Nicole C. Cardoso scite author profile

Reduction of nitrate to nitrite in bacteria is an essential step in the nitrogen cycle, catalysed by a variety of nitrate reductase (NR) enzymes. The soil dweller, Mycobacterium smegmatis is able to assimilate nitrate and herein we set out to confirm the genetic basis for this by probing NR activity in mutants defective for putative nitrate reductase (NR) encoding genes. In addition to the annotated narB and narGHJI, bioinformatics identified three other putative NR-encoding genes: MSMEG_4206, MSMEG_2237 and MSMEG_6816. To assess the relative contribution of each, the corresponding gene loci were deleted using two-step allelic replacement, individually and in combination. The resulting strains were tested for their ability to assimilate nitrate and reduce nitrate under aerobic and anaerobic conditions, using nitrate assimilation and modified Griess assays. We demonstrated that narB, narGHJI, MSMEG_2237 and MSMEG_6816 were individually dispensable for nitrate assimilation and for nitrate reductase activity under aerobic and anaerobic conditions. Only deletion of MSMEG_4206 resulted in significant reduction in nitrate assimilation under aerobic conditions. These data confirm that in M. smegmatis, narB, narGHJI, MSMEG_2237 and MSMEG_6816 are not required for nitrate reduction as MSMEG_4206 serves as the sole assimilatory NR.

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Implications of Mycobacterium tuberculosis Metabolic Adaptability on Drug Discovery and Development

Cardoso

Chibale

Singh

2022

ACS Infect. Dis.

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Tuberculosis remains a global health threat that is being exacerbated by the increase in infections attributed to drug resistant Mycobacterium tuberculosis. To combat this, there has been a surge in drug discovery programs to develop new, potent compounds and identify promising drug targets in the pathogen. Two areas of M. tuberculosis biology that have emerged as rich sources of potential novel drug targets are cell wall biosynthesis and energy metabolism. Both processes are important for survival of M. tuberculosis under replicating and nonreplicating conditions. However, both processes are also inherently adaptable under different conditions. Furthermore, cell wall biosynthesis is energy intensive and, thus, reliant on an efficiently functioning energy production system. This Perspective focuses on the interplay between cell wall biosynthesis and energy metabolism in M. tuberculosis, how adaptations in one pathway may affect the other, and what consequences this could have for drug discovery and development and the identification of novel drug targets.

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The contribution of the NarB and NarGHI enzymes to nitrate reduction in Mycobacterium smegmatis

Cardoso¹,

Kana²

2019

Preprint

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Background: Nitrate reduction in bacteria is an essential step in the nitrogen cycle. For this, the reduction of nitrate to nitrite is catalyzed by a variety of nitrate reductase enzymes. In the pathogen Mycobacterium tuberculosis, nitrate reduction is driven by the NarGHI respiratory and assimilatory nitrate reductase. In addition to this enzyme, Mycobacterium smegmatis carries a second putative narB-encoded nitrate reductase and the contribution of this enzyme to nitrate reduction remains unknown. Herein, we set out to investigate this. Results: To assess the relative contribution of NarGHI and NarB, the corresponding gene loci we deleted using two-step allelic replacement, individually and in combination, followed by investigation of nitrate reduction using the Griess assay. However, previous reports demonstrated that this assay was unable to report on nitrate reduction in M. smegmatis, as it yielded no detectable levels of the nitrite product. To address this, we modified the assay through the addition of zinc, which reduces nitrate remaining in the reaction to nitrite thus allowing for assessment of nitrate depletion. This then serves as a surrogate for nitrate reductase activity. The mutant strains lacking narB and/or narGHJI retained the ability to reduce nitrate at levels comparable to the wild type. We further investigated nitrate assimilation and all strains defective for these enzymes were able to grow on nitrate as the sole nitrogen source. Conclusions: Collectively, these data confirm that NarB and NarGHI are individually and collectively dispensable for both respiratory and assimilatory nitrate reduction in M. smegmatis. Furthermore, we identified MSMEG_4206 as a putative, previously unannotated, nitrate reductase in this organism.

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Chemotherapy for Drug-Susceptible Tuberculosis

Singh

Cardoso

Huszár

2023

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Nicole C. Cardoso

Mycobacterium smegmatis does not display functional redundancy in nitrate reductase enzymes

Implications of Mycobacterium tuberculosis Metabolic Adaptability on Drug Discovery and Development

The contribution of the NarB and NarGHI enzymes to nitrate reduction in Mycobacterium smegmatis

Chemotherapy for Drug-Susceptible Tuberculosis

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