M. leprae HSP18 suppresses copper (II) mediated ROS generation: Effect of redox stress on its structure and function.

Mycobacterium leprae, causative organism of leprosy, is known to counter redox stress generated by reactive oxygen species (ROS) during its survival inside host macrophages. But, the involvement of any antigenic protein(s) for countering such redox stress is still unknown. Interestingly, M. leprae HSP18, an important antigenic protein that helps in the growth and survival of M. leprae pathogen inside host macrophages, is induced under redox stress. Moreover, HSP18 also interacts with Cu2+. Copper (II) can induce redox stress via Fenton reaction. But, whether HSP18 suppresses Cu2+ mediated ROS generation, is still far from clear. Also, the effect of redox stress on its structure and function is not known. In this study, we show that HSP18 efficiently suppresses Cu2+ mediated generation of ROS and also prevents the redox mediated aggregation of a client protein (γD-crystallin). Upon exposure to substantial redox stress, irreversible perturbation in the secondary and tertiary structure of HSP18 and the tryptophan and tyrosine oxidation are evidenced. Interestingly, HSP18 retains a considerable amount of functionality even after being exposed to substantial redox stress. Perhaps, the redox scavenging ability as well as the chaperone function of HSP18 may possibly help M. leprae pathogen to counter redox stress inside host macrophages.

High throughput atmospheric pressure plasma-induced graft polymerization for identifying protein-resistant surfaces.

Three critical aspects of searching for and understanding how to find highly resistant surfaces to protein adhesion are addressed here with specific application to synthetic membrane filtration. They include the (i) discovery of a series of previously unreported monomers from a large library of monomers with high protein resistance and subsequent low fouling characteristics for membrane ultrafiltration of protein-containing fluids, (ii) development of a new approach to investigate protein-resistant mechanisms from structure-property relationships, and (iii) adaptation of a new surface modification method, called atmospheric pressure plasma-induced graft polymerization (APP), together with a high throughput platform (HTP), for low cost vacuum-free synthesis of anti-fouling membranes. Several new high-performing chemistries comprising two polyethylene glycol (PEG), two amines and one zwitterionic monomers were identified from a library (44 commercial monomers) of five different classes of monomers as strong protein-resistant monomers. Combining our analysis here, using the Hansen solubility parameters (HSP) approach, and data from the literature, we conclude that strong interactions with water (hydrogen bonding) and surface flexibility are necessary for producing the highest protein resistance. Superior protein-resistant surfaces and subsequent anti-fouling performance was obtained with the HTP-APP as compared with our earlier HTP-photo graft-induced polymerization (PGP).

A comparative study of the redox-cycling of a quinone (rifamycin S) and a quinonimine (rifabutin) antibiotic by rat liver microsomes.

Rifamycin S and rifabutin are clinical drugs used to treat tuberculosis and leprosy. The formation of reactive oxygen species during the redox-cycling of rifamycin S (quinone) and rifabutin (quinonimine) was evaluated. The semiquinone (or semiquinonimine) and hydroquinone (or hydroquinonimine) formed during the reduction of the parent molecules by microsomal electron transfer in the presence of nicotinamide-adenine dinucleotide phosphate, reduced (NADPH) or nicotinamide-adenine dinucleotide, reduced (NADH) reoxidizes in air to generate superoxide radical and hydrogen peroxide. In the presence of added iron, hydroxyl radicals, formed by the Fenton reaction, were detected using 5,5'-dimethyl-1-pyroline-N-oxide as the spin-trap. Rifamycin S, a quinone, redox cycles more efficiently than rifabutin, a quinonimine, as approximately five times the concentration of hydroxyl radical adduct of 5,5'-dimethyl-1-pyroline-N-oxide (DMPO) was detected, when compared with rifabutin. The NADPH-dependent microsomal production of hydroxyl radical in the presence of rifamycin S was somewhat higher than the NADH-rifamycin S system with most iron chelators. However, with rifabutin, NADH-dependent microsomal production of hydroxyl radical was higher than that found with the NADPH-rifabutin system. An exception was the iron chelator, diethylene-triamine-pentacetic acid (DTPA), in which NADPH-dependent rates exceeded the rates with NADH with both antibiotics. Rat liver sub-mitochondrial particles also generated hydroxyl radical in the presence of NADH and either rifamycin S or rifabutin. The electron transport chain inhibitors such as rotenone and antimycin A enhanced the signal intensity of DMPO-OH, suggesting NADH dehydrogenase (complex I) as the major component involved in the reduction of rifamycin S. Rifamycin S was shown to be readily reduced to rifamycin SV, the corresponding hydroquinone by Fe(II); under similar conditions Fe(II) did not reduce rifabutin. Using optical spectroscopy, we determined that rifamycin S forms a complex with Fe(II). The stoichiometry of the complex was Fe(rifamycin S)3 in phosphate buffer at pH 7.4. Rifabutin did not form a detectable complex with Fe(II). The redox cycling of rifamycin S and rifabutin did not cause microsomal lipid peroxidation. In fact, the Fe:ATP induced lipid peroxidation was completely inhibited by these two molecules. These results indicate that rifamycin S and rifabutin can interact with rat liver microsomes to undergo redox-cycling, with the subsequent production of hydroxyl radicals when iron complexes are present. Compared to NADPH, NADH is almost as effective (rifamycin S) or even more effective (rifabutin) in promoting these interactions. These interactions may play a role in the hepatotoxicity associated with the use of these antibiotics.

In vitro susceptibility of Mycobacterium leprae to oxygen-mediated damage.

In order to evaluate factors responsible for the failure of Mycobacterium leprae to multiply in cell-free cultures in vitro studies were undertaken to determine the possible poisoning of the organism by hydroxide and superoxide radicals produced in the growth medium. The superoxide dismutase activity was very low, 10% of the levels found in armadillo cells, while measured activity of catalase and glutathione peroxidase was negligible. Susceptibility of M. leprae to hydrogen peroxide was enhanced by potassium iodide but not by lactoperoxidase. The addition of high amounts of catalase completely prevented hydrogen peroxide-mediated killing of M. leprae. Superoxide generated by the action of xanthine oxidase on xanthine was lethal to M. leprae, but superoxide dismutase added to the reaction mixture gave significant protection. Thus superoxide radicals may be a major cause for the sudden termination of growth of M. leprae in primary cultures and also for failure of subcultures.

Microbial glycolipids: possible virulence factors that scavenge oxygen radicals.

Two important pathogens of developing countries, Mycobacterium leprae, the etiologic agent of leprosy, and Leishmania donovani, the protozoal parasite that causes kalaazar, persist in the human host primarily in mononuclear phagocytes. The mechanisms by which they survive in these otherwise highly cytocidal cells are presently unknown. Since the best understood cytocidal mechanism of these cells is the oxygen-dependent system that provides lethal oxidants including the superoxide anion (O2-), hydrogen peroxide (H2O2), hydroxyl radical (OH), and singlet oxygen (1O2), we sought specific microbial products of these organisms that might enable them to elude oxidative cytocidal mechanisms. Phenolic glycolipid I of M. leprae and lipophosphoglycan of L. donovani are unique cell-wall-associated glycolipids produced in large amounts by the organisms. In this study, phenolic glycolipid I derivatives and lipophosphoglycan were examined for their ability to scavenge potentially cytocidal oxygen metabolites in vitro. Electron spin resonance and spin-trapping indicate that phenolic glycolipid I derivatives and lipophosphoglycan are highly effective in scavenging hydroxyl radicals and superoxide anions. The results suggest that complex glycolipids and carbohydrates of intracellular pathogens that can scavenge oxygen radicals may contribute to their pathogenicity and virulence.

Oxygen metabolism in phagocytes of leprotic patients: enhanced endogenous superoxide dismutase activity and hydroxyl radical generation by clofazimine.

We examined the generation of active oxygens (O2-, H2O2, and OH X ) and the superoxide dismutase (SOD) activity of polymorphonuclear leukocytes (PMNs) and monocytes from 14 leprotic patients manifesting a bacillary index above 2.2. Patients with disease of more than 4 years in duration showed significantly enhanced SOD activity and a decrease in O2- and OH X production. The antileprotic agent, clofazimine, significantly increased the generation of OH X in a dose-dependent manner, with a subsequent decrease in H2O2, but had no effect on the SOD activity of the PMNs and monocytes. In medium containing FeSO4 or Fe2+-EDTA, the drug elevated OH X production markedly further. Phagocytic SOD in PMNs and monocytes of leprotic patients was both host and bacillus derived, because the presence of cyanide, to which human-derived cuprozinc SOD is susceptible, did not completely abrogate SOD activity. The difficulty in treating leprosy may be partly ascribable to decreased phagocytic OH X generation, which in leprosy patients is apparently due to the uptake of Hansen bacillus-derived SOD. Clofazimine may be effective in leprosy by chelating Fe2+, with the resultant potentiation of the catalyzing activity of Fe2+ in the Haber-Weiss reaction increasing OH X formation from H2O2.