Terminal deoxynucleotidyl transferase in AKR leukemic cells and lack of relation of enzyme activity to cell cycle phase.

Cholate and taurocholate uptakes were studied in presence of albumin using isolated rat hepatocytes. Albumin decreased nonspecific binding of both bile acids and inhibited cholate uptake noncompetitively and taurocholate uptake competitively. Although different bile acids except dehydrocholate inhibited both cholate and taurocholate uptake, their relative inhibitory potency was not the same for both bile acids. Uptake of both bile acids was characterized by a saturable as well as an unsaturable process both in presence and in absence of albumin. The results suggest that both bile acids may be transported by more than one carrier and taurocholate is transported more efficiently than cholate by hepatocytes.     

Absence of negative feedback control of bile acid biosynthesis in cultured rat hepatocytes

The effect of individual bile acids on bile acid synthesis was studied in primary hepatocyte cultures. Relative rates of bile acid synthesis were measured as the conversion of lipoprotein [4-14C]cholesterol into 4-14C-labeled bile acids. Additions to the culture media of cholate, taurocholate, glycocholate, chenodeoxycholate, taurochenodeoxycholate, glycochenodeoxycholate, deoxycholate, and taurodeoxycholate (10-200 microM) did not inhibit bile acid synthesis. The addition of cholate (100 microM) to the medium raised the intracellular level of cholate 10-fold, documenting effective uptake of added bile acid by cultured hepatocytes. The addition of 200 microM taurocholate to cultured hepatocytes prelabeled with [4-14C]cholesterol did not result in inhibition of bile acid synthesis. Taurocholate (10-200 microM) also failed to inhibit bile acid synthesis in suspensions of freshly isolated hepatocytes after 2, 4, and 6 h of incubation. Surprisingly, the addition of taurocholate and taurochenodeoxycholate (10-200 microM) stimulated taurocholate synthesis from [2-14C]mevalonate-labeled cholesterol (p less than 0.05). Neither taurocholate nor taurochenodeoxycholate directly inhibited cholesterol 7 alpha-hydroxylase activity in the microsomes prepared from cholestyramine-fed rats. By contrast, 7-ketocholesterol and 20 alpha-hydroxycholesterol strongly inhibited cholesterol 7 alpha-hydroxylase activity at low concentrations (10 microM). In conclusion, these data strongly suggest that bile acids, at the level of the hepatocyte, do not directly inhibit bile acid synthesis from exogenous or endogenous cholesterol even at concentrations 3-6-fold higher than those found in rat portal blood.     

Bile acid binding proteins in hepatocellular membranes of newborn and adult rats. Identification of transport proteins with azidobenzamidotauro[14C]cholate ([14C]ABATC)

Neonatal hepatocytes are less active in uptake of bile acids than are mature hepatocytes. This phenomenon has been further investigated by transport studies with azidobenzamidotaurocholate (ABATC). Taurocholate, cholate and the photolabile ABATC were taken up by liver cells of adult rats by a sodium-dependent and by an additional sodium-independent mechanism. In the dark, ABATC inhibited the uptake of taurocholate and cholate. Taurocholate decreased the transport of ABATC in a competitive manner, both in the presence and absence of sodium. In neonatal hepatocytes the Vmax for taurocholate and for ABATC was similar but was lower than in mature liver cells. In contrast, the Km was similar for neonatal and mature hepatocytes. For identification of binding proteins in both kinds of cells ABATC was photolysed after preincubation with isolated hepatocytes. Under our experimental conditions (single ultraviolet flash) about 80% of the azido groups was converted to nitrene. The covalently binding nitrene derivative inhibited bile salt transport irreversibly. Photolabeling of intact hepatocytes or of isolated plasma membranes with ABATC resulted in radioindication of membrane proteins with 67, 60, 54, 50 and 43 kDa in mature plasma membranes but of proteins with masses of 67, 54, 43 and 37 kDa in neonatal basolateral membranes. The 50 kDa protein in largely lacking in membranes of 9-day-old rats. The process of photolabeling itself was sodium-independent when isolated cells were treated with ABATC. In contrast, the degree of labeling of intact hepatocytes was markedly reduced in the absence of sodium and chloride. 100-fold molar excess of taurocholate, benzamidotaurocholate (BATC), phalloidin or cyclosomatostatin protected isolated plasma membranes against coupling of ABATC. Photolabeling of hepatoma cells known to be deficient in bile salt transport did not result in radiomodification of membrane proteins.     

Taurocholate is more potent than cholate in suppression of bile salt synthesis in the rat

Synthesis of bile salts is regulated through negative feedback inhibition by bile salts returning to the liver. Individual bile salts have not been distinguished with regard to inhibitory potential. We assessed inhibition of bile salt synthesis by either cholate or its taurine conjugate in bile fistula rats. After allowing synthesis to maximize, baseline synthesis was determined by measuring bile salt output in four consecutive 6-hr periods. Next, sodium cholate (+[(14)C]cholate) or taurocholate (+[(14)C]taurocholate) was infused into the jugular vein for 36 hr and bile was collected in 6-hr aliquots. Hepatic flux of exogenous bile salt was determined by measuring output of radioactivity in bile divided by specific activity of the infusate. Synthesis was determined during the last four 6-hr periods of infusion by subtracting exogenous bile salt secretion from the total bile salt output. Thirteen studies using cholate and 13 using taurocholate were performed. Hepatic flux of infused bile salt varied from 1 to 12 micro mol/100 g per rat per hr. Percent suppression of synthesis varied directly with hepatic flux of exogenous bile salt for both cholate and taurocholate in a linear fashion (r = 0.66, P < 0.01 and r = 0.87, P < 0.0005, respectively). Slope of the taurocholate line was 7.82 (% suppression/ micro mol per 100 g per hr), while slope of the cholate line was 3.66 (P < 0.05), indicating that taurocholate was approximately twice as potent as cholate in suppression of synthesis. At fluxes of 10-12 micro mol/100 g per hr, taurocholate suppressed synthesis 84 +/- 8 (SEM) % while cholate suppressed synthesis only 42 +/- 12% (P < 0.02). The x-intercept of the taurocholate line was 0.65 ( micro mol/100 g per hr), while that of the cholate line was -1.01 (NS) suggesting that the threshold for initial suppression of synthesis did not differ for these two bile salts. We conclude that taurocholate is a more effective inhibitor of hepatic bile salt synthesis than cholate, and that intestinal deconjugation of bile salts may play a role in the regulation of synthesis.-Pries, J. M., A. Gustafson, D. Wiegand, and W. C. Duane. Taurocholate is more potent than cholate in suppression of bile salt synthesis in the rat.     

Human lysosomal beta-glucosidase: kinetic characterization of the catalytic, aglycon, and hydrophobic binding sites

Three binding sites on highly purified lysosomal beta-glucosidase from human placenta were identified by studies of the effects of interactions of various enzyme modifiers. The negatively charged lipids, taurocholate and phosphatidylserine, were shown to be noncompetitive, nonessential activators of 4-methylumbelliferyl-beta-D-glucoside hydrolysis. Similar results were observed using the natural substrate, glucosyl ceramide, and low concentrations of taurocholate (less than 1.8 mM) or phosphatidylserine (0.5 mM). However, higher concentrations resulted in a complex partial inhibition of glucosyl ceramide hydrolysis. Increasing concentrations of phosphatidylserine obviated the effects of taurocholate, suggesting that these compounds compete for a common binding site on the enzyme. Glucosyl sphingosine and its N-hexyl derivative were potent noncompetitive inhibitors of the enzyme activity using either substrate. Taurocholate (or phosphatidylserine) and glucosyl sphingosine were shown to be mutually exclusive, indicating competition for a common binding site. In contrast, octyl- and dodecyl-beta-glucosides were linear-mixed-type inhibitors of glucosyl ceramide or 4-methylumbelliferyl-beta-D-glucoside hydrolysis, indicating at least two binding sites on the enzyme. Inhibition by these alkyl beta-glucosides was observed only in the presence of taurocholate or phosphatidylserine. The competitive component [Ki (slope)] for the two alkyl beta-glucosides decreased with increasing alkyl chain length, and was unaffected by increasing taurocholate or phosphatidylserine concentration. The noncompetitive component [Ki (intercept)] was nearly identical for both alkyl beta-glucosides and was decreased by increasing taurocholate or phosphatidylserine concentration. These results indicated that the negatively charged lipids and alkyl beta-glucosides were not mutually exclusive, but interacted with different binding sites on the enzyme. Gluconolactone was shown to protect the enzyme from inhibition by the catalytic site-directed covalent inhibitor, conduritol B indicating an interaction at a common binding site. In the presence of substrate, taurocholate facilitated the inhibition of gluconolactone or conduritol B epoxide. These studies indicated that lysosomal beta-glucosidase had at least three binding sites: (i) a catalytic site which cleaves the beta-glucosidic moiety, (ii) an aglycon site which binds the acyl or alkyl moieties of substrates and some inhibitors, and (iii) a hydrophobic site which interacts with negatively charged lipids and facilitates enzyme catalysis.     

Comparison of bile acid binding to sinusoidal and bile canalicular membranes isolated from rat liver

Simon et al. (J. Clin. Invest., 70 (1982) 401) studied cholate binding to crude liver plasma membrane vesicles and suggested that the binding may represent mainly the binding to the receptor (carrier) on the canalicular membrane. This hypothesis was supported by finding a good correlation between the number of cholate binding sites on liver plasma membrane and the maximal rate of biliary secretion (Tm) for taurocholate. We studied bile acid binding to sinusoidal and canalicular membrane vesicles isolated from rat liver by a rapid filtration technique. Scatchard analysis of the saturation kinetics showed both [3H]cholate and [3H]chenodeoxycholate bind to two classes of binding site on each membrane. However, little difference was observed between the binding to sinusoidal and canalicular membrane vesicles for each bile acid (cholate, Kd1 = 10.4 and 19.8 microM, n1 = 31.0 23.6 pmol/mg protein, Kd2 = 1.32 and 1.73 mM, n2 = 13.1 and 23.4 nmol/mg protein; and chenodeoxycholate, Kd1 = 0.207 and 0.328 microM, n1 = 36.7 and 27.4 pmol/mg protein, Kd2 = 1.16 and 2.26 mM, and n2 = 20.6 and 24.2 nmol/mg protein; numbers show the mean values sinusoidal and canalicular membrane vesicles, respectively). Chenodeoxycholate binding to sinusoidal membrane vesicles was markedly inhibited by cholate but not by Rose bengal, an organic anion dye. These studies indicate that both membranes (sinusoidal and canalicular membrane vesicles) have two kinds of binding site for bile acids, although no clear difference in the binding properties was observed between the two membranes. Consequently, the cholate binding Simon detected may represent the binding not only to canalicular membrane vesicles but also to sinusoidal membrane vesicles.     

Nonspecific high affinity binding of bile salts to carboxylester lipases

The interactions with bile salts of carboxylester lipases (EC 3.1.1.13) from human pancreatic juice and pig pancreas were characterized by physical methods. Bile salts cause a decrease in the fluorescence intensity of the proteins at the emission maximum of 333-335 nm. The concentration dependence of this decrease shows saturation behavior, is relatively nonspecific with respect to bile salt conjugation or the presence of the 7 alpha-hydroxyl group, and is consistent with a 1:1 interaction between enzyme and bile salt. Direct measurement of the binding of [3H]cholate by equilibrium dialysis supports the stoichiometry. Other detergents also bind, causing fluorescence changes, but with much lower affinities. Binding of taurocholate to the monomeric pig enzyme is enhanced by increasing ionic strength, indicating the predominance of hydrophobic interactions. In the range of pH 5.5-6.8, binding is pH-independent with dissociation constants of 3-20 microM. At higher pH, affinity is greatly reduced and the fluorescence spectrum changes, indicating the importance of a protonated group for efficient interaction. Occupancy of the bile salt binding site partially stabilizes the enzyme against inactivation by heat but not trypsin. However, circular dichroism spectra do not indicate that bile salt binding is accompanied by any change in secondary structure. The monomeric pig enzyme binds to the argon/water interface in the presence of bile salts and binding of taurocholate to diisopropylphosphoryl-enzyme is similar to that measured with native enzyme. These results suggest that surface binding and catalysis occur at sites distinct from the bile salt binding site of the enzyme. Stabilization of the monomeric pig enzyme against denaturation at high energy surfaces occurs concomitantly with occupancy of the bile salt binding site. Overall, the data suggest that an important role of bile salts in vivo is to stabilize these enzymes at lipid-water interfaces.     

Bile acid uptake by isolated intestinal mucosa cells of guinea pig

Isolated intestinal mucosa cells of the guinea pig were employed to study intestinal transport of bile acids. Chenodeoxycholate and lithocholate were rapidly taken up into jejunal and ileal cells by diffusion. Taurocholate and cholate however showed only a minor diffusion rate and were preferentially taken up by the ileal bile acid carrier. This uptake was saturable with an apparent K_m of 231 μM and V of 7 nmol/mg protein per min for taurocholate; this bile acid was accumulated 90-fold. Its uptake was strongly inhibited by antimycin A, FCCP, ouabain or Na⁺-deficiency in the medium. Sugars or amino acids did not interfere with uptake. Experimental conditions were optimized with regard to incubation medium, cell amount, cell age and length of preincubation. It is concluded that ileal cells of the guinea pig are superior to other experimental models for characterizing the ileal bile acid carrier, because they allow us to determine initial rates of uptake and have a very efficient energetic coupling.     

Mapping interactions between germinants and Clostridium difficile spores

Germination of Clostridium difficile spores is the first required step in establishing C. difficile-associated disease (CDAD). Taurocholate (a bile salt) and glycine (an amino acid) have been shown to be important germinants of C. difficile spores. In the present study, we tested a series of glycine and taurocholate analogs for the ability to induce or inhibit C. difficile spore germination. Testing of glycine analogs revealed that both the carboxy and amino groups are important epitopes for recognition and that the glycine binding site can accommodate compounds with more widely separated termini. The C. difficile germination machinery also recognizes other hydrophobic amino acids. In general, linear alkyl side chains are better activators of spore germination than their branched analogs. However, L-phenylalanine and L-arginine are also good germinants and are probably recognized by distinct binding sites. Testing of taurocholate analogs revealed that the 12-hydroxyl group of taurocholate is necessary, but not sufficient, to activate spore germination. In contrast, the 6- and 7-hydroxyl groups are required for inhibition of C. difficile spore germination. Similarly, C. difficile spores are able to detect taurocholate analogs with shorter, but not longer, alkyl amino sulfonic acid side chains. Furthermore, the sulfonic acid group can be partially substituted with other acidic groups. Finally, a taurocholate analog with an m-aminobenzenesulfonic acid side chain is a strong inhibitor of C. difficile spore germination. In conclusion, C. difficile spores recognize both amino acids and taurocholate through multiple interactions that are required to bind the germinants and/or activate the germination machinery.     

Taurocholate feeding prevents CCl4-induced damage of large cholangiocytes through PI3-kinase-dependent mechanism

Bile acids are cytoprotective in hepatocytes by activating phosphatidylinositol-3-kinase (PI3-K) and its downstream signal AKT. Our aim was to determine whether feeding taurocholate to CCl(4)-treated rats reduces cholangiocyte apoptosis and whether this cytoprotective effect is dependent on PI3-K. Cholangiocyte proliferation, secretion, and apoptosis were determined in cholangiocytes from bile duct ligation (BDL), CCl(4)-treated BDL rats, and CCl(4)-treated taurocholate-fed rats. In vitro, we tested whether CCl(4) induces apoptosis and whether loss of cholangiocyte proliferation and secretion is dependent on PI3-K. The CCl(4)-induced cholangiocyte apoptosis and loss of cholangiocyte proliferation and secretion were reduced in CCl(4)-treated rats fed taurocholate. CCl(4)-induced cholangiocyte apoptosis, loss of cholangiocytes secretion, and proliferation were prevented by preincubation with taurocholate. Taurocholate cytoprotective effects were ablated by wortmannin. Taurocholate prevented, in vitro, CCl(4)-induced decrease of phosphorylated AKT protein expression in cholangiocytes. The cytoprotective effects of taurocholate on CCl(4) effects on cholangiocyte proliferation and secretion were abolished by wortmannin. Taurocholate protects cholangiocytes from CCl(4)-induced apoptosis by a PI3-K-dependent mechanism. Bile acids are important in the prevention of drug-induced ductopenia in cholangiopathies.     

On the probable involvement of arginine residues in the bile-salt-binding site of human pancreatic carboxylic ester hydrolase

Modification of arginine residues with 2,3-butanedione inhibits the carboxylic-ester hydrolase activity on soluble and emulsified substrates when assayed with bile salts. The alpha-dicarbonyl reagent modifies seven of the nineteen arginine residues present per enzyme molecule. Nevertheless the inactivation with butanedione is greatly diminished when the protein is in the presence of negatively charged micellar bile salt. In these conditions we observe the protection of one arginine residue by sodium taurodeoxycholate and of two arginine residues by sodium cholate. This suggests that the carboxylic-ester hydrolase from human pancreatic juice contains at least two arginine residues essential for the activation by bile salts. All our data confirm the presence of two bile-salt-binding sites on the enzyme in which one arginine per site is involved and plays the general role of an anionic binding site. This study provides evidence that arginine residues may play an essential role in the interaction between bile salts and protein.     

Subcellular distribution of bile acids, bile salts, and taurocholate binding sites in rat liver

We have quantitated bile acids and their conjugates in rat liver using high-pressure liquid chromatography. Over 95% of the hepatic bile acid pool in rat liver homogenates is present as taurocholate and tauromuricholate. Although over 60% of the bile acid pool is recovered in the supernatant, evidence is presented suggesting that taurocholate redistributes among the subcellular fractions during their isolation. Taurocholate (TC) binding to purified subcellular fractions from rat liver was determined by using equilibrium dialysis in a TC concentration range from 0.1 to 100 microM. This is well below the critical micellar concentration of taurocholate (3 mM). All of the fractions investigated exhibited low-affinity binding with dissociation constants from 80 to 240 microM as did membrane lipid vesicles. Therefore, low-affinity binding appears referable to taurocholate nonspecifically partitioning into the lipid bilayer. High-affinity binding is present in plasma membranes, Golgi, and cell supernatant. The high-affinity binding sites in Golgi have a mean dissociation constant (A1) of 1.0 microM and bind 0.15 nmol of TC/mg of protein. Similarly, the high-affinity binding sites of plasma membrane have an A1 of 1.3 microM and bind 0.15 nmol of TC/mg of protein. For cell supernatant, the A1 was 4.8 microM, and 0.35 nmol of TC was bound per mg of protein. Mitochondria, smooth and rough microsomes, and Golgi liposomes showed no detectable amounts of high-affinity binding. These results are compatible with a role for the Golgi complex, cytoplasmic component(s), and plasma membranes in transhepatic bile acid transport.     

Structural basis for bile salt inhibition of pancreatic phospholipase A2

Bile salt interactions with phospholipid monolayers of fat emulsions are known to regulate the actions of gastrointestinal lipolytic enzymes in order to control the uptake of dietary fat. Specifically, on the lipid/aqueous interface of fat emulsions, the anionic portions of amphipathic bile salts have been thought to interact with and activate the enzyme group-IB phospholipase A2 (PLA2) derived from the pancreas. To explore this regulatory process, we have determined the crystal structures of the complexes of pancreatic PLA2 with the naturally occurring bile salts: cholate, glycocholate, taurocholate, glycochenodeoxycholate, and taurochenodeoxycholate. The five PLA2-bile salt complexes each result in a partly occluded active site, and the resulting ligand binding displays specific hydrogen bonding interactions and extensive hydrophobic packing. The amphipathic bile salts are bound to PLA2 with their polar hydroxyl and sulfate/carboxy groups oriented away from the enzyme's hydrophobic core. The impaired catalytic and interface binding functions implied by these structures provide a basis for the previous numerous observations of a biphasic dependence of the rate of PLA2 catalyzed hydrolysis of zwitterionic glycerophospholipids in the presence of bile salts. The rising or activation phase is consistent with enhanced binding and activation of the bound PLA2 by the bile salt induced anionic charge in a zwitterionic interface. The falling or inhibitory phase can be explained by the formation of a catalytically inert stoichiometric complex between PLA2 and any bile salts in which it forms a stable complex. The model provides new insight into the regulatory role that specific PLA2-bile salt interactions are likely to play in fat metabolism.     

Thermodynamic study of taurocholate binding to rat serum albumin

Taurocholate binding to rat serum albumin was studied by equilibrium dialysis. The bile salt-protein interaction was studied under different experimental conditions with respect to temperature; ionic strength; Cl- concentration; pH and the presence of butanol in the medium. The results obtained suggest the existence of two binding sites for taurocholate on the albumin molecule, and indicate that both electrostatic and hydrophobic interaction play a role in the binding process.