Stereoselective Glucuronidation of Carvedilol in Human Liver and Intestinal Microsomes

Background and Purpose: Carvedilol is used clinically as a β-adrenoceptor antagonist for the treatment of chronic heart failure and is primarily metabolized into glucuronides by UDP-glucuronosyltransferase (UGT). In this study, the stereoselective glucuronidation of carvedilol by the human liver and intestinal microsomes was examined using racemate and enantiomers. Methods: Carvedilol glucuronidation activities at substrate concentrations of 1-1,000 μmol/l in human liver and intestinal microsomes were determined by high-performance liquid chromatography with fluorescence detection, and the kinetic parameters were estimated. Results: The activities of S-glucuronidation toward racemic and enantiomeric carvedilol in liver microsomes were higher than those of R-glucuronidation at all substrate concentrations examined. In intestinal microsomes, the activities of S-glucuronidation from racemic and enantiomeric carvedilol at ≤100 μmol/l substrates were higher than those of R-glucuronidation, whereas the glucuronidation activities at ≥200 μmol/l substrates exhibited the opposite stereoselectivity (R > S) compared with those at ≤100 μmol/l substrates. The activities of R- and S-calvedilol glucuronidation from racemate and enantiomers in the liver and intestinal microsomes were decreased at substrate concentrations of ≥100 or 200 μmol/l, and the kinetics at substrate concentrations of 1-100 and 1-1,000 μmol/l fitted with Michaelis-Menten and substrate inhibition models, respectively. The stereoselectivities of CL(int) values for carvedilol glucuronidation followed by Michaelis-Menten and substrate inhibition models were R < S for liver microsomes and R ≈ S for intestinal microsomes. Conclusion: These findings demonstrate that the stereoselectivity of carvedilol glucuronidation was different between human liver and intestinal microsomes, and suggest that the difference is due to the tissue-specific expression of UGT isoforms involved in the glucuronidation of carvedilol.     

Glucuronidation of flavonoids by recombinant UGT1A3 and UGT1A9

Flavonoids are highlighted for their potential roles in the prevention of oxidative stress-associated diseases. Their metabolisms in vivo, such as glucuronidation, are the key points to determine their health beneficial properties. In this paper, we tested the glucuronidation of nineteen flavonoids by both recombinant human UGT1A3 and UGT1A9. Eleven compounds could be catalyzed by both enzymes. In general, both enzymes showed moderate to high catalyzing activity to most flavonoid aglycones, while the catalyzing efficiency changed with structures. Each flavonoid produced more than one monoglucuronide with no diglucuronide detected by liquid chromatography-mass spectrometry (LC-MS). Enzymatic kinetic analysis indicated that the catalyzing efficiency (Vmax/Km) of UGT1A9 was higher than that of UGT1A3, suggesting its important role in flavonoid glucuronidation. Both human UGT1A3 and UGT1A9 preferred flavonoid aglycone to flavonoid glycoside, and their metabolism to arabinoside was stronger than to other glycosides. Of the flavonoids studied, it is the first time to report isorhamnetin, morin, silybin, kaempferol, daidzein, quercetin-3',4'-OCHO-, quercetin xylopyranoside and avicularin as substrates of UGT1A3. Apigenin, morin, daidzein, quercetin-3',4'-OCHO-, quercetin xylopyranoside and avicularin were the newly reported substrates of UGT1A9.     

Use of Isoform-Specific UGT Metabolism to Determine and Describe Rates and Profiles of Glucuronidation of Wogonin and Oroxylin A by Human Liver and Intestinal Microsomes

Purposes  

Glucuronidation via UDP-glucuronosyltransferases (or UGTs) is a major metabolic pathway. The purposes of this study are to determine the UGT-isoform-specific metabolic fingerprint (or GSMF) of wogonin and oroxylin A, and to use isoform-specific metabolism rates and kinetics to determine and describe their glucuronidation behaviors in tissue microsomes.     

Regioselective Glucuronidation of Flavonols by Six Human UGT1A Isoforms

Purpose  

Glucuronidation is a major barrier to flavonoid bioavailability; understanding its regiospecificity and reaction kinetics would greatly enhance our ability to model and predict flavonoid disposition. We aimed to determine the regioselective glucuronidation of four model flavonols using six expressed human UGT1A isoforms (UGT1A1, 1A3, 1A7, 1A8, 1A9, 1A10).     

In Vitro Glucuronidation of Ochratoxin A by Rat Liver Microsomes

Ochratoxin A (OTA), one of the most toxic mycotoxins, can contaminate a wide range of food and feedstuff. To date, the data on its conjugates via glucuronidation request clarification and consolidation. In the present study, the combined approaches of ultra high performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS), UHPLC-Orbitrap-high resolution mass spectrometry (HRMS) and liquid chromatography-multiple stage mass spectrometry (LC-MSⁿ) were utilized to investigate the metabolic profile of OTA in rat liver microsomes. Three conjugated products of OTA corresponding to amino-, phenol- and acyl-glucuronides were identified, and the related structures were confirmed by hydrolysis with β-glucuronidase. Moreover, OTA methyl ester, OTα and OTα-glucuronide were also found in the reaction solution. Based on these results, an in vitro metabolic pathway of OTA has been proposed for the first time.     

Drug Hydroxylation and Glucuronidation in Liver Microsomes of Phenobarbital-Treated Rats

Abstract

1. The rise in p-nitroanisole O-demethylase activity in liver microsomes after phenobarbital treatment of rats slightly preceded, and was greater than, the increase in hepatic microsomal UDP-glucuronyltransferase activity.

2. Predigestion of hepatic microsomes with trypsin was necessary in order to detect the increase in UDP-glucuronyltransferase activity. Digitonin was not able to reveal the increase induced by phenobarbital.

3. Trypsin digestion of hepatic microsomes solubilized about 30% of the proteins in control rats and 45% in microsomes isolated from phenobarbital-treated rats. The amount of solubilized phospholipids was only about 6% in both cases.

4. The proteins solubilized by trypsin contained some components of the mixed-function oxidase including all of the NADPH cytochrome c reductase and a part of the cytochrome P-450 (as cytochrome P-420).

5. The trypsin digestion appears to peel off the superficial proteins of the microsomal vesicle and to uncover UDP-glucuronyltransferase from the deep layers of the microsomal membrane.     

Identification of Human UDP-Glucuronosyltransferase Responsible for the Glucuronidation of Niflumic Acid in Human Liver

Purpose To assess the uridine diphosphate (UDP)-glucuronosyltransferase (UGT) isozymes involved in the glucuronidation of niflumic acid in human liver. Methods The glucuronidation activity of niflumic acid was determined in liver microsomes and recombinant UGT isozymes by incubation of niflumic acid with UDP-glucuronic acid (UDPGA). Results Incubation of niflumic acid with liver microsomes and UDPGA produced one peak, which was identified as a glucuronide from mass spectrometric analysis. A study involving a panel of recombinant human UGT isozymes showed that glucuronidation activity was highest in UGT1A1 among the isozymes investigated. The glucuronidation in human liver microsomes (HLMs) followed Michaelis-Menten kinetics with a K_m value of 16 μM, which is similar to that found with recombinant UGT1A1. The glucuronidation activity of niflumic acid in microsomes from eight human livers significantly correlated with UGT1A1-catalyzed estradiol 3β-glucuronidation activity (r=0.78, p<0.05). β-Estradiol inhibited niflumic acid glucuronidation with an IC₅₀ of 25 μM in HLMs, comparable to that for UGT1A1. Conclusions These findings indicate that UGT1A1 is the main isozyme involved in the glucuronidation of niflumic acid in the human liver.     

Glucuronidation of 1'-hydroxyestragole (1'-HE) by human UDP-glucuronosyltransferases UGT2B7 and UGT1A9.

Estragole (4-allyl-1-methoxybenzene) is a naturally occurring food flavoring agent found in basil, fennel, bay leaves, and other spices. Estragole and its metabolite, 1'-hydroxyestragole (1'-HE), are hepatocarcinogens in rodent models. Recent studies from our laboratory have shown that glucuronidation of 1'-HE is a major detoxification pathway for estragole and 1'-HE, accounting for as much as 30% of urinary metabolites of estragole in rodents. Therefore, this study was designed to investigate the glucuronidation of 1'-HE in human liver microsomes in vitro and identify the specific uridine diphosphate glucuronosyltransferase (UGT) isoforms responsible for 1'-HE glucuronidation. The formation of the glucuronide of 1'-HE (1'-HEG) followed atypical kinetics, and the data best fit to a Hill equation, resulting in apparent kinetic parameters of Km = 1.45 mM, Vmax = 164.5 pmoles/min/mg protein, and n = 1.4. There was a significant intersubject variation in 1'-HE glucuronidation in 27 human liver samples, with a CV of 42%. A screen of cDNA expressed UGT isoforms indicated that UGT2B7 (83.94 +/- 0.188 pmols/min/mg), UGT1A9 (51.36 +/- 0.72 pmoles/min/mg), and UGT2B15 (8.18 +/- 0.037 pmoles/min/mg) were responsible for 1'-HEG formation. Glucuronidation of 1'-HE was not detected in cells expressing UGT1A1, UGT1A3, UGT1A4, UGT1A6, UGT1A7, UGT1A8, and UGT1A10. 1'-HE glucuronidation in 27 individual human liver samples significantly (p < 0.05) correlated with the glucuronidation of other UGT2B7 substrates (morphine and ibuprofen). These results imply that concomitant chronic intake of therapeutic drugs and dietary components that are UGT2B7 and/or UGT1A9 substrates may interfere with estragole metabolism. Our results also have toxicogenetic significance, as UGT2B7 is polymorphic and could potentially result in genetic differences in glucuronidation of 1'-HE and, hence, toxicity of estragole.     

Glucuronidation of piceatannol by human liver microsomes: major role of UGT1A1, UGT1A8 and UGT1A10

Objectives Piceatannol, a dietary polyphenol present in grapes and wine, is known for its promising anticancer and anti‐inflammatory activity. The aim of this study was to analyse the concentration‐dependent glucuronidation of piceatannol in vitro. Methods To determine the glucuronidation of piceatannol, experiments were conducted with human liver microsomes as well as using a panel of 12 recombinant UDP‐glucuronosyltransferase isoforms. Furthermore, the chemical structures of novel glucuronides were identified by liquid chromatography‐tandem mass spectrometry (LC‐MS/MS). Key findings Along with piceatannol it was possible to identify three metabolites whose structures were identified by LC‐MS/MS as piceatannol monoglucuronides (M1–M3). Formation of M1 and M3 exhibited a pattern of substrate inhibition, with apparent K_i and V_max/K_m values of 103 ± 26.6 µm and 3.8 ± 1.3 µl/mg protein per min, respectively, for M1 and 233 ± 61.4 µm and 19.8 ± 9.5 µl/mg protein per min, respectively, for M3. In contrast, formation of metabolite M2 followed classical Michaelis–Menten kinetics, with a K_m of 18.9 ± 8.1 µm and a V_max of 0.21 ± 0.02 nmol/mg protein per min. Incubation in the presence of human recombinant UDP‐glucuronosyltransferases (UGTs) demonstrated that M1 was formed nearly equally by UGT1A1 and UGT1A8. M2 was preferentially catalysed by UGT1A10 and to a lesser extent by UGT1A1 and UGT1A8. The formation of M3, however, was mainly catalysed by UGT1A1 and UGT1A8. Conclusions Our results elucidate the importance of piceatannol glucuronidation in the human liver, which must be taken into account in humans after dietary intake of piceatannol.     

Accurate Prediction of Glucuronidation of Structurally Diverse Phenolics by Human UGT1A9 Using Combined Experimental and In Silico Approaches

Purpose

Catalytic selectivity of human UGT1A9, an important membrane-bound enzyme catalyzing glucuronidation of xenobiotics, was determined experimentally using 145 phenolics and analyzed by 3D-QSAR methods.

Methods

Catalytic efficiency of UGT1A9 was determined by kinetic profiling. Quantitative structure activity relationships were analyzed using CoMFA and CoMSIA techniques. Molecular alignment of substrate structures was made by superimposing the glucuronidation site and its adjacent aromatic ring to achieve maximal steric overlap. For a substrate with multiple active glucuronidation sites, each site was considered a separate substrate.

Results

3D-QSAR analyses produced statistically reliable models with good predictive power (CoMFA: q²?=?0.548, r²?=?0.949, r _pred ² ?=?0.775; CoMSIA: q²?=?0.579, r²?=?0.876, r _pred ² ?=?0.700). Contour coefficient maps were applied to elucidate structural features among substrates that are responsible for selectivity differences. Contour coefficient maps were overlaid in the catalytic pocket of a homology model of UGT1A9, enabling identification of the UGT1A9 catalytic pocket with a high degree of confidence.

Conclusion

CoMFA/CoMSIA models can predict substrate selectivity and in vitro clearance of UGT1A9. Our findings also provide a possible molecular basis for understanding UGT1A9 functions and substrate selectivity.     

Glucuronidation of 1-hydroxypyrene by human liver microsomes and human UDP-glucuronosyltransferases UGT1A6, UGT1A7, and UGT1A9: development of a high-sensitivity glucuronidation assay for human tissue.

Human UDP-glucuronosyltransferases (UGT, EC 2.4.1.17) involved in the biotransformation of pyrene were investigated by a sensitive fluorometric high-performance liquid chromatography (HPLC)method developed for determining activities toward 1-hydroxypyrene. The endpoint metabolite of pyrene, 1-pyrenylglucuronide, is a well-known urinary biomarker for the assessment of human exposure to polycyclic aromatic hydrocarbons. 1-Pyrenylglucuronide was synthesized using rat liver microsomes as biocatalyst. The yield was satisfactory, 22%. 1-Pyrenylglucuronide, identified by (1)H NMR and by electrospray mass spectrometry, was used for method validation and calibration. The HPLC assay was very sensitive with a quantitation limit of 3 pg (8 fmol) for 1-pyrenylglucuronide. The assay was precise, showing a relative standard deviation of 5% or less at 0.1 to 300 microM 1-hydroxypyrene. Only 2 microg of microsomal protein was required for the assay in human liver. The glucuronidation of 1-hydroxypyrene was catalyzed at high rates in microsomes from pooled or three individual liver samples, showing comparable apparent K(m) values. The formation of 1-pyrenylglucuronide was catalyzed by recombinant human UGT1A6, UGT1A7, and UGT1A9, the K(m) values being 45, 12, and 1 microM, respectively. The apparent K(m) values in human liver microsomes, ranging from 6.9 to 8.6 microM, agreed well with these results. The method provides a sensitive tool for measuring extremely low UGT activities and a specific means for assessing interindividual differences in 1-hydroxypyrene-metabolizing UGT activities in human liver and other tissues.     

人UGT1A3重组酶催化芹菜素葡醛酸结合反应

目的旨在了解人UGT1A3重组酶与芹菜素的有关代谢及其酶动力学参数,并阐述不同有机溶剂对酶动力学参数测定的影响。方法采用Bac-to-Bac系统表达人UGT1A3重组酶与芹菜素37℃共孵育,用HPLC法测定孵育液中剩余底物浓度,利用Lineweaver Burk法计算酶动力学参数,并进一步进行代谢物的确认。同时考察了用不同有机溶剂溶解底物对酶动力学参数测定的影响。结果采用Bac-to-Bac系统表达人UGT1A3重组酶,测得其催化芹菜素的Km为(28.88±2.47)μmol.L-1,Vmax为(224.19±21.11)nmol.m in-1.g-1,Vmax/Km为(7.75±0.29)mL.m in-1.g-1。不同有机溶剂对酶动力学参数测定无显著影响。结论芹菜素可被人UGT1A3重组酶催化,进行葡醛酸结合反应。     

Glucuronidation of bioflavonoids by human UGT1A10: structure-function relationships

The extrahepatic human UDP glucuronosyltransferase 1A10 is found throughout the gastrointestinal tract and is thought to participate in the removal of orally ingested lipophilic chemicals. However, its substrate specificity towards these chemicals has not been fully characterized. The structurally diverse bioflavonoids are present in considerable amounts in fruits, vegetables and plant-derived beverages and have been shown to have many biological functions, including antioxidant properties. This study proposes features of the bioflavonoid structure necessary to confer it as a substrate of UGT1A10. The preferred substrates of UGT1A10 contain the hydroxyl group to be glucuronidated at C6 or C7, but not C5 of the A-ring or on C4' of the B-ring. Up to two additional hydroxyl groups on the A-ring enhance activity, whereas the presence of other groups, notably sugar groups, decreases activity. The high glucuronidation efficiency towards many bioflavonoids observed suggests that the contribution of UGT1A10 in the metabolism of these dietary compounds in the gastrointestinal tract may be significant.     

Enantiomer Selective Glucuronidation of the Non‐Steroidal Pure Anti‐Androgen Bicalutamide by Human Liver and Kidney: Role of the Human UDP‐Glucuronosyltransferase (UGT)1A9 Enzyme

Bicalutamide (Casodex^®) is a non‐steroidal pure anti‐androgen used in the treatment of localized prostate cancer. It is a racemate drug, and its activity resides in the (R)‐enantiomer, with little in the (S)‐enantiomer. A major metabolic pathway for bicalutamide is glucuronidation catalysed by UDP‐glucuronosyltransferase (UGT) enzymes. While (S)bicalutamide is directly glucuronidated, (R)bicalutamide requires hydroxylation prior to glucuronidation. The contribution of human tissues and UGT isoforms in the metabolism of these enantiomers has not been extensively investigated. In this study, both (R) and/or (S)bicalutamide were converted into glucuronide (‐G) derivatives after incubation of pure and racemic solutions with microsomal extracts from human liver and kidney. Intestinal microsomes exhibited only low reactivity with these substrates. Km values of liver and kidney samples for (S)bicalutamide glucuronidation were similar, and lower than values obtained with the (R)‐enantiomer. Among the 16 human UGTs tested, UGT1A8 and UGT1A9 were able to form both (S) and (R)bicalutamide‐G from pure or racemic substrates. UGT2B7 was also able to form (R)bicalutamide‐G. Kinetic parameters of the recombinant UGT2B7, UGT1A8 and UGT1A9 enzymes support a predominant role of the UGT1A9 isoform in bicalutamide metabolism. Accordingly, (S)bicalutamide inhibited the ability of human liver and kidney microsomes to glucuronidate the UGT1A9 probe substrate, propofol. In conclusion, the present study provides the first comprehensive analysis of in vitro bicalutamide glucuronidation by human tissues and UGTs and identifies UGT1A9 as a major contributor for (R) and (S) glucuronidation in the human liver and kidney.     

Glucuronidation of acetaminophen is independent of UGT1A1 promotor genotype

The metabolism of acetaminophen (paracetamol) is thought to be altered in patients with Gilbert's syndrome (GS), a chronic unconjugated hyperbilirubinemia. The underlying cause of GS is a polymorphism in the promotor region of the uridine diphosphate glucuronosyltransferase isoform 1A1 gene (UGT1A1*28), its encoded enzyme being responsible for the glucuronidation of bilirubin and presumably acetaminophen. Decreased enzyme activity results in elevated bilirubin levels and may activate various metabolic pathways leading to higher amounts of potentially hepatotoxic acetaminophen metabolites. Patients with GS might be more susceptible to unexpected side effects while taking acetaminophen and other drugs which are substrates of UGT1A1. The possibility of a correlation between glucuronidation capacity with respect to acetaminophen, UGT1A1 promotor polymorphism and the bilirubin serum level were investigated in 23 healthy male volunteers selected for UGT1A1 genotype (6 wildtypes, 9 mutants and 8 heterozygotes). One gram acetaminophen was administered p.o. and urine was collected over 2 4-hour periods. Unchanged acetaminophen and its glucuronide metabolite were determined using HPLC. The metabolic ratios unchanged acetaminophen/acetaminophen glucuronide in UGT1A1-wildtypes, heterozygotes and mutants showed no statistically significant differences. An association between metabolic ratio and serum bilirubin level could not be detected in any of the urine collection periods. These data confirm that there is no correlation between the capacity to glucuronidate acetaminophen, the UGT1A1 genotype and the bilirubin serum level. Acetaminophen is likely to be substrate of a UGT isoform other than the UGT1A1.     

Biochemical Basis for Deficient Paracetamol Glucuronidation in Cats: an Interspecies Comparison of Enzyme Constraint in Liver Microsomes

Unlike most other mammalian species, domestic cats glucuronidate phenolic compounds poorly and are therefore highly susceptible to the toxic side effects of many drugs, including paracetamol. In this study, we evaluated the role of enzyme constraint, a characteristic that limits the activity of all uridine 5′-diphosphoglucuronosyltransferase (UGT) enzymes, in the aetiology of this species-dependent defect of drug metabolism. Detergent activation experiments were performed using hepatic microsomes from cats (4), dogs (4), man (4), and 6 other mammalian species (1 liver each). In addition, we used microsomes from Gunn rats which are sensitive to paracetamol toxicity because of a genetic defect affecting all family 1 UGTs. Increase in paracetamol-UGT activity at optimum concentrations of detergent was used as an index of enzyme constraint. Native activity (measured in the absence of detergent) was less than one-sixth in cats compared with other species. Optimum detergent treatment tended to enhance rather than abolish this difference, however, indicating relatively lower levels of constraint of paracetamol-UGT in cats compared with other species. Similarly, detergent treatment failed to reduce the native activity difference between homozygous mutant and normal Gunn rats. Initially CHAPS (3-(3-cholamidopropyl)-dimethylamrnonio-1-propanesulphonic acid) was used as the detergent activator; in 3 of 4 microsomal preparations from man, however, inhibition rather than activation was observed at all detergent concentrations used. Studies were repeated using the non-ionic detergent, Brij 58 (polyoxyethylene 20-cetyl ether), which resulted in similar although more profound activation and no inhibition. We conclude that deficient paracetamol glucuronidation in cats does not result from increased paracetamol-UGT constraint in this species compared with other mammalian species. Other causes, such as differences in enzyme protein concentration or substrate affinity might be responsible.