Lithocholic Acid Conjugates Research Articles

Biochemical characterization of EphA2 antagonists with improved physico-chemical properties by cell-based assays and surface plasmon resonance analysis

Amino acid conjugates of lithocholic acid (LCA) have been recently described as effective disruptors of the EphA2⿿ephrin-A1 interaction able to inhibit EphA2 phosphorylation in intact cells and thus able to block prometastatic responses such as cellular retraction and angiogenesis. However, these LCA-based compounds were significantly more potent at disrupting the EphA2⿿ephrin-A1 interaction than at blocking phenotype responses in cells, which might reflect an unclear mechanism of action or a metabolic issue responsible for a reduction of the compound concentration at the cell⿿s surface. Through the synthesis of new compounds and their examination by a combination of cell-based assays and real-time interaction analysis by surface plasmon resonance, we showed at molecular level that l-tryptophan conjugates of lithocholic acid disrupt EphA2⿿ephrin-A1 interaction by targeting the EphA 2 receptor and that the presence of a polar group in position 3 of steroid scaffold is a key factor to increase the effective concentration of the compounds in cancer cell lines.

Targeting the Eph-ephrin System with Protein-Protein Interaction (PPI) Inhibitors.

Eph-ephrin system is emerging as a new potential target in several diseases including cancer, diabetes, neurodegenerative diseases and inflammation. In the last decade, several efforts have been made to develop small molecule antagonists of Eph receptors. Both natural and synthetic compounds were discovered with (poly) phenol and steroidal derivatives on one side and the α1 agonist doxazosin, 2,5-dimethylpyrrol- 1-yl-benzoic acids and amino acid conjugates of lithocholic acid on the other. In the present paper we critically present available data for these compounds and discuss their potential usefulness as pharmacological tools or as candidates for a lead-optimization program.

Amino Acid Conjugates of Lithocholic Acid As Antagonists of the EphA2 Receptor

The Eph receptor-ephrin system is an emerging target for the development of novel antiangiogenetic agents. We recently identified lithocholic acid (LCA) as a small molecule able to block EphA2-dependent signals in cancer cells, suggesting that its (5β)-cholan-24-oic acid scaffold can be used as a template to design a new generation of improved EphA2 antagonists. Here, we report the design and synthesis of an extended set of LCA derivatives obtained by conjugation of its carboxyl group with different α-amino acids. Structure-activity relationships indicate that the presence of a lipophilic amino acid side chain is fundamental to achieve good potencies. The l-Trp derivative (20, PCM126) was the most potent antagonist of the series disrupting EphA2-ephrinA1 interaction and blocking EphA2 phosphorylation in prostate cancer cells at low μM concentrations, thus being significantly more potent than LCA. Compound 20 is among the most potent small-molecule antagonists of the EphA2 receptor.

The Human UGT1A3 Enzyme Conjugates Norursodeoxycholic Acid into a C23-ester Glucuronide in the Liver

Norursodeoxycholic acid (norUDCA) exhibits efficient anti-cholestatic properties in an animal model of sclerosing cholangitis. norUDCA is eliminated as a C(23)-ester glucuronide (norUDCA-23G) in humans. The present study aimed at identifying the human UDP-glucuronosyltransferase (UGT) enzyme(s) involved in hepatic norUDCA glucuronidation and at evaluating the consequences of single nucleotide polymorphisms in the coding region of UGT genes on norUDCA-23G formation. The effects of norUDCA on the formation of the cholestatic lithocholic acid-glucuronide derivative and of rifampicin on hepatic norUDCA glucuronidation were also explored. In vitro glucuronidation assays were performed with microsomes from human tissues (liver and intestine) and HEK293 cells expressing human UGT enzymes and variant allozymes. UGT1A3 was identified as the major hepatic UGT enzyme catalyzing the formation of norUDCA-23G. Correlation studies using samples from a human liver bank (n = 16) indicated that the level of UGT1A3 protein is a strong determinant of in vitro norUDCA glucuronidation. Analyses of the norUDCA-conjugating activity by 11 UGT1A3 variant allozymes identified three phenotypes with high, low, and intermediate capacity. norUDCA is also identified as a competitive inhibitor for the hepatic formation of the pro-cholestatic lithocholic acid-glucuronide derivative, whereas norUDCA glucuronidation is weakly stimulated by rifampicin. This study identifies human UGT1A3 as the major enzyme for the hepatic norUDCA glucuronidation and supports that some coding polymorphisms affecting the conjugating activity of UGT1A3 in vitro may alter the pharmacokinetic properties of norUDCA in cholestasis treatment.

Lithocholylcholine, a bile acid/acetylcholine hybrid, is a muscarinic receptor antagonist.

Previous work from our laboratory indicates that bile acids, specifically lithocholic acid conjugates, interact with muscarinic receptors on gastric chief cells. Structural similarities between acetylcholine and lithocholyltaurine suggest a potential molecular basis for their interaction with the same receptor. We synthesized a hybrid molecule consisting of the steroid nucleus of lithocholyltaurine and the choline moiety of acetylcholine. The new molecule, lithocholylcholine, is hydrolyzed by acetyl-cholinesterase. Lithocholylcholine inhibited binding of a cholinergic radioligand to Chinese hamster ovary cells expressing each of the five muscarinic receptor subtypes. The binding affinities (K(i); micromolar) of lithocholylcholine for these receptors were: M3 (1.0) > M1 (2.7) > M2 (4.1) = M4 (4.9) > M5 (6.2). Lithocholylcholine inhibited intracellular signaling pathways mediated by interaction with M1, M2, and M3 muscarinic receptors. Regarding M3 receptors, lithocholylcholine was 10-fold more potent than lithocholyltaurine in terms of binding affinity and inhibition of acetylcholine-induced increases in inositol phosphate formation and mitogen-activated protein kinase phosphorylation. In a functional assay, lithocholylcholine inhibited acetylcholine-induced relaxation of rat aortic rings. These observations indicate that lithocholylcholine is a muscarinic receptor antagonist and provide further evidence that bile acids may have gastrointestinal signaling functions that extend beyond their effects on sterol metabolism, lipid absorption, and cholesterol elimination. Hybrid molecules created from bile acids and acetylcholine may be used to develop selective muscarinic receptor ligands.

Functional interaction of lithocholic acid conjugates with M3 muscarinic receptors on a human colon cancer cell line

Lithocholic acid (LA) conjugates interact with M3 receptors, the muscarinic receptor subtype that modulates colon cancer cell proliferation. This observation prompted us to examine the action of bile acids on two human colon cancer cell lines: H508, which expresses M3 receptors, and SNU-C4, which does not. Cellular proliferation was determined using a colorimetric assay. Interaction with muscarinic receptors was determined by measuring inhibition of muscarinic radioligand binding and changes in cellular inositol phosphate (IP) formation. Lithocholyltaurine (LCT) caused a dose-dependent increase in H508 cell proliferation that was not observed in SNU-C4 cells. After a 6-day incubation with 300 μM LCT, H508 cell proliferation increased by 200% compared to control. Moreover, in H508 cells, LCT caused a dose-dependent inhibition of radioligand binding and an increase in IP formation. LCT did not alter the rate of apoptosis in H508 or SNU-C4 cells. These data indicate that, at concentrations achievable in the gut, LA derivatives interact with M3 muscarinic receptors on H508 human colon cancer cells, thereby causing an increase in IP formation and cell proliferation. This suggests a mechanism whereby alterations in intestinal bile acids may affect the growth of colon cancer cells.

Interaction of taurine conjugates of lithocholic acid with M3 muscarinic receptors on a colon cancer cell line

Interaction of taurine conjugates of lithocholic acid with M3 muscarinic receptors on a colon cancer cell line

The identification of unusual bile acid metabolites by tandem mass spectrometry: use of low-energy collision-induced dissociation to produce informative spectra.

The use of collision-induced dissociation (CID) tandem mass spectrometry (MS/MS) has been shown to produce fragmentation that is useful for the structural analysis of bile acids and their conjugates. Low-energy CID using a triple quadrupole has been used to help characterise bile acid identity but the majority of work has been conducted using high-energy CID on specialised instrumentation. This paper describes the use of low-energy CID as a rapid method for identification of urinary bile acids and presents some examples of its use in the diagnosis of liver disease in infants. These include the differential diagnosis of peroxisomal disorders, identification of compounds (e.g. 3 beta,7 alpha-dihydroxy-5-cholenoic acid 3-sulphate) indicative of 3 beta-hydroxy-delta 5-C27-steroid dehydrogenase/isomerase deficiency and the confirmation of the identity of an unusual bile acid series consisting of different conjugates of lithocholic acid. The use of lithium cationisation and derivatisation with aminosulfonic acids for the analysis of unconjugated and glycine-conjugated bile acids has also been evaluated.

DNA Condensation by Bile Acid Conjugates of Thermine and Spermine

DNA condensation was achieved with polyamine conjugates of bile acids. Spermine and thermine, linear tetraamines, were mono-acylated on a primary amine with cholic and lithocholic acids. The resulting polyamine amides were triamines containing either a propyl-butyl or a dipropyl spacing. Thus, the former mimics both the positive charge and its regiochemical distribution found in the natural product spermidine. Calf thymus DNA was extended by saturation with an intercalator, ethidium bromide. DNA binding affinity was then measured by fluorescence quenching with detection of residual intercalated ethidium bromide at 600 nm. The results obtained with this exclusion assay show that polyamine lithocholic acid conjugates condense DNA more efficiently than the analogous cholic acid polyamine amides.

Serum bile acid concentrations in mild liver cirrhosis

Fasting serum conjugated bile salt concentrations were measured in a group of 20 patients with moderate post-hepatitis cirrhosis. Twenty healthy volunteers were used as controls. The individual conjugated bile acids were analyzed by a specific and sensitive method which couples reversed-phase high-performance liquid chromatography with mass spectrometry. Significantly elevated levels of the total and individual conjugated bile acids were found in cirrhotic patients. The predominant serum bile acids were conjugates of chenodeoxycholic acid. The conjugates of lithocholic acid were also increased; in subjects with normal liver function, on the contrary, they were found only in traces.

Cholestasis and the interactions of sulfated glyco- and taurolithocholate with calcium.

To elucidate possible mechanisms of the differential cholestatic effect of sulfated glyco- and taurolithocholate (SGLC and STLC) the interactions of these bile acids with calcium were studied both in vitro and in vivo. In vitro, SGLC was readily precipitated by Ca in physiological concentrations (less than 5 mM). It appeared that only micelles of SGLC were precipitated and that both the sulfate and the carboxylate anionic groups participated in Ca binding. Conjugation with taurine almost completely prevented this Ca-dependent precipitation. Intravenous infusion of SGLC (12 mumol/h) in unanesthetized rats with permanent biliary drainage induced cholestasis, which was preceded by the formation of a biliary Ca-SGLC precipitate, suggesting a causal relationship. Taurine conjugation prevented this biliary precipitation as well as cholestasis. Furthermore, we studied in vitro the binding of the sulfated bile acids to insoluble calcium phosphate, simulating interactions with Ca at the intestinal level. Compared with STLC, micellar SGLC was bound with much higher affinity. This high-affinity binding was probably due to the involvement of both the sulfate and the carboxylate group. This might also explain that the apparent critical micellar concentration of SGLC, in contrast to that of STLC, was extremely Ca dependent. The present findings indicate that 1) interaction with calcium might be responsible for the differential cholestatic properties of SGLC and STLC and 2) binding of sulfated lithocholic acid conjugates to insoluble calcium phosphate in the intestinal lumen is likely to prevent their accumulation in the enterohepatic circulation.

Intestinal absorption of lithocholic acid sulfates in the rat: inhibitory effects of calcium.

Sulfation of lithocholic acid has been proposed as a mechanism for elimination of this hepatotoxic bile acid from the body by accelerating its fecal excretion. However, quantitative data on the absorption characteristics of sulfated lithocholic acid conjugates in vivo are scarce. We studied the intestinal absorption of 14C-labeled glycolithocholic acid (GLC), taurolithocholic acid (TLC), and their 3 alpha-sulfate esters, SGLC and STLC, respectively. Studies were performed in unanesthetized rats with a permanent biliary drainage. At an intestinal infusion rate of 125 nmol/min, which is comparable to 7% of the normal biliary bile acid output in the rat, the absorption of sulfated lithocholic acid conjugates was delayed when compared with their unsulfated precursors but quantitatively only slightly reduced over a 24-h period: SGLC 90.9 +/- 3.6%, GLC 94.4 +/- 1.1%, STLC 84.4 +/- 3.0%, and TLC 94.2 +/- 2.1%. Urinary excretion of sulfated and unsulfated bile acids was similar and never exceeded 2% of the dose. SGLC absorption was dose dependent, was not altered by coinfusion of rat bile, and was only slightly reduced by a sixfold overdose of taurocholic acid. SGLC and STLC were excreted into bile largely unchanged in form. In contrast, GLC and TLC were extensively metabolized to more polar bile acids, predominantly to beta-muricholic acid conjugates. Replacement of NaCl in the infusion fluid by CaCl2 reduced the absorption of SGLC and STLC by 63 and 52%, respectively. This calcium effect was less pronounced for the unsulfated bile acids: GLC -22%, and TLC -19%. Absorption of taurocholic acid was unaffected by CaCl2.(ABSTRACT TRUNCATED AT 250 WORDS)

Sulphated lithocholic acid conjugates in serum from children with hepatic and intestinal diseases.

Sulphated lithocholic acid conjugates (SGLC) were measured in the sera of 268 children with various hepatic and intestinal disorders. Two groups were distinguished: (I) SGLC concentration less than or equal to 1.2 mumol/l, n = 198, and (II) SGLC concentration greater than 1.2 mumol/l, n = 70. In 28 patients of the latter group the SGLC concentration was less than 25% of the concentration of glycocholic acid (GC) in the same serum sample. This group (IIA) consisted predominantly of patients with cholestasis, as characterized by high serum bile acid levels and deviating liver function tests. The rest of the group (IIB), with SGLC levels exceeding 25% of the GC concentration and relatively low serum bile acid concentrations, showed no clear cholestatic symptoms. A postprandial increase in serum SGLC (delta SGLC) greater than 1.0 mumol/l was found in only 1 of 32 patients of group I (3%), in 1 of 6 patients of group IIA (17%), but in 9 of 11 patients of group IIB (81%). delta SGLC did not correlate with delta GC in the same test, which indicated that a general hepatic bile acid clearance defect was not responsible. In two patients with intermittent cholestasis, the distinct postprandial rise in serum SGLC that was always found during anicteric periods could be prevented by adding cholestyramine to the test meal. We conclude that elevated serum concentrations of SGLC develop during the course of cholestasis but may also be caused by influx of this bile acid from the intestine. Because of its hepatotoxic properties, SGLC may be involved in the initiation or perpetuation of specific cholestatic phenomena.

Quantitative determination of bile acid glucuronides in serum by mass fragmentography.

Individual non-glucuronidated . non-sulfated, glucuronidated and sulfated bile acids in serum were determined, i.e. lithocholic acid, deoxycholic acid, chenodeoxycholic acid, ursodeoxycholic acid, and cholic acid, by mass fragmentography. Glucuronic acid conjugates of lithocholic acid, deoxycholic acid, chenodeoxycholic acid, and cholic acid were synthesized via the Koenigs-Knorr condensation reaction. Deuterium labeled deoxycholic acid, lithocholic acid glucuronide, deoxycholic acid glucuronide, and deoxycholic acid sulfate were synthesized and used as internal standards. A serum sample of 1 ml including internal standards was purified with a Sep-Pak C18 cartridge. After the enzymatic cleavage of amino acid conjugates, bile acids were separated into three fractions, free, glucuronidated, and sulfated bile acids, using piperidinohydroxypropyl Sephadex LH-20 (Goto et al. (1978) Clin. Chim. Acta 87). Glucuronidated and sulfated bile acids were deconjugated by beta-glucuronidase treatment and solvolysis. Each fraction was converted to the hexafluoroisopropyl-trifluoroacetyl derivative and quantitated by mass fragmentography. The average concentrations of individual bile acid glucuronides from healthy fasting subjects (n = 9) were as follows; lithocholic acid 0.013 microgram/ml, deoxycholic acid 0.083 microgram/ml, chenodeoxycholic acid 0.078 microgram/ml, ursodeoxycholic acid 0.013 microgram/ml, and cholic acid 0.007 microgram/ml. Bile acid glucuronides occupied 7.8% of the total bile acids.

Serum bile acids in newborns and children.

A specific and sensitive radioimmunoassay for cholic, chenodeoxycholic, and lithocholic acid conjugates and for sulfolithocholylglycine was used to measure serum bile acids (BA) in infants and children. Elevated cholic and chenodeoxycholic acid values were observed in the first year of life in fasting infants. Newborn babies presented high levels of primary BA not correlated with those of the mothers. In premature newborn babies who had not yet been fed, meal induced a considerable reduction in the primary BA levels in serum. In normally fed babies, meal induced a significant increase in the primary BA levels in serum. These data suggest a progressive maturity throughout the first year of life of the serum BA determinants, i.e., gallbladder emptying, intestinal motility and absorption, and hepatic uptake.

A radioimmunoassay for lithocholic acid conjugates in human serum and liver tissue

A sensitive and specific radioimmunoassay for glycine and taurine conjugates of lithocholic acid (CLCA) has been developed. 3H-glycolithocholic acid (S.A. = 17Ci/mmol) was used as tracer. Separation of free from antibody-bound bile acid was carried out using ammonium sulphate (saturated solution). The antiserum showed high specificity for both glyco and tauro conjugated lithocholate (100% cross reaction) and lithocholic acid (25% cross reaction). The sensitivity of the assay (1 pmole/tube), was adequate for measuring CLCA in peripheral blood and hepatic tissue in man.

Purification and characterization of bile salt hydrolase from Bacteroides fragilis subsp. fragilis

A high-molecular-weight (250 000) bile salt hydrolase (cholylglycine hydrolase, EC 3.5.-.-) was isolated and purified 128-fold from the “spheroplast lysate” fraction prepared from Bacteroides fragilis subsp. fragilis ATCC 25285. The intact enzyme had a molecular weight of approx. 250 000 as determined by gel filtration chromatography. One major protein band, corresponding to a molecular weight of 32 500, was observed on 7% sodium dodecyl sulfate polyacrylamide gel electrophoresis of pooled fractions from DEAE-cellulose column chromatography (128-fold purified). The pH optimum for the 64-fold purified enzyme isolated from Bio-Gel A 1.5 M chromatography was 4.2 and bile salt hydrolase activity measured in intact cell suspensions had a pH optimum of 4.5. Substrate specificity studies indicated that taurine and glycine conjugates of cholic acid, chenodeoxycholic acid and deoxycholic acid were readily hydrolyzed; however, lithocholic acid conjugates were not hydrolyzed. Substrate saturation kinetics were biphasic with an intermediate plateau (0.2–0.3 mM) and a complete loss of enzymatic activity was observed at high concentration for certain substrates. The presence or absence of 7-α-hydroxysteroid dehydrogenase was absolutely correlated with that of bile salt hydrolase activity in six to ten strains and subspecies of B. fragilis.

APPLICATION OF GEL FILTRATION OF BILE ACIDS TO STUDIES OF LIPID-COMPLEXES IN BILE.

SummaryGel filtration on Sephadex G-25 was applied to conjugated bile acids in water solution or in bile. 1. An adsorption of bile acids occurs during gel filtration. The adsorption was more pronounced when gel filtration was performed with saline than with water. Conjugates of monohydroxycholanic acid were adsorbed to the greatest extent followed by trihydroxycholanic acid and dihydroxycholanic acid. Rates of elution of taurine and glycine conjugates of a bile acid were about the same. 2. Labeled conjugated bile acids dissolved in bile or in vivo labeled conjugates, obtained by administration of the corresponding free acid to patients, showed the same behavior on gel filtration. The conjugates of cholic, deoxycholic and chenodeoxycholic acid were all absent from the molecular weight fraction (M > 3,500-4,500) and were eluted at about the same rate as the corresponding conjugates gel filtered in the absence of bile. A small amount of the lithocholic acid conjugates in bile were eluted in the macromolecula...