Pathogen DNA as target for host-generated oxidative stress: Role for repair of bacterial DNA damage in
            <i>Helicobacter pylori</i>
            colonization

O’Rourke, Eyleen J.; Chevalier, Catherine; Pinto, Alicia Viviana; Thiberge, Jean Michel; Ielpi, Luis; Labigne, Agnès; Radicella, J. Pablo

doi:10.1073/pnas.0337641100

Cited by 122 publications

(118 citation statements)

References 37 publications

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“…AF233683). X47 had been used primarily for studies of immune responses and for vaccine development (Ermak et al, 1998;Kleanthous et al, 2001;Londono-Arcila et al, 2002), but is becoming increasingly popular for mutational analyses (Jeong et al, 2001;O'Rourke et al, 2003), in part because it is easier than SS1 to transform with mutated DNAs. Strain X47 lacks the cag pathogenicity island entirely, but contains an s1 allele of vacA (GenBank accession no.…”

Section: Methodsmentioning

confidence: 99%

“…It is one of the most genetically diverse bacterial species: independent clinical isolates typically differ by some 2-5 % in sequences of essential genes and by some 5 % or more in gene content (Achtman et al, 1999;Alm et al, 1999;Israel et al, 2001;Salama et al, 2000). This diversity probably reflects a combination of factors including: (i) mutation (Bjorkholm et al, 2001;Wang & Taylor, 1999); (ii) recombination among divergent lineages (Achtman et al, 1999;Kersulyte et al, 1999;Suerbaum et al, 1998); (iii) gene transfer from unrelated species (Tomb et al, 1997); (iv) preferential transmission among family members, and thus little chance of selection for any one or few potentially optimal genotypes (Mukhopadhyay et al, 2003);and (v) diversity among hosts in traits that are important to individual strains, and selection for adaptive changes after transmission to new hosts (Dubois et al, 1999).…”

Section: Introductionmentioning

confidence: 99%

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Helicobacter pylori tissue tropism: mouse-colonizing strains can target different gastric niches

et al. 2003

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Studies with the mouse-adapted Helicobacter pylori strain SS1 had supported an idea that infections by this pathogen start in the gastric antrum and spread to the corpus after extensive mucosal damage. This paper shows that the unrelated strain X47 colonizes the corpus preferentially. Differences between strains in preferred gastric region were detected by co-inoculating mice with a mixture of SS1 and X47, and genotyping H. pylori recovered after 2-8 weeks of infection by vacA s allele PCR and RAPD fingerprinting. Mixed infections were found in each of 59 co-inoculated young C57BL/6J mice. On average, however, SS1 was fourfold more abundant than X47 in the antrum and X47 was threefold more abundant than SS1 in the corpus. Similar results were obtained in mice inoculated first with one strain and then the other strain 2 weeks later. SS1 was even more abundant in the antrum of elderly (>1 year old) mice (97 % of isolates). Qualitatively similar SS1 and X47 tissue distributions were seen using unrelated mouse lines (AKR/J, A/J, DBA/2J, BALB/cJ, LG/J, SM/J), but with significantly different SS1 : X47 ratios in some cases. These results suggest the existence of at least two distinct gastric niches whose characteristics may be affected by host genotype and age (physiology), and indicate that strains differ in how effectively they colonize each niche. Differences among gastric regions and the mixed infections that these allow may contribute to H. pylori diversity and genome evolution.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Helicobacter pylori tissue tropism: mouse-colonizing strains can target different gastric niches

et al. 2003

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“…A S a defense against bacterial pathogens, higher eukaryotes produce DNA-damaging agents such as nitric oxide (Vazquez-Torres and Fang 2000) and reactive oxygen species (O'Rourke et al 2003). As a consequence, the pathogen relies on protective functions to prevent injuries caused by host-synthesized compounds and on DNA repair functions to repair them.…”

mentioning

confidence: 99%

“…As a consequence, the pathogen relies on protective functions to prevent injuries caused by host-synthesized compounds and on DNA repair functions to repair them. Known examples of DNA repair functions required for bacterial virulence include base excision repair (BER) in Helicobacter pylori (O'Rourke et al 2003) and Salmonella enterica (Suvarnapunya et al 2003), mismatch repair in Listeria monocytogenes (Merino et al 2002), nucleotide excision repair (NER) in Mycobacterium tuberculosis (Darwin and Nathan 2005), and homologous recombination in S. enterica (Buchmeier et al 1993;Cano et al 2002;Schapiro et al 2003).…”

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confidence: 99%

Repair of DNA Damage Induced by Bile Salts in Salmonella enterica

2006

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Exposure of Salmonella enterica to sodium cholate, sodium deoxycholate, sodium chenodeoxycholate, sodium glychocholate, sodium taurocholate, or sodium glycochenodeoxycholate induces the SOS response, indicating that the DNA-damaging activity of bile resides in bile salts. Bile increases the frequency of GC / AT transitions and induces the expression of genes belonging to the OxyR and SoxRS regulons, suggesting that bile salts may cause oxidative DNA damage. S. enterica mutants lacking both exonuclease III (XthA) and endonuclease IV (Nfo) are bile sensitive, indicating that S. enterica requires base excision repair (BER) to overcome DNA damage caused by bile salts. Bile resistance also requires DinB polymerase, suggesting the need of SOS-associated translesion DNA synthesis. Certain recombination functions are also required for bile resistance, and a key factor is the RecBCD enzyme. The extreme bile sensitivity of RecB À , RecC À , and RecA À RecD À mutants provides evidence that bile-induced damage may impair DNA replication.

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“…Additionally, the role of bifunctional BER glycosylases in Salmonella pathogenesis is consistent with that reported for Helicobacter pylori. H. pylori encodes only one oxidative BER glycosylase, Nth, and H. pylori nth mutants are reduced for macrophage survival and are inhibited for colonization in the murine model (O'Rourke et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

DNA base excision repair potentiates the protective effect of Salmonella Pathogenicity Island 2 within macrophages

Suvarnapunya

Stein

2005

Microbiology

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Reactive oxidants are a primary weapon of the macrophage antibacterial arsenal. The ability of virulent Salmonella to repair oxidative DNA lesions via the base-excision repair system (BER) enables its survival and replication within the macrophage, but is not required for extracellular growth. Salmonella also inhibits the targeting of oxidant generators to the Salmonella-containing vacuole (SCV) via Salmonella Pathogenicity Island 2 (SPI2). Accordingly, the relative contributions of these two discrete systems to Salmonella resistance to both oxidative mutagenesis and lethality within RAW 264.7 macrophages were investigated. A mutant unable to initiate BER was constructed by deleting all three BER bifunctional glycosylases (Dfpg/nth/nei ), and was significantly impaired for early intramacrophage survival. Mutations in various SPI2 effector (sifA and sseEFG) and structural (ssaV ) genes were then analysed in the BER mutant background. Loss of SPI2 function alone appeared to increase macrophage-induced mutation. Statistical analyses of the reduced intramacrophage survival of SPI2 mutants and the corresponding SPI2/BER mutants indicated a synergistic interaction between BER and SPI2, suggesting that SPI2 promotes intramacrophage survival by protecting Salmonella DNA from exposure to macrophage oxidants. Furthermore, this protection may involve the SseF and SseG effectors. In contrast, the SifA effector did not seem to play a major role in oxidant protection. It is speculated that Salmonella initially stalls oxidative killing by preserving its genomic integrity through the function of BER, until it can upregulate SPI2 to limit its exposure to macrophage oxidants.

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Pathogen DNA as target for host-generated oxidative stress: Role for repair of bacterial DNA damage in Helicobacter pylori colonization

Cited by 122 publications

References 37 publications

Helicobacter pylori tissue tropism: mouse-colonizing strains can target different gastric niches

Helicobacter pylori tissue tropism: mouse-colonizing strains can target different gastric niches

Repair of DNA Damage Induced by Bile Salts in Salmonella enterica

DNA base excision repair potentiates the protective effect of Salmonella Pathogenicity Island 2 within macrophages

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