SummaryEdwardsiella tarda is an important cause of haemorrhagic septicaemia in fish and also of gastro-and extraintestinal infections in humans. Using a combination of comparative proteomics and Tn phoA mutagenesis, we have identified five proteins that may contribute to E . tarda PPD130/91 pathogenesis. Lowered protein secretion, impaired autoaggregation and the absence of six proteins were observed only in three highly attenuated mutants when cultured in Dulbecco's modified eagle medium (DMEM). Five out of six proteins could be identified by their mass spectra. Three proteins were identified as putative effector proteins (EseB, EseC and EseD) that are homologous to SseB, SseC and SseD of a type III secretion system (TTSS) in Salmonella species. The other two were EvpA and EvpC, homologous to Eip20 and Eip18 in Edwardsiella ictaluri . The complete sequencing and homology studies of evpA-H indicate that similar gene clusters are widely distributed in other pathogens such as Escherichia , Salmonella , Vibrio and Yersinia species with unknown functions. Insertional inactivation and deletion of evpB or evpC led to lower replication rates in gourami phagocytes, and reduced protein secretion and virulence in blue gourami. Complementation of these deletion mutants showed partial recovery in the above three phenotypes, indicating that these genes are vital for E. tarda pathogenesis. The transport of the EvpC protein may not use the TTSS in E. tarda . The expression of EvpA and EvpC as well as EseB, EseC and EseD was temperature dependent (suppressed at 37 ∞ ∞ ∞ ∞ C), and disruption of esrB affected their expression. The present study identifies two possible secretion systems (TTSS and Evp) that are vital for E. tarda pathogenesis.
Mycobacteria store triacylglycerols (TGs) under various stress conditions, such as hypoxia, exposure to nitric oxide, and acidic environments. These stress conditions are known to induce nonreplicating persistence in mycobacteria. The importance of TG accumulation and utilization during regrowth is not clearly understood. Here we specifically determined the levels of accumulated TG and TG lipase activity in Mycobacterium bovis bacillus Calmette-Guerin (BCG) in various different physiological states (logarithmic growth, aerated stationary phase, hypoxia-induced dormancy, and regrowth from dormancy). We found extensive accumulation and degradation of TGs in the bacilli during entry into and exit from hypoxia-induced dormancy, respectively. These processes are accompanied by dynamic appearance and disappearance of intracellular TG lipid particles. The reduction in TG levels coincides with an increase in cellular TG lipase activity in the regrowing bacilli. Tetrahydrolipstatin, an inhibitor of TG lipases, reduces total lipase activity, prevents breakdown of TGs, and blocks the growth of mycobacteria upon resuscitation with air. Our results demonstrate that utilization of TGs is essential for the regrowth of mycobacteria during their exit from the hypoxic nonreplicating state.Mycobacterium tuberculosis is the causative agent of tuberculosis (TB), one of the major infectious diseases, which affects one-third of the world's population (http://www.who .int/mediacentre/factsheets/fs104/en/). The majority of TB patients carry a latent infection. However, reactivation leading to active disease (16, 27) often occurs once the host defenses are weakened. During the latency period, mycobacteria are tolerant to many conventional antibiotics (23, 28), thus making eradication of TB challenging.In the human body, M. tuberculosis is believed to persist in lung lesions with hypoxic environments (6, 27). Wayne and Hayes established an "in vitro dormancy model" in which mycobacterial cultures are subjected to gradual depletion of oxygen, which causes the obligate aerobic cells to exit the cell cycle and enter into a nonreplicating persistent state (26). The bacilli in the nonreplicating persistent state are phenotypically drug resistant. Recent efforts to explore the mechanisms which allow the tubercle bacilli to enter into dormancy and survive in the host for a long period of time suggest that fatty acids (FAs) could be an important source of energy during the persistent state (1,17,20). In particular, triacylglycerols (TGs), a class of neutral lipids, are postulated to be a likely source of FAs (8).TGs are an efficient form of energy reserves in many organisms during long-term survival.Recently, it was reported that tubercle bacilli in sputum from patients with TB contain lipid bodies (11). Moreover, TGs accumulate in hypervirulent W-Beijing strains of M. tuberculosis (19). It is interesting that TGs accumulate in these clinical strains of TB. However, no systematic study has been carried out yet to investigate the accumulation and ...
We have developed a software program that weights and integrates specific properties on the genes in a pathogen so that they may be ranked as drug targets. We applied this software to produce three prioritized drug target lists for Mycobacterium tuberculosis, the causative agent of tuberculosis, a disease for which a new drug is desperately needed. Each list is based on an individual criterion. The first list prioritizes metabolic drug targets by the uniqueness of their roles in the M. tuberculosis metabolome (“metabolic chokepoints”) and their similarity to known “druggable” protein classes (i.e., classes whose activity has previously been shown to be modulated by binding a small molecule). The second list prioritizes targets that would specifically impair M. tuberculosis, by weighting heavily those that are closely conserved within the Actinobacteria class but lack close homology to the host and gut flora. M. tuberculosis can survive asymptomatically in its host for many years by adapting to a dormant state referred to as “persistence.” The final list aims to prioritize potential targets involved in maintaining persistence in M. tuberculosis. The rankings of current, candidate, and proposed drug targets are highlighted with respect to these lists. Some features were found to be more accurate than others in prioritizing studied targets. It can also be shown that targets can be prioritized by using evolutionary programming to optimize the weights of each desired property. We demonstrate this approach in prioritizing persistence targets.
Edwardsiella tarda is responsible for hemorrhagic septicemia (edwardsiellosis) in fish and also causes diseases in higher vertebrates such as birds, reptiles, and mammals, including humans. Interactions of E. tarda with blue gourami phagocytes were studied by light microscopy as well as by adherence, intracellular replication, and superoxide anion assays. Both nonopsonized virulent (PPD130/91 and AL9379) and avirulent (PPD125/87 and PPD76/87) bacteria could adhere to and survive and replicate within phagocytes, while only opsonized virulent strains replicated within the phagocytes. Furthermore, only avirulent E. tarda elicited a higher rate of production of reactive oxygen intermediates (ROIs) by phagocytes, indicating that they were unable to avoid and/or resist reactive oxygen radical-based killing by the fish phagocytes. TnphoA transposon mutagenesis was used to construct a library of 200 alkaline phosphatase (PhoA ؉ ) fusion mutants from a total of 182,000 transconjugants derived from E. tarda PPD130/91. Five of these mutants induced more ROI production in phagocytes than the wild-type strain. Two mutants had lower replication ability inside phagocytes and moderately higher 50% lethal dose values than the wild-type strain. Sequence analysis revealed that three of these mutants had insertions at sequences having homology to PhoS, dipeptidase, and a surface polymer ligase of lipid A core proteins of other pathogens. These three independent mutations might have changed the cell surface characteristics of the bacteria, which in turn induced phagocytes to produce increased ROIs. Sequences from two other mutants had no homology to known genes, indicating that they may be novel genes for antiphagocytic killing. The present study showed that there are differences in the interactions of virulent and avirulent E. tarda organisms with fish phagocytes and PhoA ؉ fusion mutants that could be used successfully to identify virulence genes. The information elucidated here would help in the development of suitable strategies to combat the disease caused by E. tarda.
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