Browsing by Subject "Glucuronosyltransferase"
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Item A systematic review of dexmedetomidine pharmacology in pediatric patients(Wiley, 2024) O'Kane, Aislinn; Quinney, Sara K.; Kinney, Emily; Bergstrom, Richard F.; Tillman, Emma M.; Medicine, School of MedicineDexmedetomidine is a centrally acting alpha-2 agonist used for initiation and maintenance of procedural sedation and mechanical ventilation in adult and pediatric settings. It is commonly used in both pediatric and neonatal intensive care units. Dexmedetomidine requires extensive titration, and patients can be over or under-sedated during titration, leading to adverse events such as hypotension and bradycardia, or inadequate sedation, which can result in self-extubation. There is a critical need to identify factors that contribute to variation in metabolism, clearance, and downstream targets of dexmedetomidine so that individualized pediatric dosing regimens can be developed. This review is focused on dexmedetomidine pharmacokinetics and pharmacodynamics in the pediatric population and dexmedetomidine-related pharmacogenes in both adults and children. We found that the strongest predictors of dexmedetomidine pharmacokinetics were age and size. Multiple pharmacogenes of significance have been identified, including ADRA2A, UGT2B10, UGT1A4, CYP1A2, CYP2A6, and CYP2D6. Evidence is weak for the correlation of these individual polymorphic genes with dexmedetomidine pharmacokinetics/dynamics, though there may be a polygenetic influence on pharmacologic response. This review provides a comprehensive overview of the genomic data gathered to date. We aim to summarize current pharmacologic studies regarding dexmedetomidine use and pharmacology in pediatric patients.Item 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 MedicineMontelukast 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.Item Influence of Uridine Diphosphate Glucuronosyltransferase Family 1 Member A1 and Solute Carrier Organic Anion Transporter Family 1 Member B1 Polymorphisms and Efavirenz on Bilirubin Disposition in Healthy Volunteers(American Society for Pharmacology and Experimental Therapeutics, 2020-03) Collins, Kimberly S.; Metzger, Ingrid F.; Gufford, Brandon T.; Lu, Jessica B.; Medeiros, Elizabeth B.; Pratt, Victoria M.; Skaar, Todd C.; Desta, Zeruesenay; Medical and Molecular Genetics, School of MedicineChronic administration of efavirenz is associated with decreased serum bilirubin levels, probably through induction of UGT1A1 We assessed the impact of efavirenz monotherapy and UGT1A1 phenotypes on total, conjugated, and unconjugated serum bilirubin levels in healthy volunteers. Healthy volunteers were enrolled into a clinical study designed to address efavirenz pharmacokinetics, drug interactions, and pharmacogenetics. Volunteers received multiple oral doses (600 mg/day for 17 days) of efavirenz. Serum bilirubin levels were obtained at study entry and 1 week after completion of the study. DNA genotyping was performed for UGT1A1 [*80 (C>T), *6 (G>A), *28 (TA7), *36 (TA5), and *37 (TA8)] and for SLCO1B1 [*5 (521T>C) and *1b (388A>G] variants. Diplotype predicted phenotypes were classified as normal, intermediate, and slow metabolizers. Compared with bilirubin levels at screening, treatment with efavirenz significantly reduced total, conjugated, and unconjugated bilirubin. After stratification by UGT1A1 phenotypes, there was a significant decrease in total bilirubin among all phenotypes, conjugated bilirubin among intermediate metabolizers, and unconjugated bilirubin among normal and intermediate metabolizers. The data also show that UGT1A1 genotype predicts serum bilirubin levels at baseline, but this relationship is lost after efavirenz treatment. SLCO1B1 genotypes did not predict bilirubin levels at baseline or after efavirenz treatment. Our data suggest that efavirenz may alter bilirubin disposition mainly through induction of UGT1A1 metabolism and efflux through multidrug resistance-associated protein 2. SIGNIFICANCE STATEMENT: Efavirenz likely alters the pharmacokinetics of coadministered drugs, potentially causing lack of efficacy or increased adverse effects, as well as the disposition of endogenous compounds relevant in homeostasis through upregulation of UGT1A1 and multidrug resistance-associated protein 2. Measurement of unconjugated and conjugated bilirubin during new drug development may provide mechanistic understanding regarding enzyme and transporters modulated by the new drug.Item Stereoselective Glucuronidation of Bupropion Metabolites In Vitro and In Vivo(American Society for Pharmacology & Experimental Therapeutics, 2016-04) Gufford, Brandon T.; Lu, Jessica Bo Li; Metzger, Ingrid F.; Jones, David R.; Desta, Zeruesenay; Medicine, School of MedicineBupropion is a widely used antidepressant and smoking cessation aid in addition to being one of two US Food and Drug Administration-recommended probe substrates for evaluation of cytochrome P450 2B6 activity. Racemic bupropion undergoes oxidative and reductive metabolism, producing a complex profile of pharmacologically active metabolites with relatively little known about the mechanisms underlying their elimination. A liquid chromatography-tandem mass spectrometry assay was developed to simultaneously separate and detect glucuronide metabolites of (R,R)- and (S,S)-hydroxybupropion, (R,R)- and (S,S)-hydrobupropion (threo) and (S,R)- and (R,S)-hydrobupropion (erythro), in human urine and liver subcellular fractions to begin exploring mechanisms underlying enantioselective metabolism and elimination of bupropion metabolites. Human liver microsomal data revealed marked glucuronidation stereoselectivity [Cl(int), 11.4 versus 4.3 µl/min per milligram for the formation of (R,R)- and (S,S)-hydroxybupropion glucuronide; and Cl(max), 7.7 versus 1.1 µl/min per milligram for the formation of (R,R)- and (S,S)-hydrobupropion glucuronide], in concurrence with observed enantioselective urinary elimination of bupropion glucuronide conjugates. Approximately 10% of the administered bupropion dose was recovered in the urine as metabolites with glucuronide metabolites, accounting for approximately 40%, 15%, and 7% of the total excreted hydroxybupropion, erythro-hydrobupropion, and threo-hydrobupropion, respectively. Elimination pathways were further characterized using an expressed UDP-glucuronosyl transferase (UGT) panel with bupropion enantiomers (both individual and racemic) as substrates. UGT2B7 catalyzed the stereoselective formation of glucuronides of hydroxybupropion, (S,S)-hydrobupropion, (S,R)- and (R,S)-hydrobupropion; UGT1A9 catalyzed the formation of (R,R)-hydrobupropion glucuronide. These data systematically describe the metabolic pathways underlying bupropion metabolite disposition and significantly expand our knowledge of potential contributors to the interindividual and intraindividual variability in therapeutic and toxic effects of bupropion in humans.