High-throughput microplate phosphorylation assays based on DevR-DevS/Rv2027c 2-component signal transduction pathway to screen for novel antitubercular compounds

DevR-DevS (Rv3133c-Rv3132c) and DevR-Rv2027c have been established through their autophosphorylation and phospho-transfer properties to constitute bonafide regulatory 2-component systems of Mycobacterium tuberculosis. DevR has also been shown by others to play a key regulatory role in the expression of M. tuberculosis genes comprising the dormancy regulon. The authors describe high-throughput phosphorylation assays in a microplate format using DevS and Rv2027c histidine kinases and DevR response regulator proteins from M. tuberculosis. The assays were designed to measure [gamma-(32)P]ATP-dependent autophosphorylation of DevS/Rv2027c and also the phosphotransfer reaction to DevR. First, the optimal reaction conditions were established using the conventional method of radiolabeling the 2-component proteins by [gamma-(32)P]ATP and followed by gel electrophoresis-based analysis. Next, the assays were converted to a high-throughput format in which the radiolabeled protein retained on a filter using mixed cellulose ester-based 96-well filter plates was analyzed for radioactivity retention by scintillation counting. The utility of these assays to screen for inhibitors is illustrated using 2-mercaptobenzimidazole, ethidium bromide, and EDTA. The high quality and flexibility of these assays will enable their use in high-throughput screening for new antitubercular compounds directed against 2-component systems that comprise a novel target in dormant mycobacteria.     

Identification and characterization of a regulatory sequence recognized by Mycobacterium tuberculosis persistence regulator MprA

Establishment and maintenance of persistent, latent infection by Mycobacterium tuberculosis are dependent on expression of the mprA-mprB regulatory system. Previously, MprA and MprB were shown to participate in phosphotransfer reactions characteristic of two-component signaling systems. To begin identifying downstream effector genes regulated by mprA-mprB during persistent stages of infection, a search for the regulatory sequence(s) recognized by response regulator MprA was carried out. Here, evidence is presented demonstrating that MprA recognizes a 19-bp sequence comprising two loosely conserved 8-bp direct repeat subunits separated by 3 nucleotides. This motif, termed the MprA box, is found upstream of the mprA coding sequence and that of downstream gene pepD (Rv0983). Protein phosphorylation was not required for binding to this DNA sequence by MprA in vitro; however, phosphorylation enhanced DNA binding by MprA and was required for the regulation of mprA and pepD by MprA in vivo. Binding of MprA to the MprA box was dependent on conserved nucleotides contained within repeat subunits and on the spacer length separating these repeats. In addition, recognition of this sequence proceeded via tandem binding of two monomers of MprA. Identification of the genetic determinants regulated by MprA will ultimately enhance our understanding of the mechanisms utilized by M. tuberculosis to undergo latency.     

In silico analysis of DosR regulon proteins of Mycobacterium tuberculosis

One of the challenges faced by Mycobacterium tuberculosis (M. tuberculosis) in dormancy is hypoxia. DosR/DevR of M. tuberculosis is a two component dormancy survival response regulator which induces the expression of 48 genes. In this study, we have used DosR regulon proteins of M. tuberculosis H37Rv as the query set and performed a comprehensive homology search against the non-redundant database. Homologs were found in environmental mycobacteria, environmental bacteria and archaebacteria. Analysis of genomic context of DosR regulon revealed that they are distributed as nine blocks in the genome of M. tuberculosis with many transposases and integrases in their vicinity. Further, we classified DosR regulon proteins into eight functional categories. One of the hypothetical proteins Rv1998c could probably be a methylisocitrate lyase or a phosphonomutase. Another hypothetical protein, Rv0572 was found only in mycobacteria. Insights gained in this study can potentially aid in the development of novel therapeutic interventions.     

Mycobacterium tuberculosis DosR regulon gene Rv0079 encodes a putative, 'dormancy associated translation inhibitor (DATIN)'

Mycobacterium tuberculosis is a major human pathogen that has evolved survival mechanisms to persist in an immune-competent host under a dormant condition. The regulation of M. tuberculosis metabolism during latent infection is not clearly known. The dormancy survival regulon (DosR regulon) is chiefly responsible for encoding dormancy related functions of M. tuberculosis. We describe functional characterization of an important gene of DosR regulon, Rv0079, which appears to be involved in the regulation of translation through the interaction of its product with bacterial ribosomal subunits. The protein encoded by Rv0079, possibly, has an inhibitory role with respect to protein synthesis, as revealed by our experiments. We performed computational modelling and docking simulation studies involving the protein encoded by Rv0079 followed by in vitro translation and growth curve analysis experiments, involving recombinant E. coli and Bacille Calmette Guérin (BCG) strains that overexpressed Rv0079. Our observations concerning the interaction of the protein with the ribosomes are supportive of its role in regulation/inhibition of translation. We propose that the protein encoded by locus Rv0079 is a 'dormancy associated translation inhibitor' or DATIN.     

结核分枝杆菌H37Rv新基因Rv2742克隆表达及纯化

Rv2742是本课题组前期基于蛋白质基因组学策略从结核分枝杆菌Mycobacteriumtuberculosis H37Rv中发现、鉴定的遗漏注释基因。文中旨在建立结核分枝杆菌H37Rv漏注释蛋白Rv2742的可溶性诱导表达、纯化体系,为进一步探索Rv2742基因参与的生物学功能奠定基础。前期实验发现构建的pGEX-4T-2-Rv2742、pET-28a-Rv2742、pET-32a-Rv2742及pMAL-c2X-Rv2742原核表达载体均无法实现目的蛋白的诱导表达。但经密码子优化后,仅有pMAL-c2X-Rv2742载体能够实现目的蛋白的可溶性诱导表达。此外,通过比较不同宿主菌、温度及IPTG浓度对目的蛋白表达量的影响,发现目的蛋白在Rosetta (DE3)中,16℃及0.5mmol/LIPTG诱导条件下表达量最高。直链淀粉树脂(Amyloseresin)亲和层析柱纯化获得较纯的产物,经LC-MS/MS验证确认是Rv2742融合蛋白肽段序列。成功获得结核分枝杆菌H37Rv新基因Rv2742的重组蛋白,可进一步开展其潜在相互作用及免疫原性研究工作。     

Molecular characterization of secretory proteins Rv3619c and Rv3620c from Mycobacterium tuberculosis H37Rv

Rv3619c and Rv3620c are the secretory, antigenic proteins of the ESAT-6/CFP-10 family of Mycobacterium tuberculosis H37Rv. In this article, we show that Rv3619c interacts with Rv3620c to form a 1 : 1 heterodimeric complex with a dissociation constant (K(d)) of 4.8 × 10(-7) M. The thermal unfolding of the heterodimer was completely reversible, with a T(m) of 48 °C. The comparative thermodynamics and thermal unfolding analysis of the Rv3619c-Rv3620c dimer, the ESAT-6-CFP-10 dimer and another ESAT family heterodimer, Rv0287-Rv0288, revealed that the binding strength and stability of Rv3619c-Rv3620c are relatively lower than those of the other two pairs. Molecular modeling and docking studies predict the structure of Rv3619c-Rv3620c to be similar to that of ESAT-6-CFP-10. Spectroscopic studies revealed that, in an acidic environment, Rv3619c and Rv3620c lose their secondary structure and interact weakly to form a complex with a lower helical content, indicating that Rv3619c-Rv3620c is destabilized at low pH. These results, combined with those of previous studies, suggest that unfolding of the proteins is required for dissociation of the complex and membrane binding. In the presence of membrane mimetics, the α-helical contents of Rv3619c and Rv3620 increased by 42% and 35%, respectively. In mice, the immune response against Rv3619c protein is characterized by increased levels of interferon-γ, interleukin-12 and IgG(2a) , indicating a dominant Th1 response, which is mandatory for protection against mycobacterial infection. This study therefore emphasizes the potential of Rv3619c as a subunit vaccine candidate.     

The Mycobacterium DosR regulon structure and diversity revealed by comparative genomic analysis

Tuberculosis (TB), caused by Mycobacterium tuberculosis (Mtb), which claims approximately two million people annually, remains a global health concern. The non‐replicating or dormancy like state of this pathogen which is impervious to anti‐tuberculosis drugs is widely recognized as the culprit for this scenario. The dormancy survival regulator (DosR) regulon, composed of 48 co‐regulated genes, is held as essential for Mtb persistence. The DosR regulon is regulated by a two‐component regulatory system consisting of two sensor kinases—DosS (Rv3132c) and DosT (Rv2027c), and a response regulator DosR (Rv3133c). The underlying regulatory mechanism of DosR regulon expression is very complex. Many factors are involved, particularly the oxygen tension. The DosR regulon enables the pathogen to persist during lengthy hypoxia. Comparative genomic analysis demonstrated that the DosR regulon is widely distributed among the mycobacterial genomes, ranging from the pathogenic strains to the environmental strains. In‐depth studies on the DosR response should provide insights into its role in TB latency in vivo and shape new measures to combat this exceeding recalcitrant pathogen. J. Cell. Biochem. 114: 1–6, 2012. © 2012 Wiley Periodicals, Inc.     

Rv1915 and Rv1916 from Mycobacterium tuberculosis H37Rv form in vitro protein-protein complex

BackgroundMycobacterium tuberculosis (Mtb) isocitrate lyase (ICL) is an established drug target that facilitates Mtb persistence. Unlike other mycobacterial strains, where ICL2 is a single gene product, H37Rv has a split event, resulting in two tandemly coded icls - rv1915 and rv1916. Our recent report on functionality of individual Rv1915 and Rv1916, led to postulate the cooperative role of these proteins in pathogen's survival under nutrient-limiting conditions. This study investigates the possibility of Rv1915 and Rv1916 interacting and forming a complex.MethodsPull down assay, activity assay, mass spectrometry and site directed mutagenesis was employed to investigate and validate Rv1915-Rv1916 complex formation.ResultsRv1915 and Rv1916 form a stable complex in vitro, with enhanced ICL/MICL activities as opposed to individual proteins. Further, activities monitored in the presence of acetyl-CoA show significant increase for Rv1916 and the complex but not of Rv0467 and Rv1915Δ90CT. Both full length and truncated Rv1915Δ90CT can form complex, implying the absence of its C-terminal disordered region in complex formation. Further, in silico analysis and site-directed mutagenesis studies reveal Y64 and Y65 to be crucial residues for Rv1915-Rv1916 complex formation.ConclusionsThis study uncovers the association between Rv1915 and Rv1916 and supports the role of acetyl-CoA in escalating the ICL/MICL activities of Rv1916 and Rv1915Δ90CT-Rv1916 complex.General significancePartitioning of ICL2 into Rv1915 and Rv1916 that associates to form a complex in Mtb H37Rv, suggests its importance in signaling and regulation of metabolic pathway particularly in carbon assimilation.