Project description:Bacteria use a number of small basic proteins for organization and compaction of their genomes. By their interaction with DNA, these nucleoid-associated proteins (NAPs) also influence gene expression. Rv3852, a NAP of Mycobacterium tuberculosis, is conserved among the pathogenic and slow-growing species of mycobacteria. Here, we show that the protein predominantly localizes in the cell membrane and that the carboxy-terminal region with the propensity to form a transmembrane helix is necessary for its membrane localization. The protein is involved in genome organization, and its ectopic expression in Mycobacterium smegmatis resulted in altered nucleoid morphology, defects in biofilm formation, sliding motility, and change in apolar lipid profile. We demonstrate its crucial role in regulating the expression of KasA, KasB, and GroEL1 proteins, which are in turn involved in controlling the surface phenotypes in mycobacteria.

Project description:Infections caused by biofilms are abundant and highly persistent, displaying phenotypic resistance to high concentrations of antimicrobials and modulating host immune systems. Tuberculosis (TB), caused by Mycobacterium tuberculosis, shares these qualities with biofilm infections. To identify genetic determinants of biofilm formation in M. tuberculosis, we performed a small-scale transposon screen using an in vitro pellicle biofilm assay. We identified five M. tuberculosis mutants that were reproducibly attenuated for biofilm production relative to that of the parent strain H37Rv. One of the most attenuated mutants is interrupted in pks1, a polyketide synthase gene. When fused with pks15, as in some M. tuberculosis isolates, pks1 contributes to synthesis of the immunomodulatory phenolic glycolipids (PGLs). However, in strains such as H37Rv with split pks15 and pks1 loci, PGL is not produced and pks1 has no previously defined role. We showed that pks1 complementation restores biofilm production independently of the known role of pks1 in PGL synthesis. We also assessed the relationship among biofilm formation, the pks15/1 genotype, and M. tuberculosis phylogeography. A global survey of M. tuberculosis clinical isolates revealed surprising sequence variability in the pks15/1 locus and substantial variation in biofilm phenotypes. Our studies identify novel M. tuberculosis genes that contribute to biofilm production, including pks1. In addition, we find that the ability to make pellicle biofilms is common among M. tuberculosis isolates from throughout the world, suggesting that this trait is relevant to TB propagation or persistence.

Project description:Tuberculosis, caused by Mycobacterium tuberculosis has remained a leading cause of death worldwide even after decades of it being declared as global health emergency by the WHO. Newer drugs with novel modes of action are urgently needed to combat the threats imposed by the constantly emerging drug resistant strains. Natural products (NPs) derived anti-mycobacterials appear lucrative because of their complex structural features and unique cellular targets they bind to. Herein, we employed co-cultivation approach to identify cryptic biosynthetic gene clusters (BGCs) from fungal genomes eliciting the expression of genes that are silent or poorly transcribed in axenic cultures. Fungi were isolated from sphagnum peat bog samples collected from different regions of North-eastern USA because aspects of this ecological niche reflect the critical microenvironment of the human tuberculosis granuloma and are a natural habitat for slow growing mycobacterial species that compete for limited nutrients with other microbes. Bioactivity-guided assay led us to identify three unique fungal isolates that selectively produce growth inhibitory metabolites during co-cultivation with Mtb. Fungal mRNA sequencing from co-cultured isolates facilitated the identification of elicited Type I Polyketide Synthase BGCs that were silent/cryptic in monoculture conditions. Bioinformatic analyses followed by chemical validation identified these molecules to be patulin, citrinin and nidulalin A. Interestingly, these induced fungal metabolites led to a highly responsive redox-stress homeostasis within Mtb. Our study thus, illustrates a co-cultivation mediated elicitation of unique fungal NPs resulting in a thiol-burst oxidative stress mediated killing of Mtb. We believe that the identification of vulnerable drug targets may yield insights into further understanding of this essential thiol stress mediated killing of the mycobacteria

Project description:Tuberculosis, caused by Mycobacterium tuberculosis has remained a leading cause of death worldwide even after decades of it being declared as global health emergency by the WHO. Newer drugs with novel modes of action are urgently needed to combat the threats imposed by the constantly emerging drug resistant strains. Natural products (NPs) derived anti-mycobacterials appear lucrative because of their complex structural features and unique cellular targets they bind to. Herein, we employed co-cultivation approach to identify cryptic biosynthetic gene clusters (BGCs) from fungal genomes eliciting the expression of genes that are silent or poorly transcribed in axenic cultures. Fungi were isolated from sphagnum peat bog samples collected from different regions of North-eastern USA because aspects of this ecological niche reflect the critical microenvironment of the human tuberculosis granuloma and are a natural habitat for slow growing mycobacterial species that compete for limited nutrients with other microbes. Bioactivity-guided assay led us to identify three unique fungal isolates that selectively produce growth inhibitory metabolites during co-cultivation with Mtb. Fungal mRNA sequencing from co-cultured isolates facilitated the identification of elicited Type I Polyketide Synthase BGCs that were silent/cryptic in monoculture conditions. Bioinformatic analyses followed by chemical validation identified these molecules to be patulin, citrinin and nidulalin A. Interestingly, these induced fungal metabolites led to a highly responsive redox-stress homeostasis within Mtb. Our study thus, illustrates a co-cultivation mediated elicitation of unique fungal NPs resulting in a thiol-burst oxidative stress mediated killing of Mtb. We believe that the identification of vulnerable drug targets may yield insights into further understanding of this essential thiol stress mediated killing of the mycobacteria

Project description:Tuberculosis, caused by Mycobacterium tuberculosis has remained a leading cause of death worldwide even after decades of it being declared as global health emergency by the WHO. Newer drugs with novel modes of action are urgently needed to combat the threats imposed by the constantly emerging drug resistant strains. Natural products (NPs) derived anti-mycobacterials appear lucrative because of their complex structural features and unique cellular targets they bind to. Herein, we employed co-cultivation approach to identify cryptic biosynthetic gene clusters (BGCs) from fungal genomes eliciting the expression of genes that are silent or poorly transcribed in axenic cultures. Fungi were isolated from sphagnum peat bog samples collected from different regions of North-eastern USA because aspects of this ecological niche reflect the critical microenvironment of the human tuberculosis granuloma and are a natural habitat for slow growing mycobacterial species that compete for limited nutrients with other microbes. Bioactivity-guided assay led us to identify three unique fungal isolates that selectively produce growth inhibitory metabolites during co-cultivation with Mtb. Fungal mRNA sequencing from co-cultured isolates facilitated the identification of elicited Type I Polyketide Synthase BGCs that were silent/cryptic in monoculture conditions. Bioinformatic analyses followed by chemical validation identified these molecules to be patulin, citrinin and nidulalin A. Interestingly, these induced fungal metabolites led to a highly responsive redox-stress homeostasis within Mtb. Our study thus, illustrates a co-cultivation mediated elicitation of unique fungal NPs resulting in a thiol-burst oxidative stress mediated killing of Mtb. We believe that the identification of vulnerable drug targets may yield insights into further understanding of this essential thiol stress mediated killing of the mycobacteria

Project description:Tuberculosis, caused by Mycobacterium tuberculosis has remained a leading cause of death worldwide even after decades of it being declared as global health emergency by the WHO. Newer drugs with novel modes of action are urgently needed to combat the threats imposed by the constantly emerging drug resistant strains. Natural products (NPs) derived anti-mycobacterials appear lucrative because of their complex structural features and unique cellular targets they bind to. Herein, we employed co-cultivation approach to identify cryptic biosynthetic gene clusters (BGCs) from fungal genomes eliciting the expression of genes that are silent or poorly transcribed in axenic cultures. Fungi were isolated from sphagnum peat bog samples collected from different regions of North-eastern USA because aspects of this ecological niche reflect the critical microenvironment of the human tuberculosis granuloma and are a natural habitat for slow growing mycobacterial species that compete for limited nutrients with other microbes. Bioactivity-guided assay led us to identify three unique fungal isolates that selectively produce growth inhibitory metabolites during co-cultivation with Mtb. Fungal mRNA sequencing from co-cultured isolates facilitated the identification of elicited Type I Polyketide Synthase BGCs that were silent/cryptic in monoculture conditions. Bioinformatic analyses followed by chemical validation identified these molecules to be patulin, citrinin and nidulalin A. Interestingly, these induced fungal metabolites led to a highly responsive redox-stress homeostasis within Mtb. Our study thus, illustrates a co-cultivation mediated elicitation of unique fungal NPs resulting in a thiol-burst oxidative stress mediated killing of Mtb. We believe that the identification of vulnerable drug targets may yield insights into further understanding of this essential thiol stress mediated killing of the mycobacteria

Project description:Tuberculosis, caused by Mycobacterium tuberculosis has remained a leading cause of death worldwide even after decades of it being declared as global health emergency by the WHO. Newer drugs with novel modes of action are urgently needed to combat the threats imposed by the constantly emerging drug resistant strains. Natural products (NPs) derived anti-mycobacterials appear lucrative because of their complex structural features and unique cellular targets they bind to. Herein, we employed co-cultivation approach to identify cryptic biosynthetic gene clusters (BGCs) from fungal genomes eliciting the expression of genes that are silent or poorly transcribed in axenic cultures. Fungi were isolated from sphagnum peat bog samples collected from different regions of North-eastern USA because aspects of this ecological niche reflect the critical microenvironment of the human tuberculosis granuloma and are a natural habitat for slow growing mycobacterial species that compete for limited nutrients with other microbes. Bioactivity-guided assay led us to identify three unique fungal isolates that selectively produce growth inhibitory metabolites during co-cultivation with Mtb. Fungal mRNA sequencing from co-cultured isolates facilitated the identification of elicited Type I Polyketide Synthase BGCs that were silent/cryptic in monoculture conditions. Bioinformatic analyses followed by chemical validation identified these molecules to be patulin, citrinin and nidulalin A. Interestingly, these induced fungal metabolites led to a highly responsive redox-stress homeostasis within Mtb. Our study thus, illustrates a co-cultivation mediated elicitation of unique fungal NPs resulting in a thiol-burst oxidative stress mediated killing of Mtb. We believe that the identification of vulnerable drug targets may yield insights into further understanding of this essential thiol stress mediated killing of the mycobacteria

Project description:Tuberculosis, caused by Mycobacterium tuberculosis has remained a leading cause of death worldwide even after decades of it being declared as global health emergency by the WHO. Newer drugs with novel modes of action are urgently needed to combat the threats imposed by the constantly emerging drug resistant strains. Natural products (NPs) derived anti-mycobacterials appear lucrative because of their complex structural features and unique cellular targets they bind to. Herein, we employed co-cultivation approach to identify cryptic biosynthetic gene clusters (BGCs) from fungal genomes eliciting the expression of genes that are silent or poorly transcribed in axenic cultures. Fungi were isolated from sphagnum peat bog samples collected from different regions of North-eastern USA because aspects of this ecological niche reflect the critical microenvironment of the human tuberculosis granuloma and are a natural habitat for slow growing mycobacterial species that compete for limited nutrients with other microbes. Bioactivity-guided assay led us to identify three unique fungal isolates that selectively produce growth inhibitory metabolites during co-cultivation with Mtb. Fungal mRNA sequencing from co-cultured isolates facilitated the identification of elicited Type I Polyketide Synthase BGCs that were silent/cryptic in monoculture conditions. Bioinformatic analyses followed by chemical validation identified these molecules to be patulin, citrinin and nidulalin A. Interestingly, these induced fungal metabolites led to a highly responsive redox-stress homeostasis within Mtb. Our study thus, illustrates a co-cultivation mediated elicitation of unique fungal NPs resulting in a thiol-burst oxidative stress mediated killing of Mtb. We believe that the identification of vulnerable drug targets may yield insights into further understanding of this essential thiol stress mediated killing of the mycobacteria

Project description:Owing to their capability to disrupt the oxidative protein folding environment in the endoplasmic reticulum (ER), thiol antioxidants such as dithiothreitol (DTT) are used as ER-specific stressors. We recently showed that thiol antioxidants modulate the methionine-homocysteine cycle by upregulating an S-adenosylmethionine-dependent methyltransferase, rips-1, in Caenorhabditis elegans. However, the changes in cellular physiology induced by thiol stress that modulate the methionine-homocysteine cycle remain uncharacterized. Here, using forward genetic screens in C. elegans, we discover that thiol stress enhances rips-1 expression via the hypoxia response pathway. We demonstrate that thiol stress activates the hypoxia response pathway. The activation of the hypoxia response pathway by thiol stress is conserved in human cells. The hypoxia response pathway enhances thiol toxicity via rips-1 expression and confers protection against thiol toxicity via rips-1-independent mechanisms. Finally, we show that DTT might activate the hypoxia response pathway by producing hydrogen sulfide. Our studies reveal an intriguing interaction between thiol-mediated reductive stress and the hypoxia response pathway and challenge the current model that thiol antioxidant DTT disrupts only the ER milieu in the cell.

Project description:Tuberculosis is a chronic disease that displays several features commonly associated with biofilm-associated infections: immune system evasion, antibiotic treatment failures, and recurrence of infection. However, although Mycobacterium tuberculosis (Mtb) can form cellulose-containing biofilms in vitro, it remains unclear whether biofilms are formed during infection in vivo. Here, we demonstrate the formation of Mtb biofilms in animal models of infection and in patients, and that biofilm formation can contribute to drug tolerance. First, we show that cellulose is also a structural component of the extracellular matrix of in vitro biofilms of fast and slow-growing nontuberculous mycobacteria. Then, we use cellulose as a biomarker to detect Mtb biofilms in the lungs of experimentally infected mice and non-human primates, as well as in lung tissue sections obtained from patients with tuberculosis. Mtb strains defective in biofilm formation are attenuated for survival in mice, suggesting that biofilms protect bacilli from the host immune system. Furthermore, the administration of nebulized cellulase enhances the antimycobacterial activity of isoniazid and rifampicin in infected mice, supporting a role for biofilms in phenotypic drug tolerance. Our findings thus indicate that Mtb biofilms are relevant to human tuberculosis.