Biotransformation and bioactivation reactions - 2015 literature highlights.

Since 1972, Drug Metabolism Reviews has been recognized as one of the principal resources for researchers in pharmacological, pharmaceutical and toxicological fields to keep abreast of advances in drug metabolism science in academia and the pharmaceutical industry. With a distinguished list of authors and editors, the journal covers topics ranging from relatively mature fields, such as cytochrome P450 enzymes, to a variety of emerging fields. We hope to continue this tradition with the current compendium of mini-reviews that highlight novel biotransformation processes that were published during the past year. Each review begins with a summary of the article followed by our comments on novel aspects of the research and their biological implications. This collection of highlights is not intended to be exhaustive, but rather to be illustrative of recent research that provides new insights or approaches that advance the field of drug metabolism. Abbreviations NAPQI N-acetyl-p-benzoquinoneimine ALDH aldehyde dehydrogenase AO aldehyde oxidase AKR aldo-keto reductase CES carboxylesterase CSB cystathionine ß-synthase CSE cystathionine γ-lyase P450 cytochrome P450 DHPO 2,3-dihydropyridin-4-one ESI electrospray FMO flavin monooxygenase GSH glutathione GSSG glutathione disulfide ICPMS inductively coupled plasma mass spectrometry i.p. intraperitoneal MDR multidrug-resistant NNAL 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol NNK 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone oaTOF orthogonal acceleration time-of-flight PBK physiologically based kinetic PCP pentachlorophenol SDR short-chain dehydrogenase/reductase SULT sulfotransferase TB tuberculosis.

2-Amino-[1,2,4]triazolo[1,5-a]pyridines as JAK2 inhibitors.

The advancement of a series of ligand efficient 2-amino-[1,2,4]triazolo[1,5-a]pyridines, initially identified from high-throughput screening, to a JAK2 inhibitor with pharmacodynamic activity in a mouse xenograft model is disclosed.

Elucidating the Mechanism of Tofacitinib Oxidative Decyanation.

BACKGROUND: Tofacitinib is known to generate two metabolites M2 (alcohol) and M4 (acid), which are formed as the result of oxidation and loss of the nitrile [1]. METHOD: Systematic in vitro investigation into generation of M2 and M4 from tofacitinib. RESULTS: In vitro using human liver microsomes, we found a new geminal diol metabolite of tofacitinib (MX) that lost the nitrile. MX was further reduced or oxidized to M2 (alcohol) and M4 (acid), respectively by enzymes such as aldo-keto reductase 1C1, aldehyde oxidase and possibly CYP3A4. Stable label studies using H2 18O and D2O suggested the source of oxygen was from water in the media. This was due to rapid water exchange with MX in the media prior to reduction to M2. In case of deuterium, one was incorporated in M2 and this was mainly as a result of tofacitinib rapid exchange of two deuterium atoms from D2O onto methylene position. After formation of MX, there was one deuterium that no longer exchanged with water and therefore retained in M2 for further reduction. CONCLUSION: The proposed mechanism involved the initial oxidation by P450 at the α-carbon to the nitrile group generating an unstable cyanohydrin intermediate; followed by the loss of the nitrile group to form a new geminal diol metabolite (MX).

Rate-Determining and Rate-Limiting Steps in the Clearance and Excretion of a Potent and Selective p21-Activated Kinase Inhibitor: A Case Study of Rapid Hepatic Uptake and Slow Elimination in Rat.

BACKGROUND: Significant under-prediction of in vivo clearance in rat was observed for a potent p21-activated kinase (PAK1) inhibitor, GNE1. OBJECTIVE: Rate-determining (rapid uptake) and rate-limiting (slow excretion) steps in systemic clearance and elimination of GNE1, respectively, were evaluated to better understand the cause of the in vitro-in vivo (IVIV) disconnect. METHODS: A series of in vivo, ex vivo, and in vitro experiments were carried out: 1) the role of organic cation transporters (Oct or Slc22a) was investigated in transporter knock-out and wild-type animals with or without 1-aminobenzotriazole (ABT) pretreatment; 2) the concentration-dependent hepatic extraction ratio was determined in isolated perfused rat liver; and 3) excreta were collected from both bile duct cannulated and non-cannulated rats after intravenous injection. RESULTS: After intravenous dosing, the rate-determining step in clearance was found to be mediated by the active uptake transporter, Oct1. In cannulated rats, biliary and renal clearance of GNE1 accounted for only approximately 14 and 16% of the total clearance, respectively. N-acetylation, an important metabolic pathway, accounted for only about 10% of the total dose. In non-cannulated rats, the majority of the dose was recovered in feces as unchanged parent (up to 91%) overnight following intravenous administration. CONCLUSION: Because the clearance of GNE1 is mediated through uptake transporters rather than metabolism, the extrahepatic expression of Oct1 in kidney and intestine in rat likely plays an important role in the IVIV disconnect in hepatic clearance prediction. The slow process of intestinal secretion is the rate-limiting step for in vivo clearance of GNE1.