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Infection and Immunity, May 2003, p. 2907-2910, Vol. 71, No. 5
0019-9567/03/$08.00+0     DOI: 10.1128/IAI.71.5.2907-2910.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.

Molecular Patchwork: Chromosomal Recombination between Two Helicobacter pylori Strains during Natural Colonization

Department of Medical Microbiology and Infection Control, Vrije Universiteit Medical Center, Amsterdam,¹ Department of Medical Microbiology, Bethesda Hospital, Hoogeveen,² Department of Gastroenterology and Hepatology, Erasmus University Medical Center, Rotterdam, The Netherlands³

Received 7 October 2002/ Returned for modification 17 January 2003/ Accepted 5 February 2003

	ABSTRACT

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Genetic analysis of two Helicobacter pylori strains isolated from a single gastric biopsy showed evidence of extensive horizontal gene transfer. Several large recombinations were identified in the rdxA gene, which is involved in metronidazole resistance.

	TEXT

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The gastric pathogen Helicobacter pylori displays considerable genetic diversity (2). This diversity can be attributed to genetic drift, which was observed in clinical isolates obtained at intervals of several years from one patient (7, 10, 14), and to horizontal gene transfer. Several studies have demonstrated that recombination between H. pylori strains occurs frequently enough to virtually eliminate the effect of clonal descent on the population structure of H. pylori and to generate a linkage equilibrium between alleles at different loci (1, 8, 17, 19). Furthermore, some H. pylori strains contain a 37-kb genomic region, the cag pathogenicity island (PAI), which is located in the glutamate racemase gene between two short direct repeats. The cag PAI is not a stable genomic region, since it can be readily lost from the chromosomes of cag⁺ strains by recombination with strains lacking the cag gene (13, 22). The variability between strains can be significant for the outcome of H. pylori infection. For instance, the cag PAI and certain alleles of the vacA and iceA genes are more frequent in strains that cause peptic ulceration or gastric cancer (4, 24).

In H. pylori, random mutations that inactivate the rdxA gene cause metronidazole resistance (9). rdxA mutations that have been described for resistant isolates include frameshifts, premature stop codons, codon changes resulting in amino acid changes, and promoter alterations (9, 11, 12, 15, 20). In a previous study, we reported that in stomach biopsies with both metronidazole-sensitive (Mtz^s) and metronidazole-resistant (Mtz^r) bacteria, usually a single H. pylori strain is present, which suggested that a subpopulation of the original, susceptible strain had become resistant by mutation (3). However, in one biopsy, random amplified polymorphic DNA and restriction fragment length polymorphism genotyping showed that two different strains were present. Interestingly, both strains contained Mtz^s as well as Mtz^r subpopulations. In the present study we determined whether horizontal gene transfer has occurred between these two strains. The results show that extensive recombination has taken place in the rdxA locus.

Strain identification. Twelve isolates were subcultured from biopsy BH9809-109 and named L1 to L12 according to increasing Mtz resistance (Table 1). Seven isolates (L1 to L7) were Mtz^s (MIC, <8 mg/liter) (Table 1), and five (L8 to L12) were Mtz^r (MIC, 8 mg/liter). Six Mtz^s isolates (L1 to L4, L6, and L8) and three Mtz^r isolates (L9, L11, and L12) belonged to the first genotype (strain 1). The second genotype (strain 2) included two Mtz^s isolates (L5 and L7) and one Mtz^r isolate (L10). cag and vacA statuses were assessed by line probe assay. The line probe assay types two variable regions of the vacA gene, the S region and M region. Furthermore, it determines the presence or absence of the cag PAI (23). Strain 1 isolates contained vacA type S1a/M2 and were cag⁺; strain 2 isolates had vacA type S2/M2 and lacked cag (Table 1). Neither strain showed variation in vacA or cagA status among individual isolates; this indicated that no recombination that affected the S/M type of the vacA gene and the presence of the cag PAI had taken place.

View larger version (48K): [in this window] [in a new window]   FIG. 1. Alignment of the rdxA ORFs of isolates L1 to L12. Numbers in parentheses indicate the strain type (1 or 2).

Origin of metronidazole resistance. All resistant isolates contained rdxA allele A, which suggests transfer of the resistance mutation. However, there was a difference between the resistant isolate of strain 2 (L10) and the resistant isolates of strain 1 (L8, L9, L11, and L12). In L10, a single-base-pair deletion was found at base position 192 of the ORF, causing a frameshift that interrupts the reading frame. This frameshift occurred in a homopolymeric stretch of 10 adenine residues interrupted by one cytosine. An identical deletion was observed earlier in an unrelated strain (11). Apparently, this locus is vulnerable to slipped-strand mispairing. The resistant isolates of strain 1 (L8, L9, L11, and L12) did not possess this frameshift but showed a C-to-T mutation at position 200 of the ORF, which causes an amino acid change from alanine to valine. To confirm that this minor difference causes metronidazole resistance, we used a PCR amplimer of the L8 rdxA allele for natural transformation (25) to susceptible H. pylori strains. This yielded Mtz^r transformants with a frequency of 10^-3 per recipient cell, which indicated that this amino acid change is sufficient to cause metronidazole resistance. We conclude that resistance in both strains arose by an independent mutation of the rdxA gene after transfer of an intact rdxA allele A had taken place. Despite the high frequency of horizontal gene transfer between strain 1 and strain 2, an rdxA mutation arose independently in both strains.

Region around rdxA. In order to determine the length of the recombinations between strain 1 and strain 2, the DNA sequence on both sides of the rdxA ORF was determined for two isolates from strain 1 (L1 with allele B and L4 with allele A), as well as two isolates from strain 2 (L7, which contains the 5' end of allele B and the complementing part of allele A, and isolate L10, which contains allele A). The results are shown in Fig. 2. Downstream, another crossover between the two alleles was identified: after a perfect homology of 145 bp between the four sequences, the sequences of the strain 1 isolates L4 and L1 were identical over a length of at least 205 bp, with eight mismatches between strain 1 (L1 and L4) and strain 2 (L7 and L10). This is concordant with ancestral combinations of strain 1 with allele B and strain 2 with allele A. Upstream of the rdxA ORF, however, the sequences of L1, L4, L7, and L10 were identical over a length of >1.7 kbp (results not shown). It is unlikely that the original sequences of strain 1 and 2 were already identical before their cohabitation, because in this region there is only 94% conservation between these strains and the published genome sequences (2, 21). Apparently, a previous, major recombination event had replaced the original sequence in one of the strains, which results in an identical sequence in all four isolates. In an attempt to find a copy of the other original sequence, from the remaining eight isolates a fragment of 800 bp upstream of rdxA was sequenced. Their sequences were identical to the one in L1, L4, L7, and L10. Thus, the second ancestral sequence is not present in our set of 12 isolates.

View larger version (27K): [in this window] [in a new window]   FIG. 2. Distribution of alleles A and B in isolates L1 to L12. Numbers in parentheses indicate the genotype (1 or 2). S and R, metronidazole susceptibility and resistance, respectively. The arrow shows the rdxA ORF. Open bars, allele A; solid bars, allele B; hatched bars, crossover sequence; gray bars, identical sequence. Strain L4 and strain L7 contain recombined sequences. The point mutations that cause resistance in the resistant isolates L8 to L12 are not shown.

Here, we demonstrate that multiple homologous recombination events occur in a single locus during cohabitation of two strains and that these events result in a molecular patchwork between two ancestral sequences. Since the duration of the contact is not known, we can make no estimate of the frequency of recombination. The sequences upstream of the rdxA ORF are identical for at least 1.7 kb, which suggests that a large fragment was transferred and integrated in the ancestors of all isolates and that H. pylori can exchange DNA fragments long enough to contain one or more complete genes. The lack of polymorphic sites for over 1.7 kb in this area obscures the second recombination site for two of the isolates, L4 and L7 (Fig. 2). Two crossovers had taken place, at 145 and 77 bases of perfect homology. This is in accordance with experimental data which indicate that recombination efficiency is highly dependent on the presence of a perfect homology of sufficient length (18). The molecular patchwork that is described here illustrates the frequent recombination during cocolonization of H. pylori strains that leads to the panmyctic population structure of this species.

	ACKNOWLEDGMENTS

 
We thank Raymond Pot (Department of Gastroenterology and Hepatology, Erasmus University Medical Center, Rotterdam, The Netherlands) for his assistance with DNA sequencing.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Medical Microbiology and Infection Control, Vrije Universiteit Medical Center, Van der Boechorststraat 7, 1081 BT Amsterdam, The Netherlands. Phone: 31 20 4448310. Fax: 31 20 4448318. E-mail: lc.smeets{at}vumc.nl.

Editor: J. T. Barbieri

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