Glutamate dehydrogenase and glutamine synthetase are regulated in response to nitrogen availability in Myocbacterium smegmatis.

BACKGROUND: The assimilation of nitrogen is an essential process in all prokaryotes, yet a relatively limited amount of information is available on nitrogen metabolism in the mycobacteria. The physiological role and pathogenic properties of glutamine synthetase (GS) have been extensively investigated in Mycobacterium tuberculosis. However, little is known about this enzyme in other mycobacterial species, or the role of an additional nitrogen assimilatory pathway via glutamate dehydrogenase (GDH), in the mycobacteria as a whole. We investigated specific enzyme activity and transcription of GS and as well as both possible isoforms of GDH (NAD+- and NADP+-specific GDH) under varying conditions of nitrogen availability in Mycobacterium smegmatis as a model for the mycobacteria. RESULTS: It was found that the specific activity of the aminating NADP+-GDH reaction and the deaminating NAD+-GDH reaction did not change appreciably in response to nitrogen availability. However, GS activity as well as the deaminating NADP+-GDH and aminating NAD+-GDH reactions were indeed significantly altered in response to exogenous nitrogen concentrations. Transcription of genes encoding for GS and the GDH isoforms were also found to be regulated under our experimental conditions. CONCLUSIONS: The physiological role and regulation of GS in M. smegmatis was similar to that which has been described for other mycobacteria, however, in our study the regulation of both NADP+- and NAD+-GDH specific activity in M. smegmatis appeared to be different to that of other Actinomycetales. It was found that NAD+-GDH played an important role in nitrogen assimilation rather than glutamate catabolism as was previously thought, and is it's activity appeared to be regulated in response to nitrogen availability. Transcription of the genes encoding for NAD+-GDH enzymes seem to be regulated in M. smegmatis under the conditions tested and may contribute to the changes in enzyme activity observed, however, our results indicate that an additional regulatory mechanism may be involved. NADP+-GDH seemed to be involved in nitrogen assimilation due to a constitutive aminating activity. The deaminating reaction, however was observed to change in response to varying ammonium concentrations which suggests that NADP+-GDH is also regulated in response to nitrogen availability. The regulation of NADP+-GDH activity was not reflected at the level of gene transcription thereby implicating post-transcriptional modification as a regulatory mechanism in response to nitrogen availability.

Glutamine synthetase sequence evolution in the mycobacteria and their use as molecular markers for Actinobacteria speciation.

BACKGROUND: Although the gene encoding for glutamine synthetase (glnA) is essential in several organisms, multiple glnA copies have been identified in bacterial genomes such as those of the phylum Actinobacteria, notably the mycobacterial species. Intriguingly, previous reports have shown that only one copy (glnA1) is essential for growth in M. tuberculosis, while the other copies (glnA2, glnA3 and glnA4) are not. RESULTS: In this report it is shown that the glnA1 and glnA2 encoded glutamine synthetase sequences were inherited from an Actinobacteria ancestor, while the glnA4 and glnA3 encoded GS sequences were sequentially acquired during Actinobacteria speciation. The glutamine synthetase sequences encoded by glnA4 and glnA3 are undergoing reductive evolution in the mycobacteria, whilst those encoded by glnA1 and glnA2 are more conserved. CONCLUSION: Different selective pressures by the ecological niche that the organisms occupy may influence the sequence evolution of glnA1 and glnA2 and thereby affecting phylogenies based on the protein sequences they encode. The findings in this report may impact the use of similar sequences as molecular markers, as well as shed some light on the evolution of glutamine synthetase in the mycobacteria.

Regulation of nitrogen metabolism in Mycobacterium tuberculosis: a comparison with mechanisms in Corynebacterium glutamicum and Streptomyces coelicolor.

The mechanisms governing the regulation of nitrogen metabolism in Corynebacterium glutamicum and Streptomyces coelicolor have been extensively studied. These Actinomycetales are closely related to the Mycobacterium genus and may therefore serve as a models to elucidate the cascade of nitrogen signalling in other mycobacteria. Some factors involved in nitrogen metabolism in Mycobacterium tuberculosis have been described, including glutamine synthetase and its adenylyltransferase, but not much data concerning the other components involved in the signalling cascade is available. In this review a comparative study of factors involved in nitrogen metabolism in C. glutamicum and S. coelicolor is made to identify similarities with M. tuberculosis on both a genomic and proteomic level. This may provide insight into a potential global mechanism of nitrogen control in Mycobacterium tuberculosis.

Differential expression of mycothiol pathway genes: are they affected by antituberculosis drugs?

Mycothiol (MSH) is the major cellular thiol in Mycobacterium tuberculosis (M.tb). We hypothesize that the mycothiol-dependent detoxification pathway may serve an important role during oxygen stress management in M. tuberculosis, derived from normal aerobic metabolism, the macrophage environment and through the action of anti-tubercular antibiotics, such as Isoniazid (INH). Total mRNA and DNA were isolated from M. bovis BCG at different stages of growth in 7H9 mycobacterial medium. Three genes involved in mycothiol metabolism and encoding the enzymes mycothiol S-conjugate amidase (Mca, Rv1082), NADPH dependent mycothiol reductase (mtr, Rv2855), and N-Acetyl-1-D-myo-Inosityl-2-Amino-2-Deoxy-alpha-D-Glucopyranoside Deacetylase (GlcNAc-Ins deacetylase, Rv1170 or mshB) were investigated for genomic rearrangements and expression. The results show that the genomic domains of the genes remain conserved in evolutionary diverse and unrelated M. tuberculosis isolates. The genes encoding enzymes implicated in mycothiol reduction, mtr (Rv2855) and the mycothiol-dependant detoxification of electrophilic agents, Mca (Rv1082), are shown to be actively transcribed during logarithmic M. bovis BCG growth. The gene encoding GlcNAc-Ins deacetylase (the rate limiting mycothiol biosynthesis step) shows induction in the presence of INH. Antisense oligonucleotides to both GlcNAc-Ins deacetylase (Rv1170) and mtr (Rv2855) mRNA affect mycobacterial growth. In conclusion the results presented here suggest that these enzymes are sensitive to free radical generating antituberculosis drugs and may be useful targets for new drug development.