K Venkatesan scite author profile

Treatment of multidrug-resistant tuberculosis has become one of the major problems in public health. Understanding the molecular mechanisms of drug resistance has been central to tuberculosis research in recent times. DNA microarray technology provides the platform to study the genomic variations related to these mechanisms on a comprehensive level. To investigate the role of efflux pumps in drug resistance, we have constructed a custom DNA microarray containing 25 drug efflux pump genes of Mycobacterium tuberculosis (Indian Patent file no. 2071/DEL/2007) and monitored changes in the expression of these genes on exposure of common anti-tuberculous drugs. Expression profiling of efflux pump genes in multidrug-resistant M. tuberculosis isolates showed overexpression of 10 genes following exposure to various anti-tuberculous drugs. Although two of these genes (Rv3065 and Rv2938) have already been reported to be active drug efflux pumps in M. tuberculosis in earlier studies, the increased activities of other eight efflux pump genes (Rv1819, Rv2209, Rv2459, Rv2477c, Rv2688, Rv2846, Rv2994, and Rv3728) have been demonstrated in multidrug-resistant isolates by us for the first time. After confirmation of differential expressions of these genes by real-time reverse transcription polymerase chain reaction, it was observed that a simultaneous overexpression of efflux pump genes Rv2459, Rv3728, and Rv3065 was associated with resistance to the combination of isoniazid and ethambutol, and these drugs, along with streptomycin, were identified to group together, where efflux-mediated drug resistance appears to be important in M. tuberculosis and follows a constant pattern of induction in multidrug-resistant isolates. Isoniazid and ethambutol combination was also found to be affected in 10% (6/60) of the clinical isolates in the presence of carbonyl cyanide m-chloro phenylhydrazone in resazurin microtitre plate assay, supporting the role of efflux pumps in the resistance to these drugs. Overexpression of two of the genes (Rv2477 and Rv2209) has also been observed with ofloxacin stress in M. tuberculosis.

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Pharmacokinetic Drug Interactions with Rifampicin

Venkatesan

1992

Clinical Pharmacokinetics

124

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Rifampicin, an antituberculosis drug, is usually administered for 4 to 12 months with other antituberculosis drugs or medications from other classes. A potential for drug interactions often exists because rifampicin is a potent inducer of hepatic drug metabolism, as evidenced by a proliferation of smooth endoplasmic reticulum and an increase in the cytochrome P450 content in the liver. The induction is a highly selective process and not every drug metabolised via oxidation is affected. Case reports and studies have demonstrated enhanced metabolism of several drugs; most of these interactions are clinically important. At the start of rifampicin treatment, and again at the end, clinicians must check the dosages of any accompanying medications with which rifampicin may potentially interact. Monitoring of clinical response and blood drug concentrations is essential to adjust the drug dosage during rifampicin therapy. Rifampicin also interacts with cholephils such as bilirubin and bromosulphthalein. Its pharmacokinetics are reported to be altered by ethambutol, p-aminosalicylic acid (through its excipient component), ketoconazole, cyclosporin, clofazimine, probenecid and phenobarbital through one or other of the following mechanisms--impaired absorption of rifampicin, competition between the drug and rifampicin for hepatic uptake and altered hepatic metabolism of rifampicin. Most interactions affecting rifampicin have been relatively minor or are not expected to alter its therapeutic efficacy.

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Proteomic analysis of Mycobacterium tuberculosis isolates resistant to kanamycin and amikacin

Kumar

Sharma

et al. 2013

Journal of Proteomics

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Comparative Proteomic Analysis of Aminoglycosides Resistant and Susceptible Mycobacterium tuberculosis Clinical Isolates for Exploring Potential Drug Targets

et al. 2015

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Aminoglycosides, amikacin (AK) and kanamycin (KM) are second line anti-tuberculosis drugs used to treat tuberculosis (TB) and resistance to them affects the treatment. Membrane and membrane associated proteins have an anticipated role in biological processes and pathogenesis and are potential targets for the development of new diagnostics/vaccine/therapeutics. In this study we compared membrane and membrane associated proteins of AK and KM resistant and susceptible Mycobacterium tuberculosis isolates by 2DE coupled with MALDI-TOF/TOF-MS and bioinformatic tools. Twelve proteins were found to have increased intensities (PDQuest Advanced Software) in resistant isolates and were identified as ATP synthase subunit alpha (Rv1308), Trigger factor (Rv2462c), Dihydrolipoyl dehydrogenase (Rv0462), Elongation factor Tu (Rv0685), Transcriptional regulator MoxR1(Rv1479), Universal stress protein (Rv2005c), 35kDa hypothetical protein (Rv2744c), Proteasome subunit alpha (Rv2109c), Putative short-chain type dehydrogenase/reductase (Rv0148), Bacterioferritin (Rv1876), Ferritin (Rv3841) and Alpha-crystallin/HspX (Rv2031c). Among these Rv2005c, Rv2744c and Rv0148 are proteins with unknown functions. Docking showed that both drugs bind to the conserved domain (Usp, PspA and SDR domain) of these hypothetical proteins and GPS-PUP predicted potential pupylation sites within them. Increased intensities of these proteins and proteasome subunit alpha might not only be neutralized/modulated the drug molecules but also involved in protein turnover to overcome the AK and KM resistance. Besides that Rv1876, Rv3841 and Rv0685 were found to be associated with iron regulation signifying the role of iron in resistance. Further research is needed to explore how these potential protein targets contribute to resistance of AK and KM.

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K Venkatesan

Microarray Analysis of Efflux Pump Genes in Multidrug-ResistantMycobacterium tuberculosisDuring Stress Induced by Common Anti-Tuberculous Drugs

Pharmacokinetic Drug Interactions with Rifampicin

Proteomic analysis of Mycobacterium tuberculosis isolates resistant to kanamycin and amikacin

Comparative Proteomic Analysis of Aminoglycosides Resistant and Susceptible Mycobacterium tuberculosis Clinical Isolates for Exploring Potential Drug Targets

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