Oxidative stress response genes in Mycobacterium tuberculosis: role of ahpC in resistance to peroxynitrite and stage-specific survival in macrophages

S. S. Master1, B. Springer3, P. Sander3, E. C. Boettger4, V. Deretic1 and G. S. Timmins2

Department of Molecular Genetics and Microbiology1 and Department of Pharmacy2, University of New Mexico Health Sciences Center, 915 Camino de Salud, Albuquerque, NM 87131, USA
Institute for Medical Microbiology, Medizinische Hochschule, 30625, Hannover, Germany3
Institute of Medical Microbiology, University of Zurich, CH-8028 Zurich, Switzerland4

Author for correspondence: V. Deretic. Tel: +1 505 272 0291. Fax: +1 505 272 6029. e-mail: vderetic{at}salud.unm.edu


   ABSTRACT
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES
 
The Mycobacterium tuberculosis ahpC gene, encoding the mycobacterial orthologue of alkylhydroperoxide reductase, undergoes an unusual regulatory cycle. The levels of AhpC alternate between stages of expression silencing in virulent strains grown as aerated cultures, secondary to a natural loss of the regulatory oxyR function in all strains of the tubercle bacillus, and expression activation in static bacilli by a yet undefined mechanism. The reasons for this unorthodox regulatory cycle controlling expression of an antioxidant factor are currently not known. In this work, M. tuberculosis H37Rv and Mycobacterium smegmatis mc2155 ahpC knockout mutants were tested for sensitivity to reactive nitrogen intermediates, in particular peroxynitrite, a highly reactive combinatorial product of reactive nitrogen and oxygen species, and sensitivity to bactericidal mechanisms in resting and activated macrophages. Both M. tuberculosis ahpC::Kmr and M. smegmatis ahpC::Kmr showed increased susceptibility to peroxynitrite. In contrast, inactivation of ahpC in M. tuberculosis did not cause increased sensitivity to donors of NO alone. M. tuberculosis ahpC::Kmr also showed decreased survival in unstimulated macrophages, but the effect was no longer detectable upon IFN{gamma} activation. These studies establish a specific role for ahpC in antioxidant defences involving peroxynitrite and most likely additional cidal mechanisms in macrophages, with the regulatory cycle likely contributing to survival upon coming out of the stationary phase during dormancy (latent infection) or upon transmission to a new host.

Keywords: M. tuberculosis, nitric oxide, ahpC, peroxynitrite, latency

Abbreviations: DETA nonoate, (Z)-1-[N-(2-aminoethyl)-N-(2-ammonioethyl)aminio]diazen-1-ium-1,2-diolate)


   INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES
 
Peroxynitrite (ONOO-) and other reactive nitrogen and oxygen intermediates produced by macrophages play a role in host defence against invading bacteria (Akaki et al., 2000 ; Darrah et al., 2000 ; Karupiah et al., 2000 ; Nathan & Shiloh, 2000 ; Paziak-Domanska et al., 2000 ; Shiloh & Nathan, 2000 ; Yu et al., 1999 ). Consequently, many bacterial pathogens have evolved protection mechanisms against reactive oxygen and nitrogen intermediates (Zahrt & Deretic, 2002 ). In mycobacteria, the katG and ahpC genes are the best studied factors from this class. The katG locus is genetically linked to the furA gene (Deretic et al., 1997 ; Pagan-Ramos et al., 1998 ), which encodes a homologue of the ferric uptake regulator (Baillon et al., 1999 ; Bsat et al., 1998 ; Dubrac & Touati, 2000 ; Hassett et al., 1997 ; Lee et al., 1998 ; Niederhoffer et al., 1990 ; Tardat & Touati, 1993 ; van Vliet et al., 1998 , 1999 ; Zheng et al., 1999 ). Interestingly, the locus encompassing furA and katG has been inactivated in Mycobacterium leprae, but has been preserved in all other mycobacteria (Cole, 1998 ; Deretic et al., 1997 ; Nakata et al., 1997 ; Pagan-Ramos et al., 1998 ). Previous studies in our laboratory indicate that FurA negatively regulates KatG expression in mycobacteria (Zahrt et al., 2001 ), and that there exists a dual and stage-specific induction of the two katG promoters (Master et al., 2001 ). The katG gene encodes a catalase-peroxidase (Heym et al., 1993 ), which in vitro has peroxynitritase and additional redox activities (Heym et al., 1993 ; Magliozzo & Marcinkeviciene, 1997 ; Wengenack et al., 1999 ) and has been shown to play a role in the virulence of M. tuberculosis (Cooper et al., 2000 ; Li et al., 1998 ; Manca et al., 1999 ; Middlebrook & Kohn, 1953 ; Mitchison et al., 1963 ; Morse et al., 1954 ; Wilson et al., 1995 ). The mycobacterial ahpC gene encodes an orthologue of bacterial alkyl hydroperoxidases (Chen et al., 1998 ; Christman et al., 1985 ; Cooper et al., 2000 ; Dhandayuthapani et al., 1996 ; Heym et al., 1997 ; Jacobson et al., 1989 ; Pagan-Ramos et al., 1998 ; Sherman et al., 1996 ; Springer et al., 2001 ; Sreevatsan et al., 1997 ; Wilson et al., 1998 ). In most mycobacteria, the ahpC gene is linked to oxyR and is activated by its gene product, an orthologue of the global regulator OxyR, controlling the peroxide stress response in bacteria (Aslund et al., 1999 ; Christman et al., 1985 ; Storz & Altuvia, 1994 ). In M. tuberculosis as a species, and in all members of the M. tuberculosis complex, the oxyR gene is inactivated and represents a pseudogene (Deretic et al., 1995 , 1997 ). Recently, we have shown that there exists a second level of ahpC regulation independent of oxyR (Springer et al., 2001 ). The ahpC gene is silenced in aerobic cultures of virulent M. tuberculosis, but is activated in statically grown organisms (Springer et al., 2001 ). AhpC has been indirectly implicated in nitric oxide metabolism using expression in heterologous systems like Salmonella (Chen et al., 1998 ). Purified AhpC has been shown to reduce hydroxyperoxide radicals (Chauhan & Mande, 2001 ; Hillas et al., 2000 ) and has also been suggested to have peroxynitritase activity (Bryk et al., 2000 ), but no direct analyses in mycobacteria have been carried out thus far.

Here, we continued our investigations of the role of ahpC in M. tuberculosis biology, specifically with respect to its proposed role in resistance to reactive nitrogen species and survival in macrophages. Using knockout strains of ahpC (ahpC::Kmr) in M. tuberculosis (Springer et al., 2001 ) and M. smegmatis (Dhandayuthapani et al., 1996 ), we compared the wild-type strains and their ahpC mutant derivatives for survival upon exposure to compounds producing reactive nitrogen intermediates and during infection of resting and activated macrophages.


   METHODS
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES
 
Bacterial strains.
M. smegmatis mc2155 strains ahpC+ (wild-type), ahpC::Kmr (VD1865-6; Dhandayuthapani et al., 1996 ) and furA::Kmr (JS106-1; Zahrt et al., 2001 ), and M. tuberculosis H37Rv Strr strains ahpC+ (RvTAM1424, wild-type) and ahpC::Kmr (RvTAM1424-1-1; Springer et al., 2001 ) were constructed previously and the specificity of the mutations confirmed by genetic complementation (Dhandayuthapani et al., 1996 ; Springer et al., 2001 ; Zahrt et al., 2001 ).

Media and growth conditions.
The strains were grown until mid-exponential phase and/or stationary phase (as indicated) on 7H9 (Difco) or 7H11 plates, supplemented with 0·5% Tween, 0·2% glycerol and OADC (oleic acid, 10% bovine serum fraction V, glucose and catalase). Bacteria were grown at 37 °C. All manipulations of live M. tuberculosis were carried out under Biosafety Level 3 conditions.

Chemicals.
Both peroxynitrite and DETA nonoate {(Z)-1-[N-(2-aminoethyl)-N-(2-ammonioethyl)aminio]diazen-1-ium-1,2-diolate)} were purchased from Alexis Corporation.

Detection of lipid peroxides.
Lipid peroxides were detected using FOX II reagent, which provides a sensitive colorimetric assay for peroxides measured spectrophotometrically at 560 nm. FOX II reagent contains 90% methanol, 25 mM H2SO4, 250 µM ferrous sulfate heptahydrate (Sigma) and 100 µM xylene orange (Sigma) (Jiang et al., 1992 ; Nourooz-Zadeh et al., 1994 ; Wolff et al., 1994 ). M. smegmatis mc2155 strains ahpC+ (wild-type), ahpC::Kmr and furA::Kmr were grown until mid-exponential phase. These cultures were then exposed to 1 mM peroxynitrite for five 3 min cycles at 37 °C. One-hundred microlitres of the treated culture was incubated for 10 min with 900 µl FOX II reagent to allow the reaction of peroxides. Experiments were carried out in triplicate and results quantified using a standard curve created with hydrogen peroxide

Sensitivity assays and survival in macrophages.
M. tuberculosis H37Rv ahpC+ and ahpC::Kmr were allowed to reach stationary phase. Similarly, M. smegmatis mc2155 strains ahpC+ (wild-type), ahpC::Kmr and furA::Kmr were grown until mid-exponential or stationary phase. These cultures were then exposed to various concentrations of peroxynitrite and DETA nonoate or used to infect J774A macrophages at an m.o.i. of 10:1 in the presence or absence of IFN{gamma} (500 U ml-1) and LPS (125 ng ml-1). The results of treatment with these compounds and macrophage infections were assessed by plating and c.f.u. determination.


   RESULTS AND DISCUSSION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES
 
Role of ahpC in mycobacterial survival against reactive nitrogen intermediates
M. smegmatis mc2155 strains ahpC+ (wild-type), ahpC::Kmr and furA::Kmr, and M. tuberculosis H37Rv Strr strains ahpC+ (wild-type) and ahpC::Kmr were grown until mid-exponential phase and/or stationary phase as indicated. M. smegmatis mid-exponential-phase and stationary-phase cultures were exposed to peroxynitrite using repeated cycles of addition of fresh reagent to the culture (1, 2 and 5 cycles) of 3 min each at 37 °C (Fig. 1a). The half-life of peroxynitrite in neutral solution is measured in seconds so a 3 min exposure is sufficient to ensure its complete consumption. Our results showed increased sensitivity to peroxynitrite of the ahpC::Kmr mutant M. smegmatis strain compared to ahpC+ cells (Fig. 1a, b). In contrast to the ahpC::Kmr mutant, another M. smegmatis mutant (furA::Kmr) was as resistant to peroxynitrite as the ahpC+ (parental) strain. The differential sensitivity to peroxynitrite was observed irrespective of whether the strains were growing exponentially or had entered stationary phase (Fig. 1b).



View larger version (16K):
[in this window]
[in a new window]
 
Fig. 1. The ahpC gene is required for full resistance of M. smegmatis to peroxynitrite. (a) Survival of mid-exponential phase exponentially growing cultures of M. smegmatis mc2155 ahpC+ ({blacksquare}), ahpC::Kmr ({bullet}) and furA::Kmr ({blacktriangleup}) upon exposure to 0·5 mM peroxynitrite for the indicated number of 3 min cycles. (b) Comparison of mid-exponential-phase ({square}) and stationary-phase ({blacksquare}) cultures of M. smegmatis mc2155 ahpC+, ahpC::Kmr and furA::Kmr exposed to 5 cycles of 1 mM peroxynitrite. Survival is expressed as percentage c.f.u. in untreated controls. **, P<0·01 (ANOVA). Actual P values are given below points showing statistically significant differences.

 
Next, experiments were carried out using M. tuberculosis H37Rv. Since ahpC is not expressed in virulent M. tuberculosis grown with aeration (Springer et al., 2001 ), but is expressed in statically grown cultures, M. tuberculosis H37Rv ahpC+ and its ahpC::Kmr derivative were grown without aeration as described previously (Springer et al., 2001 ). Here too, after 5 cycles of peroxynitrite treatment, a significant increase in sensitivity to peroxynitrite was observed in ahpC::Kmr mutant cells (Fig. 2a). To test the sensitivity of M. tuberculosis H37Rv strains ahpC+ and ahpC::Kmr to NO alone, stationary-phase cultures were exposed to an NO donor, DETA nonoate. No detectable differences in survival were observed between the wild-type and the ahpC::Kmr mutant under the conditions tested (Fig. 2b), although DETA did have an overall inhibitory effect on M. tuberculosis, consistent with a mycobactericidal action of NO.



View larger version (13K):
[in this window]
[in a new window]
 
Fig. 2. The ahpC gene is required for full resistance of M. tuberculosis H37Rv to peroxynitrite, but not to nitric oxide. (a) Survival of M. tuberculosis H37Rv ahpC+ and ahpC::Kmr upon exposure to 0·5 ({blacksquare}) and 1·0 mM ({square}) peroxynitrite. (b) Survival of M. tuberculosis H37Rv ahpC+ ({blacksquare}) and ahpC::Kmr ({square}) treated with the NO donor DETA nonoate. Stationary-phase cultures were exposed to the indicated concentrations for five 3 min cycles (peroxynitrite) or for 3 days (DETA) at 37 °C. Survival is expressed as percentage c.f.u. in untreated cultures. *, P=0·05; **, P=0·01 (ANOVA).

 
Elevated lipid peroxides in the absence of ahpC
Peroxynitrite can react to form several oxidizing species that react with lipids to form lipid peroxides (see Fig. 3a). To examine whether differences in lipid peroxidation could be detected among the three M. smegmatis mc2155 strains, ahpC+ (wild-type), ahpC::Kmr and furA::Kmr, cultures were treated with peroxynitrite as described in Methods and assayed spectrophotometrically using the FOX II reagent. Our results show that the ahpC::Kmr mutant strain produced the maximum amount of lipid peroxides (P<0·5, ANOVA), while the furA::Kmr mutant, which constitutively expresses KatG (Zahrt et al., 2001 ), produced the least amount of lipid peroxides (Fig. 3b). The correlation observed between these results and the sensitivity of the strains to peroxynitrite (compare Fig. 1 with Fig. 3.) suggests that lipid peroxidation levels correlate with the killing of mycobacteria. These results indicate that AhpC protects mycobacteria from the deleterious effects of peroxynitrite-induced oxidation.



View larger version (8K):
[in this window]
[in a new window]
 
Fig. 3. Increased production of lipid peroxides in the absence of the ahpC gene. (a) Chemistry of the reaction of peroxynitrite-derived oxidizing species with lipids to form lipid peroxides. (b) Spectrophotometric detection of lipid hydroperoxides on exposure of M. smegmatis mc2155 ahpC+, ahpC::Kmr and furA::Kmr to 1 mM peroxynitrite for five cycles. Results are expressed as nmol peroxide produced±SE, quantified using a standard curve generated with hydrogen peroxide.

 
Role of AhpC in M. tuberculosis survival during macrophage infection
Statically grown cultures of M. tuberculosis H37Rv ahpC+ and ahpC::Kmr were allowed to reach stationary phase and then used to infect J774A macrophages at an m.o.i. of 10:1 in the presence or absence of IFN{gamma} and LPS. No differences in survival were observed within the first 3 days of infection (data not shown). However, after 7 days of infection, the survival of the mutant and the wild-type differed by one order of magnitude in resting macrophages (Fig. 4, filled bars), indicating a contribution of ahpC to innate defences in unstimulated macrophages, although our data cannot exclude a role for AhpC under some untested, immune phase conditions. The difference between ahpC+ and ahpC::Kmr strains was abrogated in macrophages stimulated with IFN{gamma} and LPS (Fig. 4, open bars). In conclusion, ahpC plays a role in M. tuberculosis survival in macrophages. However, its action seems to be either independent of IFN{gamma}-induced effectors (e.g. NO; compare results with NO donors in Fig. 2), or its contribution is masked by additional cidal mechanisms in activated macrophages or by activation of additional defence mechanisms in M. tuberculosis.



View larger version (11K):
[in this window]
[in a new window]
 
Fig. 4. Decreased survival of M. tuberculosis ahpC::Kmr after 7 days infection in macrophages. Survival is expressed as percentage c.f.u. obtained with ahpC+ cells in unstimulated ({blacksquare}) J774A macrophages at day 7. I+L ({square}) macrophages were activated with 500 U IFN{gamma} ml-1 and 125 ng LPS ml-1.

 
Conclusions
Our results indicate that an intact ahpC gene is preserved in M. tuberculosis, despite the loss of its activator oxyR, because it does confer a selective advantage under a subset of circumstances encountered by the organism during infection as modelled in this study. It is also likely that KatG and AhpC have partially overlapping defence activities, and that they undergo stage-specific and/or tissue-specific expression with compensatory activities, as previously noted (Dhandayuthapani et al., 1996 ; Sherman et al., 1996 ; Heym et al., 1997 ; Master et al., 2001 ; Musser, 1995 ; Wallis et al., 1999 , 2000 ). Thus, the absence of oxyR (Deretic et al., 1995 , 1997 ), the silencing of ahpC (Springer et al., 2001 ), and its differential expression and infection-stage-specific induction (Springer et al., 2001 ) most likely reflect adaptations of M. tuberculosis to various aspects of its infectious cycle. For example, upon transmission to a new host or possibly during initial stages of reactivation from latent infection, the probably stationary-phase M. tuberculosis infects naïve, resting monocytes where ahpC may play a role in resistance to the very early, innate cidal mechanisms in macrophages (as shown in Fig. 4.). Once IFN{gamma} and other protective cytokines become available, ahpC may play a lesser role, as indicated by the loss of differential survival between ahpC+ and ahpC::Kmr cells in macrophages, although our studies do not permit us to rule out a role for AhpC under some other, untested conditions operating during the adaptive immunity stage of the host response to mycobacterial infection. We propose that, at the very minimum, ahpC plays a role of an early sentinel, as the tubercle bacillus comes out of the stationary phase during dormancy (latent infection) upon reactivation or upon transmission to a new host.


   ACKNOWLEDGEMENTS
 
This work was supported by NIH grant AI42999.


   REFERENCES
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES
 
Akaki, T., Tomioka, H., Shimizu, T., Dekio, S. & Sato, K. (2000). Comparative roles of free fatty acids with reactive nitrogen intermediates and reactive oxygen intermediates in expression of the anti-microbial activity of macrophages against Mycobacterium tuberculosis. Clin Exp Immunol 121, 302-310.[Medline]

Aslund, F., Zheng, M., Beckwith, J. & Storz, G. (1999). Regulation of the OxyR transcription factor by hydrogen peroxide and the cellular thiol-disulfide status. Proc Natl Acad Sci USA 96, 6161-6165.[Abstract/Free Full Text]

Baillon, M. L., van Vliet, A. H., Ketley, J. M., Constantinidou, C. & Penn, C. W. (1999). An iron-regulated alkyl hydroperoxide reductase (AhpC) confers aerotolerance and oxidative stress resistance to the microaerophilic pathogen Campylobacter jejuni. J Bacteriol 181, 4798-4804.[Abstract/Free Full Text]

Bryk, R., Griffin, P. & Nathan, C. (2000). Peroxynitrite reductase activity of bacterial peroxiredoxins. Nature 407, 211-215.[Medline]

Bsat, N., Herbig, A., Casillas-Martinez, L., Setlow, P. & Helmann, J. D. (1998). Bacillus subtilis contains multiple Fur homologues: identification of the iron uptake (Fur) and peroxide regulon (PerR) repressors. Mol Microbiol 29, 189-198.[Medline]

Chauhan, R. & Mande, S. C. (2001). Characterization of the Mycobacterium tuberculosis H37Rv alkyl hydroperoxidase AhpC points to the importance of ionic interactions in oligomerization and activity. Biochem J 354, 209-215.[Medline]

Chen, L., Xie, Q. W. & Nathan, C. (1998). Alkyl hydroperoxide reductase subunit C (AhpC) protects bacterial and human cells against reactive nitrogen intermediates. Mol Cell 1, 795-805.[Medline]

Christman, M. F., Morgan, R. W., Jacobson, F. S. & Ames, B. N. (1985). Positive control of a regulon for defenses against oxidative stress and some heat-shock proteins in Salmonella typhimurium. Cell 41, 753-762.[Medline]

Cole, S. T. (1998). The Mycobacterium leprae genome project. Int J Lepr Other Mycobact Dis 66, 589-591.[Medline]

Cooper, A. M., Segal, B. H., Frank, A. A., Holland, S. M. & Orme, I. M. (2000). Transient loss of resistance to pulmonary tuberculosis in p47(phox-/-) mice. Infect Immun 68, 1231-1234.[Abstract/Free Full Text]

Darrah, P. A., Hondalus, M. K., Chen, Q., Ischiropoulos, H. & Mosser, D. M. (2000). Cooperation between reactive oxygen and nitrogen intermediates in killing of Rhodococcus equi by activated macrophages. Infect Immun 68, 3587-3593.[Abstract/Free Full Text]

Deretic, V., Philipp, W., Dhandayuthapani, S., Mudd, M. H., Curcic, R., Garbe, T., Heym, B., Via, L. E. & Cole, S. T. (1995). Mycobacterium tuberculosis is a natural mutant with an inactivated oxidative-stress regulatory gene: implications for sensitivity to isoniazid. Mol Microbiol 17, 889-900.[Medline]

Deretic, V., Song, J. & Pagan-Ramos, E. (1997). Loss of oxyR in Mycobacterium tuberculosis. Trends Microbiol 5, 367-372.[Medline]

Dhandayuthapani, S., Zhang, Y., Mudd, M. H. & Deretic, V. (1996). Oxidative stress response and its role in sensitivity to isonicotinic acid hydrazide in Mycobacterium species: characterization and inducibility of ahpC by peroxides in M. smegmatis and lack of expression in M. aurum and M. tuberculosis. J Bacteriol 178, 3641-3649.[Abstract]

Dubrac, S. & Touati, D. (2000). Fur positive regulation of iron superoxide dismutase in Escherichia coli: functional analysis of the sodB promoter. J Bacteriol 182, 3802-3808.[Abstract/Free Full Text]

Hassett, D. J., Howell, M. L., Ochsner, U. A., Vasil, M. L., Johnson, Z. & Dean, G. E. (1997). An operon containing fumC and sodA encoding fumarase C and manganese superoxide dismutase is controlled by the ferric uptake regulator in Pseudomonas aeruginosa: fur mutants produce elevated alginate levels. J Bacteriol 179, 1452-1459.[Abstract]

Heym, B., Zhang, Y., Poulet, S., Young, D. & Cole, S. T. (1993). Characterization of the katG gene encoding a catalase-peroxidase required for the isoniazid susceptibility of Mycobacterium tuberculosis. J Bacteriol 175, 4255-4259.[Abstract]

Heym, B., Stavropoulos, E., Honore, N., Domenech, P., Saint-Joanis, B. T., Wilson, M., Collins, D. M., Colston, M. J. & Cole, S. T. (1997). Effects of overexpression of the alkyl hydroperoxide reductase AhpC on the virulence and isoniazid resistance of Mycobacterium tuberculosis. Infect Immun 65, 1395-1401.[Abstract]

Hillas, P. J., del Alba, F. S., Oyarzabal, J., Wilks, A. & Ortiz De Montellano, P. R. (2000). The AhpC and AhpD antioxidant defense system of Mycobacterium tuberculosis. J Biol Chem 275, 18801-18809.[Abstract/Free Full Text]

Jacobson, F. S., Morgan, R. W., Christman, M. F. & Ames, B. N. (1989). An alkyl hydroperoxide reductase from Salmonella typhimurium involved in the defense of DNA against oxidative damage. J Biol Chem 264, 1488-1496.[Abstract/Free Full Text]

Jiang, Z.-Y., Hunt, J. V. & Wolff, S. P. (1992). Ferrous ion oxidation in the presence of xylenol orange for detection of lipid hydroperoxide in low-density lipoprotein. Ann Biochem 202, 384-389.

Karupiah, G., Hunt, N. H., King, N. J. & Chaudhri, G. (2000). NADPH oxidase, Nramp1 and nitric oxide synthase 2 in the host antimicrobial response. Rev Immunogenet 2, 387-415.[Medline]

Lee, H. S., Lee, Y. S., Kim, H. S., Choi, J. Y., Hassan, H. M. & Chung, M. H. (1998). Mechanism of regulation of 8-hydroxyguanine endonuclease by oxidative stress: roles of FNR, ArcA, and Fur. Free Radic Biol Med 24, 1193-1201.[Medline]

Li, Z., Kelley, C., Collins, F., Rouse, D. & Morris, S. (1998). Expression of katG in Mycobacterium tuberculosis is associated with its growth and persistence in mice and guinea pigs. J Infect Dis 177, 1030-1035.[Medline]

Magliozzo, R. S. & Marcinkeviciene, J. A. (1997). The role of Mn(II)-peroxidase activity of mycobacterial catalase-peroxidase in activation of the antibiotic isoniazid. J Biol Chem 272, 8867-8870.[Abstract/Free Full Text]

Manca, C., Paul, S., Barry, C. E.3rd, Freedman, V. H. & Kaplan, G. (1999). Mycobacterium tuberculosis catalase and peroxidase activities and resistance to oxidative killing in human monocytes in vitro. Infect Immun 67, 74-79.[Abstract/Free Full Text]

Master, S., Zahrt, T. C., Song, J. & Deretic, V. (2001). Mapping of Mycobacterium tuberculosis katG promoters and their differential expression in infected macrophages. J Bacteriol 183, 4033-4039.[Abstract/Free Full Text]

Middlebrook, G. & Kohn, M. L. (1953). Some observations on the pathogenicity of isoniazid resistant variants of the tubercle bacilli. Science 118, 297-299.

Mitchison, D. A., Selkon, J. B. & Lloyd, J. (1963). Virulence in the guinea pig, susceptibility to hydrogen peroxide, and catalase activity of isoniazid-sensitive tubercle bacilli from South Indian and British patients. J Pathol Bacteriol 86, 377-386.[Medline]

Morse, W. C., Weiser, O. L., Kuhns, D. M., Fusillo, M., Dail, M. C. & Evans, J. R. (1954). Study of the virulence of isoniazid-resistant tubercle bacilli in guinea pigs and mice. Am Rev Tuberc 69, 464-468.[Medline]

Musser, J. M. (1995). Antimicrobial agent resistance in mycobacteria: molecular genetic insights. Clin Microbiol Rev 8, 496-514.[Abstract]

Nakata, N., Matsuoka, M., Kashiwabara, Y., Okada, N. & Sasakawa, C. (1997). Nucleotide sequence of the Mycobacterium leprae katG region. J Bacteriol 179, 3053-3057.[Abstract]

Nathan, C. & Shiloh, M. U. (2000). Reactive oxygen and nitrogen intermediates in the relationship between mammalian hosts and microbial pathogens. Proc Natl Acad Sci USA 97, 8841-8848.[Abstract/Free Full Text]

Niederhoffer, E. C., Naranjo, C. M., Bradley, K. L. & Fee, J. A. (1990). Control of Escherichia coli superoxide dismutase (sodA and sodB) genes by the ferric uptake regulation (fur) locus. J Bacteriol 172, 1930-1938.[Medline]

Nourooz-Zadeh, J., Tajaddini-Sarmadi, J. & Wolff, S. P. (1994). Measurement of plasma hydroperoxide concentrations by the ferrous oxidation xylenol orange assay in conjunction with triphenylphosphine. Anal Biochem 220, 403-409.[Medline]

Pagan-Ramos, E., Song, J., McFalone, M., Mudd, M. H. & Deretic, V. (1998). Oxidative stress response and characterization of the oxyR-ahpC and furA-katG loci in Mycobacterium marinum. J Bacteriol 180, 4856-4864.[Abstract/Free Full Text]

Paziak-Domanska, B., Klink, M., Jurkiewicz, M. & Rudnicka, W. (2000). Production of reactive nitrogen and oxygen intermediates in human granulocytes and monocytes during internalization of live BCG bacilli. Med Dosw Mikrobiol 52, 353-360.[Medline]

Sherman, D. R., Mdluli, K., Hickey, M. J., Arain, T. M., Morris, S. L., Barry, C. E. & Stover, C. K. (1996). Compensatory ahpC gene expression in isoniazid-resistant Mycobacterium tuberculosis. Science 272, 1641-1643.[Abstract]

Shiloh, M. U. & Nathan, C. F. (2000). Reactive nitrogen intermediates and the pathogenesis of Salmonella and mycobacteria. Curr Opin Microbiol 3, 35-42.[Medline]

Springer, B., Master, S., Sander, P. & 7 other authors (2001). Silencing the oxidative stress response in Mycobacterium tuberculosis: Expression patterns of ahpC in virulent and avirulent strains and the effect of ahpC inactivation. Infect Immun 69, 5967–5973.[Abstract/Free Full Text]

Sreevatsan, S., Pan, X., Zhang, Y., Deretic, V. & Musser, J. M. (1997). Analysis of the oxyR-ahpC region in isoniazid-resistant and -susceptible Mycobacterium tuberculosis complex organisms recovered from diseased humans and animals in diverse localities. Antimicrob Agents Chemother 41, 600-606.[Abstract]

Storz, G. & Altuvia, S. (1994). OxyR regulon. Methods Enzymol 234, 217-223.[Medline]

Tardat, B. & Touati, D. (1993). Iron and oxygen regulation of Escherichia coli MnSOD expression: competition between the global regulators Fur and ArcA for binding to DNA. Mol Microbiol 9, 53-63.[Medline]

van Vliet, A. H., Wooldridge, K. G. & Ketley, J. M. (1998). Iron-responsive gene regulation in a Campylobacter jejuni fur mutant. J Bacteriol 180, 5291-5298.[Abstract/Free Full Text]

van Vliet, A. H., Baillon, M. L., Penn, C. W. & Ketley, J. M. (1999). Campylobacter jejuni contains two fur homologs: characterization of iron-responsive regulation of peroxide stress defense genes by the PerR repressor. J Bacteriol 181, 6371-6376.[Abstract/Free Full Text]

Wallis, R. S., Patil, S., Cheon, S. H. & 12 other authors (1999). Drug tolerance in Mycobacterium tuberculosis. Antimicrob Agents Chemother 43, 2600–2606.[Abstract/Free Full Text]

Wallis, R. S., Perkins, M. D., Phillips, M. & 10 other authors (2000). Predicting the outcome of therapy for pulmonary tuberculosis. Am J Respir Crit Care Med 161, 1076–1080.[Abstract/Free Full Text]

Wengenack, N. L., Jensen, M. P., Rusnak, F. & Stern, M. K. (1999). Mycobacterium tuberculosis KatG is a peroxynitritase. Biochem Biophys Res Commun 256, 485-487.[Medline]

Wilson, T., de Lisle, G. W., Marcinkeviciene, J. A., Blanchard, J. S. & Collins, D. M. (1998). Antisense RNA to ahpC, an oxidative stress defence gene involved in isoniazid resistance, indicates that AhpC of Mycobacterium bovis has virulence properties. Microbiology 144, 2687-2695.[Abstract]

Wilson, T. M., de Lisle, G. W. & Collins, D. M. (1995). Effect of inhA and katG on isoniazid resistance and virulence of Mycobacterium bovis. Mol Microbiol 15, 1009-1015.[Medline]

Wolff, S. P. (1994). Ferrous ion oxidation in the presence of ferric iron indicator xylenol orange for measurement of hydroperoxides. Methods Enzymol 223, 182-189.

Yu, K., Mitchell, C., Xing, Y., Magliozzo, R. S., Bloom, B. R. & Chan, J. (1999). Toxicity of nitrogen oxides and related oxidants on mycobacteria: M. tuberculosis is resistant to peroxynitrite anion. Tuber Lung Dis 79, 191-198.[Medline]

Zahrt, T. C. & Deretic, V. (2002). Reactive nitrogen and oxygen intermediates and bacterial defenses: unusual adaptations in Mycobacterium tuberculosis. Antioxid Redox Signal 4, 141-159.[Medline]

Zahrt, T. C., Song, J., Siple, J. & Deretic, V. (2001). Mycobacterial FurA is a negative regulator of catalase-peroxidase gene katG. Mol Microbiol 39, 1174-1185.[Medline]

Zheng, M., Doan, B., Schneider, T. D. & Storz, G. (1999). OxyR and SoxRS regulation of fur. J Bacteriol 181, 4639-4643.[Abstract/Free Full Text]

Received 22 March 2002; revised 22 June 2002; accepted 26 July 2002.