Many UDP-glucuronosyltransferases (UGTs) require phosphorylation by protein kinase C (PKC) for glucuronidation activity. Inhibition of UGT phosphorylation by PKC inhibitor drugs may represent a novel mechanism for drug–drug interactions.
The potential for PKC-mediated inhibition of human UGT1A6, an isoform involved in the glucuronidation of drugs such as acetaminophen (paracetamol) and endogenous substrates including serotonin, was evaluated using various cell model systems.
Of ten different PKC inhibitors screened for their effects on acetaminophen glucuronidation by human LS180 colon cells, only rottlerin (PKC δ selective inhibitor; IC50?=?9.0?±?1.2 μM) and the non-selective PKC inhibitors (calphostin-C, curcumin and hypericin) decreased glucuronidation by more than 50%.
Using UGT1A6-infected Sf9 insect cells, calphostin-C and hypericin showed three times more potent inhibition of serotonin glucuronidation in treated whole cells versus cell lysates. However, both curcumin and rottlerin showed significant direct inhibition and so (indirect) PKC effects could not be differentiated in this model system.
Of nine PKC isoforms co-expressed with UGT1A6 in human embryonic kidney 293T cells only PKC δ increased protein-normalized UGT1A6-mediated serotonin glucuronidation significantly (by 63% ± 4%).
These results identify an important role for PKC δ in UGT1A6-mediated glucuronidation and suggest that PKC δ inhibitors could interfere with glucuronidation of UGT1A6 substrates.
This study compared the hepatic glucuronidation of Picroside II in different species and characterized the glucuronidation activities of human intestinal microsomes (HIMs) and recombinant human UDP-glucuronosyltransferases (UGTs) for Picroside II.
The rank order of hepatic microsomal glucuronidation activity of Picroside II was rat > mouse > human > dog. The intrinsic clearance of Picroside II hepatic glucuronidation in rat, mouse and dog was about 10.6-, 6.0- and 2.3-fold of that in human, respectively.
Among the 12 recombinant human UGTs, UGT1A7, UGT1A8, UGT1A9 and UGT1A10 catalyzed the glucuronidation. UGT1A10, which are expressed in extrahepatic tissues, showed the highest activity of Picroside II glucuronidation (Km?=?45.1 μM, Vmax?=?831.9 pmol/min/mg protein). UGT1A9 played a primary role in glucuronidation in human liver microsomes (HLM; Km?=?81.3 μM, Vmax?=?242.2 pmol/min/mg protein). In addition, both mycophenolic acid (substrate of UGT1A9) and emodin (substrate of UGT1A8 and UGT1A10) could inhibit the glucuronidation of Picroside II with the half maximal inhibitory concentration (IC50) values of 173.6 and 76.2 μM, respectively.
Enzyme kinetics was also performed in HIMs. The Km value of Picroside II glucuronidation was close to that in recombinant human UGT1A10 (Km?=?58.6 μM, Vmax?=?721.4 pmol/min/mg protein). The intrinsic clearance was 5.4-fold of HLMs. Intestinal UGT enzymes play an important role in Picroside II glucuronidation in human.
4-n-Nonylphenol and bisphenol A are endocrine disrupting chemicals that are mainly detoxified through glucuronidation. A factor that may modulate their glucuronidation rates is co-exposure to pharmaceuticals.
This study aimed to identify and characterize the potential metabolic interactions between 14 drugs and these two endocrine disruptors.
Nonylphenol and bisphenol A were co-incubated in freshly isolated rat hepatocytes with, drugs at a high concentration. Statistically significant metabolic inhibition of bisphenol A and nonylphenol biotransformation was observed with nine drugs (>50% inhibition by naproxen, salicylic acid, carbamazepine and mefenamic acid). Inhibition assays of UGT activity in rat liver microsomes revealed: 1) competitive inhibition by naproxen (Kiapp = 848.3 μM) and carbamazepine (Kiapp = 1023.1 μM), 2) no inhibition by salicylic acid suggesting another mechanism of inhibition.
Detoxification of nonylphenol and bisphenol A was shown to be impaired by excessive concentrations of many drugs and health risk assessment should therefore address this issue.
A transgenic ‘knock-in’ mouse model expressing a human UGT1 locus (Tg-UGT1) was recently developed and validated. Although these animals express mouse UGT1A proteins, UGT1A4 is a pseudo-gene in mice. Therefore, Tg-UGT1 mice serve as a ‘humanized’ UGT1A4 animal model.
Lamotrigine (LTG) is primarily metabolized to its N-glucuronide (LTGG) by hUGT1A4. This investigation aimed at examining the impact of pregnane X receptor (PXR), constitutive androstane receptor (CAR) and peroxisome proliferator-activated receptor (PPAR) activators on LTG glucuronidation in vivo and in vitro. Tg-UGT1 mice were administered the inducers phenobarbital (CAR), pregnenolone-16α-carbonitrile (PXR), WY-14643 (PPAR-α), ciglitazone (PPAR-γ), or L-165041 (PPAR-β), once daily for 3 or 4 days. Thereafter, LTG was administered orally and blood samples were collected over 24?h. LTG was measured in blood and formation of LTGG was measured in pooled microsomes made from the livers of treated animals.
A three-fold increase in in vivo LTG clearance was seen after phenobarbital administration. In microsomes prepared from phenobarbital-treated Tg-UGT1 animals, 13-fold higher CLint (Vmax/Km) value was observed as compared with the untreated transgenic mice. A trend toward induction of catalytic activity in vitro and in vivo was also observed following pregnenolone-16α-carbonitrile and WY-14643 treatment. This study demonstrates the successful application of Tg-UGT1 mice as a novel tool to study the impact of induction and regulation on metabolism of UGT1A4 substrates.
Human exposure to magnolol can reach a high dose in daily life. Our previous studies indicated that magnolol showed high affinities to several UDP-glucuronosyltransferases (UGTs) This study was designed to examine the in vitro inhibitory effects of magnolol on UGTs, and further to evaluate the possibility of the in vivo inhibition that might happen.
Assays with recombinant UGTs and human liver microsomes (HLM) indicated that magnolol (10 µM) can selectively inhibit activities of UGT1A9 and extra-hepatic UGT1A7. Inhibition of magnolol on UGT1A7 followed competitive inhibition mechanism, while the inhibition on UGT1A9 obeyed either competitive or mixed inhibition mechanism, depending on substrates. The Ki values for UGT1A7 and 1A9 are all in nanomolar ranges, lower than possible magnolol concentrations in human gut lumen and blood, indicating the in vivo inhibition on these two enzymes would likely occur.
In conclusion, UGT1A7 and 1A9 can be strongly inhibited by magnolol, raising the alarm for safe application of magnolol and traditional Chinese medicines containing magnolol. Additionally, given that UGT1A7 is an extra-hepatic enzyme, magnolol can serve as a selective UGT1A9 inhibitor that will act as a new useful tool in future hepatic glucuronidation phenotyping.
Lamotrigine (LTG), a diaminotriazine anti-epileptic, is principally metabolized at the 2-position of the triazine ring to form a quaternary ammonium glucuronide (LTGG) by uridine glucuronosyl transferease (UGT) 1A3 and UGT1A4. It has been hypothesized that glucuronidation of anti-epileptic drugs is spared with age, despite a known decrease in liver mass, based on older studies with benzodiazepines such as lorazepam. To examine this, the formation rates of LTGG formation were measured by liquid chromatography-mass spectrometry (LC-MS) in a bank of human liver microsomes (HLMs) obtained from younger and elderly donors at therapeutic concentrations.
The formation rate of LTGG was not significantly different in HLMs obtained from younger and elderly subjects. A four- to five-fold variation for the formation of LTGG was observed within each microsomal bank obtained from elderly and younger donors, and the range of LTGG formation was observed to be 0.15–0.78?nmoles min?1 mg?1 of protein across the entire set of HLMs (n?=?36, elderly and younger HLMs).
UGT1A4 and UGT1A3 catalysed the formation of LTGG with an intrinsic clearances of 0.28 and 0.02?μl min?1 mg?1 protein, respectively. UGT2B7 and UGT2B4 showed no measurable activity. No correlation was observed across the HLM bank for glucuronidation of LTG and valproic acid (a substrate for multiple UGT isoforms including UGT1A4).
Scutellarin (SG) is a bioactive flavonoid used to treat cardiovascular disease. Scutellarein (S) is the aglycone form of SG. This study aimed to characterize their intestinal transport and first-pass metabolism by UDP-glucuronosyltransferase-mediated glucuronidation and β-glucuronidase-mediated hydrolysis.
Results showed that S is more readily passed through Caco-2 cell monolayers by passive diffusion than SG. SG was the predominant metabolite of S, which was formed during the transportation of S across Caco-2 cell monolayers or following incubation of S with human microsomes. SG was extensively generated in human liver microsomes (HLMs), which was demonstrated by its higher catalyzing efficiency (Clint) in liver microsomes than in human intestinal microsomes (HIMs).
Enzymatic kinetic analysis indicated that the catalyzing efficiency of UGT1A9 was the highest among the tested UGTs under the present experimental conditions, followed by UGT1A1 and UGT1A3. No significant P450-mediated hydroxylation of S was found. SG may be hydrolyzed into S in both HLMs and HIMs.
The UDP-glucuronosyltransferase (UGT) enzyme catalyzes the glucuronidation reaction which is a major metabolic and detoxification pathway in humans. Understanding the mechanisms for substrate recognition by UGT assumes great importance in an attempt to predict its contribution to xenobiotic/drug disposition in vivo.
Spurred on by this interest, 2D/3D-quantitative structure activity relationships and pharmacophore models have been established in the absence of a complete mammalian UGT crystal structure.
This review discusses the recent progress in modeling human UGT substrates including those with multiple sites of glucuronidation. A better understanding of UGT active site contributing to substrate selectivity (and regioselectivity) from the homologous enzymes (i.e. plant and bacterial UGTs, all belong to family 1 of glycosyltransferase (GT1)) is also highlighted, as these enzymes share a common catalytic mechanism and/or overlapping substrate selectivity.
It was hypothesized that cis-resveratrol glucuronidation contributes to a greater extent to in-vitro disposition of total resveratrol than previously assumed. To this end, the kinetic data for cis-resveratrol glucuronidation are reported.
Glucuronidation assays were conducted in human liver and intestinal microsomes and in uridine diphosphate-glucuronosyltransferases (UGTs) UGT1A1, UGT1A6, UGT1A9, and UGT1A10. Kinetic parameters were estimated for the major cis-resveratrol-3-O-glucuronide (cis-R3G). Substrate inhibition was observed with apparent Vmax, Km and Ki of 6.1?±?0.3/27.2?±?1.2 nmol min?1 mg?1, 415?±?48.1/989.9?±?92.8 and 789.6?±?76.3/1012?±?55.9?μM in human intestinal microsomes (HIMs) and UGT1A6, respectively (estimate?±?standard error (SE)). Biphasic kinetics were observed in human liver microsomes (HLMs), while sigmoidal kinetics were seen in UGT1A9 (Vmax?=?11.92?±?0.2 nmol min?1 mg?1; Km?=?360?μM; n?=?1.27?±?0.07). The 4′-O-glucuronide (cis-R4′G) exhibited atypical kinetics in HLM, HIM, UGT1A1, and UGT1A10. UGT1A9 catalysed cis-R4′G formation at high substrate concentrations (Vmax?=?0.33?±?0.015 nmol min?1 mg?1; Km?=?537.8?±?67.8?μM).
In conclusion, although the rates of formation of cis-R3G in HLM and UGT1A9 were higher than those for trans-R3G, the contribution to total resveratrol disposition could not be determined fully due to atypical kinetics observed.
Carvacrol (2-methyl-5-(1-methylethyl)-phenol), one of the main components occurring in many essential oils of the family Labiatae, has been widely used in food, spice and pharmaceutical industries.
The carvacrol glucuronidation was characterized by human liver microsomes (HLMs), human intestinal microsomes (HIMs) and 12 recombinant UGT (rUGT) isoforms.
One metabolite was identified as a mono-glucuronide by liquid chromatography/mass spectrometry with HLMs, HIMs, rUGT1A3, rUGT1A6, rUGT1A7, rUGT1A9 and rUGT2B7.
The study with a chemical inhibition, rUGT, and kinetics study demonstrated that rUGT1A9 was the major isozyme responsible for glucuronidation in HLMs, and rUGT1A7 played a major role for glucuronidation in HIMs.
High concentrations of endogenous oestradiol (E2) correlate with the proliferation of cancer cells. Resveratrol (a dietary chemopreventive agent) at high concentrations has an anti-oestrogenic effect. E2 and resveratrol are conjugated via common uridine diphosphoglucuronosyltransferase (UGT) and sulfotransferases (SULT) enzymes.
Experiments were conducted in MCF-7 mammalian cells stably expressing human SULT1A1 or SULT1E1 to observe the effect of resveratrol on E2-mediated cell proliferation. The combination of E2 and resveratrol did have a proliferative effect in cells expressing SULT1E1, but not in those expressing SULT1A1.
The effect of resveratrol (1–500 μM) on the glucuronidation of E2 (0.25–2.25 μM) was characterized in human liver microsomes. The highest resveratrol concentration significantly decreased the intrinsic clearance of E2 glucuronidation.
The results corroborate the reported significant inhibition of SULT1E1-mediated E2 sulfation in vitro by resveratrol. Thus, resveratrol may interact with E2 in vivo by inhibiting its conjugation.
Metabolic disposition of drugs and other xenobiotics includes glucuronidation reactions that are catalyzed by the uridine diphosphate glucuronosyltransferases (UGTs). The most common glucuronidation reactions are O- and N-glucuronidation and in this review, we discuss both, while the emphasis is on N-glucuronidation.
Interspecies difference in glucuronidation is another central issue in this review due to its importance in drug development. Accordingly, the available data on glucuronidation in different animals comes mainly from the species that are used in preclinical studies to assess the safety of drugs under development.
Both O- and N-glucuronidation reactions are chemically diverse. Different O-glucuronidation reactions are described and discussed, and many drugs that undergo such reactions are indicated. The compounds that undergo N-glucuronidation include primary aromatic amines, hydroxylamines, amides, tertiary aliphatic amines, and aromatic N-heterocycles.
The interspecies variability in N-glucuronidation is particularly high, above all when it comes to aliphatic tertiary amines and aromatic N-heterocycles.
The N-glucuronidation rates in humans are typically much higher than in animals, largely due to the activity of two enzymes, the extensively studied UGT1A4, and the more recently identified as a main player in N-glucuronidation, UGT2B10. We discuss both enzymes and review the findings that revealed the role of UGT2B10 in N-glucuronidation.
Commonly used herbal supplements were screened for their potential to inhibit UGT1A1 activity using human liver microsomes. Extracts screened included ginseng, echinacea, black cohosh, milk thistle, garlic, valerian, saw palmetto, and green tea epigallocatechin gallate (EGCG). Estradiol-3-O-glucuronide (E-3-G) formation was used as the index of UGT1A1 activity.
All herbal extracts except garlic showed inhibition of UGT1A1 activity at one or more of the three concentrations tested. A volume per dose index (VDI) was calculated to estimate the volume in which the daily dose should be diluted to obtain an IC50-equivalent concentration. EGCG, echinacea, saw palmetto, and milk thistle had VDI values >2.0?L per dose unit, suggesting a higher potential for interaction.
Inhibition curves were constructed for EGCG, echinacea, saw palmetto, and milk thistle. IC50 values were (mean ± SE) 7.8?±?0.9, 211.7?±?43.5, 55.2?±?9.2, and 30.4?±?6.9 µg/ml for EGCG, echinacea, saw palmetto, and milk thistle extracts, respectively.
Based on our findings, inhibition of UGT1A1 by milk thistle and EGCG and to a lesser extent by echinacea and saw palmetto is plausible, particularly in the intestine where higher extract concentrations are anticipated. Further clinical studies are warranted.
The flavonolignan silybin, the main component of silymarin, extract from the seeds of Silybum marianum, is used mostly as a hepatoprotectant. Silybin is almost 1:1 mixture of two diastereomers A and B. The individual UDP-glucuronosyltransferases (UGTs) contributing to the metabolism of silybin diastereomers have not been identified yet. In this study, the contribution of UGTs to silybin metabolism was examined.
The potential silybin metabolites were formed in vitro by incubating silybin (i) with the human liver microsomal fraction, (ii) with human hepatocytes and finally (iii) with 12 recombinant UGTs (UGT1A1, 1A3, 1A4, 1A6, 1A7, 1A8, 1A9, 1A10, 2B4, 2B7, 2B15 and 2B17). High-performance liquid chromatographic (HPLC) techniques with UV detection and additionally MS detection were used for metabolite identification.
Hepatocytes and microsomes formed silybin A-7-O-β-d-glucuronides, B-7-O-β-d-glucuronides, A-20-O-β-d-glucuronides and B-20-O-β-d-glucuronides. With recombinant UGTs, the major role of the UGT1A1, 1A3, 1A8 and 1A10 enzymes but also of the UGT1A6, 1A7, 1A9, 2B7 and 2B15 in the stereoselective reactions leading to the respective silybin glucuronides was confirmed. UGT1A4, UGT2B4 and UGT2B17 did not participate in silybin glucuronidation.
The predominant formation of 7-O-β-d-glucuronides and the preferential glucuronidation of silybin B diastereomer in vitro by human UGTs were confirmed.
Recently, there has been a rise in abuse of synthetic cannabinoids (SCBs). The consumption of SCBs results in various effects and can induce toxic reactions, including paranoia, seizures, tachycardia and even death. 1-Naphthyl 1-(4-fluorobenzyl)-1H-indole-3-carboxylate (FDU-PB-22) is a third generation SCB whose metabolic pathway has not been fully characterized.
In this study, we conducted in vitro pharmacokinetic analysis of FDU-PB-22 metabolism.
Metabolic reactions containing FDU-PB-22 and human liver microsomes (HLMs) were independent of NADPH but not UDP-glucuronic acid (UDPGA), suggesting that UDP-glucuronosyltransferases (UGTs) are the primary enzymes involved in this metabolism. It was further determined that the metabolite extensively formed after incubating FDU-PB-22 with UDPGA in HLMs was the glucuronide of FDU-PB-22 3-carboxyindole (FBI-COOH). Various hepatic UGTs showed enzymatic activity for FBI-COOH. A series of UGT inhibitors showed moderate to strong inhibition of FBI-COOH-glucuronidation in HLMs, suggesting that multiple UGT isoforms are involved in FBI-COOH-glucuronidation in the liver. Interestingly, an extra-hepatic isoform, UGT1A10, exhibited the highest activity with a Km value of 38 µM and a Vmax value of 5.90?nmol/min/mg.
Collectively, these results suggest that both genetic mutations of and the co-administration of inhibitors for FDU-PB-22-metabolizing UGTs will likely increase the risk of FDU-PB-22-induced toxicity.
Neutrophil growth factors (NGFs) stimulate neutrophil growth and survival. The first synthetic cytokinin-derived NGF was recently discovered and is a prospective drug owing to its potential use in anti-inflammatory therapy. The metabolism of some cytokinin-derived drugs (e.g. R-roscovitine, olomoucine II) has already been studied and it has been shown that they may give rise to drug-drug interactions.
In this in vitro study, the interactions of the novel neutrophil growth factor NGF1568 with two of the main classes of human drug-metabolizing enzymes, cytochromes P450 (CYPs) and UDP-glucuronosyltransferases (UGTs), were tested. Of the CYPs evaluated, NGF1568 was found to inhibit only CYP2C9, by an uncompetitive mechanism and with a Ki value of 349 μM.
Formation of a glucuronide of NGF1568 was detected by LC/MS/MS analysis after it was incubated with human liver microsomes and UDP-glucuronic acid. The human recombinant UGT1A9 enzyme (major liver expression) and UGT1A7, UGT1A8, UGT1A10 enzymes (expressed in gastrointestinal tract instead of liver) were found to be responsible for NGF1568 glucuronidation.
These results show that interaction of NGF1568 with CYPs is not as important as it is in the case of the cytokinin CDK inhibitors R-roscovitine and olomoucine II, but the conjugation enzymes (UGTs) play a major role in its metabolism. Thus, possible interference of NGF1568 with metabolism of other coadministered drugs at least on level of liver, kidney or intestinal UGTs should be thoroughly considered.
This study aimed to characterize the glucuronidation pathway of licochalcone A (LCA) in human liver microsomes (HLM).
HLM incubation systems were employed to catalyze the formation of LCA glucuronide. The glucuronidation activity of commercially recombinant UDP-glucuronosyltransferase (UGT) isoforms toward LCA was screened. Kinetic analysis was used to identify the UGT isoforms involved in the glucuronidation of LCA in HLM.
LCA could be metabolized to two monoglucuronides in HLM, including a major monoglucuronide, namely, 4-O-glucuronide, and a minor monoglucuronide, namely, 4′-O-glucuronide. Species-dependent differences were observed among the glucuronidation profiles of LCA in liver microsomes from different species. UGT1A1, UGT1A3, UGT1A7, UGT1A8, UGT1A9, UGT1A10 and UGT2B7 participated in the formation of 4-O-glucuronide, with UGT1A9 exhibiting the highest catalytic activity in this biotransformation. Only UGT1A1 and UGT1A3 were involved in the formation of 4′-O-glucuronide, exhibiting similar reaction rates. Kinetic analysis demonstrated that UGT1A9 was the major contributor to LCA-4-O-glucuronidation, while UGT1A1 played important roles in the formation of both LCA-4-O- and 4′-O-glucuronide.
UGT1A9 was the major contributor to the formation of LCA-4-O-glucuronide, while UGT1A1 played important roles in both LCA-4-O- and 4′-O-glucuronidation.
As intestinal glucuronidation has been suggested to generate the low oral bioavailability (F) of drugs, estimating its effects would be valuable for selecting drug candidates. Here, we investigated the absorption and intestinal availability (FaFg) in animals, and intrinsic clearance via UDP-glucuronosyltransferase (UGT) in intestinal microsomes (CLint,UGT) for three drug candidates possessing a carboxylic acid group, in an attempt to estimate the impact of intestinal glucuronidation on F and select potential drug candidates with high F in humans.
The FaFg values of the three test compounds were low in rats and monkeys (0.16–0.51), and high in dogs (≥0.81). Correspondingly, the CLint,UGT values were high in rats and monkeys (101–731 µL/min/mg), and low in dogs (≤?59.6 µL/min/mg). A good inverse correlation was observed between FaFg and CLint,UGT, suggesting that intestinal glucuronidation was a major factor influencing FaFg of these compounds.
By applying this correlation to FaFg in humans using human CLint,UGT values (26.9–114 µL/min/mg), compounds 1–3 were predicted to have relatively high FaFg.
Our approach is expected to be useful for estimating the impact of intestinal glucuronidation on F in animals and semiquantitatively predicting human F for drug candidates.
Coumadin (R/S-warfarin) metabolism plays a critical role in patient response to anticoagulant therapy. Several cytochrome P450s oxidize warfarin into R/S-6-, 7-, 8-, 10, and 4′-hydroxywarfarin that can undergo subsequent glucuronidation by UDP-glucuronosyltransferases (UGTs); however, current studies on recombinant UGTs cannot be adequately extrapolated to microsomal glucuronidation capacities for the liver.
Herein, we estimated the capacity of the average human liver to glucuronidate hydroxywarfarin and identified UGTs responsible for those metabolic reactions through inhibitor phenotyping. There was no observable activity toward R/S-warfarin, R/S-10-hydroxywarfarin or R/S-4′-hydroxywarfarin.
The observed metabolic efficiencies (Vmax/Km) toward R/S-6-, 7-, and especially 8-hydroxywarfarin indicated a high glucuronidation capacity to metabolize these compounds.
UGTs demonstrated strong regioselectivity toward the hydroxywarfarins. UGT1A6 and UGT1A1 played a major role in R/S-6- and 7-hydroxywarfarin glucuronidation, respectively, whereas UGT1A9 accounted for almost all of the generation of the R/S-8-hydroxywarfarin glucuronide.
In summary, these studies expanded insights to glucuronidation of hydroxywarfarins by pooled human liver microsomes, novel roles for UGT1A6 and 1A9, and the overall degree of regioselectivity for the UGT reactions.
Alpinetin is a natural flavonoid showing a variety of pharmacological effects such as anti-inflammatory, anti-tumor and hypolipidemic activities. Here, we aim to determine the roles of UDP-glucuronosyltransferases (UGTs) and breast cancer resistance protein (BCRP) in disposition of alpinetin.
Glucuronidation potential of alpinetin was evaluated using pooled human liver microsomes (pHLM), pooled human intestine microsomes (pHIM) and expressed UGT enzymes supplemented with the cofactor UDPGA. Activity correlation analyses with a bank of individual HLMs were performed to identify the main contributing UGT isozymes in hepatic glucuronidation of alpinetin. The effect of BCRP on alpinetin disposition was assessed using HeLa cells overexpressing UGT1A1 (HeLa1A1) cells.
Alpinetin underwent extensive glucuronidation in pHLM and pHIM, generating one glucuronide metabolite. Of 12 test UGT enzymes, UGT1A3 was the most active one toward alpinetin with an intrinsic clearance (CLint?=?Vmax/Km) value of 66.5?μl/min/nmol, followed by UGT1A1 (CLint?=?48.6?μl/min/nmol), UGT1A9 (CLint?=?21.0?μl/min/nmol), UGT2B15 (CLint?=?16.7?μl/min/nmol) and UGT1A10 (CLint?=?1.60?μl/min/nmol). Glucuronidation of alpinetin was significantly correlated with glucuronidation of estradiol (an activity marker of UGT1A1), chenodeoxycholic acid (an activity marker of UGT1A3), propofol (an activity marker of UGT1A9) and 5-hydroxyrofecoxib (an activity marker of UGT2B15), confirming the important roles of UGT1A1, UGT1A3, UGT1A9 and UGT2B15 in alpinetin glucuronidation. Inhibition of BCRP by its specific inhibitor Ko143 significantly reduced excretion of alpinetin glucuronide, leading to a significant decrease in cellular glucuronidation of alpinetin.
Our data suggest UGTs and BCRP as two important determinants of alpinetin pharmacokinetics.