[Detailed characterization of bile acid and glucocorticoid world by mass spectrometry]

  The Nobel Prize in Chemistry for 2002 was shared by John B. Fenn and Koichi Tanaka "for their development of soft desorption methods for mass spectrometric analyses of biological macromolecules". Indeed, electrospray ionization and soft laser desorption ionization have proved to be of great value in "omics", such as metabolomics, transcriptomics and proteomics in providing a systematic and quantitative approach to the study of biological systems and networks. Moreover, these techniques have made great contributions to metabolic studies that are used for development of new drugs, as well as to the diagnosis of diseases including cancer based on the specific and sensitive detection of molecular biomarkers. In this article, we describe our recent results on characterization of bile acid metabolism in hepatobiliary disease as well as measurement of conjugated urinary tetrahydrocorticosteroids for assessment of altered corticoid metabolism in endocrine disease and the metabolic syndrome.

Characterization of non-enzymatic acylation of amino or thiol groups of bionucleophiles by the acyl-adenylate or acyl-CoA thioester of cholic acid

Acyl-adenylates and acyl-CoA thioesters of bile acids (BAs) are highly electrophilic acyl-linked metabolites which can undergo transacylation reactions with amino and thiol groups of nucleophilic groups on acceptor molecules such as amino acids, peptides, and proteins. Here, non-enzymatic acylation at pH 7.4 of glycine, taurine, glutathione (GSH), and N-acetylcysteine (NAC) by cholyl-adenylate (CA-AMP) was compared with that mediated by cholyl-CoA thioester (CA-CoA) using a 1:1 mixture of stable isotopically labeled CA-AMP and unlabeled CA-CoA. The transacylation products of these substrates were analyzed by liquid chromatography/electrospray ionization linear ion-trap mass spectrometry in negative-ion detection mode. CA-AMP was more reactive than CA-CoA with the amino group of glycine or taurine than with the thiol group of GSH or NAC. In contrast, CA-CoA was more reactive than CA-AMP with the thiol group of GSH or NAC and was far less reactive with the amino group of glycine or taurine. These differences in the reactivity of CA-AMP as compared with that of CA-CoA towards amino and thiol groups may be attributed to the electrophilicity of the carbonyl carbon of these acyl-linked cholic acid metabolites and the nucleophilicity of the amino and thiol group in the bionucleophiles that were studied.

Production and characterization of a monoclonal antibody to capture proteins tagged with lithocholic acid

Reactive metabolic-modified proteins have been proposed to play an important role in the mechanism(s) of the hepatotoxicity and colon cancer of lithocholic acid (LCA). To identify cellular proteins chemically modified with LCA, we have generated a monoclonal antibody that recognizes the 3alpha-hydroxy-5beta-steroid moiety of LCA. The spleen cells from a BALB/c mouse, which was immunized with an immunogen in which the side chain of LCA was coupled to bovine serum albumin (BSA) via a succinic acid spacer, was fused with SP2/0 myeloma cells to generate antibody-secreting hybridoma clones. The resulting monoclonal antibody (gamma2b, kappa) was specific to LCA-N(alpha)-BOC-lysine as well as the amidated and nonamidated forms of LCA. The immunoblot enabled the detection of LCA residues anchored on BSA and lysozyme. The antibody will be useful for monitoring the generation, localization, and capture of proteins tagged with LCA, which may be the cause of LCA-induced toxicity.

Formation and biliary excretion of glutathione conjugates of bile acids in the rat as shown by liquid chromatography/electrospray ionization-linear ion trap mass spectrometry

Acyl-adenylates and acyl-CoA thioesters of bile acids (BAs) are reactive acyl-linked metabolites that have been shown to undergo transacylation-type reactions with the thiol group of glutathione (GSH), leading to the formation of thioester-linked GSH conjugates. In the current study, we examined the transformation of cholyl-adenylate (CA-AMP) and cholyl-coenzyme A thioester (CA-CoA) into a cholyl-S-acyl GSH (CA-GSH) conjugate by rat hepatic glutathione S-transferase (GST). The reaction product was analyzed by liquid chromatography (LC)/electrospray ionization (ESI)-linear ion trap mass spectrometry (MS). The GST-catalyzed formation of CA-GSH occurred with both CA-AMP and CA-CoA. Ursodeoxycholic acid, lithocholic acid, and 2,2,4,4-(2)H4-labeled lithocholic acid were administered orally to biliary fistula rats, and their corresponding GSH conjugates were identified in bile by LC/ESI-MS2. These in vitro and in vivo studies confirm a new mode of BA conjugation in which BAs are transformed into their GSH conjugates via their acyl-linked intermediary metabolites by the catalytic action of GST in the liver, and the GSH conjugates are then excreted into the bile.

Analysis of bile acid glutathione thioesters by liquid chromatography/electrospray ionization-tandem mass spectrometry

The formation of thioester-linked glutathione (GSH) conjugates of bile acids (BAs) is presumed to occur via trans-acylation reactions between GSH and reactive acyl-linked metabolites of BAs. The present study examines the chemical reactivity of cholyl-adenylate and cholyl-CoA thioester, acyl-linked metabolites of cholic acid (CA), with GSH to form CA-GSH conjugate in vitro. The authentic specimen of CA-GSH was synthesized along with GSH conjugates of four common BAs found in the human body. Their structures were confirmed by proton-nuclear magnetic resonance spectroscopy and electrospray ionization (ESI)-tandem mass spectrometry in positive- and negative-ion modes. Incubation of cholyl-adenylate or cholyl-CoA thioester with GSH was carried out at pH 7.5 and 37 degrees C for 30 min, with analysis of the reaction mixture by liquid chromatography/ESI-tandem mass spectrometry, where CA-GSH was detected on the product ion mass chromatograms monitored with stable and abundant dehydrated positive-ion [M+HH(2)O](+) at m/z 680.3 and fragmented negative-ion [GSHH](-) at m/z 306.0, and was definitely identified by CID spectra by comparison with those of the authentic sample. The results show that both cholyl-adenylate and cholyl-CoA thioester are able to acylate GSH in vitro.

LC/ESI-tandem mass spectrometric determination of bile acid 3-sulfates in human urine

We developed a highly sensitive and quantitative method to detect bile acid 3-sulfates in human urine employing liquid chromatography/electrospray ionization-tandem mass spectrometry. This method allows simultaneous analysis of bile acid 3-sulfates, including nonamidated, glycine-, and taurine-conjugated bile acids, cholic acid (CA), chenodeoxycholic acid (CDCA), deoxycholic acid (DCA), ursodeoxycholic acid (UDCA), and lithocholic acid (LCA), using selected reaction monitoring (SRM) analysis. The method was applied to analyze bile acid 3-sulfates in human urine from healthy volunteers. The results indicated an unknown compound with the nonamidated common bile acid 3-sulfates on the chromatogram obtained by the selected reaction monitoring analysis. By comparison of the retention behavior and MS/MS spectrum of the unknown peak with the authentic specimen, the unknown compound was identified as 3beta,12alpha-dihydroxy-5beta-cholanoic acid 3-sulfate.

Chemical synthesis of 24-β-d-galactopyranosides of bile acids: a new type of bile acid conjugates in human urine

A method is reported for the preparation of the C-24 carboxyl-linked beta-D-galactopyranosides of lithocholic, deoxycholic, chenodeoxycholic, ursodeoxycholic, and cholic acids, two of which were recently identified as a novel type of the metabolites of bile acids excreted in human urine. Direct esterification (galactosidation) of the unprotected bile acids with 2,3,4,6-tetra-O-benzyl-D-galactopyranose in the presence of 2-chloro-1,3,5-trinitrobenzene as a coupling agent and subsequent hydrogenolysis of the resulting benzyloxy-protected bile acid 24-beta-D-galactopyranosides over 10% palladium on charcoal under atmospheric pressure afforded the title compounds. The structures of the bile acid acyl galactosides were confirmed by measuring several (1)H-(1)H and (1)H-(13)C shift correlated 2D NMR.

Inhibition of the rat hepatic microsomal flurbiprofen acyl glucuronidation by bile acids

Glucuronidation of carboxylic acids, primarily catalyzed by hepatic UDP-glucuronosyltransferases, is an important phase II metabolic pathway functioning in detoxification. Acyl glucuronides of 2-aryl propionates, however, can form covalently bound protein adducts, which may generate hypersensitive reactions. We previously identified and quantified R- and S-flurbiprofen acyl glucuronides in human urine following the oral administration of flurbiprofen by liquid chromatography/electrospray ionization mass spectrometry. Recent studies also demonstrated the inhibitory effect of bile acids and their metabolites toward rat hepatic bile acid acyl glucuronidation, which may also be the target of the flurbiprofen isoenzyme. We therefore performed a kinetic analysis of rat hepatic flurbiprofen UDP-glucuronosyltransferase using bisubstrate kinetic analysis and inhibition studies. The results indicated that both bile acid and its metabolites clearly inhibited flurbiprofen acyl glucuronidation. The inhibitory effect on flurbiprofen was more efficient than the effect seen on bile acid acyl glucuronidation. Unconjugated, glycine- and taurine-conjugated chenodeoxycholic acids inhibited glucuronidation using a noncompetitive mechanism, whereas the inhibition by chenodeoxycholic acid 24-acyl glucuronide occurred according to a mixed type mechanism. The inhibition by bile acids and their metabolites may be responsible for the suppression of the toxicity of carboxy-linked glucuronides.

Synthesis and characterization of deoxycholyl 2-deoxyglucuronide: A water-soluble affinity labeling reagent

Acyl glucuronides, which are biosynthesized by the action of glucuronosyltransferases to material for detoxification, are water-soluble and chemically active; they produce irreversible protein adducts via both the transacylation mechanism and the imine mechanism. The acyl group at the C-1 position migrates from the anomeric carbon to the C-2 position of the glucuronic acid moiety, producing the aldehyde group at the C-1 position, where the protein easily condenses through a Schiff's base, in the open-chain aldose form. The elimination of the hydroxyl group at the C-2 position therefore may prevent a protein-bound adduct via the imine mechanism. In this paper, we describe the synthesis and characterization of an acyl 2-deoxyglucuronide of deoxycholic acid as a model compound to investigate its possible utility as a water-soluble affinity labeling reagent for lipophilic carboxylic acids. The solubility of deoxycholyl 2-deoxyglucuronide in an aqueous solution was sufficient under physiological conditions, and the desired material reacted with model peptides to produce covalently bound adducts only via the transacylation mechanism.

Rapid and simple quantitative assay method for diastereomeric flurbiprofen glucuronides in the incubation mixture

Acyl glucuronides of nonsteroidal anti-inflammatory drugs having a chiral center are known to be chemically very active and form covalently bound adducts with proteins, such as human serum albumin, which may be the cause of hypersensitive reactions. Hepatic acyl glucuronosyltransferase catalyzes the transformation of alpha-aryl propionates into these diastereoisomeric acyl glucuronides, and, hence, its activity needs to be characterized. From this point of view, we developed a rapid, accurate and reproducible analytical method for the separation and determination of diastereoisomeric glucuronides of flurbiprofen, one of the nonsteroidal anti-inflammatory drugs, in the incubation mixture of the hepatic microsomal preparation by high-performance liquid chromatography with a simple column-switching technique for deproteinization. The glucuronides were separated on a TSKgel ODS-80Ts column with 20 mM ammonium acetate buffer (pH 5.6)-ethanol-acetonitrile as the mobile phase and monitored with a UV detector at 246 nm. The detection limit of the proposed method was 600 fmol/injection at a signal-to-noise ratio of 10. The validation results indicated that this method would be very useful for the determination of diastereomeric acyl glucuronides formed from flurbiprofen in an incubation mixture.

Characterization of rat liver bile acid acyl glucuronosyltransferase

Recent studies have suggested that bile acid acyl glucuronides form covalently bound protein adducts which may cause hypersensitivity reactions and increased morbidity in patients. Although the preferential biosynthesis of the acyl glucuronides has been known, the characterization of hepatic bile acid acyl glucuronosyltransferase has not yet been clearly elucidated. We have investigated the substrate specificity of the hepatic bile acid acyl glucuronosyltransferase using five common bile acids as substrates. The glucuronidation rate was dependent on the number of the hydroxy group on the steroid nucleus and mono-hydroxylated lithocholic acid, the more lipophilic common bile acid, was most effectively metabolized into its acyl glucuronide. The tri-hydroxylated cholic acid, the more water-soluble common bile acid, barely transformed into its glucuronide. Results showed decreasing of the initial velocity of the acyl glucuronidation with increasing of the concentration of substrate, lithocholic acid, owing to the substrate inhibition of the hepatic bile acid acyl glucuronosyltransferase. The substrate analogues, glycine and taurine conjugated bile acids, which exist in the body fluids in high concentrations, also inhibited the enzyme's activity. In addition, enzymatic reaction products, bile acid acyl glucuronides, also inhibited the activity. These inhibitory mechanisms may be responsible for the low concentration of bile acid acyl glucuronides in urine and may be an important detoxification system in the body.

Separation and Determination of Diastereomeric Flurbiprofen Acyl Glucuronides in Human Urine by LC/ESI-MS with a Simple Column-Switching Technique

Endogenous and exogenous compounds having a carboxyl group, such as alpha-arylpropionic acid derivatives, undergo a phase II metabolic reaction to produce an amino acid conjugate through the acyl CoA thioester as well as the acyl glucuronide. It was previously shown that flurbiprofen, one of the nonsteroidal anti-inflammatory drugs, is not subjected to activation of the carboxyl group by the CoA thioester ligase, suggesting that acyl glucuronidation is the main phase II metabolic pathway. Recent observations, however, have demonstrated that the nonenzymatic formation of a covalently protein-bound drug, which is produced by the action of the acyl glucuronide, may cause hypersensitive reactions. Accordingly, a reliable method to measure diastereomeric flurbiprofen glucuronides in human biological fluids is required. In this study, we describe a liquid chromatographic/mass spectrometric method with a simple column switching technique to determine diastereomeric flurbiprofen acyl glucuronides in human urine specimens. The optimal conditions for the electrospray ionization were established based on the effects of orifice and ring lens voltages as well as mobile phase additives. The proposed method applied to urine specimens demonstrates high accuracy and reproducibility for the determination of flurbiprofen glucuronides in a quantitative range from 0.74 to 146.5 microg/mL, with a detection limit of 7.4 pg (17.6 fmol)/injection of S-flurbiprofen glucuronide, at a signal-to-noise ratio of 10 under the selected ion-monitoring mode. The urinary concentration of R-flurbiprofen glucuronides in healthy subjects determined by the proposed method were 6.8-29.4 microg/mL, and those values were slightly higher than that of S-flurbiprofen glucuronides (3.9-18.0 microg/mL).

Potential bile acid metabolites. 24. An efficient synthesis of carboxyl-linked glucosides and their chemical properties

A facile and efficient synthesis of the carboxyl-linked glucosides of bile acids is described. Direct esterification of unprotected bile acids with 2,3,4,6-tetra-O-benzyl-D-glucopyranose in pyridine in the presence of 2-chloro-1,3,5-trinitrobenzene as a coupling agent afforded a mixture of the alpha- and beta-anomers (ca. 1:3) of the 1-O-acyl-D-glucoside benzyl ethers of bile acids, which was separated effectively on a C18 reversed-phase chromatography column (isolated yields of alpha- and beta-anomers are 4-9% and 12-19%, respectively). Subsequent hydrogenolysis of the alpha- and beta-acyl glucoside benzyl ethers on a 10% Pd-C catalyst in acetic acid/methanol/EtOAc (1:2:2, by vol) at 35 degrees C under atmospheric pressure gave the corresponding free esters in good yields (79-89%). Chemical specificities such as facile hydrolysis and transesterification of the acyl glucosides in various solvents were also discussed.

A method for the determination of the hepatic enzyme activity catalyzing bile acid acyl glucuronide formation by high-performance liquid chromatography with pulsed amperometric detection

A method for the determination of the activity of hepatic glucuronyltransferase catalyzing formation of bile acid 24-glucuronides using high-performance liquid chromatography (HPLC) with pulsed amperometric detection (PAD) has been developed. Bile acid 24-glucuronides were simultaneously separated on a semimicrobore column, Capcell Pak C18UG120, using 20 mM ammonium phosphate (pH 6.0)-acetonitrile (27:10 and 16:10) as the mobile phase in the stepwise gradient elution mode. A 1 M potassium hydroxide solution for the hydrolysis of the 24-glucuronides, which liberates the corresponding bile acids and glucuronic acid, was mixed with the mobile phase in a post-column mode, and the resulting eluant was heated at 90 degrees C, the 24-glucuronides being monitored using a pulsed amperometric detector; the limit of detection was 10 ng. The proposed method was applied to the determination of the hepatic enzyme activity catalyzing bile acid 24-glucuronide formation and the result exhibited the efficient 24-glucuronide formation of the monohydroxylated bile acid, lithocholic acid.