Carboxylesterase-2 plays a critical role in dabigatran etexilate active metabolite formation

Dabigatran etexilate (DABE), an oral anticoagulant prodrug, is nearly completely metabolized to the dabigatran (DAB) active metabolite by carboxylesterase-1 (CES1) and carboxylesterase-2 (CES2). The high interpatient variation in DAB plasma concentrations, coupled with its low therapeutic index, emphasizes the need to understand how CES1 and CES2 impact active metabolite formation. Previous work focused on CES1 enzyme activity but the contributions of CES2 remain unclear. The purpose of this study was to determine how CES2 activity influences DAB active metabolite formation. We compared the efficiency of DAB formation from DABE when exposed sequentially to human intestinal and then human hepatic microsomes (mimicking the normal metabolic sequence) with the reverse metabolic sequence in which DABE is exposed to hepatic and then intestinal microsomes. The poor efficiency of DAB formation with reverse sequential hydrolysis indicates that CES2 activity is crucial for active metabolite formation. Thus, the decrease in DAB formation with normal sequential hydrolysis was more sensitive to CES2 inhibition by verapamil (CES2 IC50 = 3.4 μM) than CES1 inhibition by diltiazem (CES2 IC50 = 9.1 μM). These results show CES2 activity plays a crucial role in DAB formation and that variability in its activity is an important determinant of therapeutic response.     

Metabolism of deltamethrin and cis- and trans-permethrin by human expressed cytochrome P450 and carboxylesterase enzymes

1. The metabolism of the pyrethroids deltamethrin (DLM), cis-permethrin (CPM) and trans-permethrin (TPM) was studied in human expressed cytochrome P450 (CYP) and carboxylesterase (CES) enzymes.

2. DLM, CPM and TPM were metabolised by human CYP2B6 and CYP2C19, with the highest apparent intrinsic clearance (CL_int) values for pyrethroid metabolism being observed with CYP2C19. Other CYP enzymes contributing to the metabolism of one or more of the three pyrethroids were CYP1A2, CYP2C8, CYP2C9*1, CYP2D6*1, CYP3A4 and CYP3A5. None of the pyrethroids were metabolised by CYP2A6, CYP2E1, CYP3A7 or CYP4A11.

3. DLM, CPM and TPM were metabolised by both human CES1 and CES2 enzymes.

4. Apparent CL_int values for pyrethroid metabolism by CYP and CES enzymes were scaled to per gram of adult human liver using abundance values for microsomal CYP enzymes and for CES enzymes in liver microsomes and cytosol. TPM had the highest and CPM the lowest apparent CL_int values for total metabolism (CYP and CES enzymes) per gram of adult human liver.

5. Due to their higher abundance, all three pyrethroids were extensively metabolised by CES enzymes in adult human liver, with CYP enzymes only accounting for 2%, 10% and 1% of total metabolism for DLM, CPM and TPM, respectively.

     

Carboxylesterase catalyzed 18O-labeling of carboxylic acid and its potential application in LC-MS/MS based quantification of drug metabolites

LC-MS quantification of drug metabolites is sometimes impeded by the availability of internal standards that often requires customized synthesis and/or extensive purification. Although isotopically labeled internal standards are considered ideal for LC-MS/MS based quantification, de novo synthesis using costly isotope-enriched starting materials makes it impractical for early stage of drug discovery. Therefore, quick access to these isotope-enriched compounds without chemical derivatization and purification will greatly facilitate LC-MS/MS based quantification. Herein, we report a novel ¹⁸O-labeling technique using metabolizing enzyme carboxylesterase (CES) and its potential application in metabolites quantification study. Substrates of CES typically undergo a two-step oxygen exchange with H₂¹⁸O in the presence of the enzyme, generating singly- and doubly-¹⁸O-labeled carboxylic acids; however, unexpected hydrolytic behavior was observed for three of the test compounds – indomethacin, piperacillin and clopidogrel. These unusual observations led to the discovery of several novel hydrolytic mechanisms. Finally, when used as internal standard for LC-MS/MS based quantification, these in situ labeled compounds generated accurate quantitation comparable to the conventional standard curve method. The preliminary results suggest that this method has potential to eliminate laborious chemical synthesis of isotope-labeled internal standards for carboxylic acid-containing compounds, and can be developed to facilitate quantitative analysis in early-stage drug discovery.     

Metabolism of KO143, an ABCG2 inhibitor

The ATP-binding cassette sub-family G member 2 (ABCG2) plays an important role in modulating drug disposition and endobiotic homeostasis. KO143 is a potent and relatively selective ABCG2 inhibitor. We found that the metabolic stability of KO143 was very poor in human liver microsomes (HLM). Our further studies illustrated that the tert-butyl ester group in KO143 can be rapidly hydrolyzed and removed by carboxylesterase 1. This metabolic pathway was confirmed as a major pathway of KO143 metabolism in both HLM and mice. K1 is an analog of KO143 without the ester group. We found that the metabolic stability of K1 was significantly improved in HLM when compared to KO143. These data suggest that the ester group in KO143 is the major cause of the poor metabolic stability of KO143. The data from this study can be used to guide the development of KO143 analogs with better metabolic properties.     

Epicatechin gallate and epigallocatechin gallate are potent inhibitors of human arylacetamide deacetylase

Recently, in addition to carboxylesterases (CESs), we found that arylacetamide deacetylase (AADAC) plays an important role in the metabolism of some clinical drugs. In this study, we screened for food-related natural compounds that could specifically inhibit human AADAC, CES1, or CES2. AADAC, CES1, and CES2 activities in human liver microsomes were measured using phenacetin, fenofibrate, and procaine as specific substrates, respectively. In total, 43 natural compounds were screened for their inhibitory effects on each of these enzymes. Curcumin and quercetin showed strong inhibitory effects against all three enzymes, whereas epicatechin, epicatechin gallate (ECg), and epigallocatechin gallate (EGCg) specifically inhibited AADAC. In particular, ECg and EGCg showed strong inhibitory effects on AADAC (IC₅₀ values: 3.0 ± 0.5 and 2.2 ± 0.2 μM, respectively). ECg and EGCg also strongly inhibited AADAC-mediated rifampicin hydrolase activity in human liver microsomes with IC₅₀ values of 2.2 ± 1.4 and 1.7 ± 0.4 μM, respectively, whereas it weakly inhibited p-nitrophenyl acetate hydrolase activity, which is catalyzed by AADAC, CES1, and CES2. Our results indicate that ECg and EGCg are potent inhibitors of AADAC.     

蚊虫杀虫药剂的抗性及防治策略

蚊虫在长期的化学杀虫剂选择压力下,已从多个生理途径进化出抵抗这种选择压的能力,给我们有效控制一些蚊媒传播的疾病带来困难。该文对蚊虫抗药性的主要分子机制和抗性基因的适合度代价进行剖析,并评述目前国内外防治蚊虫传播疾病的各种策略,以期为我国媒介蚊虫的防治工作提供借鉴。     

Role of gut in xenobiotic metabolism

The gastrointestinal tract forms the first line of defense in the body against the main load of xenobiotics. The gastrointestinal mucosa has several mechanisms through which the xenobiotics are modified. The monooxygenase activities in most species are relatively low in the mucosa as compared to the liver, but conjugation, for example, via glucuronide formation proceeds efficiently. UDP-glucuronosyltransferase activities can exceed those in the liver. Glutathione S-transferase activity is also high. The biotransformation activities are readily inducible in the mucosa and this is, at least partly, responsible for the oral-aboral gradient seen in enzyme activities. In rainbow trout glutathione S-transferase is, however, significantly higher at the aboral third than in two oral segments, although in rats the intestinal glutathione S-transferase shows a clear oral-aboral gradient. The gradient is independent of the presence of microflora at least in the case of carboxylesterase and glutathione S-transferase. A similar gradient can also be found from the gut lumen, in both germ-free and specific pathogen-free rats. The cells in the middle of the villi appear to be most responsive under the influence of inducers. The readily occurring induction in the mucosa provides a suitable model for studies on biological effects to defined compounds and mixtures.Dedicated to Professor Dr. med. Herbert Remmer on the occasion of this 65th birthday     

Transesterification of a series of 12 parabens by liver and small-intestinal microsomes of rats and humans

Hydrolytic transformation of parabens (4-hydroxybenzoic acid esters; used as antibacterial agents) to 4-hydroxybenzoic acid and alcohols by tissue microsomes is well-known both in vitro and in vivo. Here, we investigated transesterification reactions of parabens catalyzed by rat and human microsomes, using a series of 12 parabens with C1–C12 alcohol side chains. Transesterification of parabens by rat liver and small-intestinal microsomes occurred in the presence of alcohols in the microsomal incubation mixture. Among the 12 parabens, propylparaben was most effectively transesterified by rat liver microsomes with methanol or ethanol, followed by butylparaben. Relatively low activity was observed with longer-side-chain parabens. In contrast, small-intestinal microsomes exhibited higher activity towards moderately long side-chain parabens, and showed the highest activity toward octylparaben. When parabens were incubated with liver or small-intestinal microsomes in the presence of C1–C12 alcohols, ethanol and decanol were most effectively transferred to parabens by rat liver microsomes and small-intestinal microsomes, respectively. Human liver and small-intestinal microsomes also exhibited significant transesterification activities with different substrate specificities, like rat microsomes. Carboxylesterase isoforms, CES1b and CES1c, and CES2, exhibited significant transesterification activity toward parabens, and showed similar substrate specificity to human liver and small-intestinal microsomes, respectively.     

Dimethylphosphorothioates

Five dimethylphosphorothioates were tested for their toxicity to rats, potentiation of malathion toxicity in rats, inhibition of carboxylesterase in vitro, and reaction with malathion in vitro. The compounds were: potassium salts of (CH₃S)₂P(O)O^–(I), (CH₃O)(CH₃S)P(O)S^–(II), (CH₃O)₂P(O)S^–(III), (CH₃O)₂P(S)S^–(IV), and (CH₃O)(CH₃S)P(O)O^–(V).The dimethylphosphorothioates are not toxic to rats (up to 1 g/kg, orally), they do not potentiate malathion toxicity in rats, and do not inhibit carboxylesterase activity in vitro (up to 1 mM concentrations). However, when the S-acid diesters (II, III, IV) are incubated with malathion for several days at room temperature or for several hours at 50° C they become methylated forming the trimethylphosphorothioates OSS-trimethyl phosphorodithioate, OOS-trimethyl phosphorothioate and OOS-trimethyl phosphorodithioate respectively, which potentiate malathion toxicity. Furthermore, these same acid diesters increase the rate of isomerization of malathion into OS-dimethyl-S-(1,2-dicarbethoxyethyl) phosphorodithioate (isomalathion) particularly, diester IV.The formation of the trimethylphosphorothioates and isomalathion from the interaction of the S-acid diesters with malathion was determined by thin layer chromatography (TLC), gas chromatography and mass spectrometry and could be detected by in vitro inhibition of carboxylesterase. TLC methods can detect 1 mg of the trimethylphosphorothioates and isomalathion per gram malathion.