Enzyme-assisted synthesis and structure characterization of glucuronic acid conjugates of losartan, candesartan, and zolarsartan.

Three angiotensin II receptor antagonists--losartan, candesartan, and zolarsartan--were investigated. All the compounds, which are structural analogues, are metabolized via conjugation to glucuronic acid. Interestingly, both O- and N-glucuronidation take place, so that regioisomers are formed. One ether O-glucuronide, two acyl O-glucuronides, and five tetrazole-N-glucuronides were biosynthesized, in milligram scale, from the three sartan aglycones. Liver microsomes from bovine, moose, rat, and pig and recombinant human UDP-glucuronosyltransferases were used as catalysts. The synthesized compounds were identified as sartan glucuronides by mass spectrometry, while the sites of glucuronidation were determined by nuclear magnetic resonance spectroscopy. Drug metabolites are needed as standards for pharmaceutical research and, as the present study shows, they can easily be produced with enzymes as catalyst.

Synthesis, structure characterization, and enzyme screening of clenbuterol glucuronides.

Two clenbuterol O-glucuronide diastereomers were synthesized by the Koenigs-Knorr reaction. Structures and glucuronidation sites of the glucuronides were characterized by tandem mass spectrometry and nuclear magnetic resonance spectroscopy. The two diastereomers were used as standard compounds in studies of stereoselective glucuronidation of clenbuterol with liver microsomes from different species and with 15 human recombinant UDP-glucuronosyltransferases. In this study, chemical and enzymatic reactions produced only O-glucuronides of clenbuterol, although on the basis of the chemical structure of the aglycone, both O- and N-glucuronides of clenbuterol could be formed. Differences in the production of diastereomers of clenbuterol glucuronides were observed among liver microsomes from the various animals. Dog and bovine liver microsomes were significantly active, and also stereoselective, each producing only one but a different diastereomer. Liver microsomes from rabbit and rat were also rather actively glucuronidating clenbuterol, but human, pig, and moose liver microsomes produced only minor amounts of glucuronides. Human liver microsomes produced only one clenbuterol glucuronide diastereomer, and the same was true of the human UDP-glucuronosyltransferases that were active (formation of glucuronide: 1A9 > 1A10 >> 1A7). The marked differences in the stereoselective glucuronidation of clenbuterol show that UDP-glucuronosyltransferases in the livers of different animals do not have the same functions, activities, or distribution. This needs to be taken into account, particularly in toxicology testing.

The human UDP-glucuronosyltransferase UGT1A3 is highly selective towards N2 in the tetrazole ring of losartan, candesartan, and zolarsartan.

Losartan, candesartan, and zolarsartan are AT(1) receptor antagonists that inhibit the effect of angiotensin II. We have examined their glucuronidation by liver microsomes from several animals and by recombinant human UDP-glucuronosyltransferases (UGTs). Large differences in the production of different glucuronide regioisomers of the three sartans were observed among liver microsomes from human (HLM), rabbit, rat, pig, moose, and bovine. However, all the liver microsomes produced one or two N-glucuronides in which either N1 or N2 of the tetrazole ring were conjugated. O-Glucuronides were also detected, including acyl glucuronides of zolarsartan and candesartan. Examination of individual human UGTs of subfamilies 1A and 2B revealed that N-glucuronidation activity is widespread, along with variable regioselectivity with respect to the tetrazole nitrogens of these sartans. Interestingly, UGT1A3 exhibited a strong regioselectivity towards the N2 position of the tetrazole ring in all three sartans. Moreover, the tetrazole-N2 of zolarsartan was only conjugated by UGT1A3, whereas the tetrazole-N1 of this aglycone was accessible to other enzymes, including UGT1A5. Zolarsartan O-glucuronide was mainly produced by UGTs 1A10 and 2B7. UGT2B7, alongside UGT1A3, glucuronidated candesartan at the tetrazole-N2 position, whereas UGTs 1A7-1A10 mainly yielded candesartan O-glucuronide. In the case of losartan, no O-glucuronide was generated by any tested human enzyme. Nevertheless, UGTs 1A1, 1A3, 1A10, 2B7, and 2B17 glucuronidated losartan at the tetrazole-N2, while UGT1A10 also yielded the respective N1-glucuronide. Kinetic analyses revealed that the main contributors to losartan glucuronidation in HLM are UGT1A1 and UGT2B7. The results provide ample new data on substrate specificity in drug glucuronidation.

Biosynthesis of dobutamine monoglucuronides and glucuronidation of dobutamine by recombinant human UDP-glucuronosyltransferases.

Selected aspects of dobutamine glucuronidation were studied in detail. There are potentially four sites at which dobutamine can be conjugated to glucuronic acid. Three of the four dobutamine monoglucuronides that can be formed were enzymatically synthesized using pig liver microsomes, isolated, and characterized by tandem mass spectrometry, and (1)H and (13)C NMR spectroscopy. Analysis of dobutamine glucuronidation by liver microsomes from various sources revealed large variability in the ratios of the three regioisomers. Interestingly, catecholic dobutamine meta-O-glucuronide, by far the major product synthesized with human liver microsomes, was only a minor product for rat liver microsomes. Rabbit liver microsomes yielded diglucuronides, in addition to monoglucuronides. Activities of individual recombinant human UDP-glucuronosyltransferases (UGTs) were investigated, and the results suggested that dobutamine glucuronidation in the human liver is mainly carried out by UGTs 2B7 and 1A9. Among the extrahepatic UGTs, the formation of monoglucuronides, mainly catecholic meta-O-glucuronide, by UGTs 1A7 and 1A8 was similar to that by 1A9, whereas UGT1A10 also efficiently catalyzed the formation of catecholic dobutamine para-O-glucuronide.