Abstract
The ability of Mycobacterium tuberculosis to respond and adapt to various stresses such as oxygen/nitrogen radicals and low pH inside macrophages is critical for the persistence of this human pathogen inside its host. We have previously shown that an AraC/XylS-type transcriptional regulator, VirS, which is induced in low pH, is involved in remodeling the architecture of the bacterial cell envelope. However, how VirS influences gene expression to coordinate these pH responses remains unclear. Here, using a genetic biosensor of cytoplasmic pH, we demonstrate that VirS is required for the intracellular pH maintenance in response to acidic stress and inside acidified macrophages. Furthermore, we observed that VirS plays an important role in blocking phagosomal-lysosomal fusions. Transcriptomics experiments revealed that VirS affects the expression of genes encoding metabolic enzymes, cell-wall envelope proteins, efflux pumps, ion transporters, detoxification enzymes, and transcriptional regulators expressed under low-pH stress. Employing electrophoretic mobility-shift assays, DNA footprinting, and in silico analysis, we identified a DNA sequence to which VirS binds and key residues in VirS required for its interaction with DNA. A significant role of VirS in M. tuberculosis survival in adverse conditions suggested it as a potential anti-mycobacterial drug target. To that end, we identified VirS inhibitors in a virtual screen; the top hit compounds inhibited its DNA-binding activity and also M. tuberculosis growth in vitro and inside macrophages. Our findings establish that VirS mediates M. tuberculosis responses to acidic stress and identify VirS-inhibiting compounds that may form the basis for developing more effective anti-mycobacterial agents.
Highlights
The ability of Mycobacterium tuberculosis to respond and adapt to various stresses such as oxygen/nitrogen radicals and low pH inside macrophages is critical for the persistence of this human pathogen inside its host
Apart from M. tuberculosis, acid resistance has been shown to be important for other bacteria, such as Helicobacter pylori, which colonizes in the human stomach, having an acidic environment; Streptococcus pneumoniae; and pathogenic strains of Escherichia coli and Salmonella enterica
We performed survival studies of WT, virS mutant, and virS complemented strain at acidic conditions of pH 4.5 in 7H9 medium containing nonhydrolyzable tyloxapol (7H9 – 4.5-Ty) as the dispersing agent instead of Tween 80 to negate the possibility of a growth defect due to hydrolysis of Tween 80 under acidic conditions to free fatty acids, which can be toxic to the cells [1]
Summary
VirS is required to survive under acidic stress and to block phagosomal maturation. VirS has been previously reported to be up-regulated under acidic conditions [12]. Compound V15B exhibited van der Waals interactions with residues Gln-1, Gly-60, and Glu-63 It showed hydrogen bonding with Tyr-61 at DNA-binding site 2 (Fig. 11D). These five analogs were further evaluated for the determination of their IC50 values They were found to display a reduced inhibitory potential against VirS DNA-binding activity compared with their parent molecules, which is tabulated in Table S5 and S6. Further modification of the isoquinoline ring to 1-methyl-3,4-dihydroisoquinoline-4-one and its attachment to the 2-(cyclohexa-1,3-dien-1-yl) pyridine moiety in compound V15B-2 showed a potential to inhibit the DNA-binding activity of VirS; it displayed a slightly lower IC50 than the parent molecule. The structural comparisons of all of these molecules with their activities emphasize the importance of the isoquinoline ring attached to 3-nitroso-2-phenyl-pyrrole as present in the parent molecule, which is essential for inhibition of the DNA-binding activity of VirS
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