Abstract
Multiple drug resistance (MDR) in Mycobacterium tuberculosis (mTB), the causative agent for tuberculosis (TB), has led to increased use of second-line drugs, including ethionamide (ETA). ETA is a prodrug bioactivated by mycobacterial and mammalian flavin-containing monooxygenases (FMOs). FMO2 is the major isoform in the lungs of most mammals, including primates. In humans a polymorphism exists in the expression of FMO2. FMO2.2 (truncated, inactive) protein is produced by the common allele, while the ancestral allele, encoding active FMO2.1, has been documented only in individuals of African and Hispanic origin, at an incidence of up to 50% and 7%, respectively. We hypothesized that FMO2 variability in TB-infected individuals would yield differences in concentrations and ratios of ETA prodrug and metabolites. In this study we assessed the impact of the FMO2 genetic polymorphism on the pharmacokinetics of ETA after administration of a single oral dose of ETA (125 mg/kg) to wild type and triple Fmo1/2/4-null mice, measuring levels of prodrug vs. metabolites in plasma collected from 0 to 3.5 h post-gavage. All mice metabolized ETA to ETA S-oxide (ETASO) and 2-ethyl-4-amidopyridine (ETAA). Wild type mice had higher plasma concentrations of metabolites than of parent compound (p = 0.001). In contrast, Fmo1/2/4-null mice had higher plasma concentrations of parent compound than of metabolites (p = 0.0001). Thus, the human FMO2 genotype could impact the therapeutic efficacy and/or toxicity of ETA.
Highlights
Tuberculosis (TB), caused by Mycobacterium tuberculosis, has been recorded throughout history and continues to afflict the World populace
Results demonstrate that Fmo1/2/4 knockouts exhibit reduced efficacy in the metabolism of ETA compared to wild type C57BL/6J mice
Our results demonstrate a significant switch of ETA and ethionamide S-oxide (ETASO) plasma concentrations between WT and KO mice
Summary
Tuberculosis (TB), caused by Mycobacterium tuberculosis (mTB), has been recorded throughout history and continues to afflict the World populace. The knockout mice showed pharmacological behavioral responses that did not occur in the wild type mice [23] We are employing this Fmo1/2/4 triple knockout model as a platform to establish the impact in vivo of the absence of FMO-dependent metabolism from lung. Results demonstrate that Fmo1/2/4 knockouts exhibit reduced efficacy in the metabolism of ETA compared to wild type C57BL/6J mice. This mouse model should be suitable for studies to assess the proposed oxidative stress model in the context of the FMO2 genetic polymorphism and likely outcomes in human populations administered ETA long-term, and assessment of therapeutic efficacy in protocols employing TB-infected mice [24]
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