UGT2B7

2O6L7364231396ENSG00000171234ENSMUSG00000070704P16662n/aNM_001074NM_001330719NM_001349568NM_001029867NP_001065NP_001317648NP_001336497n/aUGT2B7 (UDP-Glucuronosyltransferase-2B7) is a phase II metabolism isoenzyme found to be active in the liver, kidneys, epithelial cells of the lower gastrointestinal tract and also has been reported in the brain. In humans, UDP-Glucuronosyltransferase-2B7 is encoded by the UGT2B7 gene. UGT2B7 (UDP-Glucuronosyltransferase-2B7) is a phase II metabolism isoenzyme found to be active in the liver, kidneys, epithelial cells of the lower gastrointestinal tract and also has been reported in the brain. In humans, UDP-Glucuronosyltransferase-2B7 is encoded by the UGT2B7 gene. The UGTs serve a major role in the conjugation and subsequent elimination of potentially toxic xenobiotics and endogenous compounds. UGT2B7 has unique specificity for 3,4-catechol estrogens and estriol, suggesting that it may play an important role in regulating the level and activity of these potent estrogen metabolites. This enzyme is located on the endoplasmic reticulum and nuclear membranes of cells. Its function is to catalyse the conjugation of a wide variety of lipophilic aglycon substrates with glucuronic acid, using uridine diphosphate glucuronic acid. Together with UGT2B4, UGT2B7 is capable of glucosidation of hyodesoxycholic acid in the liver, but, unlike the 2B4 isoform, 2B7 is also able to glucuronidate various steroid hormones (androsterone, epitestosterone) and fatty acids. It is also able to conjugate major classes of drugs such as analgesics (morphine), carboxylic nonsteroidal anti-inflammatory drugs (ketoprofen), and anticarcinogens (all-trans retinoic acid). UGT2B7 is the major enzyme isoform for the metabolism of morphine to the main metabolites, morphine-3-glucuronide (M3G) which has no analgesic effect and morphine-6-glucuronide (M6G), which has analgesic effects more potent than morphine. As a consequence, altered UGT2B7 activity can significantly affect both the effectiveness and side-effects of morphine, as well as some related opiate drugs. No structure of a full human UGT enzyme has been determined yet, however Miley et al. resolved a partial UGT2B7 structure of the C-terminal portion showing two dimeric domains with Rossman-like folds in complex. The Rossman fold typically binds nucleotide substrates, in this case the UDP-glucuronic acid cofactor involved in glucuronidation by UGT2B7. Generally, the C-terminus of UGT enzymes is highly conserved and binds the UDP-glucuronic acid cofactor, while the N-terminus (not resolved in this structure) is responsible for substrate binding. This first resolved structure indicated that the C-terminus of one of the two dimers projected into the UDP-glucuronic acid binding site of the second dimer, thus rendering the second dimer ineffective. Further studies have investigated dimerization of UGT enzyme polymorphisms and found both homodimer and heterodimer (with genetic polymorphisms of UGT2B7 or other UGT enzymes such as UGT1A1) formation are possible, with some combinations having an effect on enzyme activity. UGT2B7 is considered to be a highly polymorphic gene. Various research efforts have investigated the potential effect of these polymorphic variants on glucuronidation activity of UGT2B7 and especially its clearance of administered drugs, including anticancer therapies. Decreased glucuronidation activity by genetically variant UGT2B7 could lead to increased toxicity due to elevated levels of the drug remaining or accumulating in a patient's organs especially liver, while increased activity could mean lower efficacy of the administered therapy due to lower than expected levels in the body. One study found that Han Chinese dye-industry workers exposed to benzidine were at higher risk for developing bladder cancer if they had the UGT2B7 single nucleotide polymorphism (SNP) C802T encoding His268Tyr. The histidine to tyrosine mutation at residue 268 is located in the N-terminal portion of UGT2B7, which binds the xenobiotic substrate as opposed to the C-terminus which binds UDP-glucuronic acid. The speculated mechanism for this increased cancer risk involved increased glucuronidation of benzidine by the mutant UGT2B7 followed by cleavage of the glucuronidated benzidine at urine pH levels, releasing higher concentrations of benzidine in the bladder. Another study looked for a similar association of variant UGT2B7 G900A with the risk of colorectal cancer but found no significant association. A study of erlotinib clearance in non-small cell lung cancer patients showed no statistical significance for SNPs of UGT2B7, which potentially metabolizes erlotinib as indicated by erlotinib inhibition of UGT2B7. An investigation into the clearance of diclofenac, a nonsteroidal anti-inflammatory drug (NSAID) that can cause serious drug-induced liver injury, showed that mutant UGT2B7 with the C802T SNP had a 6-fold lower clearance of diclofenac than wild-type UGT27B, possibly contributing to increased liver toxicity in patients with this mutation. Analysis of genetic polymorphisms of UGT2B7 in anti-tuberculosis drug-induced liver injury (ATLI) found no association between mutations of UGT2B7 and ATLI in the studied population.