Rhodococcus sp. strain RHA1, a soil bacterium related to Mycobacterium tuberculosis, degrades an exceptionally broad range of organic compounds. Transcriptomic analysis of cholesterol-grown RHA1 revealed a catabolic pathway predicted to proceed via 4-androstene-3,17-dione and 3,4-dihydroxy-9,10-seconandrost-1,3,5(10)-triene-9,17-dione (3,4-DHSA). Inactivation of each of the hsaC, supAB, and mce4 genes in RHA1 substantiated their roles in cholesterol catabolism. Moreover, the hsaC ؊ mutant accumulated 3,4-DHSA, indicating that HsaCRHA1, formerly annotated as a biphenyl-degrading dioxygenase, catalyzes the oxygenolytic cleavage of steroid ring A. Bioinformatic analyses revealed that 51 rhodococcal genes specifically expressed during growth on cholesterol, including all predicted to specify the catabolism of rings A and B, are conserved within an 82-gene cluster in M. tuberculosis H37Rv and Mycobacterium bovis bacillus Calmette-Gué rin. M. bovis bacillus Calmette-Gué rin grew on cholesterol, and hsaC and kshA were up-regulated under these conditions. Heterologously produced HsaCH37Rv and HsaDH37Rv transformed 3,4-DHSA and its ring-cleaved product, respectively, with apparent specificities Ϸ40-fold higher than for the corresponding biphenyl metabolites. Overall, we annotated 28 RHA1 genes and proposed physiological roles for a similar number of mycobacterial genes. During survival of M. tuberculosis in the macrophage, these genes are specifically expressed, and many appear to be essential. We have delineated a complete suite of genes necessary for microbial steroid degradation, and pathogenic mycobacteria have been shown to catabolize cholesterol. The results suggest that cholesterol metabolism is central to M. tuberculosis's unusual ability to survive in macrophages and provide insights into potential targets for novel therapeutics.catabolic pathway ͉ oxygenase ͉ Rhodococcus ͉ steroid degradation
As a first step to validate the use of carbon nanotubes as novel vaccine or drug delivery devices, their interaction with a part of the human immune system, complement, has been explored. Haemolytic assays were conducted to investigate the activation of the human serum complement system via the classical and alternative pathways. Western blot and sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) techniques were used to elucidate the mechanism of activation of complement via the classical pathway, and to analyse the interaction of complement and other plasma proteins with carbon nanotubes. We report for the first time that carbon nanotubes activate human complement via both classical and alternative pathways. We conclude that complement activation by nanotubes is consistent with reported adjuvant effects, and might also in various circumstances promote damaging effects of excessive complement activation, such as inflammation and granuloma formation. C1q binds directly to carbon nanotubes. Protein binding to carbon nanotubes is highly selective, since out of the many different proteins in plasma, very few bind to the carbon nanotubes. Fibrinogen and apolipoproteins (AI, AIV and CIII) were the proteins that bound to carbon nanotubes in greatest quantity.
The complement protein C3, when activated by limited proteolysis, forms a short-lived reactive intermediate fragment, 'nascent' C3b, which is known to bind covalently to certain surfaces. The characteristics of the covalent binding reaction have been studied by using Sepharose-trypsin as a combined proteolytic activator and binding surface for C3. Binding of C3 to Sepharose-trypsin is saturable, with a maximum of 25-26 molecules of C3b bound per molecule of trypsin. A minimum life-time of about 60 microseconds for the reactive intermediate has been calculated from binding of C3 at saturation. Initial binding efficiencies of over 30% can be obtained at physiological pH and ionic strength. The efficiency of C3 binding to Sepharose-trypsin decreases as pH increases and also shows a slight decline at high ionic strength. The covalent binding of C3 to Sepharose-trypsin can be inhibited by a range of oxygen and nitrogen nucleophiles. Activation of C3 in the presence of radioactive forms of four such nucleophiles, phenylhydrazine, methylamine, glycerol and glucosamine results in apparent covalent incorporation of the nucleophile into the C3d fragment of C3. The quantity of radioactive nucleophile bound can be predicted from the observed potency of the nucleophile as an inhibitor of the binding of C3 to Sepharose-trypsin. The radioactive nucleophiles may be considered as 'active-site' labels for C3.
The arylamine N-acetyltransferases (NATs) are involved in the metabolism of a variety of different compounds that we are exposed to on a daily basis. Many drugs and chemicals found in the environment, such as those in cigarette smoke, car exhaust fumes and in foodstuffs, can be either detoxified by NATs and eliminated from the body or bioactivated to metabolites that have the potential to cause toxicity and/or cancer. NATs have been implicated in some adverse drug reactions and as risk factors for several different types of cancers. As a result, the levels of NATs in the body have important consequences with regard to an individual's susceptibility to certain druginduced toxicities and cancers. This review focuses on recent advances in the molecular genetics of the human NATs.
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