Characterization of bile acid binding to rat intestinal brush border membranes

Summary Studies were performed to characterize the binding¹ of bile acids to intestinal brush border membranes. Total¹⁴C-taurodeoxycholate binding was: 1) similar for brush borders prepared from jejunum and ileum, 2) linear with respect to monomer concentration, 3) uninhibited by a structural analog, and 4) not depressed by boiling or trypsin. A linear relationship existed between binding and the number of hydrogen bonds formed by a bile acid and the slope of the line corresponded to F of 300 cal/mol. The binding of bile acids to the 105,000×g supernatant fraction of sonicated brush borders was similar to the binding of phospholipid liposomes using gel chromatography. These data suggest that: 1) the kinetics and characteristics of binding of bile acid to ileal brush borders do not reflect the kinetics and characteristics of active ileal transport previously obtained in whole tissue preparations, but instead reflect the kinetics and characteristics of passive jejunal transport; 2) a determinant of binding is hydrogen bonding with water; 3) isolated intact brush borders are relatively polar membranes; and 4) binding to solubilized brush borders may represent partitioning between the aqueous phase and membrane lipid.Part of this work was presented at the National Meeting of the American Federation for Clinical Research, May 2, 1976, Atlantic City, New Jersey.     

Glycodeoxycholate transport in brush border membrane vesicles isolated from rat jejunum and ileum.

The transport of the bile salt, glycodeoxycholate, was studied in vesicles derived from rat jejunal and ileal brush border membranes using a rapid filtration technique. The uptake was osmotically sensitive, linearly related to membrane protein and resembled D-glucose transport. In ileal, but not jejunal, vesicles glycodeoxycholate uptake showed a transient vesicle/medium ratio greater than 1 in the presence of an initial sodium gradient. The differences between glycodeoxycholate uptake in the presence and absence of a Na+ gradient yielded a saturable transport component. Kinetic analysis revealed a Km value similar to that described previously in everted whole intestinal segments and epithelial cells isolated from the ileum. These findings support the existence of a transport system in the brush border membrane that: (1) reflects kinetics and characteristics of bile salt transport in intact intestinal preparations, and (2) catalyzes the co-transport of Na+ and bile salt across the ileal membrane in a manner analogous to D-glucose transport.     

Glycodeoxycholate transport in brush border membrane vesicles isolated from rat jejunum and ileum

The transport of the bile salt, glycodeoxycholate, was studied in vesicles derived from rat jejunal and ileal brush border membranes using a rapid filtration technique. The uptake was osmotically sensitive, linearly related to membrane protein and resembled d-glucose transport. In ileal, but not jejunal, vesicles glycodeoxycholate uptake showed a transient vesicle/medium ratio greater than 1 in the presence of an initial sodium gradient. The differences between glycodeoxycholate uptake in the presence and absence of a Na⁺ gradient yielded a saturable transport component. Kinetic analysis revealed a $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ value similar to that described previously in everted whole intestinal segments and epithelial cells isolated from the ileum. These findings support the existence of a transport system in the brush border membrane that: (1) reflects kinetics and characteristics of bile salt transport in intact intestinal preparations, and (2) catalyzes the co-transport of Na⁺ and bile salt across the ileal membrane in a manner analogous to d-glucose transport.     

Ion requirements for taurocholate transport by ileal brush border membrane vesicles.

The ion requirements for intestinal taurocholate transport were studied using vesicles prepared from the brush borders of guinea pig small intestines. For each experimental electrolyte, parallel uptake experiments were performed with vesicles from jejunal and ileal brush border membranes to differentiate between uptake by passive fluxes and non-specific binding and uptake by the ileal bile salt active transport system. Uptake of taurocholate prior to the addition of electrolyte was the same for vesicles prepared from jejunal and ileal tissue. During the presence of a sodium gradient (extravesicular concentration greater than intravesicular), only ileal vesicles displayed the enhanced uptake which is characteristic of the overshoot phenomenon. When NaCl was replaced by KCl or LiCl, the overshoot was not observed. Replacement of NaCl with NaCNS, Na₂SO₄, or NaSO₃C₂H₄OH, however, resulted in no significant difference in the initial uptake values observed in either the jejunal or ileal vesicles. This pattern of taurocholate transport independence of relative anion permeability differs from the pattern observed by others for the Na⁺ dependent transport of D-glucose by intestinal brush border membrane vesicles. This difference may be attributed in part to the fact that, unlike the situation with glucose, the binding of a taurocholate anion and a sodium cation by the hypothetical carrier would result in an electroneutral addition.     

Taurocholate uptake by membrane vesicles prepared from ileal brush borders

Taurocholate uptake by vesicles prepared from brush borders obtained from the small intestines of guinea pigs was studied. Vesicles obtained from the brush borders of ileums demonstrated an enhanced initial uptake in those incubations where a sodium ion gradient (extravesicular sodium concentration greater than intravesicular) was present at the outset. With the dissipation of this sodium gradient the intravesicular concentration of taurocholate declined. This overshoot phenomenon was absent in parallel incubations of vesicles made from jejunal tissue. When the sodium chloride was replaced by isosmotic amounts of mannitol no overshoot was observed in incubations of ileal vesicles until subsequent addition of sodium chloride to these incubations. These observations are in accord with the idea that those subcellular structural elements operating in the ileal bile salt transport system are associated with the brush border membranes of the ileal mucosal cells.     

Substrate specificity of the ileal and the hepatic Na(+)/bile acid cotransporters of the rabbit. I. Transport studies with membrane vesicles and cell lines expressing the cloned transporters.

The substrate specificity of the ileal and the hepatic Na(+)/bile acid cotransporters was determined using brush border membrane vesicles and CHO cell lines permanently expressing the Na(+)/bile acid cotransporters from rabbit ileum or rabbit liver. The hepatic transporter showed a remarkably broad specificity for interaction with cholephilic compounds in contrast to the ileal system. The anion transport inhibitor diisothiocyanostilbene disulfonate (DIDS) is a strong inhibitor of the hepatic Na(+)/bile acid cotransporter, but does not show any affinity to its ileal counterpart. Inhibition studies and uptake measurements with about 40 different bile acid analogues differing in the number, position, and stereochemistry of the hydroxyl groups at the steroid nucleus resulted in clear structure;-activity relationships for the ileal and hepatic bile acid transporters. The affinity to the ileal and hepatic Na(+)/bile acid cotransport systems and the uptake rates by cell lines expressing those transporters as well as rabbit ileal brush border membrane vesicles is primarily determined by the substituents on the steroid nucleus. Two hydroxy groups at position 3, 7, or 12 are optimal whereas the presence of three hydroxy groups decreased affinity. Vicinal hydroxy groups at positions 6 and 7 or a shift of the 7-hydroxy group to the 6-position significantly decreased the affinity to the ileal transporter in contrast to the hepatic system. 6-Hydroxylated bile acid derivatives are preferred substrates of the hepatic Na(+)/bile acid cotransporter. Surprisingly, the 3alpha-hydroxy group being present in all natural bile acids is not essential for high affinity interaction with the ileal and the hepatic bile acid transporter. The 3alpha-hydroxy group seems to be necessary for optimal transport of a bile acid across the hepatocyte canalicular membrane. A modification of bile acids at the 3-position therefore conserves the bile acid character thus determining the 3-position of bile acids as the ideal position for drug targeting strategies using bile acid transport pathways.     

Substrate specificity of the ileal and the hepatic Na(+)/bile acid cotransporters of the rabbit. II. A reliable 3D QSAR pharmacophore model for the ileal Na(+)/bile acid cotransporter

To design a reliable 3D QSAR model of the intestinal Na(+)/bile acid cotransporter, we have used a training set of 17 inhibitors of the rabbit ileal Na(+)/bile acid cotransporter. The IC(50) values of the training set of compounds covered a range of four orders of magnitude for inhibition of [(3)H]cholyltaurine uptake by CHO cells expressing the rabbit ileal Na(+)/bile acid cotransporter allowing the generation of a pharmacophore using the CATALYST algorithm. After thorough conformational analysis of each molecule, CATALYST generated a pharmacophore model characterized by five chemical features: one hydrogen bond donor, one hydrogen bond acceptor, and three hydrophobic features. The 3D pharmacophore was enantiospecific and correctly estimated the activities of the members of the training set. The predicted interactions of natural bile acids with the pharmacophore model of the ileal Na(+)/bile acid cotransporter explain exactly the experimentally found structure;-activity relationships for the interaction of bile acids with the ileal Na(+)/bile acid cotransporter (Kramer et al. 1999. J. Lipid. Res. 40: 1604;-1617). The natural bile acid analogues cholyltaurine, chenodeoxycholyltaurine, or deoxycholyltaurine were able to map four of the five features of the pharmacophore model: a) the five-membered ring D and the methyl group at position 18 map one hydrophobic site and the 21-methyl group of the side chain maps a second hydrophobic site; b) one of the alpha-oriented hydroxyl groups at position 7 or 12 fits the hydrogen bond donor feature; c) the negatively charged side chain acts as hydrogen bond acceptor; and d) the hydroxy group at position 3 does not specifically map any of the five binding features of the pharmacophore model. The 3-hydroxy group of natural bile acids is not essential for interactions with ileal or hepatic Na(+)/bile acid cotransporters. A modification of the 3-position of a natural bile acid molecule is therefore the preferred position for drug targeting strategies using bile acid transport pathways.     

Identification of a ligand-binding site in the Na+/bile acid cotransporting protein from rabbit ileum.

Reabsorption of bile acids occurs in the terminal ileum by a Na(+)-dependent transport system composed of several subunits of the ileal bile acid transporter (IBAT) and the ileal lipid-binding protein. To identify the bile acid-binding site of the transporter protein IBAT, ileal brush border membrane vesicles from rabbit ileum were photoaffinity labeled with a radioactive 7-azi-derivative of cholyltaurine followed by enrichment of IBAT protein by preparative SDS gel electrophoresis. Enzymatic fragmentation with chymotrypsin yielded IBAT peptide fragments in the molecular range of 20.4-4 kDa. With epitope-specific antibodies generated against the C terminus a peptide of molecular mass of 6.6-7 kDa was identified as the smallest peptide fragment carrying both the C terminus and the covalently attached radiolabeled bile acid derivative. This clearly indicates that the ileal Na(+)/bile acid cotransporting protein IBAT contains a bile acid-binding site within the C-terminal 56-67 amino acids. Based on the seven-transmembrane domain model for IBAT, the bile acid-binding site is localized to a region containing the seventh transmembrane domain and the cytoplasmic C terminus. Alternatively, assuming the nine-transmembrane domain model, this bile acid-binding site is localized to the ninth transmembrane domain and the C terminus.     

Identification and functional characterization of the bile acid transport proteins in non-mammalian ileum and mammalian liver

It has been proposed that intracellular carrier proteins mediate active transport of the bile acids within hepatocytes and ileocytes, during the enterohepatic circulation. In mammalian species only ileal bile acid binding proteins have been so far identified, while liver cytosolic carriers have never been found. On the contrary, in non-mammalian vertebrates, only liver, and not ileal, bile acid binding proteins were reported. The aim of the present work is to find the missing cytosolic transport proteins. A bioinformatic search allowed us to identify a non-mammalian putative bile acid binding protein in the chicken ileum (cI-BABP), which we recombinantly expressed and purified. The protein exhibits the capability, tested by in vitro NMR experiments, of binding bile acids. Furthermore, strong NMR evidence reported that the human liver fatty acid binding protein (hL-FABP) can also bind bile acids. Taken together, these data strongly suggest that both cI-BABP and hL-FABP have a bile acid binding function in the two organisms, and support a previous hypothesis on the role of hL-FABP in regulating bile acid metabolism and determining bile acid pool size.     

Bile salt-binding polypeptides in brush-border membrane vesicles from rat small intestine revealed by photoaffinity labeling

Photoaffinity labeling of small intestinal brush-border membrane vesicles with photolabile bile salt derivatives was performed to identify bile salt-binding polypeptides in these membranes. The derivatives used in this study were the sodium salts of 7,7-azo-3 alpha, 12 alpha-dihydroxy-5 beta-cholan-24-oic acid, 3 beta-azido-7 alpha, 12 alpha-dihydroxy-5 beta-cholan-24-oic acid, their respective taurine conjugates, and (11 xi-azido-12-oxo-3 alpha, 7 alpha-dihydroxy-5 beta-cholan-24-oyl)-2-aminoethanesulfonic acid. With ileal brush-border membrane vesicles, photoaffinity labeling resulted in the identification of 5 polypeptides with apparent molecular weights of 125,000, 99,000, 83,000, 67,000, and 43,000. The extent of labeling depended on the photolabile derivative employed. In jejunal brush-border membrane vesicles, polypeptides with apparent molecular weights of 125,000, 94,000, 83,000, 67,000, and 43,000 were labeled. The results indicate that the binding polypeptides involved in bile salt transport in ileal brush-border membrane vesicles are 1) similar with one exception to those concerned with bile salt transport in jejunal brush-border membranes, and 2) markedly different from those previously shown to be concerned with bile salt transport in plasma membranes of hepatocytes.     

Ligand specificity and conformational stability of human fatty acid-binding proteins.

Fatty acid binding proteins (FABPs) are small cytosolic proteins with virtually identical backbone structures that facilitate the solubility and intracellular transport of fatty acids. At least eight different types of FABP occur, each with a specific tissue distribution and possibly with a distinct function. To define the functional characteristics of all eight human FABPs, viz. heart (H), brain (B), myelin (M), adipocyte (A), epidermal (E), intestinal (I), liver (L) and ileal lipid-binding protein (I-LBP), we studied their ligand specificity, their conformational stability and their immunological crossreactivity. Additionally, binding of bile acids to I-LBP was studied. The FABP types showed differences in fatty acid binding affinity. Generally, the affinity for palmitic acid was lower than for oleic and arachidonic acid. All FABP types, except E-FABP, I-FABP and I-LBP interacted with 1-anilinonaphtalene-8-sulphonic acid (ANS). Only L-FABP, I-FABP and M-FABP showed binding of 11-((5-dimethylaminonaphtalene-1-sulfonyl)amino)undecanoic acid (DAUDA). I-LBP showed increasing binding of bile acids in the order taurine-conjugated>glycine-conjugated>unconjugated bile acids. A hydroxylgroup of bile acids at position 7 decreased and at position 12 increased the binding affinity to I-LBP. The fatty acid-binding affinity and the conformation of FABP types were differentially affected in the presence of urea. Our results demonstrate significant differences in ligand binding, conformational stability and surface properties between different FABP types which may point to a specific function in certain cells and tissues. The preference of I-LBP (but not L-FABP) for conjugated bile acids is in accordance with a specific role in bile acid reabsorption in the ileum.     

Liver-specific drug targeting by coupling to bile acids.

Bile acids are selectively taken up from portal blood into the liver by specific transport systems in the hepatocyte plasma membrane. Therefore, studies were performed to evaluate the potential of bile acids as shuttles to deliver drugs specifically to the liver. The alkylating cytostatic drug chlorambucil and the fluorescent prolyl-4-hydroxylase inhibitor 4-nitrobenzo-2-oxa-1,3-diazol-beta-Ala-Phe-5-oxaproline-Gly were covalently linked via an amide bond to 7 alpha, 12 alpha,-dihydroxy-3 beta- (omega-aminoalkoxy)-5-beta-cholan-24-oic acid. The chlorambucil-bile acid conjugates S 2521, S 2539, S 2567, and S 2576 inhibited Na(+)-dependent [3H]taurocholate uptake in a concentration-dependent manner both into isolated rat hepatocytes and rabbit ileal brush border membrane vesicles, whereas the parent drug chlorambucil showed no significant inhibitory effect. The chlorambucil-bile acid conjugates were able to prevent photoaffinity labeling of bile acid binding proteins in rat hepatocytes by the photolabile [3H]7,7-azo derivative of taurocholic acid indicating their bile acid character. The chlorambucil-bile acid conjugate S 2577 was able to alkylate proteins demonstrating the drug character conserved in the hybrid-molecules. Liver perfusion experiments revealed a secretion profile of the chlorambucil-bile acid conjugate S 2576 into bile very similar to taurocholate compared to chlorambucil which is predominantly excreted by the kidney. 4-Nitrobenzo-2-oxa-1,3-diazol-beta-Ala-Phe-5-oxaproline-Gly- t-butylester (S 4404), a fluorescent peptide inhibitor of prolyl-4-hydroxylase, was not transported in intact form from portal blood into bile in contrast to its bile acid conjugate S 3744; about 25% of the peptide-bile acid conjugate S 3744 was secreted in intact form into bile within 40 min compared with less than 4% of the parent oxaprolylpeptide S 4404. In conclusion, these studies reveal that modified bile acid molecules can be used as "Trojan horses" to deliver a drug molecule specifically into the liver and the biliary system. This offers important pharmacological options for the development of liver-specific drugs.     

Effect of antiserum to a 99 kDa polypeptide on the uptake of taurocholic acid by rat ileal brush border membrane vesicles

A 99 kDa polypeptide in rat ileal brush border membrane (BBM), regarded as a component of the active bile acid transport system on account of photoaffinity labeling, has been purified by affinity chromatography and preparative gel electrophoresis and utilized as an immunogen for raising polyclonal antibody. Immune serum, but not preimmune serum, specifically recognized a single band of 99 kDa protein on immunoblots of ileal and renal BBM. In contrast, no reactivity was observed with proteins in jejunal BBM. This polyclonal antibody, compared with preimmune serum and anticytosolic bile acid binding protein (14 kDa) serum, significantly inhibited the Na+ dependent uptake of [3H] taurocholate by BBM vesicles (p less than 0.01). [14C] D-glucose uptake by BBM vesicles was not influenced by the immune serum (p less than 0.01). Thus, these studies provide further support for the specific role of a 99 kDa protein in ileal BBM bile acid transport.     

Multiple transport pathways for neutral amino acids in rabbit jejunal brush border vesicles

Amino acids enter rabbit jejunal brush border membrane vesicles via three major transport systems: (1) simple passive diffusion; (2) Na-independent carriers; and (3) Na-dependent carriers. The passive permeability sequence of amino acids is very similar to that observed in other studies involving natural and artificial membranes. Based on uptake kinetics and cross-inhibition profiles, at least two Na-independent and three Na-dependent carrier-mediated pathways exist. One Na-independent pathway, similar to the classical L system, favors neutral amino acids, while the other pathway favors dibasic amino acids such as lysine. One Na-dependent pathway primarily serves neutral L-amino acids including 2-amino-2-norbornanecarboxylic acid hemihydrate (BCH), but not beta-alanine or alpha-methylaminoisobutyric acid (MeAIB). Another Na-dependent route favors phenylalanine and methionine, while the third pathway is selective for imino acids and MeAIB. Li is unable to substitute for Na in these systems. Cross-inhibition profiles indicated that none of the Na-dependent systems conform to classical A or ACS paradigms. Other notable features of jejunal brush border vesicles include (1) no beta-alanine carrier, and (2) no major proline/glycine interactions.     

In vivo antibody-mediated modulation of aminopeptidase A in mouse proximal tubular epithelial cells.

Aminopeptidase A (APA) is one of the many renal hydrolases. In mouse kidney, APA is predominantly expressed on the brush borders and sparsely on the basolateral membranes of proximal tubular epithelial cells. However, when large amounts of monoclonal antibodies (MAbs) against APA were injected into mice, we observed strong binding of the MAbs to the basolateral membranes, whereas the MAbs bound only transiently to the brush borders of the proximal tubular epithelial cells. In parallel, APA itself disappeared from the brush borders by both endocytosis and shedding, whereas it was increasingly expressed on the basolateral sides. Using ultrastructural immunohistology, we found no evidence for transcellular transport of endocytosed APA to the basolateral side of the proximal tubular epithelial cells. The absence of transcellular transport was confirmed by experiments in which we used a low dose of the MAbs. Such a low dose did not result in binding of the MAbs to the brush borders and had no effect on the presence of APA in the brush borders of the proximal tubular epithelial cells. In these experiments we still could observe binding of the MAbs to the basolateral membranes in parallel with the local appearance of APA. In addition, treatment of mice with chlorpromazine, a calmodulin antagonist that interferes with cytoskeletal function, largely inhibited the MAb-induced modulation of APA. Our studies suggest that injection of MAbs to APA specifically interrupts the normal intracellular traffic of this enzyme in proximal tubular epithelial cells. This intracellular transport is dependent on the action of cytoskeletal proteins.     

Jejunal and ileal D-glucose transport in isolated brush border membranes.

D-Glucose transport was investigated in isolated brush border membranes from small intestine. The transport properties of membranes from upper jejunum were compared with those from terminal ileum. The jejunal membranes accumulate D-glucose to a greater extent than the ileal membranes when supplied with energy in the form of a NaSCN gradient. This difference in behavior is similar to that of the more intact epithelial preparations and suggests that the isolated membranes actually reflect the state present in intact cells. Ileal membranes transported D-glucose about two to three times slower than the jejunal ones, which can partially explain the lower sugar accumulation.     

Jejunal and ileal d-glucose transport in isolated brush border membranes

d-Glucose transport was investigated in isolated brush border membranes from small intestine. The transport properties of membranes from upper jejunum were compared with those from terminal ileum. The jejunal membranes accumulated d-glucose to a greater extent than the ileal membranes when supplied with energy in the form of a NASCN gradient. This difference is behavior is similar to that of the more intact epithelial preparations and suggests that the isolated membranes actually reflect the state present in intact cells. Ileal membranes transported d-glucose about two to three times slower than the jejunal ones, which can partially explain the lower sugar accumulation.     

Steroid ring hydroxylation patterns govern cooperativity in human bile acid binding protein

Human ileal bile acid binding protein (I-BABP) is a member of the intracellular lipid binding protein family. This protein is thought to function in the transcellular transport and enterohepatic circulation of bile salts. Human I-BABP binds two molecules of glycocholate, the physiologically most abundant bile salt, with modest intrinsic affinity but a remarkably high degree of positive cooperativity. Here we report a calorimetric analysis for the binding of a broad panel of bile salts to human I-BABP. The interaction of I-BABP with nine physiologically relevant derivatives of cholic acid, chenodeoxycholic acid, and deoxycholic acid in their conjugated (glycine and taurine) and unconjugated forms was monitored by isothermal titration calorimetry. All bile salts bound to I-BABP with a 2:1 stoichiometry and similar overall affinity, but the derivatives of cholic acid displayed much higher Hill coefficients, a measure of macroscopic positive cooperativity. To test whether the cooperativity was dependent on individual structural features of the bile salt side chain, a series of side-chain-extended bile salts that lacked a hydrogen bond donor or acceptor at C-24 were chemically synthesized. These synthetic variants exhibited the same energetic and cooperativity profile as the naturally occurring bile salts. Our findings indicate that cooperativity in bile salt-I-BABP recognition is governed by the pattern of steroid B- and C-ring hydroxylation and not the presence or type of side-chain conjugation.