Membrane topology and cell surface targeting of microsomal epoxide hydrolase. Evidence for multiple topological orientations.

Microsomal epoxide hydrolase (mEH) is a bifunctional membrane protein that plays a central role in the metabolism of xenobiotics and in the hepatocyte uptake of bile acids. Numerous studies have established that this protein is expressed both in the endoplasmic reticulum and at the sinusoidal plasma membrane. Preliminary evidence has suggested that mEH is expressed in the endoplasmic reticulum (ER) membrane with two distinct topological orientations. To further characterize the membrane topology and targeting of this protein, an N-glycosylation site was engineered into mEH to serve as a topological probe for the elucidation of the cellular location of mEH domains. The cDNAs for mEH and this mEH derivative (mEHg) were then expressed in vitro and in COS-7 cells. Analysis of total expressed protein in these systems indicated that mEHg was largely unglycosylated, suggesting that expression in the ER was primarily of a type I orientation (Ccyt/Nexo). However, analysis, by biotin/avidin labeling procedures, of mEHg expressed at the surface of transfected COS-7 cells, showed it to be fully glycosylated, indicating that the topological form targeted to this site originally had a type II orientation (Cexo/Ncyt) in the ER. The surface expression of mEH was also confirmed by confocal fluorescence scanning microscopy. The sensitivity of mEH topology to the charge at the N-terminal domain was demonstrated by altering the net charge over a range of 0 to +3. The introduction of one positive charge led to a significant inversion in mEH topology based on glycosylation site analysis. A truncated form of mEH lacking the N-terminal hydrophobic transmembrane domain was also detected on the extracellular surface of transfected COS-7 cells, demonstrating the existence of at least one additional transmembrane segment. These results suggest that mEH may be integrated into the membrane with multiple transmembrane domains and is inserted into the ER membrane with two topological orientations, one of which is targeted to the plasma membrane where it mediates bile acid transport.

The functional expression of sodium-dependent bile acid transport in Madin-Darby canine kidney cells transfected with the cDNA for microsomal epoxide hydrolase.

Previous studies have suggested that the enzyme microsomal epoxide hydrolase (mEH) is able to mediate sodium-dependent transport of bile acids such as taurocholate into hepatocytes (von Dippe, P., Amoui, M., Alves, C., and Levy, D.(1993) Am. J. Physiol. 264, G528-G534). In order to characterize directly the putative transport properties of the enzyme, a pCB6 vector containing the cDNA for this protein (pCB6-mEH) was transfected into Madin-Darby canine kidney (MDCK) cells, and stable transformants were isolated that could express mEH at levels comparable with the levels expressed in hepatocytes. Sodium-dependent transport of taurocholate was shown to be dependent on the expression of mEH and to be inhibited by the bile acid transport inhibitor 4,4'-diisothiocyanostilbene-2,2'disulfonic acid (DIDS), as well as by other bile acids. Kinetic analysis of this system indicated a Km of 26.3 microM and a Vmax of 117 pmol/mg protein/min. The Km value is essentially the same as that observed in intact hepatocytes. The transfected MDCK cells also exhibited sodium-dependent transport of cholate at levels 150% of taurocholate in contrast to hepatocytes where cholate transport is only 30% of taurocholate levels, suggesting that total hepatocyte bile acid transport is a function of multiple transport systems with different substrate specificities, where mEH preferentially transports cholate. This hypothesis is further supported by the observation that a monoclonal antibody that partially protects (26%) taurocholate transport from inhibition by DIDS in hepatocytes provides almost complete protection (88%) from DIDS inhibition of hepatocyte cholate transport, suggesting that taurocholate is also taken up by an alternative system not recognized by this antibody. Additional support for this concept is provided by the observation that the taurocholate transport system is almost completely protected (92%) from DIDS inhibition by this antibody in MDCK cells that express mEH as the only bile acid transporter. These results demonstrate that mEH is expressed on the surface of hepatocytes as well as on transfected MDCK cells and is able to mediate sodium-dependent transport of taurocholate and cholate.

Bile acid transport into hepatocyte smooth endoplasmic reticulum vesicles is mediated by microsomal epoxide hydrolase, a membrane protein exhibiting two distinct topological orientations.

Bile acids, such as taurocholate, have been shown to be transported into hepatocyte smooth endoplasmic reticulum (SER) vesicles. This process is Na(+)-independent, electrogenic, inhibitable by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid and taurochenodeoxycholate, with a Km of 352 microM and a Vmax of 29.6 nmol/mg protein/min. The observed transport is mediated by the bifunctional protein, microsomal epoxide hydrolase (mEH) which can also mediate bile acid transport into hepatocytes across the sinusoidal plasma membrane (von Dippe, P., Amoui, M., Alves, C., and Levy, D. (1993) Am. J. Physiol. 264, G528-G534). mEH was isolated from SER membranes by immunoprecipitation with monoclonal antibody (mAb) 25D-1 which recognizes this protein on the surface of intact hepatocytes. The SER-derived protein exhibited an apparent molecular weight, isoelectric point, N-terminal amino acid sequence, and mEH-specific activity that were indistinguishable from the plasma membrane form of the enzyme. Proteoliposome reconstitution of the SER taurocholate transport system indicated that mEH was absolutely required for the expression of transport capacity. The interaction of mAb 25D-1 with mEH on intact right-side-out SER vesicles demonstrated that the epitope found on the surface of hepatocytes was also found on the cytoplasmic surface of these vesicles (80%) and in the lumen (20%) suggesting the presence of two forms of this protein in the SER, the latter from being sorted to the cell surface. The existence of two orientations of this protein in the SER was confirmed by the sensitivity to tryptic digestion, where 75% of the mAb epitope was accessible to the enzyme. The loss of the 25D-1 epitope correlated with loss of taurocholate transport capacity. The role of mEH in the transport process and the orientation of the transporting isoform was further established by demonstrating that mAb 25A-3, which also reacts with mEH on the hepatocyte surface, was able to directly inhibit taurocholate transport in the SER vesicle system. These and previous results thus establish that isoforms of mEH can mediate taurocholate transport at the sinusoidal plasma membrane and in SER vesicles and that this bifunctional protein can exist in two orientations in the SER membrane. The association of bile acids with the SER suggests a possible role of intracellular vesicles in the transhepatocellular movement of bile acids from the sinusoidal to the canalicular compartment.

Na(+)-dependent bile acid transport by hepatocytes is mediated by a protein similar to microsomal epoxide hydrolase.

A protein mediating hepatocyte sodium-dependent bile acid transport across the sinusoidal plasma membrane has been purified by immunoprecipitation with monoclonal antibody (MAb) 25D-1, which specifically recognizes this protein on the surface of intact hepatocytes (Ananthanarayanan et al. J. Biol. Chem. 263: 8338-8343, 1988). The function of this protein was further established by proteoliposome reconstitution (von Dippe et al. J. Biol. Chem. 265: 14812-14816, 1990). NH2-terminal amino acid sequence analysis and amino acid composition revealed this protein to be closely related to the enzyme microsomal epoxide hydrolase (mEH). Both proteins exhibited the same elution times on a reverse-phase high-pressure liquid chromatography column, comigrated with an apparent molecular weight of 49,000 as measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and possessed identical isoelectric points of 8.2. The MAb was capable of immunoprecipitating chromatographically purified mEH, as well as a protein derived from the sinusoidal plasma membrane that exhibited mEH activity comparable to that of the protein isolated from the endoplasmic reticulum. The subtilisin fragmentation patterns derived from chromatographically purified mEH and the MAb-precipitated plasma membrane protein were also identical. Hydropathy profile analysis of the amino acid sequence of mEH suggested the presence of four transmembrane domains. The results of these studies indicate that a protein that is involved in mediating sodium-dependent bile acid transport is closely related to mEH.

Reconstitution of the immunopurified 49-kDa sodium-dependent bile acid transport protein derived from hepatocyte sinusoidal plasma membranes.

Reconstitution, using phosphatidylcholine liposomes in conjugation with immunological purification procedures, has been used to establish directly the identity of the hepatocyte Na(+)-dependent bile acid transport protein. Octyl glucoside-solubilized sinusoidal plasma membranes were shown to form proteoliposomes exhibiting taurocholate transport properties which were similar to those of plasma membrane vesicles, namely, Na(+)-dependence and marked inhibition by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid and by taurochenodeoxycholate. Proteoliposomes formed from plasma membrane proteins depleted of the putative 49-kDa bile acid transport protein by immunoprecipitation with monoclonal antibody 25D-1, which specifically recognizes this protein (Ananthanarayanan, M., von Dippe, P., and Levy, D. (1988) J. Biol. Chem. 263, 8338-8343), showed a 94% reduction in mediated transport capacity. Proteoliposomes containing total membrane protein also demonstrated Na(+)-dependent alanine transport. The addition of taurochenodeoxycholate or the removal of the 49-kDa protein by monoclonal antibody 25D-1 immunoprecipitation had no effect on the uptake of alanine, thus confirming the specificity of these procedures. When only the immunoprecipitated 48-kDa protein was used in the reconstitution system, a 2200% increase of taurocholate uptake was observed. These results definitively establish that this 49-kDa sinusoidal membrane protein is the sole essential component of the Na(+)-dependent bile acid transport system.

Expression of the bile acid transport protein during liver development and in hepatoma cells.

The expression of the hepatocyte Na(+)-dependent bile acid transport protein during liver development and in hepatoma cells has been characterized using a monoclonal antibody (mAb 25D-1) which specifically recognizes this 49-kDa carrier system. mAb binding studies demonstrated a greatly reduced concentration of this transport protein on the surface of hepatoma tissue culture (HTC) cells, a result consistent with the greater than 95% reduction in bile acid transport capacity when compared with normal adult hepatocytes. Immunoprecipitation procedures with 25D-1 were utilized to quantitate the presence of this transport protein in HTC cells as well as in adult hepatocytes that had been labeled with [35S]methionine or Na125I. These studies indicate that the 49-kDa transport protein is not expressed either on the surface or in any intracellular compartment in HTC cells. mAb binding to fetal cells (day 17) also indicated a greatly decreased number of transport molecules in the plasma membrane. Total cell content of this carrier protein during the next 7 weeks of liver development, as measured by immunoprecipitation, increased in a linear fashion reaching 92% of the adult level at 4 weeks after birth, which parallels the increase in transport function. These results demonstrate that bile acid transport capacity is directly related to the level of expression of this 49-kDa membrane protein.

Identification of the hepatocyte Na+-dependent bile acid transport protein using monoclonal antibodies.

Monoclonal antibodies have been utilized to characterize the hepatocyte Na+-dependent bile acid transport system. Sinusoidal plasma membrane proteins in the 49-54-kDa range, which are thought to be components of this transport system, based on photo-affinity labeling and reconstitution studies, have been partially purified by affinity chromatography and utilized as an immunogen for the production of a panel of monoclonal antibodies (mAb). One of these mAbs, 25A-3, recognized both a 49- and a 54-kDa protein as assessed by immunoprecipitation. In addition, it was shown to protect the bile acid transport system from inhibition by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) in a dose-dependent manner. DIDS covalently labeled membrane proteins of 49 and 54 kDa, and this process could be significantly inhibited when performed in the presence of mAb 25A-3. Furthermore, the DIDS-labeled membrane proteins were immunoprecipitated by 25A-3. These results establish that one of these membrane components is the bile acid carrier protein. Another mAb (25D-1) which immunoprecipitated only a 49-kDa protein was shown to block the protective effect of 25A-3 on DIDS inhibition of bile acid transport. In addition both antibodies effected each other's binding capacity to hepatocytes and reacted with the same 49-kDa protein as established by sequential immunoprecipitation. Binding studies indicated that there are approximately 3.3 X 10(6) 49-kDa transport molecules/hepatocyte. These results firmly establish that the 49-kDa protein is the Na+-dependent hepatocyte bile acid transporter.

Purification and reconstitution of the bile acid transport system from hepatocyte sinusoidal plasma membranes.

The taurocholic acid transport system from hepatocyte sinusoidal plasma membranes has been studied using proteoliposome reconstitution procedures. Membrane proteins were initially solubilized in Triton X-100. Following detergent removal, the resultant proteins were incorporated into lipid vesicles prepared from soybean phospholipids (asolectin) using sonication and freeze-thaw procedures. The resultant proteoliposomes demonstrated Na+-dependent transport of taurocholic acid which could be inhibited by bile acids. Greatly reduced amounts of taurocholic acid were associated with the phospholipid or membrane proteins alone prior to proteoliposome formation. Membrane proteins were fractionated on an anionic glycocholate-Sepharose 4B affinity column which was prepared by coupling (3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-cholan-24-oyl)-N alpha-lysine to activated CH-Sepharose 4B via the epsilon-amino group of lysine resulting in the retention of a free carboxyl group. The adsorbed proteins enriched in components in the 54 kDa zone, which were originally identified by photoaffinity labeling to be components of the bile acid transport system, were also incorporated into liposomes. This vesicle system showed almost a 4-fold increase in Na+-dependent taurocholic acid uptake when compared to proteoliposomes formed from total membrane protein, as well as sensitivity to inhibition by bile acids. These results demonstrate that the bile acid carrier system can be reconstituted in proteoliposomes and that utilizing proteins in the 54 kDa zone leads to a significant enhancement in the transport capacity of the reconstituted system, consistent with the role of 54 kDa protein(s) as component(s) of the bile acid carrier system.

Characterization of the bile acid transport system in normal and transformed hepatocytes. Photoaffinity labeling of the taurocholate carrier protein.

The taurocholate transport system in normal and transformed hepatocytes has been characterized using transport kinetics and photoaffinity labeling procedures. A photoreactive diazirine derivative of taurocholate, (7,7-azo-3 alpha,12 alpha-dihydroxy-5 beta-cholan-24-oyl)-2-amino [ 1,2-3H ]ethanesulfonic acid (7-ADTC), which has been shown to be a substrate for the bile acid carrier system, was photolyzed in the presence of intact hepatocytes, hepatoma tissue culture (HTC) cells, and plasma membranes derived from the hepatocyte sinusoidal surface. Irradiation of membranes in the presence of 7-ADTC resulted in the incorporation of the photoprobe into two proteins with Mr = 68,000 and 54,000. The specificity of labeling was confirmed by the significant inhibition of labeling observed when photolysis was carried out in the presence of taurocholate. The 68,000-Da protein was easily extracted with water and was shown to exhibit electrophoretic properties identical with rat serum albumin. The 54,000-Da protein required Triton X-100 for solubilization, indicating a strong association with the plasma membrane. Labeling of intact hepatocytes also resulted in specific labeling of the 54,000-Da protein. In contrast to hepatocytes, HTC cells derived from Morris hepatoma 7288C as well as H4-II-E cells derived from Reuber hepatoma H-35 exhibited a total loss of mediated bile acid uptake. Photolysis of 7-ADTC in the presence of HTC cells did not result in the labeling of any proteins, a result consistent with the loss of transport activity, and further supporting the specificity of the labeling reaction. The anion transport inhibitor N-(4-azido-2-nitrophenyl)-2-aminoethyl-[ 35S ]sulfonate, which has been shown to be a substrate for the bile acid carrier system also labeled the 54,000-Da plasma membrane protein when photolyzed in the presence of intact hepatocytes. These results suggest that the 54,000-Da protein is a component of the hepatocyte bile acid transport system and that the activity of this system is greatly reduced in several hepatoma cell lines.

Synthesis and transport characteristics of photoaffinity probes for the hepatocyte bile acid transport system.

In an effort to characterize the hepatocyte bile acid transport system, a photoreactive derivative of taurocholate, (7,7-azo-3 alpha,12 alpha-dihydroxy-5 beta-cholan-24-oyl)-2-aminoethanesulfonic acid (7-ADTC) has been synthesized and its transport properties compared to those of the natural substrate. Both the bile acid and its synthetic analog were shown to be transported against an electrochemical gradient as well as a chemical gradient. Transport as a function of concentration and the presence of sodium indicated that both substrates were taken up by a sodium-dependent and a sodium-independent route. Taurocholate had Km values of 26 and 57 microM and Vmax values of 0.77 and 0.15 nmol/mg of protein/min, respectively. In comparison, 7-ADTC had very similar kinetic properties with Km values of 25 and 31 microM and Vmax values of 1.14 and 0.27 nmol/mg of protein/min. Each compound was shown to inhibit competitively the transport of the other, suggesting that these substrates utilized a common membrane carrier. The transport properties of the photoreactive anion transport inhibitor, N-(4-azido-2-nitrophenyl)-2-aminoethylsulfonate (NAP-taurine) were also characterized in the hepatocyte system. Transport occurred via a sodium-dependent and a sodium-independent route with Km values of 210 and 555 microM and Vmax values of 0.57 and 1.62 nmol/mg of protein/min. As in the case of 7-ADTC, NAP-taurine and taurocholate were also shown to be mutual competitive inhibitors. In the absence of light, 7-ADTC was a reversible inhibitor of taurocholate uptake. Upon irradiation, irreversible photoinactivation of the taurocholate uptake system was observed. These results indicate that 7-ADTC and NAP-taurine can be utilized as photoaffinity probes for the identification of the bile acid carrier protein(s) in hepatocyte plasma membranes.

The effect of ether stress and cycloheximide treatment on cholesterol binding and enzyme turnover of adrenal cortical cytochrome P450scc.

Relative rate constants for the formation of pregnenolone from cytochrome P450scc bound cholesterol in adrenal cortical mitochondria of stressed, stressed plus cycloheximide treated and dexamethasone treated rats were calculated from the ratios of initial rates of pregnenolone formation and the pregnenolone induced difference spectrum. In mitochondria from adrenals removed under aerobic conditions in vivo, the rate constant for the enzyme in stressed rats is twice a high as the rate constant for the enzyme from the stressed plus cycloheximide group, and four times as high as that for the enzyme from dexamethasone treated rats. Anoxia for 5 min in the intact gland increases the rate constant in all groups. Pregnenolone difference spectra are higher in mitochondria from stressed plus cycloheximide treated rats than in mitochondria from stressed rats, when adrenals are removed aerobically. It is concluded that ACTH increases cholesterol binding to cytochrome P450scc, by increasing either the enzymes affinity for its substrate or the availability of cholesterol and in addition promotes turnover of the enzyme. Both of these effects of ACTH are inhibited by cycloheximide.

Analysis of the transport system for inorganic anions in normal and transformed hepatocytes.

The transport system for inorganic anions has been investigated in hepatocytes and hepatoma tissue culture cells. Sulfate transport in hepatocytes is temperature sensitive and occurs against an electrochemical gradient. Uptake was shown to occur by a sodium-dependent and a sodium-independent route with Km values of 2.3 and 33 mM and Vmax values of 2.1 and 10 nmol/mg of protein/min, respectively. An analysis of the sodium dependency indicates a Hill coefficient of 1.05 suggesting an equimolar stoichiometry for sodium and sulfate transport. The transport of sulfate was decreased by metabolic and sodium transport inhibitors. Bicarbonate was shown to effect the transport of sulfate, where uptake was accelerated by intracellular bicarbonate and competitively inhibited by extracellular bicarbonate. In addition, sulfate efflux was stimulated by extracellular bicarbonate. These results suggested that bicarbonate is a substrate for the sulfate transport system and can accelerate uptake and efflux by an anion exchange mechanism. Inhibition of bicarbonate uptake by extracellular sulfate and by the anion transport inhibitor 4,4'-diisothiocyano-2,2'-stilbene disulfonate demonstrates that bicarbonate does not enter the cell exclusively by CO2 diffusion but can be transported in part as an anionic species. These results are consistent with its role in the sulfate-bicarbonate exchange system. This inorganic anion transport system was shown to be inhibited by approximately 80% in hepatoma tissue culture cells where altered sodium dependency, Km, and Vmax values reflect possible alterations in the structure and/or membrane content of the carrier.

Mechanism of energy coupling for transport of deoxycytidine, uridine, uracil, adenine and hypoxanthine in Escherichia coli.

The transport processes for uridine, deoxycytidine, uracil, adenine and hypoxanthine require an energy source and are active under anaerobic or aerobic conditions. Inhibitory effects of cyanide, arsenate, carbonylcyanide m-chlorophenylhydrazone, 2,4-dinitrophenol and N,N'-dicyclohexylcarbodiimide on the transport of uridine and deoxycytidine differ from the corresponding effects on the transport of uracil, adenine and hypoxanthine. The nature of these inhibitory effects supports the conclusion that uridine and deoxycytidine transport is energized either by electron transport or by ATP hydrolysis via (Ca2+ + Mg2+)-ATPase. The transport or uracil, adenine and hypoxanthine is dependent upon ATP or some high energy phosphate derivative of ATP, but is independent of (Ca2+ + Mg+)-ATPase and electron transport. Uptake of the ribose moiety of uridine by a mutant of Escherichia coli B, which lacks the transport system for uracil and intact uridine, is neither stimulated by energy sources nor inhibited by various inhibitors of energy metabolism under either aerobic or anaerobic conditions.

Deoxycytidine transport in the presence of a cytidine deaminase inhibitor and the transport of uracil in Escherichia coli B.

Tetrahydrouridine, a cytidine deaminase inhibitor, prevents periplasmic degradation of deoxycytidine by Escherichia coli B. It does not inhibit deoxycytidine transport and therefore allows an accurate determination of deoxycytidine transport. Data obtained using tetrahydrouridine show that deoxycytidine is transported in E. coli B as the intact nucleoside by an active transport process, with a K-m of 6 times 10-minus 6 M. Cytidine and deoxyadenosine inhibit transport competitively, whereas guanosine has no effect on transport. Arsenate or KCN greatly reduces transport. In a mutant resistant to the nucleoside antibiotic, showdomycin, the active transport of deoxycytidine is lost, and residual slow uptake occurs by passive diffusion. Uracil is accumulated in E. coli B by an active transport process with a K-m of 5 times 10-minus 7 M.