Reductive metabolism of tiaprofenic acid by the human liver and recombinant carbonyl reducing enzymes.

Tiaprofenic acid is a widely used anti-inflammatory drug; however, the reductive metabolism of tiaprofenic acid is not yet well understood. Here, we compared the reduction of tiaprofenic acid in microsomes and cytosol from the human liver. The microsomes exhibited lower K value toward tiaprofenic acid than the cytosol (K = 164 ± 18 μM vs.

In vitro metabolism of fenofibric acid by carbonyl reducing enzymes.

Fenofibric acid is a hypolipidemic drug that is used as an active ingredient per se or is administered in the form of fenofibrate that releases fenofibric acid after absorption. The metabolism of fenofibric acid is mediated primarily by glucuronidation. However, the other part of fenofibric acid is excreted as reduced fenofibric acid.

Carbonyl reduction of warfarin: Identification and characterization of human warfarin reductases.

Warfarin is a widely used anticoagulant and, unfortunately, is a drug that is commonly implicated in serious adverse events including fatalities. Although several factors, including the metabolism of warfarin via CYP450, have been reported to affect the safety and efficacy of warfarin therapy, the wide variance in the warfarin dosage in patients has not been completely clarified. In addition to the oxidative metabolism of warfarin mediated by CYP450, reductive metabolism is involved in warfarin biotransformation.

The role of carbonyl reducing enzymes in oxcarbazepine in vitro metabolism in man.

Oxcarbazepine, a second generation antiepileptic drug belonging to the family of dibenz[b,f]azepines, is subjected to a rapid and extensive biotransformation. Oxcarbazepine demonstrates a low potential for drug interactions because its biotransformation is mainly mediated by the reduction pathway instead of oxidative pathways, which are very susceptible to drug interactions. The reductive metabolism of oxcarbazepine yields a 10-monohydroxy derivative (10,11-dihydro-10-hydroxy-carbazepine), which is responsible for the pharmacological activity.

Carbonyl reduction pathways in drug metabolism.

The understanding of drug biotransformation is an important medical topic. The oxidative pathways that involve CYPs have been extensively studied in drug metabolism in contrast to the reductive pathways. This review focuses on drugs that have been reported to be reduced at the carbonyl group in vivo.

Expression of human carbonyl reductase 3 (CBR3; SDR21C2) is inducible by pro-inflammatory stimuli.

Until today, the physiologic role of human carbonyl reductase 3 (CBR3; SDR21C2), a member of the short-chain dehydrogenase/reductase superfamily remains obscure. Since the transcriptional regulation is closely related to the function of a protein, elucidation of the regulation of CBR3 should help to understand its physiologic role. We recently identified CBR3 as a novel target gene of Nrf2, a cellular sensor of oxidative stress.

Human carbonyl reductases.

Enzymatic carbonyl reduction means the formation of a hydroxy function out of a ketone or aldehyde moiety and applies for the metabolism of physiological (endogenous) or xenobiotic (exogenous) molecules. As for endogenous substrates, carbonyl reduction is often part of a reversible oxidoreductase process and involves the activation or inactivation of important signal molecules like steroids, prostaglandins, retinoids and biogenic amines. These reactions are carried out by NAD(P)(H)-dependent dehydrogenases belonging to two protein superfamilies, the aldo-keto reductases (AKR) and the short-chain dehydrogenases/reductases (SDR).

Regulation of human carbonyl reductase 3 (CBR3; SDR21C2) expression by Nrf2 in cultured cancer cells.

Carbonyl reduction is a central metabolic process that controls the level of key regulatory molecules as well as xenobiotics. Carbonyl reductase 3 (CBR3; SDR21C2), a member of the short-chain dehydrogenase/reductase (SDR) superfamily, has been poorly characterized so far, and the regulation of its expression is a complete mystery. Here, we show that CBR3 expression is regulated via Nrf2, a key regulator in response to oxidative stress.