NADPH: ferredoxin oxidoreductase acts as a paraquat diaphorase and is a member of the soxRS regulon

Response of Mycobacterium tuberculosis to reactive oxygen and nitrogen intermediates

BACKGROUND

Mycobacterium tuberculosis is a significant human pathogen capable of replicating in mononuclear phagocytic cells. Exposure to reactive oxygen and nitrogen intermediates is likely to represent an important aspect of the life cycle of this organism. The response of M. tuberculosis to these agents may be of significance for its survival in the host.

MATERIALS AND METHODS

Patterns of de novo proteins synthesized in M. tuberculosis H37Rv exposed to compounds that generate reactive oxygen and nitrogen intermediates were studied by metabolic labeling and two-dimensional electrophoresis.

RESULTS

Menadione, a redox cycling compound which increases intracellular superoxide levels, caused enhanced synthesis of seven polypeptides, six of which appeared to be heat shock proteins. Chemical release of nitric oxide induced eight polypeptides of which only one could be identified as a heat shock protein. Nitric oxide also exhibited a mild inhibitory action on general protein synthesis in the concentration range tested. Hydrogen peroxide did not cause differential gene expression and exerted a generalized inhibition in a dose-dependent manner. Cumene hydroperoxide caused mostly inhibition but induction of two heat shock proteins was detectable.

CONCLUSIONS

The presented findings indicate major differences between M. tuberculosis and the paradigms of oxidative stress response in enteric bacteria, and are consistent with the multiple lesions found in oxyR of this organism. The effect of hydrogen peroxide, which in Escherichia coli induces eight polypeptides known to be controlled by the central regulator oxyR, appears to be absent in M. tuberculosis. Superoxide and nitric oxide responses, which in E. coli overlap and are controlled by the same regulatory system soxRS, represent discrete and independent phenomena in M. tuberculosis.

Purification and regulatory properties of MarA protein, a transcriptional activator of Escherichia coli multiple antibiotic and superoxide resistance promoters

Expression of the marA or soxS genes is induced by exposure of Escherichia coli to salicylate or superoxides, respectively. This, in turn, enhances the expression of a common set of promoters (the mar/soxRS regulons), resulting in both multiple antibiotic and superoxide resistance. Since MarA protein is highly homologous to SoxS, and since a MalE-SoxS fusion protein has recently been shown to activate soxRS regulon transcription, the ability of MarA to activate transcription of these genes was tested. MarA was overexpressed as a histidine-tagged fusion protein, purified, cleaved with thrombin (leaving one N-terminal histidine residue), and renatured. Like MalE-SoxS, MarA (i) activated the transcription of zwf, fpr, fumC, micF, nfo, and sodA; (ii) required a 21-bp "soxbox" sequence to activate zwf transcription; and (iii) was "ambidextrous," i.e., required the C-terminal domain of the alpha subunit of RNA polymerase for activation of zwf but not fumC or micF. Thus, the mar and soxRS systems use activators with very similar specificities and mechanisms of action to respond to different environmental signals.

Azotobacter vinelandii NADPH:ferredoxin reductase cloning, sequencing, and overexpression

Azotobacter vinelandii ferredoxin I (AvFdI) controls the expression of another protein that was originally designated Protein X. Recently we reported that Protein X is a NADPH-specific flavoprotein that binds specifically to FdI (Isas, J.M., and Burgess, B.K. (1994) J. Biol. Chem. 269, 19404-19409). The gene encoding this protein has now been cloned and sequenced. Protein X is 33% identical and has an overall 53% similarity with the fpr gene product from Escherichia coli that encodes NADPH:ferredoxin reductase. On the basis of this similarity and the similarity of the physical properties of the two proteins, we now designate Protein X as A. vinelandii NADPH:ferredoxin reductase and its gene as the fpr gene. The protein has been overexpressed in its native background in A. vinelandii by using the broad host range multicopy plasmid, pKT230. In addition to being regulated by FdI, the fpr gene product is overexpressed when A. vinelandii is grown under N2-fixing conditions even though the fpr gene is not preceded by a nif specific promoter. By analogy to what is known about fpr expression in E. coli, we propose that FdI may exert its regulatory effect on fpr by interacting with the SoxRS regulon.

Interruption of the ferredoxin (flavodoxin) NADP+ oxidoreductase gene of Escherichia coli does not affect anaerobic growth but increases sensitivity to paraquat

Ferredoxin (flavodoxin) NADP+ oxidoreductase participates in methionine biosynthesis and in the function of two anaerobic enzymes, pyruvate formate-lyase and ribonucleotide reductase. We prepared insertion mutants of Escherichia coli lacking a functional enzyme. They do not require methionine and they grow well anaerobically, but they show increased sensitivity to paraquat.

Isolation of a novel paraquat-inducible (pqi) gene regulated by the soxRS locus in Escherichia coli

We have isolated promoters inducible by paraquat, a superoxide radical-generating agent, from Escherichia coli, using promoter-probing plasmid pJAC4 (Y.S. Koh and J.H. Roe, Korean J. Microbiol. 31:267-273, 1993). One promoter clone pqi-5 (pqi denotes paraquat-inducible gene) was mapped at 21.8 min on the E. coli chromosome by using the Kohara phage library. We constructed an operon fusion of the lacZ gene with the pqi-5 promoter to monitor the expression of the gene in the single-copy state. LacZ expression was induced about 7- to 13-fold by 77 to 780 microM paraquat. Other known superoxide generators such as menadione, phenazine methosulfate, and plumbagin also induced the expression of beta-galactosidase in this fusion strain. On the other hand, no significant induction was observed with treatment with hydrogen peroxide, ethanol, and heat shock. Induction of beta-galactosidase was significantly reduced by introducing a delta sox-8::cat or soxS3::Tn10 mutation into the fusion strain, indicating that pqi-5 is a member of the soxRS regulon. A DNA fragment containing the pqi-5 promoter was cloned and sequenced from the Kohara phage E2E5. We identified two pqi-5 open reading frames (ORFs); ORF-A encodes a predicted protein of 342 amino acids, and ORF-B is truncated at the cloning site. The transcription start site from the pqi-5 promoter was determined by primer extension and S1 nuclease protection analyses. Northern (RNA) and S1 analyses indicated that there are two kinds of pqi-5 transcript; one covers ORF-A only and the other covers ORF-A and possibly also ORF-B.

Overproduction and physical characterization of SoxR, a [2Fe-2S] protein that governs an oxidative response regulon in Escherichia coli

SoxR protein governs the soxRS (superoxide response) regulon of Escherichia coli by becoming a transcriptional activator when the cells are exposed to compounds that mediate univalent redox reactions, many of which produce superoxide as a by-product. SoxR was overproduced and purified to near homogeneity from a strain bearing an expression vector. It could bind specifically to the soxS operator even in the absence of RNA polymerase. The aerobically purified protein, which is readily autooxidized, could activate the transcription of soxS DNA even without exposure to known inducing agents. SoxR is a globular homodimer. It contains one [2Fe-2S] cluster per polypeptide chain, as demonstrated by optical and EPR spectroscopy combined with stoichiometric analysis of iron content, unpaired-electron-spin density, and reduction by dithionite. The protein is active in its oxidized ([2Fe-2S]2+) state. The presence of a prosthetic group capable of univalent redox reactions may help to explain the activation of the regulon in vivo by compounds that can mediate such reactions.

Roles of nitric oxide in inducible resistance of Escherichia coli to activated murine macrophages

Nitric oxide (NO.) is produced as a cytotoxic free radical through enzymatic oxidation of L-arginine in activated macrophages. Pure NO. gas was previously found to induce the Escherichia coli soxRS oxidative stress regulon, which is readily monitored by using a soxS'::lac fusion. The soxRS system includes antioxidant defenses, such as a superoxide dismutase and a DNA repair enzyme for oxidative damage, and protects E. coli from the cytotoxicity of NO.-generating macrophages. Previous experiments involved exposing E. coli to a bolus of NO. rather than the steadily generated gas expected of activated macrophages. We show here detectable induction of soxS transcription by NO. delivered at rates as low as 25 microM/h. Maximal induction was observed at 25 microM NO. per h under anaerobic conditions but at 125 microM/h aerobically. After incubation with murine macrophages, soxS expression was induced in the phagocytosed bacteria up to approximately 30-fold after an 8-h exposure. This in vivo induction was almost completely eliminated by the NO. synthase inhibitor NG-monomethyl-L-arginine. The inhibitor increased the survival of a delta soxRS strain but not that of wild-type E. coli after phagocytosis, which suggests that induction of the soxRS regulon by NO. can counteract most of the cytotoxic effects of NO. production by the macrophages. We show that the soxRS-regulated enzyme glucose-6-phosphate dehydrogenase is an important element of the defense against macrophages.

The NADPH: sulfite reductase of Escherichia coli is a paraquat reductase

The NADPH:sulfite reductase of Escherichia coli is a soluble enzyme that has a subunit structure alpha 8 beta 4, where the alpha subunit is a flavoprotein and the beta subunit is a metalloprotein. Overexpression of the holoenzyme in E. coli has greatly simplified the purification of this enzyme. Under aerobic conditions, recombinant sulfite reductase catalyzes the reduction of 1,1'-dimethyl-4,4'-bipyridinium dichloride (paraquat) by NADPH, with Km values for paraquat and NADPH of approximately 70 microM and 80 microM, respectively. Since pure flavoprotein alpha subunit, encoded by the cysJ gene, has similar catalytic activities, it is suggested that paraquat receives electrons directly from the alpha subunit. A mutant strain lacking an active cysJ gene is resistant to paraquat. The NADPH:ferredoxin reductase of E. coli is also a paraquat reductase but with much higher Km values for paraquat and lower enzyme activities. These results suggest that the sulfite reductase is a major paraquat reductase in E. coli and is responsible for the toxic activation of the drug.

Purification of a MalE-SoxS fusion protein and identification of the control sites of Escherichia coli superoxide-inducible genes

In Escherichia coli, the soxRS genes effect the cell's defence against superoxide by activating the transcription of more than 14 genes, including zwf, sodA, nfo, micF and fumC. Previous work from other laboratories has indicated that SoxR is the sensor of oxidative stress and induces synthesis of SoxS, which in turn activates transcription of the regulon's target genes. Although SoxS appears to be a DNA-binding protein, its ability to bind to the promoter regions of target genes has not been demonstrated. To facilitate purification and characterization of SoxS, we constructed a fusion of soxS to malE, which encodes maltose-binding protein, and demonstrated that the in vivo expression of the MalE-SoxS fusion protein can provide SoxS function to a soxRS deletion mutant. We purified the fusion protein by affinity chromatography on an amylose column. The purified fusion protein stimulated in vitro expression of zwf in a coupled transcription-translation system and formed specific complexes with DNA fragments carrying target gene promoters. Moreover, MalE-SoxS protected from DNase I attack 22-27 bp segments immediately adjacent to or overlapping the -35 hexamers of the zwf, sodA, nfo, micF, and fumC promoters. The protected regions revealed a consensus 'soxbox' sequence.