Superoxide Dismutase-Deficient Mutants of
            <i>Helicobacter pylori</i>
            Are Hypersensitive to Oxidative Stress and Defective in Host Colonization

Seyler, Richard W.; Olson, Jonathan W.; Maier, Robert J.

doi:10.1128/iai.69.6.4034-4040.2001

Cited by 147 publications

(130 citation statements)

References 38 publications

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“…Although postulated, oxidative host-generated lethal or premutagenic DNA damage on H. pylori DNA has not been demonstrated (6)(7)(8). Superoxide dismutase-deficient mutants have an impaired ability to colonize the mouse stomach, confirming that this pathogen is exposed to the toxic effect of oxygen-derived products during infection (6). The fact that superoxide dismutase is associated with the bacterial surface is consistent with its action as a primary barrier for exogenous reactive molecules.…”

mentioning

confidence: 55%

“…H. pylori induces an oxidative stress that enhances DNA damage in the host's gastric mucosa (2)(3)(4)(5). Although postulated, oxidative host-generated lethal or premutagenic DNA damage on H. pylori DNA has not been demonstrated (6)(7)(8). Superoxide dismutase-deficient mutants have an impaired ability to colonize the mouse stomach, confirming that this pathogen is exposed to the toxic effect of oxygen-derived products during infection (6).…”

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confidence: 90%

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

O’Rourke

Chevalier

Pinto

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

122

110

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Helicobacter pylori elicits an oxidative stress during host colonization. This oxidative stress is known to cause lesions in the host DNA. Here we addressed the question as to whether the pathogen DNA is subject to lethal or mutational damage by the host-generated oxidative response. H. pylori Hpnth mutants unable to repair oxidized pyrimidines from the bacterial DNA were generated. H. pylori strains lacking a functional endonuclease III (HpNth) showed elevated spontaneous and induced mutation rates and were more sensitive than the parental strain to killing by exposure to oxidative agents or activated macrophages. Although under laboratory conditions the Hpnth mutant strain grows as well as the wild-type strain, in a mouse infection the stomach bacterial load gradually decreases while the population in the wild-type strain remains stable, showing that endonuclease III deficiency reduces the colonization capacity of the pathogen. In coinfection experiments with a wild-type strain, Hpnth cells are eradicated 15 days postinfection (p.i.) even when inoculated in a 1:9 wild-type:mutant strain ratio, revealing mutagenic lesions that are counterselected under competition conditions. These results show that the host effectively induces lethal and premutagenic oxidative DNA adducts on the H. pylori genome. The possible consequences of these DNA lesions on the adaptability of H. pylori strains to new hosts are discussed.

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confidence: 55%

mentioning

confidence: 90%

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

O’Rourke

Chevalier

Pinto

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

122

110

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“…However, superoxide-deficient mutants of aerobic organisms [e.g. E. coli (Carlioz & Touati, 1986), Candida albicans (Hwang et al, 2002), Streptococcus agalactiae (Poyart et al, 2001)], or of microaerophilic bacteria exemplified by Helicobacter pylori (Seyler et al, 2001), have been readily obtained. These mutants are generally more sensitive to oxygen or to oxidative stress than the wild-type and display an increased susceptibility to bacterial killing by macrophages.…”

Section: Discussionmentioning

confidence: 99%

Oxidative stress response in Clostridium perfringens

2004

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Clostridium perfringens, a strictly anaerobic bacterium, is able to survive when exposed to oxygen for short periods of time and exhibits a complex adaptive response to reactive oxygen species, both under aerobic and anaerobic conditions. However, this adaptive response is not completely understood. C. perfringens possesses specialized genes that might be involved in this adaptive process, such as those encoding superoxide dismutase (SOD), superoxide reductase and alkyl hydroperoxide reductase, but their contribution to the oxidative stress response and their control mechanisms are unknown. By a combination of functional complementation of Escherichia coli strains impaired in either SOD, alkyl hydroperoxide reductase (AhpC) or catalase activity (Cat), transcription analysis and characterization of mutants impaired in regulatory genes, it was concluded that: (i) the product of the sod gene is certainly essential to scavenge superoxide radicals, (ii) the ahpC gene, which is fully induced in all oxidative stress conditions, is probably involved in the scavenging of all intracellular peroxides, (iii) the three rubrerythrin (rbr) genes of C. perfringens do not encode proteins with in vivo H 2 O 2 reductase activity, and (iv) the two rubredoxin (rub) genes do not contribute to the hypothetical superoxide reductase activity, but are likely to belong to an electron transfer chain involved in energy metabolism.

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“…The construction of other mutant strains (sodB, mdaB, ahpC1, ahpC2, ahpC,napA, and napA) in our laboratory was described previously (13,15,18). An H. pylori ATCC43504 katA,ahpC double mutant was constructed in this study by transforming ahpC:Kan (type I) mutant strain with the plasmid pGEM-katA:Cm.…”

Section: Methodsmentioning

confidence: 99%

“…NapA, a ferritin-like iron-binding protein, is involved in oxidative stress resistance probably through sequestering free iron in the cells (13,14); also, a NADPH quinone reductase (MdaB) confers oxidative stress resistance by maintaining the quinone pool of the cell in the reduced state (15). The disruption of each individual gene for superoxide dismutase, KatA, AhpC, or MdaB affects severely the ability of the bacterium to colonize the host stomach (15)(16)(17)(18), demonstrating the importance of these enzymes in oxidative stress resistance and host colonization.…”

mentioning

confidence: 99%

Role of a Bacterial Organic Hydroperoxide Detoxification System in Preventing Catalase Inactivation

Wang¹,

Conover

Benoit³

et al. 2004

Journal of Biological Chemistry

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In the gastric pathogen Helicobacter pylori, catalase (KatA) and alkyl hydroperoxide reductase (AhpC) are two highly abundant enzymes that are crucial for oxidative stress resistance and survival of the bacterium in the host. Here we report a connection unidentified previously between the two stress resistance enzymes. We observed that the catalase in ahpC mutant cells in comparison with the parent strain is inactivated partially (approximately 50%). The decrease of catalase activity is well correlated with the perturbation of the heme environment in catalase, as detected by electron paramagnetic resonance spectroscopy. To understand the reason for this catalase inactivation, we examined the inhibitory effects of hydroperoxides on H. pylori catalase (either present in cell extracts or added to the purified enzyme) by monitoring the enzyme activity and the EPR signal of catalase. H. pylori catalase is highly resistant to its own substrate, without the loss of enzyme activity by treatment with a molar ratio of 1:3000 H 2 O 2 . However, it is inactivated by lower concentrations of organic hydroperoxides (the substrate of AhpC). Treatment with a molar ratio of 1:400 t-butyl hydroperoxide resulted in an inactivation of catalase by approximately 50%. UV-visible absorption spectra indicated that the catalase inactivation by organic hydroperoxides is caused by the formation of a catalytically incompetent compound II species. To further support the idea that organic hydroperoxides, which accumulate in the ahpC mutant cells, are responsible for the inactivation of catalase, we compared the level of lipid peroxidation found in ahpC mutant cells with that found in wild type cells. The results showed that the total amount of extractable lipid hydroperoxides in the ahpC mutant cells is approximately three times that in the wild type cells. Our findings reveal a novel role of the organic hydroperoxide detoxification system in preventing catalase inactivation.

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Superoxide Dismutase-Deficient Mutants of Helicobacter pylori Are Hypersensitive to Oxidative Stress and Defective in Host Colonization

Cited by 147 publications

References 38 publications

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

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

Oxidative stress response in Clostridium perfringens

Role of a Bacterial Organic Hydroperoxide Detoxification System in Preventing Catalase Inactivation

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