The alternative sigma factor SigH regulates major components of oxidative and heat stress responses in Mycobacterium tuberculosis

Mycobacterium tuberculosis is a specialized intracellular pathogen that must regulate gene expression to overcome stresses produced by host defenses during infection. SigH is an alternative sigma factor that we have previously shown plays a role in the response to stress of the saprophyte Mycobacterium smegmatis. In this work we investigated the role of sigH in the M. tuberculosis response to heat and oxidative stress. We determined that a M. tuberculosis sigH mutant is more susceptible to oxidative stresses and that the inducible expression of the thioredoxin reductase/thioredoxin genes trxB2/trxC and a gene of unknown function, Rv2466c, is regulated by sigH via expression from promoters directly recognized by SigH. We also determined that the sigH mutant is more susceptible to heat stress and that inducible expression of the heat shock genes dnaK and clpB is positively regulated by sigH. The induction of these heat shock gene promoters but not of other SigH-dependent promoters was markedly greater in response to heat versus oxidative stress, consistent with their additional regulation by a heat-labile repressor. To further understand the role of sigH in the M. tuberculosis stress response, we investigated the regulation of the stress-responsive sigma factor genes sigE and sigB. We determined that inducible expression of sigE is regulated by sigH and that basal and inducible expression of sigB is dependent on sigE and sigH. These data indicate that sigH plays a central role in a network that regulates heat and oxidative-stress responses that are likely to be important in M. tuberculosis pathogenesis.     

Identifying sigma factors in Mycobacterium smegmatis by comparative genomic analysis

Mycobacterium smegmatis is a saprophytic species that has been used for 15 years as a model to perform heterologous regulation and virulence studies of Mycobacterium tuberculosis. Members of the extracytoplasmic sigma factors family, which are required for adaptive responses to various environmental stresses, are responsible for some of the virulence traits of M. tuberculosis. A bioinformatic search on the genome of M. smegmatis has predicted the existence of 26 sigma factors, which is twice the number that are present in M. tuberculosis. A phylogenetic analysis has shown that despite this high number of sigma factors the orthologs of the genes sigC, sigI and sigK of M. tuberculosis are absent in the M. smegmatis genome. Several sigma factors are specific for M. smegmatis, with a special enrichment in the sigH and, to a lesser extent, in the sigJ and sigL subfamily, pinpointing the potential variability of the repertoire of adaptive response in this saprophytic species.     

The Influence of Mycobacterium tuberculosis Sigma Factors on the Promotion Efficiency of ptpAt Promoter in Mycobacterium smegmatis

It was found in a previous study that Mycobacterium tuberculosis protein tyrosine phosphatase ptpAt promoter is a highly active promoter in slow-growing species of mycobacteria, such as M. tuberculosis and M. bovis BCG, but inert in fast-growing mycobacterial species, such as M. smegmatis. This difference is presumed to be due to the differences between sigma factors systems of slow-growing pathogenic mycobacteria and the fast-growing saprophyte M. smegmatis. Therefore, we constructed a series of plasmids, named pOLYG-13x, which can express various M. tuberculosis sigma factors and also contain a P(ptpAt)-gfp reporter gene construct. By inducing different sigma factor genes of M. tuberculosis in M. smegmatis, we were able to explore the influences of various sigma factors on the expression efficiency of the ptpAt promoter. The result show that of the 10 sigma factors evaluated, only sigF and sigL were able to weakly drive the ptpAt promoter in M. smegmatis and other sigma factors were unable to drive the promoter.     

AhpC, oxidative stress and drug resistance in Mycobacterium tuberculosis

The Mycobacterium tuberculosis AhpC is similar to a family of bacterial and eukaryotic antioxidant proteins with alkylhydroperoxidase (Ahp) and thioredoxin-dependent peroxidase (TPx) activities. AhpC expression is associated with resistance to the front-line antitubercular drug isoniazid in the naturally resistant organisms E. coli and M. smegmatis. We identified several isoniazid-resistant M. tuberculosis isolates with ahpC promoter mutations resulting in AhpC overexpression. These strains were more resistant to cumene hydroperoxide than were wild-type strains. However, these strains were unchanged in their sensitivity to isoniazid, refuting a role for AhpC in detoxification of this drug. All the isoniazid-resistant, AhpC-overexpressing strains were also deficient in activity of the mycobacterial catalase-peroxidase KatG. KatG, the only known catalase in M. tuberculosis, is required for activation of isoniazid. We propose that compensatory ahpC promoter mutations are selected from KatG-deficient, isoniazid-resistant M. tuberculosis during infections, to mitigate the added burden imposed by organic peroxides on these strains.     

The HtrA-like serine protease PepD interacts with and modulates the Mycobacterium tuberculosis 35-kDa antigen outer envelope protein

Mycobacterium tuberculosis remains a significant global health concern largely due to its ability to persist for extended periods within the granuloma of the host. While residing within the granuloma, the tubercle bacilli are likely to be exposed to stress that can result in formation of aberrant proteins with altered structures. Bacteria encode stress responsive determinants such as proteases and chaperones to deal with misfolded or unfolded proteins. pepD encodes an HtrA-like serine protease and is thought to process proteins altered following exposure of M. tuberculosis to extra-cytoplasmic stress. PepD functions both as a protease and chaperone in vitro, and is required for aspects of M. tuberculosis virulence in vivo. pepD is directly regulated by the stress-responsive two-component signal transduction system MprAB and indirectly by extracytoplasmic function (ECF) sigma factor SigE. Loss of PepD also impacts expression of other stress-responsive determinants in M. tuberculosis. To further understand the role of PepD in stress adaptation by M. tuberculosis, a proteomics approach was taken to identify binding proteins and possible substrates of this protein. Using subcellular fractionation, the cellular localization of wild-type and PepD variants was determined. Purified fractions as well as whole cell lysates from Mycobacterium smegmatis or M. tuberculosis strains expressing a catalytically compromised PepD variant were immunoprecipitated for PepD and subjected to LC-MS/MS analyses. Using this strategy, the 35-kDa antigen encoding a homolog of the PspA phage shock protein was identified as a predominant binding partner and substrate of PepD. We postulate that proteolytic cleavage of the 35-kDa antigen by PepD helps maintain cell wall homeostasis in Mycobacterium and regulates specific stress response pathways during periods of extracytoplasmic stress.     

Functional analysis of sigH expression in Corynebacterium glutamicum

The sigH gene of Corynebacterium glutamicum encodes ECF sigma factor sigmaH. The gene apparently plays an important role in other stress responses as well as heat stress response. In this study, we found that deleting the sigH gene made C. glutamicum cells sensitive to the thiol-specific oxidant diamide. In the sigH mutant strain, the activity of thioredoxin reductase markedly decreased, suggesting that the trxB gene encoding thioredoxin reductase is probably under the control of sigmaH. The expression of sigH was stimulated in the stationary growth phase and modulated by diamide. In addition, the SigH protein was required for the expression of its own gene. These data indicate that the sigH gene of C. glutamicum stimulates and regulates its own expression in the stationary growth phase in response to environmental stimuli, and participates in the expression of other genes which are important for survival following heat and oxidative stress response.     

Defining the stressome of Mycobacterium avium subsp. paratuberculosis in vitro and in naturally infected cows

Mycobacterium avium subsp. paratuberculosis causes an enteric infection in cattle, with a great impact on the dairy industry in the United States and worldwide. Characterizing the gene expression profile of M. avium subsp. paratuberculosis exposed to different stress conditions, or shed in cow feces, could improve our understanding of the pathogenesis of M. avium subsp. paratuberculosis. In this report, the stress response of M. avium subsp. paratuberculosis on a genome-wide level (stressome) was defined for the first time using DNA microarrays. Expression data analysis revealed unique gene groups of M. avium subsp. paratuberculosis that were regulated under in vitro stressors while additional groups were regulated in the cow samples. Interestingly, acidic pH induced the regulation of a large number of genes (n=597), suggesting the high sensitivity of M. avium subsp. paratuberculosis to acidic environments. Generally, responses to heat shock, acidity, and oxidative stress were similar in M. avium subsp. paratuberculosis and Mycobacterium tuberculosis, suggesting common pathways for mycobacterial defense against stressors. Several sigma factors (e.g., sigH and sigE) were differentially coregulated with a large number of genes depending on the type of each stressor. Subsequently, we analyzed the virulence of six M. avium subsp. paratuberculosis mutants with inactivation of differentially regulated genes using a murine model of paratuberculosis. Both bacterial and histopathological examinations indicated the attenuation of all gene mutants, especially those selected based on their expression in the cow samples (e.g., lipN). Overall, the employed approach profiled mycobacterial genetic networks triggered by variable stressors and identified a novel set of putative virulence genes. A similar approach could be applied to analyze other intracellular pathogens.     

Oxidative stress response and its role in sensitivity to isoniazid in mycobacteria: characterization and inducibility of ahpC by peroxides in Mycobacterium smegmatis and lack of expression in M. aurum and M. tuberculosis.

Mycobacterium tuberculosis is a natural mutant with inactivated oxidative stress regulatory gene oxyR. This characteristic has been linked to the exquisite sensitivity of M. tuberculosis to isonicotinic acid hydrazide (INH). In the majority of mycobacteria tested, including M. tuberculosis, oxyR is divergently transcribed from ahpC, a gene encoding a homolog of the subunit of alkyl hydroperoxide reductase that carries out substrate peroxide reduction. Here we compared ahpC expression in Mycobacterium smegmatis, a mycobacterium less sensitive to INH, with that in two highly INH sensitive species, M. tuberculosis and Mycobacterium aurum. The ahpC gene of M. smegmatis was cloned and characterized, and the 5' ends of ahpC mRNA were mapped by S1 nuclease protection analysis. M. smegmatis AhpC and eight other polypeptides were inducible by exposure to H2O2 or organic peroxides, as determined by metabolic labeling and Western blot (immunoblot) analysis. In contrast, M. aurum displayed differential induction of only one 18-kDa polypeptide when exposed to organic peroxides. AhpC could not be detected in this organism by immunological means. AhpC was also below detection levels in M. tuberculosis H37Rv. These observations are consistent with the interpretation that ahpC expression and INH sensitivity are inversely correlated in the mycobacterial species tested. In further support of this conclusion, the presence of plasmid-borne ahpC reduced M. smegmatis susceptibility to INH. Interestingly, mutations in the intergenic region between oxyR and ahpC were identified and increased ahpC expression observed in deltakatG M. tuberculosis and Mycobacterium bovis INH(r) strains. We propose that mutations activating ahpC expression may contribute to the emergence of INH(r) strains.