Browsing by Subject "Cytochrome P-450 Enzyme System"

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    GENETIC VARIATION IN CYP4A11 AND BLOOD PRESSURE RESPONSE TO MINERALOCORTICOID RECEPTOR ANTAGONISM OR ENAC INHIBITION: AN EXPLORATORY PILOT STUDY IN AFRICAN AMERICANS
    (Elsevier, 2014-07) Laffer, Cheryl L.; Elijovich, Fernando; Eckert, George J.; Tu, Wanzhu; Pratt, J. Howard; Brown, Nancy J.; Department of Biostatistics, School of Public Health
    Background An rs3890011 variant of CYP4A11, which is in linkage disequilibrium with the loss-of-function variant rs1126742, is associated with hypertension in humans. In mice, Cyp4a deficiency results in salt-sensitive hypertension through activation of ENaC. We tested the hypothesis that the rs3890011 variant is associated with blood pressure response to drugs acting via the ENaC pathway. Methods and Results African Americans with volume-dependent, resistant hypertension were randomized to treatment with placebo, spironolactone, amiloride, or combination. Blood pressure responses were analyzed by CYP4A11 genotypes. Rs3890011 (GG:GC:CC=20:35:28) and rs1126742 (TT:TC:CC=45:31:7) were in linkage disequilibrium (D′=1, r=0.561). Expected small number of rs1126742 CC homozygotes precluded analysis of the effect of this genotype on treatment responses. Spironolactone reduced blood pressure in rs3890011 GG and GC individuals, but not in CC homozygotes (p=0.002), whereas amiloride reduced blood pressure similarly in all rs3890011 genotypes. The antihypertensive effects of spironolactone and amiloride were comparable in GG and GC participants, but only amiloride reduced pressure in CC homozygotes (−6.3±7.3/−3.2±4.0 versus +6.8±7.9/+4.8±8.6 mmHg, p<0.01/<0.05). The aldosterone response to spironolactone was also blunted in the CC genotype. Conclusions In individuals homozygous for the CYP4A11 rs3890011 C allele, blood pressure is resistant to mineralocorticoid receptor antagonism, but sensitive to ENaC inhibition, consistent with ENaC activation. Studies in a larger population are needed to replicate these findings.
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    In Vitro Metabolism of Montelukast by Cytochrome P450s and UDP-Glucuronosyltransferases
    (ASPET, 2015-12) Cardoso, Josiane de Oliveira; Oliveira, Regina Vincenzi; Lu, Jessica Bo Li; Desta, Zeruesenay; Department of Medicine, IU School of Medicine
    Montelukast has been recommended as a selective in vitro and in vivo probe of cytochrome P450 (P450) CYP2C8 activity, but its selectivity toward this enzyme remains unclear. We performed detailed characterization of montelukast metabolism in vitro using human liver microsomes (HLMs), expressed P450s, and uridine 5′-diphospho-glucuronosyltransferases (UGTs). Kinetic and inhibition experiments performed at therapeutically relevant concentrations reveal that CYP2C8 and CYP2C9 are the principal enzymes responsible for montelukast 36-hydroxylation to 1,2-diol. CYP3A4 was the main catalyst of montelukast sulfoxidation and stereoselective 21-hydroxylation, and multiple P450s participated in montelukast 25-hydroxylation. We confirmed direct glucuronidation of montelukast to an acyl-glucuronide. We also identified a novel peak that appears consistent with an ether-glucuronide. Kinetic analysis in HLMs and experiments in expressed UGTs indicate that both metabolites were exclusively formed by UGT1A3. Comparison of in vitro intrinsic clearance in HLMs suggest that direct glucuronidation may play a greater role in the overall metabolism of montelukast than does P450-mediated oxidation, but the in vivo contribution of UGT1A3 needs further testing. In conclusion, our in vitro findings provide new insight toward montelukast metabolism. The utility of montelukast as a probe of CYP2C8 activity may be compromised owing to involvement of multiple P450s and UGT1A3 in its metabolism.
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    Regulation of MicroRNA Expression by Rifampin in Human Hepatocytes
    (American Society for Pharmacology and Experimental Therapeutics, 2013-10) Ramamoorthy, Anuradha; Liu, Yunlong; Philips, Santosh; Desta, Zeruesenay; Lin, Hai; Goswami, Chirayu; Gaedigk, Andrea; Li, Lang; Flockhart, David A.; Skaar, Todd C.
    Rifampin causes drug interactions by altering hepatic drug metabolism. Because microRNAs (miRNAs) have been shown to regulate genes involved in drug metabolism, we determined the effect of rifampin on the expression of hepatic miRNAs. Primary human hepatocytes from seven subjects were treated with rifampin, and the expression of miRNA and cytochrome P450 (P450) mRNAs was measured by TaqMan assays and RNA-seq, respectively. Rifampin induced the expression of 10 clinically important and 13 additional P450 genes and repressed the expression of 9 other P450 genes (P < 0.05). Rifampin induced the expression of 33 miRNAs and repressed the expression of 35 miRNAs (P < 0.05). Several of these changes were highly negatively correlated with the rifampin-induced changes in the expression of their predicted target P450 mRNAs, supporting the possibility of miRNA-induced regulation of P450 mRNA expression. In addition, several other miRNA changes were positively correlated with the changes in P450 mRNA expression, suggesting similar regulatory mechanisms. Despite the interindividual variability in the rifampin effects on miRNA expression, principal components analysis clearly separated the rifampin-treated samples from the controls. In conclusion, rifampin treatment alters miRNA expression patterns in human hepatocytes, and some of the changes were correlated with the rifampin-induced changes in expression of the P450 mRNAs they are predicted to target.