TiD: Standalone software for mining putative drug targets from bacterial proteome

TiD is a standalone application, which relies on basic assumption that a protein must be essential for pathogens survival and non-homologous with host to qualify as putative target. With an input bacterial proteome, TiD removes paralogous proteins, picks essential ones, and excludes proteins homologous with host organisms. The targets illustrate non-homology with at least 40 out of 84 gut microbes, considered safe for human. TiD classifies proposed targets as known, novel and virulent. Users can perform pathway analysis, choke point analysis, interactome analysis, subcellular localization and functional annotations through web servers cross-referenced with the application. Drug targets identified by TiD for Listeria monocytogenes, Bacillus anthracis and Pseudomonas aeruginosa have revealed significant overlaps with previous studies. TiD takes < 2 h to scan putative targets from a bacterial proteome with ~ 5000 proteins; hence, we propose it as a useful tool for rational drug design. TiD is available at http://bmicnip.in/TiD/.     

Excess mortality in persons with severe mental disorders: a multilevel intervention framework and priorities for clinical practice,policy and research agendas

Excess mortality in persons with severe mental disorders (SMD) is a major public health challenge that warrants action. The number and scope of truly tested interventions in this area remain limited, and strategies for implementation and scaling up of programmes with a strong evidence base are scarce. Furthermore, the majority of available interventions focus on a single or an otherwise limited number of risk factors. Here we present a multilevel model highlighting risk factors for excess mortality in persons with SMD at the individual, health system and socio‐environmental levels. Informed by that model, we describe a comprehensive framework that may be useful for designing, implementing and evaluating interventions and programmes to reduce excess mortality in persons with SMD. This framework includes individual‐focused, health system‐focused, and community level and policy‐focused interventions. Incorporating lessons learned from the multilevel model of risk and the comprehensive intervention framework, we identify priorities for clinical practice, policy and research agendas.     

Mechanistic studies of displacer–protein binding in chemically selective displacement systems using NMR and MD simulations

A parallel batch screening technique was employed to identify chemically selective displacers which exhibited exclusive separation behavior for the protein pair α‐chymotrypsin/ribonuclease A on a strong cation exchange resin. Two selective displacers, 1‐(4‐chlorobenzyl)piperidin‐3‐aminesulfate and N′1′‐(4‐methyl‐quinolin‐2‐yl)‐ethane‐1,2‐diamine dinitrate, and one non‐selective displacer, spermidine, were selected as model systems to investigate the mechanism of chemically selective displacement chromatography. Saturation transfer difference (STD) NMR was used to directly evaluate displacer–protein binding. The results indicated that while binding occurred between the two chemically selective displacers and the more hydrophobic protein, α‐chymotrypsin, no binding was observed with ribonuclease A. Further, the non‐selective displacer, spermidine, was not observed to bind to either protein. Importantly, the binding event was observed to occur primarily on the aromatic portion of the selective displacers. Extensive molecular dynamic simulations of protein–displacer–water solution were also carried out. The MD results corroborated the NMR findings demonstrating that the binding of selective displacers occurred primarily on hydrophobic surface patches of α‐chymotrypsin, while no significant long term binding to ribonuclease A was observed. The non‐selective displacer did not show significant binding to either of the proteins. MD simulations also indicated that the charged amine group of the selective displacers in the bound state was primarily oriented towards the solvent, potentially facilitating their interaction with a resin surface. These results directly confirm that selective binding between a protein and displacer is the mechanism by which chemically selective displacement occurs. This opens up many possibilities for future molecular design of selective displacers for a range of applications. Biotechnol. Bioeng. 2009;102: 1428–1437. © 2008 Wiley Periodicals, Inc.     

Genetic Characterization of Hepatitis B Virus in Peripheral Blood Leukocytes: Evidence for Selection and Compartmentalization of Viral Variants with the Immune Escape G145R Mutation

The compartmentalization of viral variants in distinct host tissues is a frequent event in many viral infections. Although hepatitis B virus (HBV) classically is considered hepatotropic, it has strong lymphotropic properties as well. However, unlike other viruses, molecular evolutionary studies to characterize HBV variants in compartments other than hepatocytes or sera have not been performed. The present work attempted to characterize HBV sequences from the peripheral blood leukocytes (PBL) of a large set of subjects, using advanced molecular biology and computational methods. The results of this study revealed the exclusive compartmentalization of HBV subgenotype Ae/A2-specific sequences with a potent immune escape G145R mutation in the PBL of the majority of the subjects. Interestingly, entirely different HBV genotypes/subgenotypes (C, D, or Aa/A1) were found to predominate in the sera of the same study populations. These results suggest that subgenotype Ae/A2 is selectively archived in the PBL, and the high prevalence of G145R indicates high immune pressure and high evolutionary rates of HBV DNA in the PBL. The results are analogous to available literature on the compartmentalization of other viruses. The present work thus provides evidence in favor of the compartment-specific abundance, evolution, and emergence of the potent immune escape mutant. These findings have important implications in the field of HBV molecular epidemiology, transmission, transfusion medicine, organ transplantation, and vaccination strategies.Hepatitis B virus (HBV) is the prototype member of the Hepadnaviridae family and classically has been described to be hepatotropic, causing a wide range of clinical and subclinical manifestations of liver disease (57). Nevertheless, studies of HBV-infected human subjects and woodchucks infected with Woodchuck hepatitis virus (WHV; an animal model of hepadnaviral infection) have reported different molecular forms of replicative intermediates in the lymphatic cells and have established that hepadnaviruses are strongly lymphotropic in nature (29). Moreover, the results of studies of human subjects as well as with animal models have revealed that the life-long occult persistence of replication- and transmission-competent viruses in lymphatic cells is a strict consequence of hepadnaviral infections (29).More interestingly, in animal models, lymphatic system-restricted occult hepadnaviral infection has been found to be transmissible vertically as an asymptomatic, serologically occult infection exclusively confined to the lymphatic system (29). Earlier we provided evidence that occult HBV persisting in the lymphatic cells are transmissible, specifically to the PBL through horizontal intrafamilial modes (9). These observations clearly indicate important immunological, pathogenic, and epidemiological implications of lymphatic system-restricted hepadnaviral infections. Although the involvement of specific viral variants has been suggested to explain this lymphatic system-restricted hepadnaviral infection and transmission (29), the classical belief that hepatocytes are the primary target and only reservoir of HBV has precluded the genetic characterization of hepadnaviruses from extrahepatic sites.Fascinatingly, despite being classically considered a hepatotropic virus, hepatitis C virus (HCV), belonging to the family Flaviviridae, also shows occult persistence and lymphotropism very similar to that of hepadnaviruses (37). Similarly to WHV, HBV, and HCV, other viruses, including HIV (human immunodeficiency virus), small ruminant lentivirus, and Epstein-Barr virus, also have been shown to infect and persist in different anatomical compartments of the body in addition to their classical target cells (38, 40, 43, 45, 50). Furthermore, recent molecular evolutionary analyses based on envelope sequences of these viruses (e.g., HIV, HCV, small ruminant lentivirus, Epstein-Barr virus, etc.) have established clearly that these viruses undergo selection and independent evolution in diverse tissues, leading to the tissue-specific compartmentalization of viral populations (38, 40, 43, 45, 50). In contrast to other viruses, to the best of our knowledge, methodical molecular evolutionary studies to characterize HBV sequences isolated from extrahepatic sites of HBV-infected subjects have not been reported in the literature.We hypothesized that similar to other viruses, HBV also undergo independent evolution in different compartments of the body under the influence of differential immune pressure. To examine our hypothesis, we used the most easily available lymphatic cells, the peripheral blood leukocytes (PBL), determined the HBV envelope sequences from HBV DNA isolated from these cells, and performed advanced genetic, phylogenetic, and mutational analysis. The results of this work demonstrate a highly compartment-specific preponderance of HBV genetic variants in serum and PBL of the same study population, providing evidence in favor of the compartmentalization of HBV genetic variants. The results and important implications of these findings are discussed in this work.     

Identification of Francisella tularensis Live Vaccine Strain CuZn Superoxide Dismutase as Critical for Resistance to Extracellularly Generated Reactive Oxygen Species

Francisella tularensis is an intracellular pathogen whose survival is in part dependent on its ability to resist the microbicidal activity of host-generated reactive oxygen species (ROS) and reactive nitrogen species (RNS). In numerous bacterial pathogens, CuZn-containing superoxide dismutases (SodC) are important virulence factors, localizing to the periplasm to offer protection from host-derived superoxide radicals (O₂⁻). In the present study, mutants of F. tularensis live vaccine strain (LVS) deficient in superoxide dismutases (SODs) were used to examine their role in defense against ROS/RNS-mediated microbicidal activity of infected macrophages. An in-frame deletion F. tularensis mutant of sodC (ΔsodC) and a F. tularensis ΔsodC mutant with attenuated Fe-superoxide dismutase (sodB) gene expression (sodB ΔsodC) were constructed and evaluated for susceptibility to ROS and RNS in gamma interferon (IFN-γ)-activated macrophages and a mouse model of respiratory tularemia. The F. tularensis ΔsodC and sodB ΔsodC mutants showed attenuated intramacrophage survival in IFN-γ-activated macrophages compared to the wild-type F. tularensis LVS. Transcomplementing the sodC gene in the ΔsodC mutant or inhibiting the IFN-γ-dependent production of O₂⁻ or nitric oxide (NO) enhanced intramacrophage survival of the sod mutants. The ΔsodC and sodB ΔsodC mutants were also significantly attenuated for virulence in intranasally challenged C57BL/6 mice compared to the wild-type F. tularensis LVS. As observed for macrophages, the virulence of the ΔsodC mutant was restored in ifn-γ^−/−, inos^−/−, and phox^−/− mice, indicating that SodC is required for resisting host-generated ROS. To conclude, this study demonstrates that SodB and SodC act to confer protection against host-derived oxidants and contribute to intramacrophage survival and virulence of F. tularensis in mice.Francisella tularensis is considered a potential biological threat due to its extreme infectivity, ease of artificial dissemination via aerosols, and substantial capacity to cause illness and death. A hallmark of all F. tularensis subspecies is their ability to survive and replicate within macrophages (18) and other cell types (6, 11, 25, 28). While recent work has furthered our understanding of F. tularensis virulence mechanisms, little is known with respect to its ability to resist the microbicidal production of reactive oxygen species (ROS) or reactive nitrogen species (RNS).Superoxide dismutases (SODs) are metalloproteins that are classified according to their coordinating active site metals. SODs catalyze the dismutation of the highly reactive superoxide (O₂⁻) anion to hydrogen peroxide (H₂O₂) and O₂ (26). The dismutation of O₂⁻ prevents accumulation of microbicidal ROS and RNS in infected macrophages. Three major categories of SODs have been identified in bacteria and include Mn-, Fe-, and CuZn-containing SODs (SodA, SodB, and SodC, respectively) and are required for aerobic survival (27). The F. tularensis genome encodes SodB (FTL_1791) and SodC (FTL_0380). In several intracellular bacterial pathogens, SodC is an important virulence factor, and its localization to the periplasmic space protects bacteria from host-derived O₂⁻ and NO radicals (8, 9, 21, 32). Moreover, many virulent bacteria possess two copies of the sodC gene (4). The evolutionary maintenance of an extra sodC gene copy suggests that it serves some essential function in survival (4). As an intracellular pathogen, F. tularensis is exposed to ROS and RNS generated by inflammatory cells during the macrophage activation process, which suggests that SODs may play an important role in its intracellular survival and pathogenesis. We have demonstrated that decreases in SodB activity render F. tularensis sensitive to ROS and attenuate virulence in mice (2). However, the contribution of F. tularensis SodC in virulence and intramacrophage survival has not been defined. In this study we have constructed a F. tularensis sodC mutant (ΔsodC) and a F. tularensis sodBC double mutant (sodB ΔsodC) and determined that SodC in conjunction with SodB primarily protects the pathogen from host-derived ROS and is required for intramacrophage survival and virulence of F. tularensis in mice.     

Identification of a New Exosite Involved in Catalytic Turnover by the Streptokinase-Plasmin Activator Complex during Human Plasminogen Activation

With the goal of identifying hitherto unknown surface exosites of streptokinase involved in substrate human plasminogen recognition and catalytic turnover, synthetic peptides encompassing the 170 loop (CQFTPLNPDDDFRPGLKDTKLLC) in the β-domain were tested for selective inhibition of substrate human plasminogen activation by the streptokinase-plasmin activator complex. Although a disulfide-constrained peptide exhibited strong inhibition, a linear peptide with the same sequence, or a disulfide-constrained variant with a single lysine to alanine mutation showed significantly reduced capabilities of inhibition. Alanine-scanning mutagenesis of the 170 loop of the β-domain of streptokinase was then performed to elucidate its importance in streptokinase-mediated plasminogen activation. Some of the 170 loop mutants showed a remarkable decline in k_cat without any alteration in apparent substrate affinity (K_m) as compared with wild-type streptokinase and identified the importance of Lys¹⁸⁰ as well as Pro¹⁷⁷ in the functioning of this loop. Remarkably, these mutants were able to generate amidolytic activity and non-proteolytic activation in “partner” plasminogen as wild-type streptokinase. Moreover, cofactor activities of the 170 loop mutants, pre-complexed with plasmin, against microplasminogen as the substrate showed a similar pattern of decline in k_cat as that observed in the case of full-length plasminogen, with no concomitant change in K_m. These results strongly suggest that the 170 loop of the β-domain of streptokinase is important for catalysis by the streptokinase-plasmin(ogen) activator complex, particularly in catalytic processing/turnover of substrate, although it does not seem to contribute significantly toward enzyme-substrate affinity per se.