Academic literature on the topic 'Rv0805 - Mycobacterium Tuberculosis'

Abstract Tuberculosis (TB), caused by Mycobacterium tuberculosis (M.tb.), an intracellular pathogen remains a major global health problem. M.tb., comprising more than 120 species has evolved by successive genomic reduction events. Comparative genomic and proteomic analysis of 13 Mycobacterium species classified into Strict pathogens (virulent), Opportunistic pathogens (Non-tuberculous Mycobacteria, NTM) and the Non-pathogenic bacteria revealed the presence of 25 unique protein. These 25 proteins share less than 20% homology with any other proteins of Mycobacteria species used in the study. Rv000B, one of the unique proteins is present in M.tb and M. bovis BCG only. The presence of Rv000B in M. tb and M.bovis BCG only points to its importance as “Signature proteins”, suggesting that Rv000B could be used for its diagnostic potential. Rv000B is a hypothetical protein and hence it will be interesting to study their functional role in the pathogenesis of M.tb. In-silico analysis of Rv000B revealed that this protein is highly disordered and unstable. Immunogenicity of Rv000B protein was evaluated by treating the splenocytes ex-vivo obtained from mice that were previously immunized with Rv000B protein. Our results showed that Rv000B is highly antigenic and elicited a pro-inflammatory immune response. High IgG reactivity of Rv000B is also seen in immunized mice and different categories of TB patients. Besides inducing Th1 responses, it also significantly induced apoptosis of macrophages. Therefore, these pro-host antigenic proteins are ideal candidates to produce recombinant BCG vaccine to enhances its vaccine potential.

ABSTRACT The pe and ppe genes are unique to mycobacteria and are widely speculated to play a role in tuberculosis pathogenesis. However, little is known about how expression of these genes is controlled. Elucidating the regulatory control of genes found exclusively in mycobacteria, such as the pe and ppe gene families, may be key to understanding the success of this pathogen. In this study, we used a transposon mutagenesis approach to elucidate pe and ppe regulation. This resulted in the identification of Rv0485, a previously uncharacterized transcriptional regulator. Microarray and quantitative real-time PCR analysis confirmed that disruption of Rv0485 reduced the expression of the pe13 and ppe18 gene pair (Rv1195 and Rv1196), defined the Rv0485 regulon, and emphasized the lack of global regulation of pe and ppe genes. The in vivo phenotype of the Rv0485 transposon mutant strain (Rv0485::Tn) was investigated in the mouse model, where it was demonstrated that the mutation has minimal effect on bacterial organ burden. Despite this, disruption of Rv0485 allowed mice to survive for significantly longer, with substantially reduced lung pathology in comparison with mice infected with wild-type Mycobacterium tuberculosis. Infection of immune-deficient SCID mice with the Rv0485::Tn strain also resulted in extended survival times, suggesting that Rv0485 plays a role in modulation of innate immune responses. This is further supported by the finding that disruption of Rv0485 resulted in reduced secretion of proinflammatory cytokines by infected murine macrophages. In summary, we have demonstrated that disruption of a previously uncharacterized transcriptional regulator, Rv0485, results in reduced expression of pe13 and ppe18 and attenuation of M. tuberculosis virulence.

A repetitive sequence specific to Mycobacterium tuberculosis was isolated from a λgt11 library of M. tuberculosis by DNA–DNA hybridization using genomic DNA of M. tuberculosis as probe followed by subtractive hybridization with a cocktail of other mycobacterial DNA. This led to identification of CD192, a 1291 bp fragment of M. tuberculosis containing repetitive sequences, which produced positive hybridization signals with M. tuberculosis DNA within 30 min. Nucleotide sequencing revealed the presence of several direct and inverted repeats within the 1291 bp fragment that belonged to a PPE family gene (Rv0355) of M. tuberculosis. The use of CD192 as a DNA probe for the identification of M. tuberculosis in culture and clinical samples was investigated. The 1291 bp sequence was present in M. tuberculosis, Mycobacterium bovis and M. bovis BCG, but was not present in many of the other mycobacterial strains tested, including M. tuberculosis H37Ra. More than 300 clinical isolates of M. tuberculosis were probed with CD192, and the presence of the 1291 bp sequence was observed in all the clinical strains, including those lacking IS6110. The sequence displayed RFLP among the clinical isolates. A PCR assay was developed which detected M. tuberculosis with 100 % specificity from specimens of sputum, cerebrospinal fluid and pleural effusion from clinically diagnosed cases of tuberculosis.

The variability assessment of PE/PPE genes, as well as of DNA repair, replication, and recombination system genes may drive the concept of mechanisms of Mycobacterium tuberculosis evolution and adaptation.The aim is to study the variability of PE_PGRS genes, 3R-system genes (DNA repair, recombination, and replication) to assess the mechanisms of evolutionary changes in M. tuberculosis.Whole genome sequencing of M. tuberculosis 11502 (the Beijing genotype subtype B0/W148 cluster 100-32), M. tuberculosis 5005 (the Beijing genotype subtype B0/W148), M. tuberculosis 4860 (the LAM genotype) strains was performed. They were isolated from patients with newly diagnosed pulmonary tuberculosis. Genomes were uploaded to the GanBank, NCBI: M. tuberculosis 11502 – access code: CP070338.1, M. tuberculosis 5005 – access code: CP053092.1, M. tuberculosis 4860 – access code: CP049108.1. A reference genome (M. tuberculosis H37Rv; NC_000962.3) was used for genetic analysis. In the M. tuberculosis 11502 genome, 44.4 ± 6.8 % of genes (24 genes out of 54) were revealed in the mutations related to the 3R system, while in M. tuberculosis 4860– 29.6 ± 6.2 % (16 genes out of 54). In the 3R system genes, a slight shift of mutations towards replacement by adenine and thymine was revealed, while the entire genome of M. tuberculosis 11502 (compared to M. tuberculosis H37Rv) demonstrated mutations, resulting in a slight accumulation of G + C. Mutations in the 3R system genes may lead to the suboptimal activity of proteins responsible for the DNA-repair, resulting in the upsurge of mutation frequency and promoting adaptive evolution. PE_PGRS genes in the genome of M. tuberculosis 11502, 4860, and 5005 exhibited a high variability and their variability diverged among different members of this gene family. A high level of tetranucleotides CGGC was found in the majority of PE_PGRS family genes, where their proportion varied from 2.11 to 8.42 %, while an average proportion of CGGC in the M. tuberculosis genome was 1.62 %. Some genes in the M. tuberculosis genome were detected to carry no tetranucleotides CGGC (Rv0011, Rv0100, Rv0460, Rv0616A, Rv0691A, Rv0722, Rv0863, Rv0909, Rv1038c, Rv1197, Rv2347c, Rv2452c, and Rv3330c). The DNA conformation analysis at the mutation sites in the genes, associated with resistance to anti-tuberculosis drugs, showed that the secondary DNA structures were mainly formed by nucleotides CGGC, GCGC, GGG, GGGG, CTGC, and mutations occurred, predominantly, at the sites of forming secondary DNA structures (hairpins) where the redistribution of energy and charges can influence the accuracy of replication and result in replication errors and a mutation event. A number of additional factors can influence the probability of a mutation event. These are the factors that can neutralize the energy changes in the DNA secondary structures, and can affect the accuracy of DNA-repair and replication (mutations in the gyrA gene, in the 3R-system genes).

The Mycobacterium tuberculosis (M. tb) genome encodes a large number of hypothetical proteins, which need to investigate their role in physiology, virulence, pathogenesis, and host interaction. To explore the role of hypothetical protein Rv0580c, we constructed the recombinant Mycobacterium smegmatis (M. smegmatis) strain, which expressed the Rv0580c protein heterologously. We observed that Rv0580c expressing M. smegmatis strain (Ms_Rv0580c) altered the colony morphology and increased the cell wall permeability, leading to this recombinant strain becoming susceptible to acidic stress, oxidative stress, cell wall-perturbing stress, and multiple antibiotics. The intracellular survival of Ms_Rv0580c was reduced in THP-1 macrophages. Ms_Rv0580c up-regulated the IFN-γ expression via NF-κB and JNK signaling, and down-regulated IL-10 expression via NF-κB signaling in THP-1 macrophages as compared to control. Moreover, Ms_Rv0580c up-regulated the expression of HIF-1α and ER stress marker genes via the NF-κB/JNK axis and JNK/p38 axis, respectively, and boosted the mitochondria-independent apoptosis in macrophages, which might be lead to eliminate the intracellular bacilli. This study explores the crucial role of Rv0580c protein in the physiology and novel host-pathogen interactions of mycobacteria.

Sigma factor C (SigC) contributes to Mycobacterium tuberculosis virulence in various animal models, but the stress response coordinated by this transcription factor was undefined. The results presented here indicate that SigC prevents copper starvation. Whole genome expression studies demonstrate short-term (4-h) induction of sigC, controlled from a tetracycline-inducible promoter, upregulates ctpB and genes in the nonribosomal peptide synthase (nrp) operon. These genes are expressed at higher levels after 48-h sigC induction, but also elevated are genes encoding copper-responsive regulator RicR and RicR-regulated copper toxicity response operon genes rv0846–rv0850, suggesting prolonged sigC induction results in excessive copper uptake. No growth and global transcriptional differences are observed between a sigC null mutant relative to its parent strain in 7H9 medium. In a copper-deficient medium, however, growth of the sigC deletion strain lags the parent, and 40 genes (including those in the nrp operon) are differentially expressed. Copper supplementation reverses the growth defect and silences most transcriptional differences. Together, these data support SigC as a transcriptional regulator of copper acquisition when the metal is scarce. Attenuation of sigC mutants in severe combined immunodeficient mice is consistent with an inability to overcome innate host defenses that sequester copper ions to deprive invading microbes of this essential micronutrient.

Acyl carrier proteins (ACPs) are important components in fatty-acid biosynthesis in prokaryotes. Rv0100 is predicted to be an essential ACP in Mycobacterium tuberculosis, the pathogen that is the causative agent of tuberculosis, and therefore has the potential to be a novel antituberculosis drug target. Here, the successful cloning and purification of Rv0100 using Mycobacterium smegmatis as a host is reported. Crystals of the purified protein were obtained that diffracted to a resolution of 1.9 Å. Overall, this work lays the foundation for the future pursuit of drug discovery and development against this potentially novel drug target.

Mycobacterium tuberculosis, the main causative agent of human tuberculosis, is transmitted from person to person via small droplets containing very few bacteria. Optimizing the chance to seed in the lungs is therefore a major adaptation to favor survival and dissemination in the human population. Here we used TnSeq to identify genes important for the early events leading to bacterial seeding in the lungs. Beside several genes encoding known virulence factors, we found three new candidates not previously described: rv0180c, rv1779c and rv1592c. We focused on the gene, rv0180c, of unknown function. First, we found that deletion of rv0180c in M. tuberculosis substantially reduced the initiation of infection in the lungs of mice. Next, we established that Rv0180c enhances entry into macrophages through the use of complement-receptor 3 (CR3), a major phagocytic receptor for M. tuberculosis. Silencing CR3 or blocking the CR3 lectin site abolished the difference in entry between the wild-type parental strain and the Δrv0180c::km mutant. However, we detected no difference in the production of both CR3-known carbohydrate ligands (glucan, arabinomannan, mannan), CR3-modulating lipids (phthiocerol dimycocerosate), or proteins in the capsule of the Δrv0180c::km mutant in comparison to the wild-type or complemented strains. By contrast, we established that Rv0180c contributes to the functionality of the bacterial cell envelope regarding resistance to toxic molecule attack and cell shape. This alteration of bacterial shape could impair the engagement of membrane receptors that M. tuberculosis uses to invade host cells, and open a new perspective on the modulation of bacterial infectivity.

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Este trabalho teve como objetivo avaliar a capacidade da enzima Rv0800 (DAP) do Mycobacterium tuberculosis como componente de vacina de subunidade proteica em dois sistemas de adjuvantes derivados de plantas. Para tanto, foi feita a produção heteróloga da enzima Rv0800 em E. coli e sua expressão pelo Mtb foi confirmada. A proteína recombinante obtida (rDAP) foi avaliada como vacina primeiramente associada ao Cn-AMP1, um peptídeo antimicrobiano proveniente da água de coco, e em outro experimento, associada ao ADVAXTM, um adjuvante polissacarídico derivado da delta inulina e foram usadas para vacinar camundongos BALB/c. As vacinas DAPC e DAPVAX induziram anticorpos IgG1 e IgG2a específicos. A vacina DAPC gerou resposta imune celular de linfócitos TCD4+ e TCD8+ produtores de IFN-γ+ antes e depois do desafio com Mtb, e quando combinada com a vacina BCG melhorou a resposta induzida por esta. Contudo, apesar de as vacinas terem induzido resposta imune específica no modelo estudado, após a infecção foram geradas extensas lesões pulmonares e não houve diminuição da carga bacilar nos pulmões. Neste projeto foram desenvolvidas novas vacinas de subunidade proteica compostas por uma enzima do Mycobacterium tuberculosis associada a adjuvantes derivados de plantas, nunca testados no modelo murino de infecção e que se mostraram imunogênicas, mas não conferiram proteção.

All organisms must sense and respond to their environment in order to survive. The processes that allow a living cell to sense changes in its environment, and respond appropriately are collectively referred to as ‘signal transduction’. Cyclic AMP is a ubiquitously used second messenger molecule that plays diverse roles from hormone signalling in mammalian cells to catabolite repression in enteric bacteria. In several bacterial pathogens such as Pseudomonas aeruginosa, cAMP has also been found to mediate pathogenesis, usually by regulating the production of several virulence factors aiding in colonisation of the host. Cyclic AMP signalling has been suggested to regulate the virulence of the obligate intracellular Mycobacterium tuberculosis. Mycobacteria, including M. tuberculosis, code for a large number of adenylyl cyclases, enzymes that synthesise cAMP. Of the 16 putative adenylyl cyclases encoded by M. tuberculosis H37Rv, 10 have received extensive biochemical attention. A knockout of one of these cyclases, Rv0386, resulted in compromised virulence of M. tuberculosis. Ten proteins predicted to bind cAMP and mediate its cellular roles have also been identified in M. tuberculosis. Among these are the cAMP-regulated transcription factor, CRPMt, and cAMP-regulated protein acetyl transferase, KATmt. Comparatively little information is available, however, regarding the roles of cAMP-degrading machinery in mycobacteria. Two phosphodiesterases, with modest activity against cAMP in vitro, have been identified from M. tuberculosis, and are encoded by the Rv0805 and Rv2795c loci. Of these, Rv2795c has orthologs in all sequenced mycobacterial genomes. However, Rv0805-like proteins are coded only by slow growing mycobacteria such as the M. tuberculosis-complex, M. marinum and M. leprae, several of which are human or animal pathogens. Rv0805 belongs to the metallophosphoesterase superfamily of proteins, consisting of metal-dependent phosphoesterases with substrates ranging from large polymers like nucleic acids to small molecules like cAMP and glycerophospholipids. Like other metallophosphoesterases, Rv0805 displays promiscuous substrate utilisation and efficient hydrolysis of 2’3’-cAMP in vitro. Rv0805 also hydrolyses 3’5’-cAMP in vitro. Overexpression of Rv0805 is reported to lead to reduction in intracellular cAMP levels in M. smegmatis and M. tuberculosis, suggesting that it is capable of hydrolysing cAMP in the bacterial cell as well. The structure of Rv0805 revealed a sandwich-like α/β fold, typical of metallophosphoesterases, along with a relatively flexible C-terminal domain of unknown function. Despite extensive biochemical and structural information on Rv0805 however, its roles in mycobacteria remain unknown. In this study, the cellular roles of Rv0805 are explored and using information from biochemical and structural analyses, novel activities and interactions of Rv0805 have been identified. Rv0805, when expressed in M. smegmatis, led to a reduction in intracellular cAMP, as previously reported. However, the extent of reduction was modest (~30 %) and limited to the exponential phase of growth when both Rv0805 and intracellular cAMP are at their highest levels. Overexpression of Rv0805 also resulted in hypersensitivity to cell wall perturbants like crystal violet and sodium dodecyl sulphate (SDS) indicative of a change in the properties of the cell envelope of M. smegmatis. Importantly, these effects were independent of cAMP-hydrolysis by Rv0805, as overexpression of catalytically inactive Rv0805N97A also elicited similar changes. Unexpectedly, Rv0805 was localised to the cell envelope, both in M. tuberculosis as well as in M. smegmatis. The ability of Rv0805 to localise to the cell envelope was dependent on it C-terminus, as truncation of Rv0805 in this region (Rv0805Δ10, Rv0805Δ20 and Rv0805Δ40) resulted in progressively greater enrichment in the cytosol of M. smegmatis. Overexpression of Rv0805Δ40, which was localised almost completely to the cytosol, did not result in hypersensitivity to SDS, suggesting that cell envelope localisation, rather than cAMP-hydrolysis, was crucial for the cell envelope modifying roles of Rv0805. A possible mechanism behind the cell envelope-related effects of Rv0805 overexpression was the ability of the protein to interact with the cell wall of mycobacteria in a C-terminus-dependent manner. Purified Rv0805, but not Rv0805Δ40, could associate with crude mycobacterial cell wall as well as purified cell wall core polymer (mycolyl-arabinogalactan-peptidoglycan complex) in vitro. In addition to the C-terminus, the architecture of the active site was also crucial for this interaction as mutations in the active site that compromised metal-binding also resulted in poor interaction with the cell wall. Most significant among these residues was His207, which when mutated to Ala almost completely abrogated interaction with the cell wall in vitro. Further, Rv0805H207A was unable to localise to the cell envelope when expressed in M. smegmatis, even in the presence of the C-terminus, highlighting the importance of this residue in maintaining the structural integrity of Rv0805, and demonstrating that the structure of the C-terminus, rather than its sequence alone, played a role in cell envelope localisation and interaction. In order to verify that the observed sensitivity of Rv0805-overexpressing M. smegmatis to cell wall perturbants was due to a change in cell envelope properties atomic force microscopy was employed. Two distinct modes of operation were used to analyse surface and bulk properties of the mycobacterial cell envelope. These were tapping mode phase imaging, and contact mode force spectroscopy. Using tapping mode phase imaging, it was found that the cell surface of M. smegmatis was inherently heterogeneous in its mechanical properties. Further, contact mode force-spectroscopy revealed that the cell envelope of M. smegmatis in cross-section had at least three layers of varying stiffness. Typically, a middle layer of high stiffness was observed, sandwiched between two lower stiffness layers. This organisation is reminiscent of the current model of the mycobacterial cell envelope, possessing a central polysaccharide rich layer and outer and inner lipid rich layers. Treatment of wild type M. smegmatis with cell wall-perturbing antibiotics isoniazid and ethambutol resulted in markedly altered phase images, as well as significantly lower stiffness of the bacterial cell envelopes, validating that the methodology employed could indeed be used to assess cell wall perturbation in mycobacteria. Further, M. smegmatis harbouring deletions in cell envelope biosynthesis related genes, MSMEG_4722 and aftC, showed significantly lower cell wall stiffness than wild type M. smegmatis, providing evidence that genetic perturbation of the cell wall of mycobacteria could also be studied using atomic force microscopy. While phase imaging revealed similar surface properties of Rv0805-overexpressing and control M. smegmatis, force spectroscopy revealed significantly lower cell envelope stiffness, particularly of the middle layer, of the former. Cell envelope stiffness was, however, unaffected by expression of Rv0805Δ40 in M. smegmatis, providing direct evidence for C-terminus-dependent cell envelope perturbation upon Rv0805 overexpression. Additionally, overexpression of Rv0805N97A, but not Rv0805H207A led to reduced stiffness of the cell envelope of M. smegmatis, demonstrating that the cell wall remodelling activity of Rv0805 was independent of cAMP-hydrolysis, but dependent on cellular localisation and cell wall interaction. Like in M. smegmatis, overexpression of Rv0805 also led to lower cAMP levels in M. tuberculosis. Using a microarray-based transcriptomics approach, pathways affected by Rv0805 overexpression were identified. Rv0805 overexpression elicited a transcriptional response, leading to the down-regulation of a number of virulence associated genes such as whiB7, eis, prpC and prpD. Importantly, Rv0805-overexpression associated gene expression changes did not include genes regulated by CRPMt, the primary cAMP-regulated transcription factor in M. tuberculosis. Further, Rv0805N97A overexpression in M. tuberculosis led to similar changes in gene expression as overexpression of the wild type protein. These observations reiterated that, at least upon overexpression, the effects of Rv0805 were largely independent of cAMP-hydrolysis. Using overexpression in M. smegmatis and M. tuberculosis, cAMP-hydrolysis independent roles of Rv0805 in mycobacteria were identified. To further validate these observations, a knockout strain of the Rv0805 gene was generated in M. bovis BCG, a well-established model to study M. tuberculosis. Curiously, deletion of Rv0805 did not lead to a change in intracellular cAMP levels, demonstrating that cAMP-hydrolysis by Rv0805 may not contribute to the modulation of mycobacterial cAMP levels under standard laboratory growth conditions. Rv0805 deletion led to altered colony morphology and possible reduction in cell wall thickness, reaffirming the roles of this phosphodiesterase in regulating cell envelope physiology of mycobacteria. Additionally, Rv0805 deletion also resulted in compromised growth of M. bovis BCG in fatty acid-deficient media, implicating Rv0805 as a possible regulator of carbon metabolism. In summary, this thesis explores novel links between Rv0805 and the mycobacterial cell wall and elucidates the critical importance of the C-terminus domain of this metallophosphodiesterase in modulating its cellular localisation to, and interaction with, the mycobacterial cell envelope. En route to understanding the effects of Rv0805 overexpression on the cell wall of M. smegmatis, an atomic force microscopy-based methodology to assess perturbation of the cell envelope of mycobacteria was also developed. Finally, using a combination of biochemical and genetic analyses, cellular roles of Rv0805, independent of cAMP-hydrolysis, were identified in slow-growing mycobacteria. This study therefore provides direct evidence against the sole role of this mycobacterial phosphodiesterase as a regulator of intracellular cAMP levels, and opens up new avenues to understanding the cellular functions of Rv0805 and indeed other members of the metallophosphoesterase superfamily.