmission and evolution.

Prevalence of vacuolating cytotoxin production and distribution of distinct vacA alleles in Helicobacter pylori from China.

Studies of Helicobacter pylori from the West have linked production of vacuolating cytotoxin and a particular signal sequence (s1a) allele of the underlying vacA gene to peptic ulcer disease (PUD). Among Chinese H. pylori, most isolates from both PUD and gastritis patients were toxigenic (35/46 and 29/35, respectively). Polymerase chain reaction and DNA sequencing showed that 95 of 96 isolates carried vacA s1a alleles. In the mid-region, 78 of 96 isolates carried m2; 14 were m1-like but only 87% identical (DNA-level) to classical m1 and were designated m1b; the other 4 were unusual hybrids (m1b-type proximal, m2-type distal). Isolates with m1b and m1b-m2 alleles produced higher levels of vacuolating activity than did isolates with m2 alleles (P < .01). There was no association between any vacA allele and disease. These results suggest that the composition of H. pylori gene pools varies geographically and that other as-yet-unknown polymorphic H. pylori genes are important in PUD.

Overexpression, purification, and characterization of the ADP-ribosyltransferase (gpAlt) of bacteriophage T4: ADP-ribosylation of E. coli RNA polymerase modulates T4 "early" transcription.

The bacteriophage T4 Alt gene product is a component of the phage head and enters the host cell in the process of infection together with the phage DNA. It immediately ADP-ribosylates host RNA polymerase, presumably at only one of the two alpha-subunits. Transcription from T4 "early" promoters, therefore, might be catalyzed, at least in part, by an altered RNA polymerase. The T4 alt gene was cloned into the expression vector pBluescript. E. coli cells, transformed with this recombinant vector, overexpressed the 76 kDa Alt gene product, which was purified to homogeneity. The purified enzyme not only ADP-ribosylates the alpha-subunit of RNA polymerase, but also subunits beta and beta', as well as the sigma 70-factor. The recombinant enzyme behaved like the native enzyme isolated from mature phage particles. The effect of the ribosylation reaction on the transcription activity of host RNA polymerase was investigated in vivo. It results in a modulation of T4 "early" promoter strengths, presumably, in a number of cases, leading to an overexpression of T4 "early" genes. The degree of overexpression, in some cases, should reach 50%, and seems to be well dosed for each promoter, controlling an individual transcription unit.

Cloning and expression of genes from the genomic region between genes cd and 30 of bacteriophage T4.

Ten open reading frames (ORFs) from the cd-30 region of bacteriophage T4, as well as genes 31 and rIII, have been cloned, and all were found to be expressed in a T7 RNA polymerase system. Expression data confirm the existence of genes 31.2, 31.1, 31, rIII, 30.9, 30.8, 30.7, 30.6, 30.5, 30.4, 30.3 and 30.2, which predict peptides of 78, 102, 111, 82, 58, 110, 121, 95, 65, 68, 152 and 278 amino acids (aa), respectively. The major product of gene 30.9 is a basic peptide initiated at the second AUG codon that is found 42 nucleotides downstream and in frame from the first AUG. A plasmid carrying gene 30.3 expresses two different peptides, one of which is of the size predicted for gp30.3. By site-directed mutagenesis we have shown that the smaller peptide is encoded by gene 30.3' which is completely embedded within gene 30.3, but in a different reading frame. Gene 30.3' encodes a 75-aa basic peptide with its C terminus rich in charged aa.

The sequences of gene rIII of bacteriophage T4 and its mutants.

The nucleotide sequences of bacteriophage T4 gene rIII, from six different rIII mutants, have been determined. We show that the mutations r67, rES35 and rES40 cause basic amino acid changes in the rIII protein, while the mutations rBB9, rCR28 and rCP24 cause chain termination.

Expression of bacteriophage T4 gene 25 is regulated via RNA secondary structure in the translational initiation region.

Analysis of the nucleotide sequence in the 5' flanking region of bacteriophage T4 gene 25 revealed three potential Shine and Dalgarno sequences, SD1, SD2 and SD3, with a spacing of 8, 17 and 27 nucleotides from the initiation codon of this gene, respectively. Results of our experiments in the bacteriophage T7 expression system clearly demonstrate that the SD3 sequence is required for efficient expression of gene 25. We propose the existence of a stem-loop structure that includes SD1 and SD2 sequences and brings the SD3 sequence to a favourable spacing with the initiation codon of gene 25. Since the predicted secondary structure in the translational initiation region of gene 25 is relatively unstable and the SD3 sequence, GAGG, is more typical than the SD1 sequence, GAG, we suggest that this structure could control the level of gene expression.

Cloning, sequence, and overexpression of bacteriophage T4 gene 51.

The nucleotide sequence of the 907-bp XbaI-EcoRV T4 DNA fragment containing gene 51 is presented. The sequence of gene 51 predicts a 249 amino acid peptide with an M(r) of 29387 and a pl of 6.34. We have cloned and overexpressed this gene in the T7 RNA polymerase system. The observed molecular mass of gp51 is in agreement with the sequence data. We also show that the low level of gene 51 expression usually seen is caused by an RNA stem-loop structure in the region between genes 26 and 51. In addition, discrepancies with the sequence published by other authors are indicated.

Gene rIII is the nearest downstream neighbour of bacteriophage T4 gene 31.

The nucleotide sequence of the 2218-bp T4 DNA fragment encompassing gene 31 and five complete open reading frames (ORFs) is presented. We show here that one of these ORFs, ORF31.-1, located downstream from gene 31, is the rIII gene. The position of the gene was established by comparison with the sequences of the rIII gene mutants, r67, rES40 and rBB9. The ORF corresponding to the rIII gene encodes a basic protein of 82 amino acids with an M(r) of 9323 and a pI of 9.28. According to the Chou and Fasman [Adv. Enzymol. 47 (1978) 45-148] secondary structure prediction, the rIII protein has a relatively high helical content. In addition, discrepancies with the overlapping sequences determined by other authors in this region are indicated.

An internal AUU codon initiates a smaller peptide encoded by bacteriophage T4 baseplate gene 26.

Bacteriophage T4 baseplate gene 26 codes for two in-frame overlapping peptides with identical C-terminal regions. By site-directed mutagenesis we have now determined that an internal AUU, codon 114 of gene 26, is used as the initiation codon for the synthesis of a smaller peptide (gp26*). Thus gene 26* gives rise to a peptide of 95 amino acid residues with an Mr of 10,873, while the complete gene 26 encodes a peptide of 208 amino acid residues of M(r) 23,880. Expression of gene 26* is shown to depend on the RNA secondary structure in the translational initiation region of this gene.

The nucleotide sequence between genes 31 and 30 of bacteriophage T4.

The nucleotide sequence of the 2994 bp T4 phage DNA fragment between genes 31 and 30 is presented. The fragment contains 7 complete open reading frames in the direction of early transcription and two early promoters, PE128.6 and PE128.2, which we show to cause difficulties in cloning DNA from this genomic region. Our data complete the nucleotide sequence and the organization of genes in the genomic region between T4 genes 31 and 30.