Reconstitution of Bile Acid Transport in a Heterologous Cell by Cotransfection of Transporters for Bile Acid Uptake and Efflux*

(Received for publication, September 27, 1996, and in revised form, May 14, 1997)

C. Jeffrey Sippel Dagger §, Paul A. Dawson , Tianxiang Shen Dagger § and David H. Perlmutter Dagger §par **

From the Departments of Dagger  Pediatrics and par  Cell Biology and Physiology, Washington University School of Medicine, the § Division of Gastroenterology and Nutrition, St. Louis Children's Hospital, St. Louis, Missouri 63110 and the  Department of Internal Medicine, Bowman Gray School of Medicine, Wake Forest University, Winston-Salem, North Carolina 27157

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

The rat liver canalicular bile acid transporter/ecto-ATPase/cell CAM 105 (CBATP) is a 110-kDa transmembrane phosphoglycoprotein that is thought to have bile acid efflux, ecto-ATPase, and cell adhesion properties. Its extracellular amino-terminal domain is highly homologous to carcinoembryonic antigen (CEA), a glycophosphatidyl inositol-anchored membrane protein with cell adhesion properties and a marker for adenocarcinoma. In the current study, we examined the possibility of more clearly defining the role of CBATP in bile acid efflux by cotransfecting a heterologous cell, the COS cell, with cDNAs for a bile acid importer, the ileal bile acid transporter (IBAT), as well as for CBATP. The results show that when IBAT mediates uptake of [3H]taurocholate to a level 20-fold higher than that achieved previously by nonspecific pinocytosis, CBATP mediates time-, temperature- and concentration-dependent efflux. Efflux of [3H]taurocholate mediated by CBATP in the cotransfected COS cells is saturable and has curvilinear kinetic characteristics (Vmax = 400 pmol/mg protein/min, Km = 70 µM). It is inhibited by 4,4'-diisothiocyanostilbene-2,2-disulfonic acid and dependent on ATP but not dependent on membrane potential. Although CEA could not mediate bile acid efflux in COS cells cotransfected with IBAT and CEA, efflux of [3H]taurocholate was detected in COS cells cotransfected with IBAT and a chimeric molecule having the carboxyl-terminal tail and membrane spanning domain of CBATP and the amino-terminal extracellular tail of CEA. Taken together, these data provide further evidence that CBATP confers bile acid efflux properties on heterologous cells and that its cytoplasmic tail and membrane spanning segment are integral to this property. The data also establish a model system for more clearly defining the molecular determinants of bile acid transport mediated by this molecule.


INTRODUCTION

The net vectorial transport of bile acids into the biliary drainage system is the major determinant of bile secretion. Transport across the canalicular domain of the hepatocyte represents the rate-limiting step in this system. Studies in canalicular membrane vesicles have indicated that canalicular bile acid efflux is predominantly driven by ATP, but electrochemical membrane potential may also drive canalicular bile acid transport to a certain extent. Most data suggest that several distinct transporters, or transport systems, are involved (1-6).

The rat liver canalicular bile acid transport protein/ecto-ATPase/cell CAM 105 (CBATP)1 is one candidate for bile acid efflux activity at the canalicular membrane of hepatocytes. It is a ~110-kDa phosphoglycoprotein localized to the canalicular domain of hepatocytes. It was purified by bile acid affinity chromatography from detergent-solubilized rat liver canalicular membrane vesicles (7). Internal amino acid sequence analysis revealed it to be identical to the rat liver ecto-ATPase and to the cell adhesion molecule cell CAM 105. It has a carboxyl-terminal cytoplasmic tail of 71 amino acids, a single membrane-spanning domain, and a large extracellular amino-terminal tail of 423 amino acids, which has extensive homology with carcinoembryonic antigen (CEA) and the immunoglobulin supergene family. Transfection studies have shown that CBATP mediates ecto-ATPase, cell adhesion, and bile acid efflux activities in heterologous COS cells (8, 9). Mutagenesis studies have shown that R98 within an ATPase consensus sequence at the extreme amino terminus is required for ecto-ATPase activity and that the 108 amino acid amino-terminal domain is required for cell adhesion activity (10, 11). Deletion of the cytoplasmic tail is associated with loss of bile acid efflux, ecto-ATPase, and cell adhesion activities, even though the protein is appropriately localized to the external surface of the plasma membrane and can bind ATP (8, 9). Site-directed mutagenesis of phosphorylation consensus sequences in the cytoplasmic tail shows that protein kinase C-dependent phosphorylation of Ser503 is required for bile acid efflux activity, that tyrosine kinase-dependent phosphorylation of Tyr488 regulates bile acid efflux activity, but neither phosphorylation is necessary for ecto-ATPase activity. Finally, bile acid efflux activity of CBATP was found to be dependent on ATP, particularly extracellular ATP, but not on its own ecto-ATPase activity (12).

In these previous studies, the bile acid efflux activity of CBATP was demonstrated in transfected COS cells by first loading the cells with [3H]taurocholate via nonspecific pinocytosis using the approach that had been pioneered in studies of efflux of chemotherapeutic agents by the multidrug resistance gene products (MDR) (8). To get sufficient nonspecific uptake, the membrane potential of the transfected COS cells had to be clamped pharmacologically with valinomycin (8). Although this system allowed us to show that CBATP had bile acid efflux activity and that this could be proven by a number of genetic criteria, the assay was cumbersome and was not amenable to studying the role of membrane potential in bile acid efflux. To develop a more physiological system and a system that could be more easily manipulated pharmacologically, we have established a model system in which uptake of [3H]taurocholate is mediated by transfection of a cloned bile acid importer, IBAT, and efflux is assayed by cotransfection of CBATP cDNA.


MATERIALS AND METHODS

Plasmid Constructs

Wild-type and mutant rat CBATP constructs have been described previously (8, 10, 11). This includes pExp3, R98ACBATP, Y488F-CBATP, T502,S503A-CBATP, and truncated CBATP. The hamster IBAT construct (IBAT-44 final) has also been described previously (13). The CEA cDNA (gcg:humcea; Ref. 14), kindly provided by Thomas Barnett, was subcloned into the HindIII-XbaI site of pCDM8. Three new constructs, R98A CEA, CBATP-CEA chimera, and CBATP-R98ACEA chimera, were generated using the polymerase chain reaction overlap extension technique (15) and then subcloned into the pCDM8 vector.

For R98ACEA, the outside primers corresponded with nucleotides 85-100 and 993-1012 of CEA together with a spacer of four nucleotides, a new EcoRI restriction site, and a new BamHI restriction site (5'-TCATGAATTCAGAGGAGGACAGAGC-3'; 5'-GGCACGTATAGGATCCACTA-3'). The inside primers corresponded to nucleotides 393-416 of CEA (5'-CGCATACAGTGGTGCAGAGATAAT-3'; 5'-ATTATCTCTGCACCACTGTATGCG-3'). The resulting polymerase chain reaction fragment was subcloned into wild-type CEA in the pCDM8 vector, which had been digested previously with EcoRI/BamHI and purified away from the wild-type internal fragment.

For the CEA-CBAT chimera, the outside primers corresponded to nucleotides 1563-1585 of CEA and nucleotides 1628-1651 of CBATP together with new EcoRI and XbaI restriction sites, and the inside primers corresponded to nucleotides 2122-2136 of CEA (five amino acids just external to the membrane insertion site of CEA) and nucleotides 1316-1330 of CBATP (transmembrane domain of CBATP): outside primers (5'-CAGTGGCCACAGCAGGACTACAG-3; 5'-GAATTCTCTAGACTGGTGCAGTCAGCAGGACAGACA-3'); inside primers (5'-TGAGAGGCCAGAATTGACTGTGATGCTCTT-3'; 5'-AAGAGCATCACAGTCAATTCTGGCCTCTCA-3'). The resulting 0.95-kilobase polymerase chain reaction fragment was digested with BalI and XbaI and cloned into pBluescript together with a 1.5-kilobase BalI/EcoRI partial digest of wild-type CEA. The resulting insert was removed at HindIII/XbaI to be subcloned into pCDM8. A similar strategy was used for the CBATP-R98ACEA chimera using the R98ACEA construct described above. In each case, the constructs were characterized by restriction map analysis (16, 17) and by dideoxynucleotide sequencing (18) to confirm the construct and to exclude polymerase chain reaction sequence artifacts.

Cell Culture and Transfection

COS 1 cells were transfected by the DEAE-dextran method and used for experimental purposes 48 h after transfection (19). In specific experiments, cellular ATP was depleted by incubating transfected COS cells for 20 min at 37 °C in DMEM without glucose but supplemented with 20 mM 2-deoxyglucose and 10 mM sodium azide. Under these conditions, cellular concentrations of ATP could be lowered from 800-1200 µM to 6-8 µM, as determined by the ATP luciferase assay (20). Results were normalized for protein concentration as determined by the Lowry assay (21). Under these conditions, cell viability as determined by trypan blue exclusion (22) was not significantly different between these depleted cells and undepleted cells (data not shown).

Bile Acid Uptake Assay

Transfected Cos cells were incubated with DMEM supplemented with [3H]taurocholate in excess. At the end of the uptake period, cell monolayers were lysed in 1 N NaOH, and the cell lysates were subjected to scintillation counting. In separate experiments, the time, temperature, and concentration of [3H]taurocholate were varied to determine the optimal conditions for uptake.

Bile Acid Efflux Assay

Transfected Cos cells were incubated with [3H]taurocholate under optimal conditions for uptake. At the end of the uptake period, monolayers were washed extensively in PBS and incubated for specified time intervals in DMEM alone for the efflux period. In specified experiments, 5 µM ATP, 1 mM DIDS, and/or unlabeled taurocholate were added. Extracellular medium was harvested, and cell monolayers were lysed in 1 N NaOH. The extracellular medium and cell lysates were then subjected to scintillation counting. Counts in the extracellular medium were converted to picomoles on the basis of the specific activity of the initial [3H]taurocholate and then plotted as pmoles/milligram protein/minute. Kinetic data (Km and Vmax) were determined on the basis of the resulting curves.

Ecto-ATPase Assay

Ecto-ATPase activity was measured by a method described previously (23) 48 h after transfection.

Analytical Techniques

For Western blot analysis, antibody to CBATP was used in a protocol described previously (7). Methods described previously were also used for studies of biosynthesis (24), cell surface iodination (25), and immunoprecipitation followed by SDS-polyacrylamide gel electrophoresis/fluorography (24).


RESULTS

Cotransfection of COS Cells with IBAT and CBATP cDNA

We determined the conditions under which uptake of [3H]taurocholate was saturated in COS cells transfected with IBAT alone or IBAT and CBATP cDNA together. To determine the duration of time necessary for saturation of uptake, transfected COS cells were incubated at 22 °C with [3H]taurocholate, 400 µM, for several different time intervals (Fig. 1A). Cells were lysed in 1 N NaOH and subjected to scintillation counting. Uptake was time-dependent, reaching a plateau within 20 min. There was no significant difference between cells transfected with IBAT alone and cells transfected with IBAT and CBATP together. Then the transfected COS cells were incubated for 20 min with [3H]taurocholate, 400 µM, at several different temperatures (Fig. 1B). Uptake was temperature-dependent, reaching a plateau at 22 °C. There was no significant difference between cells transfected with IBAT alone and those transfected with IBAT and CBATP together. Next, the transfected COS cells were incubated for 20 min at 22 °C in [3H]taurocholate in several different concentrations (Fig. 1C). The results show that uptake was concentration-dependent, reaching a plateau between 200 and 400 µM. In COS cells transfected with IBAT and CBATP, there was a minimal decrease in the amount of uptake as compared with COS cells transfected with IBAT alone. This is probably due to efflux mediated by cotransfected CBATP. Efflux mediated by cotransfected CBATP does not have a more significant effect in Fig. 1C or any effect in Fig. 1, A and B, because these experiments were done in the absence of exogenous ATP. Because efflux mediated by CBATP is stimulated by exogenous ATP (see Fig. 3), this means that there will be minimal efflux mediated by CBATP during uptake studies done in the absence of exogenous ATP. Even when exogenous ATP is present, CBATP pumps [3H]taurocholate out of cells less efficiently than IBAT pumps [3H]taurocholate into cells. For uptake mediated by IBAT, Km congruent  23 µM and Vmax congruent  396 pmol/mg protein/min (13), and for efflux mediated by CBATP in the presence of exogenous ATP, Km congruent  70 µM and Vmax congruent  400 pmol/mg protein/min (Fig. 2A). When uptake of [3H]taurocholate was assayed in the presence of exogenous ATP (5 mM), there was ~40-50% reduction in uptake after 60 min in COS cells cotransfected with IBAT and CBATP as compared with COS cells transfected with IBAT alone (Fig. 1D).


Fig. 1. Uptake of [3H]taurocholate in transfected COS cells. Cells were transfected with IBAT cDNA alone (bullet ), IBAT and CBATP cDNAs together (open circle ), or vector alone (black-square), using conditions described previously. After 48 h, transfected cells were subjected to uptake assays. A, time dependence. Cells were incubated with 400 µM [3H]taurocholate at 22 °C for several different time intervals up to 60 min. B, temperature dependence. Cells were incubated with 400 µM [3H]taurocholate for 60 min at several different temperatures. C, concentration dependence. Cells were incubated at 22 °C for 60 min with [3H]taurocholate in several different concentrations. At the end of these incubations, the cells were rinsed extensively, homogenized, and subjected to scintillation counting. D, effect of ATP. Cells were incubated at 22 °C with 400 µM [3H]taurocholate for several different time intervals up to 60 min. This incubation was done in the absence or presence of 5 mM ATP. The results of three replicate samples at each data point are reported as mean ± 1.0 S.D. (bars). open circle , IBAT; bullet , IBAT + ATP; diamond , IBAT + CBATP; black-diamond , IBAT + CBATP + ATP.
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Fig. 3. Effect of ATP on bile acid efflux in cotransfected COS cells. Cells were cotransfected with IBAT and CBATP cDNA and studied 48 h later. At that time, the cells were incubated for 20 min at 22 °C with 400 µM [3H]taurocholate to load the cells as well as 20 mM 2-deoxyglucose and 10 mM sodium azide to deplete cellular ATP. Previous studies have shown that these conditions severely deplete cellular ATP levels but do not affect cell viability or one function of CBAT, its ecto-ATPase activity (20). These conditions did not significantly alter uptake of [3H]taurocholate (data not shown). The cells were then washed and incubated for 5 min at 22 °C with fresh unlabeled medium in the absence or presence of 1 mM DIDS and in absence or presence of ATP in several different concentrations. Results are reported as mean ± 1.0 S.D. (bars). Km congruent  10 µM; Vmax = 300 pmol/mg protein/min.
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Fig. 2. Efflux of [3H]taurocholate in transfected COS cells. Cells were transfected with IBAT cDNA alone, cotransfected with both IBAT and CBATP cDNA, or cotransfected with IBAT and the T502A, S503A mutant CBATP. A, concentration dependence. After 48 h, the cells were incubated for 60 min at 22 °C in DMEM supplemented with [3H]taurocholate in several different concentrations. The cells were then washed and incubated for 5 min at 22 °C in medium supplemented with 5 mM ATP in the absence or presence of 1 mM DIDS. The medium was then harvested; the cells were homogenized, and each was subjected to scintillation counting. There was no significant difference in the amount of counts present in the cells at the end of the uptake for cells transfected with IBAT alone (black-square), IBAT and CBATP (bullet ), or IBAT and T502A, S503A mutant CBATP (black-triangle). Vmax = 400 pmol/mg protein/min, Km = 70 µM. B, time dependence. After 48 h, the cells were incubated for 60 min at 22 °C with DMEM supplemented with 400 µM [3H]taurocholate. The cells were then washed and incubated at 22 °C in DMEM supplemented with unlabeled taurocholate (400 µM), 5 mM ATP in the absence (bullet ) or presence (black-triangle) of 1 mM DIDS for several different time intervals up to 10 min. The extracellular medium was then harvested; the cells were homogenized, and each was subjected to scintillation counting. The results are reported as relative percentage by comparing the counts in the specified sample to the total amount of counts taken up by the cells after 60 min of uptake. The results of three samples at each time point are reported as mean ± 1.0 S.D. (bars). IC, cell monolayers; EC, extracellular medium.
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Taken together, the experiments in Fig. 1 (A-C) show that uptake reaches a plateau at 200-400 µM in the cotransfected cells and establish a time of 20 min, temperature of 22 °C, and concentration of [3H]taurocholate of 400 µM as optimal for the subsequent studies. In each case, the uptake of [3H]taurocholate was 20-fold or more greater in COS cells transfected with IBAT alone or both IBAT and CBATP than untransfected COS cells and COS cells transfected with CBATP alone and pharmacologically clamped with valinomycin (8).

Next, we examined the possibility that CBATP mediated bile acid efflux under these conditions. For Fig. 2A, COS cells were transfected with IBAT alone, cotransfected with IBAT and CBATP, or cotransfected with IBAT and a mutant CBATP (T502A, S503A-CBATP). Our previous studies had shown that this mutant CBATP did not undergo protein kinase C-mediated phosphorylation and lacked bile acid efflux activity, even though it was appropriately targeted to the external surface of the plasma membrane (12). After 48 h, the cells were incubated at 22 °C for 60 min with [3H]taurocholate in several different concentrations. At the end of this time interval, the cells were washed extensively and incubated at 22 °C for 5 min in the absence of [3H]taurocholate, in the presence of ATP, and in the absence or presence of DIDS. Radioactivity appearing in the extracellular medium was determined by scintillation counting. The results show that there was DIDS-sensitive, concentration-dependent, and saturable efflux only in cells cotransfected with IBATP and CBATP, not in cells transfected with IBAT alone or cotransfected with IBAT and mutant T502A, S503A-CBATP. Efflux had curvilinear characteristics, with a Vmax of 400 pmol/mg protein/min and a Km of 70 µM. These values are similar to those obtained using our previous assay system. These values are also similar to values that have been reported previously in canalicular vesicle studies (17). For the studies shown in Fig. 2A, we also measured radioactivity remaining in cell lysates. The results were plotted as pmoles/mg protein/minute versus concentration of taurocholate and showed that disappearance from the cell had almost identical curvilinear characteristics, Km and Vmax values (data not shown) as observed in Fig. 2A for appearance in the extracellular medium. In both cases, however, we did not determine what proportion of taurocholate that is in the cells is freely available for efflux. Thus, the Km and Vmax values reported here must be considered estimates which apply only if all the taurocholate in the cell is freely available for efflux.

Next, we examined the time course of efflux mediated by CBATP (Fig. 2B). COS cells transfected with IBAT alone or cotransfected with IBAT and CBATP were incubated for 60 min at 22 °C with [3H]taurocholate 400 µM. At the end of this time interval, the cells were washed extensively and then incubated at 22 °C for several different time intervals in medium supplemented with unlabeled taurocholate (400 µM) and 5 mM ATP in the absence or presence of 1 mM DIDS. At the end of each time interval, the extracellular medium was harvested, and the cell monolayers were lysed for analysis by scintillation counting. Results are reported as a relative percentage using counts present in the cell lysate at time 0 as arbitrarily designated 100%. There was no difference in the counts present in the cell lysates at time 0 for cells transfected with IBAT alone or cells cotransfected with IBAT and CBATP. For cells cotransfected with IBAT and CBATP, the results show that there is time-dependent disappearance of radioactivity from the cells between time 0 and 5 min, coincident with the appearance of radioactivity in the extracellular medium. Almost 80% of the initial radioactivity has disappeared from the cells by 5 min of the chase period, and a similar percentage has appeared in the extracellular medium. The majority of this disappearance from cell monolayers and appearance in extracellular medium is DIDS-sensitive. There is, however, some radioactivity that leaks from the cells in the presence of DIDS. Interestingly, this DIDS-insensitive fraction has different kinetics, reaching a plateau within 3 min. For cells transfected with IBAT alone, there is some time-dependent disappearance of radioactivity from the cells and appearance of radioactivity in the extracellular medium. It is much less than that observed in the cotransfected cells. Only 30% of the initial radioactivity disappears, even by 10 min. This disappearance is completely insensitive to DIDS and is identical in magnitude and kinetics to the DIDS-insensitive fraction of the cotransfected cells, therefore providing evidence that it represents nonspecific diffusion. Unlabeled taurocholate was used in this experiment to optimize the chase effect, but similar results have been observed without unlabeled taurocholate (data not shown). Taken together, these studies show that CBATP can mediate specific, facilitated efflux of taurocholate in cotransfected COS cells and that its efflux properties can be detected more easily, over a longer duration of time and in the absence of the pharmacologic agent valinomycin originally used to promote nonspecific uptake of taurocholate by clamping the membrane potential.

Effect of ATP and Membrane Potential on Bile Acid Efflux in Cotransfected COS Cells

Now we could use this assay to examine the possibility that bile acid efflux mediated by CBATP is driven by ATP and/or membrane potential differences. COS cells were cotransfected with IBAT and CBATP and then, 48 h later, the cotransfected cells were incubated in 2-deoxyglucose and sodium azide under conditions associated with depletion of cellular ATP but without affecting cell viability. During this same 20-min interval, 400 µM [3H]taurocholate were also added to the medium for uptake studies. The cells were then washed extensively, and separate monolayers were incubated in the absence or presence of 1 mM DIDS and in the absence or presence of exogenous ATP in several different concentrations for an efflux assay of 5 min (Fig. 3). The results show that there is no efflux in the absence of ATP. It also shows that efflux is absolutely dependent on ATP. The effect of extracellular ATP is concentration-dependent and saturable with a Km congruent  10 µM and Vmax of 300 pmol/mg protein/min.

To determine whether the electrochemical potential of the membrane drives bile acid efflux activity mediated by CBATP, we examined the effect of clamping the membrane potential with valinomycin. Cells were cotransfected with IBAT and CBATP and then, 48 h later, incubated with 150 µM [3H]taurocholate in the absence and presence of DIDS and in the absence or presence of 100 µM valinomycin, an ionophore that clamps the membrane potential (8, 10, 11). Cells were then washed and incubated for an additional 5 min at 22 °C in buffer supplemented with 5 mM ATP. The results show that valinomycin does not inhibit bile acid efflux (data not shown). Taken together, these data indicate that bile acid efflux mediated by CBATP is dependent on ATP but not on the electrochemical membrane potential. Thus, it cannot account for electrogenic bile acid transport demonstrated previously in canalicular membrane vesicles (26-28).

Specificity of Bile Acid Efflux Mediated by CBATP in the Cotransfection Assay

To further examine the specificity of the bile acid efflux activity mediated by CBATP and to further establish the validity of the cotransfection assay, we examined a series of positive and negative controls in the assay. In each case, these controls, shown schematically on the basis of their presumed relationship to the plasma membrane in Fig. 4, were cotransfected with IBAT. The negative controls included a truncated CBATP construct in which 66 of the 71 amino acids in the cytoplasmic tail have been deleted and two constructs in which specific amino acids required for phosphorylation have been deleted, Y488F-CBATP and T502A, S503A-CBATP. These three constructs did not mediate bile acid efflux in our previous assay system (12). The R98A-CBATP construct represented a positive control. It has a mutation in the ectoplasmic ATPase consensus sequence, which abrogates ecto-ATPase activity but not bile acid efflux activity. We also used several new constructs based on the structure of CEA. CBATP shares extensive homology with CEA in its amino-terminal extracellular tail, particularly the extreme amino-terminal half of CEA. However, CEA lacks a membrane-spanning domain and cytoplasmic tail. It is linked to the membrane by a phosphatidylinositol-glycan moiety (29). Because our previous studies had shown that the bile acid efflux activity of CBATP depended on its cytoplasmic tail, we doubted that CEA would have bile acid efflux activity. We also generated a chimeric construct in which the cytoplasmic tail and membrane-spanning domain of CBATP were fused to the extracellular domain of CEA, a construct we called the CBATP-CEA chimera, predicting that it would now possess bile acid efflux activity. Finally, we generated two additional constructs that were based on the observation that CEA has an ATPase consensus sequence almost identical to that of CBATP and at the exact same distance from the amino terminus as in CBATP. For the last two constructs, we subjected the CEA construct and the CBATP-CEA chimeric construct to site-directed mutagenesis of Arg98 to alanine, the mutation that abrogated ecto-ATPase activity in CBATP. These constructs are referred to as R98A-CEA and CBATP-R98A-CEA.


Fig. 4. Schematic diagram of wild-type, mutant, and chimeric CBATP and CEA molecules. Wild-type CBATP has cytoplasmic (CYT) and transmembrane (TM) domains. Wild-type CEA is linked to the membrane by a phosphatidylinositol-glycan moiety (M). N, the amino-terminal immunoglobulin V-like region. A1, A2, A3, B1, B2, and B3, immunoglobulin C-like regions.
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We examined the expression of all of these mutants after transfection of COS cells by Western blot analysis, immunoprecipitation after metabolic labeling, and immunoprecipitation after cell surface labeling using antibodies to CBATP and CEA. In Western blot analysis (Fig. 5A), we detected equivalent amounts of an ~180-kDa polypeptide for CEA, R98A-CEA, CBATP-CEA, and CBATP-R98A-CEA and ~110-kDa polypeptide for R98A-CBATP, Y488F-CBATP, T502, S503-CBATP, and wild-type CBATP. There was an equivalent amount of a ~100-kDa polypeptide for truncated CBATP but no polypeptide detected for vector alone (CON). These results showed that cotransfected COS cells expressed an approximately equivalent steady-state level of the wild-type, chimeric, and mutant CEA and CBATP molecules. Cotransfected COS cells were also pulse-labeled with [35S]methionine for 3 h, and the resulting radiolabeled cell lysates were subjected to immunoprecipitation followed by SDS-polyacrylamide gel electrophoresis/fluorography (Fig. 5B). Polypeptides of ~180 kDa were detected in similar amounts in COS cells cotransfected with IBAT and wild-type, chimeric, and mutant CEA cDNAs. Similar amounts of ~100- and 110-kDa polypeptides were detected in COS cells cotransfected with IBAT and wild-type or mutant CBATP. Polypeptides of ~90 and ~100 kDa were detected in similar amounts for truncated CBATP. The biochemical nature of the faster migrating ~100-kDa polypeptide for wild-type and mutant CBATP or ~90-kDa polypeptide for truncated CBATP is not yet known. They have been observed in our previous studies (8, 10, 12) as well as studies of others (36-38). Their immunoprecipitation is blocked by purified unlabeled CBATP (data not shown). They are, therefore, thought to be precursors or intermediates. Taken together, the results demonstrated that there were similar levels of synthesis of wild-type, chimeric, and mutant CEA molecules and CBATP molecules in the appropriate cotransfected COS cells. Finally, we examined whether the same polypeptides could be detected at the external aspect of the plasma membrane of cotransfected COS cells by immunoprecipitation after cell surface iodination (Fig. 5C). The results showed that there were similar amounts of CEA and CBATP detected in each case. Our previous studies have shown that only proteins on the external surface of the plasma membrane are labeled under these conditions (8, 10, 12), and thus these results indicate that similar amounts of CEA and CBATP reach the cell surface in the COS cells transfected with IBAT and wild-type, chimeric, and mutant CEA.


Fig. 5. Expression of wild-type, mutant, and chimeric CEA and CBATP molecules in transfected COS cells. Cells were analyzed by Western blot analysis (A), biosynthetic labeling (B), and cell surface labeling (C). Left, relative electrophoretic migration of molecular mass markers. We could not detect a decrease in electrophoretic migration of the chimeric CEA molecules as compared with the wild-type molecule on these 10% gels, but there was a decrease in electrophoretic migration of ~8 kDa for the chimeric CEA molecules on 6.5% gels in which proteins of 180 kDa were resolved in the middle of the gel (data not shown).
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We could now examine the bile acid efflux activity in these cotransfected COS cells. Separate monolayers that had been cotransfected 48 h earlier were incubated for 1 h at 22 °C in DMEM supplemented with 400 µM [3H]taurocholate acid. The cells were then washed extensively and then incubated in DMEM supplemented with 5 µM ATP in the absence or presence of DIDS for 5 min. The resulting cell culture media samples were subjected to scintillation counting (Fig. 6). The results show that there is significant efflux of taurocholate by COS cells cotransfected with IBAT and CBATP, with IBAT and R98A-CBATP, and to a lesser extent, by IBAT and Y488FCBATP but not by COS cells transfected with IBAT alone or by COS cells cotransfected with IBAT and truncated CBATP or IBAT and T502A, S503A-CBATP. These results are similar to results in our previous assay system (8, 10, 12). The results also show that there is significant efflux of taurocholate in COS cells cotransfected with IBAT and the CBATP-CEA chimera and with IBAT and the CBATP-R98A-CEA chimera but not in COS cells cotransfected with IBAT and CEA or IBAT and R98A-CEA. These results indicate that the cytoplasmic tail and membrane-spanning domain of CBATP can confer bile acid efflux properties on another protein, CEA, which does not ordinarily have these properties. The results also provide evidence that the effect of CBATP on bile acid efflux in the cotransfection assay is highly specific and, therein, provide further evidence for the validity of the cotransfection assay system.


Fig. 6. Bile acid efflux in COS cells cotransfected with IBAT and wild-type, mutant, or chimeric CBATP or CEA genes. Cells were subjected to bile acid efflux assays 48 h after transfection. Cotransfected cells were incubated for 60 min at 22 °C in medium supplemented with 400 µM [3H]taurocholate. The cells were then washed and incubated for 5 min at 22 °C in medium supplemented with ATP in the absence or presence of 1 mM DIDS.
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We also examined the ecto-ATPase activity conferred on COS cells by transfection of these CBATP and CEA constructs (Fig. 7). The results show that the Y488F-CBATP, T502, S503A-CBATP, CBATP, and CBATP-CEA chimera confer ecto-ATPase activity on the transfected COS cells but control vector alone, truncated CBATP, R98A CBATP, CEA, R98A-CEA, and CBATP-R98A-CEA do not confer ecto-ATPase activity. Finally, we examined the binding of ATP by wild-type and mutant CEA molecules. Our previous studies have shown that the truncated CBATP mutant and the R98A-CBATP can bind ATP as well as wild-type CBATP, even though these mutants cannot mediate ATP hydrolysis. Here we examined the possibility that CEA and R98A-CEA bind ATP by photoaffinity labeling with [35S]ATPgamma S (Fig. 8). The results show an ~180-kDa polypeptide in cells transfected with wild-type and R98A-CEA but not in untransfected cells. The labeling is blocked by unlabeled ATPgamma S. These results show that CEA does not have ecto-ATPase activity, even though it has an ATPase consensus sequence and binds ATP. This lack of ATPase activity can be attributed to the lack of a cytoplasmic tail and membrane-spanning domain. When fused to the cytoplasmic domain and membrane-spanning domain of CBATP, it now has ecto-ATPase activity. Moreover, the ecto-ATPase activity of the CBATP-CEA chimeric molecule can be clearly attributed to the ATPase consensus sequence because the activity of the chimera is abrogated by site-directed mutagenesis of Arg98, in the same way that the ecto-ATPase activity of CBATP is abrogated by mutagenesis of Arg98. Thus, these results also provide evidence that the effect of CBATP on the ecto-ATPase activity of transfected COS cells is highly specific as well as providing further evidence for the validity of the ecto-ATPase activity in transfected COS cells.


Fig. 7. Ecto-ATPase activity in COS cells cotransfected with IBAT and wild-type, mutant, or chimeric CBATP or CEA genes.
[View Larger Version of this Image (30K GIF file)]


Fig. 8. Photoaffinity labeling of CEA and R98A-CEA molecules in transfected COS cells. Briefly, 48 h after transfection, cells were labeled with [35]ATPgamma S in the absence or presence of unlabeled ATPgamma S in 200-fold molar excess (8). Cells were then photolyzed and homogenized so that the cell homogenates could be analyzed by immunoprecipitation, SDS-polyacrylamide gel electrophoresis/fluorography. Left, relative electrophoretic migration of molecular mass markers.
[View Larger Version of this Image (81K GIF file)]


DISCUSSION

The results of this study establish the validity of a new system for assaying carrier-mediated bile acid efflux. In our previous studies, we used a system in which transfected cells were loaded with [3H]taurocholate by nonspecific pinocytosis, which required pharmacologic clamping of the membrane potential with valinomycin (8, 10, 12). By cotransfecting the genes for a transporter that mediates uptake of bile acids and for a candidate efflux transporter, there is an ~20-fold increase in loading of the cells and no need for clamping of the membrane potential. Furthermore, the efflux capacity of candidate gene products can be detected for a much longer period of time. In the studies reported here, we could see the effects of CBATP for as long as the studies were done, 60 min, whereas the effects of CBATP were only apparent for several minutes in the previous assay system. Results of the study provide further evidence that CBATP can mediate bile acid efflux. The effect of CBATP is time-dependent, temperature-dependent, concentration-dependent, saturable, and has kinetic characteristics that are similar to those reported previously in rat liver canalicular membrane vesicles (7). The effect of CBATP on efflux of [3H]taurocholate is modulated by one pharmacologic state (ATP depletion) but not by another (valinomycin). This effect is abrogated by truncation of the cytoplasmic tail and by site-directed mutagenesis of one phosphorylation site (S503A) in the cytoplasmic tail, is decreased but not eliminated by site-directed mutagenesis of another phosphorylation site (Y488F), and is unaffected by site-directed mutagenesis of an ATP consensus sequence in the extracellular tail. This effect can be conferred on a related protein, CEA, by fusing its cytoplasmic tail and membrane-spanning domain onto that protein. Site-directed mutagenesis of the ATPase consensus sequence in the extracellular tail of the chimera does not alter bile acid efflux activity, even though it abrogates ecto-ATPase activity. The reduction in bile acid efflux activity mediated by Y488F-CBATP and the abrogation of bile acid efflux activity mediated by T502A, S503A-CBATP are again notable, in that neither of these mutations affected ecto-ATPase activity. None of the alterations in bile acid efflux activity or ecto-ATPase activity, resulting from pharmacologic or genetic manipulation, could be attributed to alterations in biosynthesis, half-life, or targeting to the external surface of the plasma membrane.

One particularly interesting result of this study is the bile acid efflux activities of the CBATP-CEA chimera. Our previous studies had shown that bile acid efflux activity was lost upon deletion of the cytoplasmic tail of CBATP (8). Here the studies show that cytoplasmic tail and membrane-spanning segment of CBATP can confer bile acid efflux properties on the extracellular amino-terminal tail of a related molecule, CEA. Presumably the cytoplasmic tail, with or without the membrane-spanning segment, plays an essential role in binding of the bile acid substrate. It was also interesting to find that the cytoplasmic tail and membrane-spanning segment of CBATP could confer ecto-ATPase activity on the same CBATP-CEA chimeric molecule. Our previous studies had shown that CBATP lost its ecto-ATPase activity when its cytoplasmic tail was deleted, but we could not exclude the possibility that this was simply explained by a failure of the truncated CBATP to be in the appropriate conformation (8). Taken together with the current studies, however, it is now apparent that the cytoplasmic tail and membrane-spanning domains transmit information that is essential for ecto-ATPase activity and can even transmit that information to CEA, a molecule which has an ectoplasmic ATPase consensus sequence and can bind ATP but does not ordinarily possess ecto-ATPase activity.

Although the results of this study show that CBATP can mediate bile acid efflux in a model system, they do not establish the role or contribution of CBATP to bile acid transport at the canalicular membrane under physiologic conditions. The results do show that CBATP cannot account for bile acid efflux driven by the electrochemical potential differences at the membrane. Bile acid transport mediated by CBATP is absolutely dependent on ATP. However, our previous studies have suggested that it is extracellular ATP that induces bile acid efflux mediated by CBATP (8, 10). Perhaps CBATP provides a mechanism for bile acid efflux in response to canalicular ATP or in response to ATP released during liver cell injury and that there are other molecules/systems responsible for canalicular bile acid transport in response to intracellular ATP (classical P-type ATPase transporter) as well as canalicular bile acid transport in response to the electrochemical membrane potential.

In contrast to most conventional transport proteins that have multiple transmembrane domains (30), CBATP has only two, or perhaps one, transmembrane domain. This may mean that it is a member of a nonconventional class of transporters that only have a single transmembrane domain and includes the minK potassium channel (31, 32) and an influenza virus M2 proton pump (33, 34). However, our recent studies of the cell adhesion properties of CBATP in infected Sf9 cells (39) have indicated that CBATP molecules bind to each other. Clustering of CBATP molecules could, therefore, bring two or more CBATP molecules and their transmembrane domains into close proximity to potentially form a pore in the membrane for bile acid efflux.

Although it was not the major focus of this study, the results do indicate that CEA can bind extracellular ATP. Because the ATPase consensus sequence responsible for ATP binding is highly conserved among members of the CEA family, it is likely that ATP binding is a property of many of these molecules. There is apparently a substantial amount of ATP and other adenine nucleotides in bile (35). However, whether CEA molecules sticking out into the lumen of the biliary canaliculus can bind ATP or other nucleotides under physiologic conditions or whether binding of ATP by CEA plays a specific physiologic role is not known.


FOOTNOTES

*   The studies were supported by National Institutes of Health Grants DK47084 and T32HDO7409.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
**   To whom correspondence should be addressed: Dept. of Pediatrics, Washington University School of Medicine, #1 Children's Place, St. Louis, MO 63110. Tel.: 314-454-6033; Fax: 314-4546-4218; E-mail: perlmutter{at}a1.kids.wustl.edu.
1   The abbreviations used are: CBATP, canalicular bile acid transport protein; CEA, carcinoembryonic antigen; DMEM, Dulbecco's modified Eagle's medium; IBAT, ileal bile acid transport protein; DIDS, 4,4'-diisothiocyanostilbene-2,2-disulfonic acid; ATPgamma S, adenosine 5'-O-(thiotriphosphate).

ACKNOWLEDGEMENTS

We are indebted to Elizabeth Karner and Joyce L. Williams for preparing the manuscript.


REFERENCES

  1. Blitzer, B. L., and Boyer, J. L. (1982) Gastroenterology 82, 346-357 [Medline] [Order article via Infotrieve]
  2. Scharschmidt, B. F., and van Dyke, R. W. (1983) Gastroenterology 85, 1199-1214 [Medline] [Order article via Infotrieve]
  3. Hardison, W. G. M., and Wood, C. A. (1978) Am. J. Physiol. 235, E158-E164 [Medline] [Order article via Infotrieve]
  4. Dumont, M., Erlinger, S., and Uchamn, S. (1980) Gastroenterology 79, 82-89 [Medline] [Order article via Infotrieve]
  5. Forker, E. L. (1977) Annu. Rev. Physiol. 39, 323-347 [Medline] [Order article via Infotrieve]
  6. Gaitman, Z. C., and Arias, I. M. (1995) Physiol. Rev. 75, 261-275 [Free Full Text]
  7. Sippel, C. J., Ananthanarayanan, M., and Suchy, F. J. (1990) Am. J. Physiol. 21, G728-G737
  8. Sippel, C. J., Suchy, F. J., Ananthanarayanan, M., and Perlmutter, D. H. (1993) J. Biol. Chem. 268, 2083-2091 [Abstract/Free Full Text]
  9. Cheung, P. H., Thompson, N. L., Earley, K., Culic, O., Hixson, D., and Lin, S.-H. (1993) J. Biol. Chem. 268, 6139-6146 [Abstract/Free Full Text]
  10. Sippel, C. J., McCollum, M. J., and Perlmutter, D. H. (1994) J. Biol. Chem. 269, 2820-2826 [Abstract/Free Full Text]
  11. Cheung, P. H., Luo, W., Qiu, Y., Zhang, X., Earley, K., Millirans, P., and Lin, S.-H. (1993) J. Biol. Chem. 268, 24303-24310 [Abstract/Free Full Text]
  12. Sippel, C. J., Fallon, R. J., and Perlmutter, D. H. (1994) J. Biol. Chem. 269, 19539-19545 [Abstract/Free Full Text]
  13. Wong, M. H., Oelkers, P., Craddock, A. L., and Dawson, P. A. (1994) J. Biol. Chem. 269, 1340-1347 [Abstract/Free Full Text]
  14. Barnett, T., Goebel, S. J., NothDurft, M. A., and Elting, J. J. (1988) Genomics 3, 59-66 [Medline] [Order article via Infotrieve]
  15. Higuchi, R. (1990) in PCR Protocols (Innis, M. A., Gelfand, D. H., Snisky, J. W., and White, T. H., eds), pp. 177-180, Academic Press, Inc., San Diego
  16. Hanahan, D. (1988) J. Mol. Biol. 166, 557-580
  17. Birnboin, H. C., and Boly, J. (1979) Nucleic Acids Res. 7, 1513-1523 [Abstract]
  18. Tabor, S., and Richardson, C. C. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 4767-4771 [Abstract]
  19. Cullen, B. R. (1987) in Methods in Enzymology (Berger, S. L., and Kimmel, A. R., eds), Vol. 152, pp. 692-693, Academic Press, Inc., San Diego
  20. Yih, L. H., Hunag, H., Jan, K. Y., and Lee, T. (1991) Cell Biol. Int. Rep. 15, 253-264 [Medline] [Order article via Infotrieve]
  21. Lowry, O. H., Rosebrough, N. J., Farr, A. L., and Randall, R. J. (1951) J. Biol. Chem. 193, 265-275 [Free Full Text]
  22. Blitzer, B., Ratoosh, S. L., Donovan, C. B., and Boyer, J. L. (1982) Am. J. Physiol. 6, G48-G53
  23. Lin, S.-H., and Guidotti, G. (1989) J. Biol. Chem. 264, 14408-14414 [Abstract/Free Full Text]
  24. Perlmutter, D. H., and Punsal, P. I. (1988) J. Biol. Chem. 263, 16499-16503 [Abstract/Free Full Text]
  25. Lederkremer, G. Z., and Lodish, H. F. (1991) J. Biol. Chem. 266, 1237-1244 [Abstract/Free Full Text]
  26. Nishida, T., Chez, M., Gaitman, Z., and Arias, I. M. (1992) Hepatology 16, 149A
  27. Kast, C., Stieger, B., Winterhalter, K. H., and Meier, P. J. (1994) J. Biol. Chem. 269, 5179-5186 [Abstract/Free Full Text]
  28. Nishida, T., Gaitam, Z., Che, M., and Arias, I. M. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 6590-6594 [Abstract]
  29. Thompson, J. A., Grunert, F., and Zimmermann, W. (1991) J. Clin. Lab. Anal. 5, 344-366 [Medline] [Order article via Infotrieve]
  30. Jennings, M. L. (1989) Annu. Rev. Biochem. 58, 999-1027 [CrossRef][Medline] [Order article via Infotrieve]
  31. Kaczmarek, L. K. (1991) New Biol. 3, 315-323 [Medline] [Order article via Infotrieve]
  32. Steve, A., Goldstein, N., and Miller, C. (1991) Neuron 7, 403-408 [CrossRef][Medline] [Order article via Infotrieve]
  33. Pinto, L. H., Holsinger, L. J., and Lamb, R. A. (1992) Cell 69, 517-528 [Medline] [Order article via Infotrieve]
  34. Skehel, J. J. (1992) Nature 358, 110-111 [Medline] [Order article via Infotrieve]
  35. McGill, J. M., Basavappa, S., Mangel, A. W., Shimolkura, G. H., Middleton, J., and Fitz, J. G. (1994) Gastroenterology 107, 236-243 [Medline] [Order article via Infotrieve]
  36. Lin, S-H, Culic, O., Flanagan, D., and Hixson, D. C. (1991) Biochem. J. 278, 155-161 [Medline] [Order article via Infotrieve]
  37. Muller, M., Ishikawa, I., Berger, U., Klunemann, C., Lucka, L., Schreyer, A., Kannichi, C., Reutter, W., Kurz, G., and Keppler, D. (1991) J. Biol. Chem. 266, 18920-18926 [Abstract/Free Full Text]
  38. Becker, A., Lucka, L., Kilian, C., Kannichi, C., and Reutter, W. (1993) Eur. J. Biochem. 214, 539-548 [Abstract]
  39. Sippel, C. J., Shen, T., and Perlmutter, D. H. (1996) J. Biol. Chem. 271, 33095-33104 [Abstract/Free Full Text]

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