The Transport Activity of the Na+-Ca2+ Exchanger NCX1 Expressed in HEK 293 Cells Is Sensitive to Covalent Modification of Intracellular Cysteine Residues by Sulfhydryl Reagents*

Xiaoyan Ren, Judith Kasir, and Hannah RahamimoffDagger

From the Department of Biochemistry, Hebrew University-Hadassah Medical School, Jerusalem 91120, Israel

Received for publication, August 28, 2000, and in revised form, November 21, 2000


    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Membrane permeable N-ethylmaleimide (NEM) and (2-aminoethyl)methanethiosulfonatehydrobromide (MTSEA) inhibited the rat brain Na+-Ca2+ exchanger RBE-2 (NCX1.5) expressed in HEK 293 cells in a dose dependent manner. 50% inhibition was obtained at 1 mM MTSEA and 1.65 mM NEM. External application of membrane impermeable [2-(trimethylammonium) ethyl]methanethiosulfonatebromide (MTSET) and sodium(2-sulfonatoethyl)methanethiosulfonate (MTSES) did not inhibit the transport activity in whole cells. Following reconstitution, however, of RBE-2 transfected cell proteins into proteoliposomes, external application of MTSET and MTSES led to a decrease in transport activity to 42.7 (S.D. = 9.1) and 51% (S.D. = 10.14), respectively. Similar results were obtained also when the rat heart isoform RHE-1 (NCX1.1) or the rat brain isoform RBE-1 (NCX1.4) was expressed. NEM and MTSEA inhibited Na+ gradient-dependent Ca2+ uptake also in HEK 293 cells expressing RBE-2/C14A/C20S/ C122S/C780S (numbering corresponds to RBE-2), a mutant in which all putative extracellular cysteines were exchanged. To study the accessibility of different cysteines to covalent modification, surface biotinylation of cells expressing the wild type exchanger and its mutants was carried out using 3-(N-maleimidylpropionyl)biocytin. Surface biotinylation revealed immunoreactive protein derived from the wild type Na+-Ca2+ exchanger only if the transfected cells were exposed to the reducing agent Tris(2-carboxyethyl)phosphine. No reduction was needed when the single cysteine mutants of RBE-2, C14A, C20S, and C780S, were expressed. Treatment of the cells expressing these mutants with MTSET before biotinylation, led to a decrease in the amount of exchanger protein that was revealed. No immunoreactive protein was detected when the quadruple mutant RBE-2, C14A/C20S/C122S/C780S, was biotinylated, suggesting that no additional cysteines are accessible directly from the extracellular face of the membrane. Permeabilizing the cells expressing RBE-2/C14A/C20S/ C122S/C780S with streptolysin O resulted in biotinylation of the exchanger protein. Its amount decreased if exposure to NEM preceded streptolysin O treatment. Our results suggest that Na+-Ca2+ exchange activity is inhibited by covalent modification with sulfhydryl reagents of cysteine residues that are accessible from the cytoplasmic face of the membrane.


    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Sulfhydryl reagents such as NEM,1 dithiothreitol, methylmethane thiosulfonate, p-chloromercuribenoate, and mersalyl were shown to have considerable effects on Na+-Ca2+ exchange activity in membrane preparations derived from sarcolemma and synaptosomes (1-3). Na+-Ca2+ exchange activity in the squid giant axon could also be modulated by internal application of p-chloromercuryphenylsulfonic acid (4). Moreover, the effects of the thiol reagents on Na+-Ca2+ exchange depended on the ionic composition of the medium (3), which suggested that ion binding or translocation sites were involved.

Yet examination of the effects of different methanethiosulfonate (MTS) reagents in conjunction with cysteine-scanning mutagenesis, which was carried out to study the membrane topology of the dog heart Na+-Ca2+ exchanger NCX1.1 (5, 6) expressed in Xenopus oocytes, suggested that none of the membrane permeable or impermeable sulfhydryl reagents tested had any significant effect on transport activity. MTSET sometimes stimulated Na+-Ca2+ exchange (5). In CCL39 cells expressing the cloned dog cardiac Na+-Ca2+ exchanger only MTSET was tested, but it also did not modulate transport activity. (7).

Recently, based on differences in electrophoretic mobility of the dog cardiac Na+-Ca2+ exchanger in the presence and absence of reducing reagents and on site-directed mutagenesis, it was suggested (8) that disulfide bonds form between cysteine 792 and either cysteine 14 or 20 in the extracellular (9) N terminus of the protein. The existence of these disulfide bonds could potentially restrict access of different reagents to some residues at the extracellular face of the membrane. The possibility that the oxidation-reduction state of these bonds might differ in the different experimental preparations might explain some of the apparent differences between the various studies using sulfhydryl reagents.

In this work, we report that the membrane permeable reagents NEM and MTSEA inhibited Na+ gradient-dependent Ca2+ influx in HEK 293 cells expressing the cloned rat brain exchangers RBE-1 (NCX1.4) and RBE-2 (NCX1.5) and the rat heart isoform RHE-1 (NCX1.1). As reported previously in oocytes (5, 6), the membrane impermeant reagents MTSET and MTSES also did not inhibit transport activity in HEK 293 cells when applied from the outside. These reagents did, however, inhibit transport activity when proteins derived from cells expressing RBE-1, RBE-2, or RHE-1 were reconstituted into proteoliposomes. We show that in the wild type exchanger the putative external cysteine residues were not directly accessible to covalent modification. Reduction, however, of the protein by Tris(2-carboxyethyl)phosphine (TCEP), or exchange of one of the three cysteine residues Cys-14, Cys-20, and Cys-780 with either alanine or serine, resulted in surface biotinylation with 3-(N-maleimidylpropionyl)biocytin (MB). Pretreatment of the cells expressing C14A, C20S, or C780S2 with MTSET considerably reduced surface biotinylation by MB but did not result in inhibition of the transporter. Permeabilizing the cells expressing a mutant in which all putative extracellular cysteines were exchanged revealed that cysteines facing the cytoplasmic side of the membrane and derived from the Na+-Ca2+ exchanger are biotinylated by the reagent. The amount of the biotinylated Na+-Ca2+ exchanger was considerably reduced when NEM treatment of cells expressing this mutant preceded biotinylation. Based on these and other results, we suggest that cysteines accessible from the cytoplasmic face of the membrane can be modified covalently by sulfhydryl reagents, which in turn might be responsible for the impaired transport activity. Some of the preliminary results were reported in a previously published abstract (10).

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
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Expression of Rat Isoforms RBE-1 (NCX1.4), RBE-2 (NCX1.5), and RHE-1 (NCX1.1) or Their Mutants in HEK 293 Cells-- Transfection of HEK 293 cells and determination of Na+-dependent Ca2+ uptake was done exactly as described (11). Transfected cells were preloaded with a solution containing 0.16 M NaCl, 0.02 M Tris HCl, pH 7.4, 0.02 M MgCl2, 25 µM nystatin, and 1 mM ouabain for 10 min. The Na+ preloading solution was replaced by a solution of identical composition except that it did not contain nystatin. When added, NEM (dissolved in Me2SO) and MTS reagents (Toronto Research Chemicals Inc.) (dissolved in H2O) at 10-50× concentrations were added directly to this solution and kept at 25 °C for 30 min. The concentration of Me2SO was kept below 1%, which by itself had no effect on the transport assays. The cells were washed with the same solution (without the sulfhydryl reagents) twice, and [Na+]-dependent 45Ca2+ uptake was measured as described (11). In some control experiments, the MTS reagents were added to the cells expressing the transporter in buffered choline chloride prior to the Na+ preloading procedure. The change in the ionic composition of the solution in which the reagents were presented to the cells expressing the transporter had no effect on the results. All measurements were done in triplicates, and each experiment was repeated with three to six different preparations of transfected cells.

Site-directed Mutagenesis-- The method of Kunkel (12) was used to prepare the different cysteine mutants. Antisense oligonucleotides that contained the desired mutation flanked by about 15 upstream and downstream bases corresponding to the nucleotide sequence of the cloned exchanger were used. All of the primers except that which was used to generate C14A also contained a silent mutation to introduce restriction sites for selection of mutants. Insertion of the Flag epitope instead of Asn-9 has been described (9, 11). Usually a segment of about 600-1000 base pairs containing the desired mutation was excised from the mutant plasmid and subcloned into a vector derived from the parent clone. The entire insert containing the mutation and parts of the vector containing the ligation sites where it was subcloned were sequenced (Dr. Mira Korner, Sequencing Service, Hebrew University).

Reconstitution of Transfected Cell Proteins-- Brain phospholipids in CHCl3 were dried under N2, suspended in 0.2 M NaPi, pH 7.4, and dispersed by sonication to form liposomes. Transfected cells were solubilized in 1% cholate in phosphate-buffered saline and added to the liposomes for 30 min at 37 °C. For confluent transfected cells grown in a 60-mm culture dish (about 0.75 mg of protein), 2.7 mg of brain phospholipds were used. Reconstitution and determination of transport activity was carried out as described (11, 13).

Surface Biotinylation-- Biotinylation of surface membrane proteins of transfected HEK 293 cells in situ was done with 3-(N-maleimidylpropionyl)biocytin (Molecular Probes) essentially as described for surface biotinylation with NHS-SS-biotin (11, 14). In most of the experiments FN-tagged RBE-2 and its cysteine mutants were used for transfection. Unless otherwise stated, cells from a single well of a 12-well plate were used for surface biotinylation. When pretreatment with MTS reagents preceded biotinylation, a single well of a 6-well plate was used. At the end of the biotinylation reaction, an excess of MB was quenched with PBSCM (phosphate-buffered saline also containing 0.1 mM CaCl2, 1 mM MgCl2) to which 2% beta  mercaptoethanol was added. Surface biotinylation with NHS-SS-biotin (Pierce, catalog no. 21331), was carried out exactly as described (11, 14). The cells were lysed with a solution containing 50 mM Tris-HCl, pH 7.5, 150 mM NaCl, 5 mM EDTA, 1% Triton X-100, 1% SDS, and 0.1 mM phenylmethylsulfonyl fluoride (Sigma), 0.01 mg/ml pepstatin A (Sigma), and 0.02 mM leupeptin (Sigma). The SDS concentration was lowered by a 10-fold dilution of the lysate with a solution of identical composition to that used to lyse the cells except that it did not contain SDS loaded on streptavidin-agarose beads (Pierce) and was gently shaken for 4 h at 4 °C. Washing of the beads was done as described (14). Biotinylated proteins were released from the beads by heating for 10 min at 85 °C with Laemmli sample buffer and separated by SDS-polyacrylamide gel electrophoresis. Western analysis was carried out as described below.

Permeabilization of HEK 293 cells with streptolysin O (Sigma) was done as described previously (15).

Western Analysis-- SDS- polyacrylamide gel electrophoresis of biotinylated proteins released from streptavidin beads and total cell extracts was carried out by standard procedures (16). For analysis of total cell extracts, 40 µg of cell protein derived from the entire contents of a single well of a 12-well plate was used. The transfection of cells used for biotinylation and for detection of total immunoreactive protein was done in parallel. To detect protein derived from the Na+-Ca2+ exchanger AbO-8, a polyclonal antibody directed against a pentadecapeptide, corresponding to the amino acids 649-663 of the rat heart exchanger, was used. (9). Preparation, testing, and purification of the antibodies was done as described (9, 17). Goat anti-rabbit horseradish peroxidase-conjugated secondary antibody (Jackson ImmunoResearch Laboratories, Inc.) was used to detect antigen-antibody complexes using the ECL kit from Amersham Pharmacia Biotech.

    RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The Effects of Sulfhydryl Reagents on Na+ Gradient-dependent Ca2+ Uptake-- Fig. 1 shows the effects of membrane permeable MTSEA (panel A) and NEM (panel B) on Na+ gradient-dependent Ca2+ uptake in HEK 293 cells transfected with RBE-2. It can be seen that the inhibition with both reagents is concentration-dependent. Exposure of cells expressing RBE-2 to 2.5 mM MTSEA reduces Na+ gradient-dependent Ca2+ uptake to about 25% relative to that measured in untreated cells, and 50% inhibition is obtained at about 1 mM MTSEA. A higher concentration of NEM is required to inhibit the transporter. Although the inhibition of Na+ gradient-dependent Ca2+ uptake is detectable already at 0.5 mM NEM and 5 mM NEM reduces Na+ gradient dependent Ca2+ uptake to below 20% relative to that of the untreated cells, 50% inhibition is reached when cells are exposed to 1.65 mM NEM.


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Fig. 1.   The effect of membrane permeable sulfhydryl reagents on Na+ gradient-dependent Ca2+ uptake in RBE-2 transfected HEK 293 cells. HEK 293 cells were transfected with wild type RBE-2 cloned in pcDNA3.1 (black squares) or with FN-RBE-2 in which the Flag epitope replaces Asn-9 (black triangle in A and black circle in B). 24 h post-transfection Ca2+ uptake was measured (see details under "Experimental Procedures") without and with different concentrations of membrane permeable MTSEA (A) and NEM (B). The data were compiled from six different transfections; individual measurements were done in triplicate. The transport activity in each experiment without the sulfhydryl reagent was taken as 100%, and other data were normalized. Bars represent standard deviations.

The inhibition of Na+ gradient-dependent Ca2+ uptake with the membrane permeable reagents is obtained both when the WT exchanger is expressed (black squares in Fig. 1) and when the glycosylation mutant FN-RBE-2, in which the Flag epitope replaces Asn-9, the single glycosylation site of the protein (11, 18) (black triangle in Fig. 1A and black circle in Fig. 1B), is expressed. Transport activity of the FN-tagged RBE-2 was similar to the WT exchanger bearing no tag.

The membrane impermeant reagents MTSET and MTSES (Fig. 2) did not inhibit Na+ gradient-dependent Ca2+ uptake when added to transfected cells in situ (Fig. 2A). In some experiments, as reported by Nicoll et al. (5), addition of the reagents led to stimulation of Na+-dependent Ca2+ uptake.


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Fig. 2.   The effect of membrane impermeable reagents MTSET and MTSES on Na+ gradient-dependent Ca2+ uptake in transfected HEK 293 cells, measured in whole cells (A) and following reconstitution of solubilized cell proteins into proteoliposomes (B). HEK 293 cells were transfected with wild type plasmid DNA or with FN-tagged RBE-2. 24 h post-transfection, Ca2+ uptake was measured (see details under "Experimental Procedures") in the presence of membrane impermeable reagents MTSET or MTSES. The average transport activity without the reagents in each experiment was defined as 100%; the transport activity with the reagents is presented in relative values: A, in whole cells; B, following reconstitution of transfected cell proteins into proteoliposomes. Bars represent standard deviations.

Because membrane permeable reagents inhibited Na+-Ca2+ exchange activity in whole cells and membrane impermeant reagents applied from the outside did not, we solubilized transfected cell proteins and reconstituted them into proteoliposomes. Fig. 2B shows the inhibition by 2 mM MTSET and 10 mM MTSES of Na+-dependent Ca2+ uptake in proteoliposomes derived from RBE-2-transfected HEK293 cells. The addition of 0.1, 0.5, and 1 mM MTSET and 3 and 5 mM MTSES to the reconstituted preparation inhibited Na+-dependent Ca2+ uptake in a concentration-dependent manner. However, increasing the concentration of MTSET to 2 mM and above (2-10 mM) and MTSES to 5 mM and above (5-15 mM) did not further increase the extent of inhibition that was reached in each preparation, which was between 40 and 60% relative to the transport activities measured in the absence of the sulfhydryl reagents.

Because none of the sulfhydryl reagents had a significant effect on the transport activity of the dog sarcolemmal Na+-Ca2+ exchanger NCX1.1 expressed in oocytes (5-7) and because the dog heart isoform has an extra cysteine in position 879 instead of a serine in the corresponding rat isoform, we prepared a mutant of RHE-1, RHE-1/S879C. RHE-1/S879C was expressed in HEK 293 cells, and Na+ gradient-dependent Ca2+ uptake activity of this mutant was determined in the absence and in the presence of the sulfhydryl reagents. Inhibition of transport activity was obtained by the membrane permeable reagents NEM and MTSEA added to whole cells from the outside and by MTSET and MTSES only following reconstitution, in a manner similar to the results presented in Figs. 1 and 2 for the rat isoforms.

Accessibility of Cysteines to Sufhydryl Reagents-- To further examine the functional and structural implications that the effects of membrane permeable and impermeable sufhydryl reagents had on the Na+-Ca2 exchanger, we determined the accessibility of the different cysteines to covalent modification. This was done by surface biotinylation of adherent cells expressing the Na+-Ca2+ exchanger and some of its cysteine mutants with MB directly or following the permeabilization of these cells in situ with SLO. Biotinylated proteins were isolated from lysed cells on immobilized streptavidin; Western analysis of the proteins released from the beads was carried out to detect the Na+-Ca2+ exchanger or its mutants. To examine whether glycosylation of the exchanger played a role in determination of accessibility of the protein to covalent modification, transfection was carried out both with glycosylated and nonglycosylated (FN-tagged) RBE-2 and its cysteine mutants. As also seen with transport activity (see Figs. 1 and 2), no differences in surface expression were detected between the glycosylated and nonglycosylated exchangers.

Fig. 3A shows the location of the different cysteines. Because the topology of the protein has not been fully established, we based the model in Fig. 3A on a combination of the hydropathy analysis model and possible changes suggested by the neural network algorithm-based analysis of secondary structure of the protein and experimental data based on immunocytochemistry (9) and cysteine-scanning mutagenesis (5, 7). We exchanged the 14 cysteines of the rat isofoms of NCX1 with either alanine or serine alone or in different combinations. Each one of the single cysteine mutants was functional. Based on the results shown in Figs. 1 and 2, we have studied in this work the accessibility of the four putative extracellular cysteines to surface biotinylation by MB. The location of these cysteines is marked by an arrow in Fig. 3A.


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Fig. 3.   A, topological model of the Na+-Ca2+ exchanger NCX1 and putative location of the cysteine residues. This model is based on hydropathy analysis (25, 26) and experimental data compiled previously (5, 7-9). The numbering of cysteine residues is shown as in the rat isoform NCX1.5. B, Na+ gradient-dependent Ca2+ uptake in transfected HEK 293 cells expressing different cysteine mutants. HEK 293 cells were transfected with different single cysteine mutants, derived from FN-RBE-2, C14A, C20S, C122S, and 780S; double cysteine mutants C14A/C20S and C20S/C122S; the triple cysteine mutant C14A/C20S/C122S; and the quadruple mutant C14A/C20S/C122S/C780S. In each individual experiment, parallel transfection with the WT FN-RBE-2 DNA was also carried out, and its transport activity was defined as 100%. The transport activity of the mutants is presented in relative values.

Fig. 3B shows the relative transport activities of the different putative extracellular single and multiple cysteine mutants that were generated. It can be seen that although relative transport activities of these mutants varied, all were functional.

Fig. 4 shows an immunoblot of surface biotinylated FN-RBE-2 (panel A) and some of its FN-tagged cysteine mutants (panels B and C). Biotinylation was carried out with MB, which botinylates cysteine residues. The amount of "total" immunoreactive protein derived from transfected cell extracts is also shown. It can be seen (Fig. 4A), that in the surface membrane, only traces of immunoreactive protein were detected when cells expressing the FN-RBE-2 were biotinylated. To examine whether disulfide bonds block the access of the biotinylating reagent MB to extracellular cysteines and thereby prevent the isolation of exchanger protein from FN-RBE-2-transfected cells, we used the reducing agent TCEP. TCEP, unlike dithiothreitol or beta -mercaptoethanol, can be added together with MB without quenching it (19-21) and used for the reduction of disulfide bonds. The addition of an equimolar concentration (500 µM) of TCEP to the biotinylating reaction mixture led to detection of immunoreactive exchanger protein. The addition of an excess of TCEP (750 µM) over the concentration of MB (500 µM) that was used led to detection of higher amounts of exchanger protein. Biotinylation of cells expressing the single cysteine mutants FN-RBE-2/C14A, FN-RBE-2/C20S, and FN-RBE-2/C780S (Fig. 4B) resulted in detection of immunoreactive exchanger protein without any reduction. No immunoreactive protein was detected when mutant FN-RBE-2/C122S was biotinylated, although the mutant was functional and protein derived from it was detected in total cell extracts.


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Fig. 4.   Expression of surface biotinylated proteins and total cell proteins derived from HEK 293 cells expressing FN-RBE-2 and its cysteine mutants. HEK 293 cells grown in 12-well plates were transfected with FN-RBE-2 plasmid DNA (A) and with some of its cysteine mutants (B and C). 24 h post-transfection, cells were surface-biotinylated and isolated by binding to immobilized streptavidin, and following release from the beads, Western analysis was carried out. Total immunoreactive protein derived from parallel transfections (40 µg of cell protein/lane) is also shown (see "Experimental Procedures"). A, immunoreactive protein derived from surface-biotinylated cells expressing FN-RBE-2 without reduction and with 500 µM or 750 µM TCEP. Immunoreactive protein derived from total transfected cell extracts prepared in parallel is also shown. B, immunoreactive biotinylated protein derived from cells expressing single cysteine mutants C14A, C20S, and C780S (lanes marked A) and from parallel total cell lysates derived from transfections with the same mutants (lanes marked B). C, the same as B but with different double, triple, and quadruple cysteine mutants.

Fig. 4C shows the immunoblot derived from the Na+-Ca2+ exchanger proteins that were detected when cells expressing the double mutants FN-RBE-2/C14A/C20S and FN-RBE-2/C20S/C122S, the triple mutant FN-RBE-2/C14A/C20S/C122S, and the quadruple mutant FN-RBE-2/C14A/C20S/C122S/C780S were biotinylated. Immunoreactive protein was revealed when each of these mutants was biotinylated except for the quadruple mutant FN-RBE-2/C14A/C20S/C122S/C780S.

Because no immunoreactive exchanger protein was revealed by surface biotinylation of cells expressing FN-RBE-2/C122S (Fig. 4B) and FN-RBE-2/C14A/C20S/C122S/C780S (Fig. 4C) with MB and because both mutants exhibited Na+ gradient-dependent Ca2+ uptake in whole transfected cells (Fig. 3B), we carried out surface biotinylation of cells expressing these mutants with NHS-SS-biotin. This membrane impermeable reagent covalently labels free amino groups such as N-terminal amines and epsilon -amino lysines (11). Fig. 5 shows that biotinylated protein derived from cells transfected with both RBE-2/C122S and RBE-2/C14A/C20S/C122S/C780S is detected in the surface membrane (lanes A) and not only in total cell extracts (lanes B). The surface expression and total cell expression of exchanger protein derived from RBE-2 is also shown.


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Fig. 5.   Surface expression of the cysteine mutants RBE-2/C122S and RBE-2/C14A/C20S/C122S/C780S. HEK293 cells were transfected with the WT Na+-Ca2+ exchanger RBE-2 and its cysteine mutants C122S and C14A/C20S/C122S/C780S. 24 h post-transfection, the cells were biotinylated with NHS-SS-biotin, biotinylated proteins were isolated by streptavidin beads, biotinylated immunoreactive protein was derived from the Na+-Ca2+ exchanger, and its mutants was analyzed by SDS-polyacrylamide gel electrophoresis (lanes marked A). Total immunoreactive protein derived from parallel transfection of cells expressing the Na+-Ca2+ exchanger and its mutants is also shown (lanes marked B).

The addition of MTSET to cells expressing FN-RBE-2 (Fig. 2A) or its mutants FN-RBE-2/C14A, FN-RBE-2/C20S, FN-RBE-2/C122S, and FN-RBE-2/C780S from the outside (Fig. 6A) did not inhibit Na+-Ca2+ exchange activity; this could result either from insensitivity of the FN-RBE-2 exchanger and the different cysteine mutants to covalent modification by MTSET or the fact that the cysteines were inaccessible to the reagent. To distinguish between these possibilities, we determined the cross-reactivity between MTSET and MB. Cells expressing FN-RBE-2 and the different cysteine mutants were biotinylated directly or incubated first with 5 mM MTSET for 30 min and biotinylated after appropriate washes with PBSCM. Because protein derived from cells expressing FN-RBE-2 was not revealed by biotinylation without reduction (Fig. 4A), 1 mM TCEP was included in the biotinylating reaction mixture of cells expressing this protein. Fig. 6B shows the results of these experiments. It can be seen that pretreatment of the cells with MTSET considerably reduced the amount of biotinylated protein that was revealed. suggesting that MTSET and MB bind to the same site. These experiments also suggest that MTSET binds to the remaining cysteine(s) after the mutation of the single cysteine in each mutant, but this binding does not result in inhibition of their transport activity.


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Fig. 6.   Na+ gradient-dependent Ca2+ uptake and immunoblot of biotinylated surface expressed cysteine mutants expressed in HEK 293 cells. HEK 293 cells were transfected with FN-RBE-2 or its single cysteine mutants C14A, C20S, and C780S. A, 24 h post-transfection, transport activity was measured without and with 5 mM MTSET. B, immunoreactive biotinylated protein of cells expressing the WT exchanger and the same single cysteine mutants without and with preincubation with 5 mM MTSET before biotinylation. 1 mM TCEP was also included in the biotinylation mixture of the WT exchanger.

To determine whether intracellular cysteines are accessible to covalent modification, we expressed mutant FN-RBE-2/RBE-2C14A/C20S/C122S/C780S, in which all the cysteines that could potentially be biotinylated by external addition of the reagent were exchanged. Biotinylation of cells expressing this mutant with MB (Fig. 4C) did not lead to detection of immunoreactive Na+-Ca2+ exchanger protein. Fig. 7A shows an experiment in which cells expressing FN-RBE-2/RBE-2C14A/C20S/C122S/C780S were permeabilized with SLO and then biotinylated with MB. Following cell lysis (see "Experimental Procedures") and isolation of the biotinylated proteins on streptavidin beads, Western analysis was carried out. It can be seen, that immunoreactive protein derived from the Na+-Ca2+ exchanger was revealed. Treatment of the cells with either 5 mM MTSEA (not shown) or 5 and 10 mM NEM prior to the biotinylation reduced the amount of biotinylated immunoreactive exchanger protein that was detected. Fig. 7B shows a parallel experiment in which the effect of NEM on the transport activity of this mutant was examined. It can be seen that Na+ gradient-dependent Ca2+ uptake was reduced when cells expressing the mutant were treated with 5 mM NEM. A similar inhibition was obtained when 2.5 mM MTSEA was added to cells expressing FN-RBE-2/C14A/C20S/C122SC780S.


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Fig. 7.   The effect of NEM on transport activity and on the detection of immunoreactive biotinylated proteins derived from cells expressing the quadruple cysteine mutant FN-RBE-2 C14A/C20S/C122S/C780S. A, HEK 293 cells were transfected with the quadruple cysteine mutant FN-RBE-2/C14A/C20S/C122S/C780S. 24 h post-transfection, the cells were permeabilized with SLO (300 units/well of a 6-well plate) and then biotinylated, or they were treated with 5 or 10 mM NEM, permeabilized with SLO, and then biotinylated. Isolation and detection of biotinylated immunoreactive protein was carried out as described under "Experimental Procedures." B, transport activity of cells expressing the quadruple cysteine mutant without and with 5 mM NEM.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In this work we have shown that the transport activity of the rat isoforms of the NCX1 gene expressed in HEK 293 cells is inhibited by membrane permeable sulfhydryl reagents such as NEM and MTSEA applied to adherent cells from the outside and with the membrane impermeable reagents MTSET and MTSES, following reconstitution. We used reconstitution of transfected cell proteins to gain access to the cytoplasmic face of the membrane, because this procedure "scrambles" the topology of membrane proteins and at least some of the transporters might assume "inside-out" orientation and undergo covalent modification with membrane impermeable reagents added from the outside. Applying the membrane impermeable sulfhydryl reagents to the reconstituted preparation resulted in a concentration-dependent inhibition of Na+-dependent Ca2+ uptake up to about 2 mM MTSET and 5 mM MTSES. At these concentrations, a 40-60% inhibition of the transport activity was obtained, which did not increase with a further increase in the concentration of the reagents. This finding suggests that in our preparation of the reconstituted proteoliposomes, about half of the transporters have an "inside-out" orientation and only these transporters are amenable to covalent modification by membrane impermeable reagents. When all of the externally accessible cysteines are covalently modified, a further increase in the concentration of the membrane impermeable reagents cannot lead to further inhibition.

To study further the effects of sulfhydryl reagents on Na+ gradient-dependent Ca2+ uptake, we monitored the accessibility of different cysteines of the Na+-Ca2+ exchanger to covalent modification. This was done by surface biotinylating transfected cells that express the protein with MB and detection of immunoreactive biotinylated Na+-Ca2+ exchanger. Our studies show that only traces of immunorective protein derived from the FN-RBE-2 could be revealed by biotinylation with MB directly, although the transporter was functional. This result is puzzling for the following reasons. First, our previous studies indicated that surface-expressed FN-tagged Na+-Ca2+ exchanger of similar transport activity is detected by indirect immunofluorescence using the anti-Flag antibody and also by surface biotinylation with NHS-SS-biotin, which reacts with the free N-terminal and epsilon -amino lysines (11). Second, MB was successfully used to monitor extracellular cysteines in different expression systems and with different transporters (15, 22, 23). Third, based on hydropathy analysis (24, 25), the position of the glycosylation site at Asn-9 (18) and indirect immunofluorescence studies with N-Flag-tagged Na+-Ca2+ exchanger (9), Cys-14 and Cys-20 are in the extracellular N terminus of the protein (Fig. 3A) and should be accessible to surface biotinylation. Fourth, Santacruz-Toloza et al. (8) suggested that, in addition to Cys-14 and Cys-20, Cys-780 also is extracellular and Cys-780 is connected by a disulfide bond to either Cys-14 or Cys-20. Yet, if this disulfide bond alternates between Cys-14 and Cys-20 to Cys-780, one of these three cysteines (or a fraction from each at a time) that is not involved in sulfhydryl bond formation should be free for biotinylation. Because exposure of the cells expressing the transporter to the reducing agent TCEP led to detection of biotinylated immunoreactive RBE-2, it is possible that an additional cysteine might be involved in disulfide bond formation, which together with Cys-14, Cys-20, and Cys-780 prevents free access to the extracellular cysteines. The existence of an additional cysteine that participates in disulfide bond formation is also consistent with the finding that immunoreactive protein was detected without reduction when Cys-14 alone, Cys-20 alone, or Cys-780 alone (Fig. 4B) was exchanged with either Ala or Ser. From current topological models, cysteine 122 could have been an appropriate candidate to interact with Cys-14 or Cys-20. Yet mutation of this residue alone did not result in detection of immunoreactive protein (Fig. 4B), suggesting that it was not involved in disulfide bond formation and it was not responsible for blocking the access of the biotinylating reagent to the WT exchanger.

The inhibition with membrane permeable reagents persisted also when all of the putative external cysteines were mutated. Taken together with the effects of the membrane impermeable reagents in the reconstituted preparation, our results suggest that covalent modification of intracellular cysteines was involved. Support for this proposal comes from the experiment shown in Fig. 7 in which we incubated cells expressing FN-RBE-2/C14A/C20S/C122S/C780S without and with NEM, permeabilized them with SLO, and then exposed them to MB. Permeabilization of cells expressing FN-RBE-2/C14A/C20S/C122S/C780S before biotinylation resulted in detection of biotinylated immunoreactive protein derived from the Na+-Ca2+ exchanger. Pretreatment of the cells with NEM led to a considerable decrease in the amount of immunoreactive protein that was revealed.

These results suggest that intracellular cysteines are accessible to covalent modification by membrane permeable sulfhydryl reagents. Because these sulfhydryl reagents impair transport activity not only of the WT transporter but also of its RBE-2/C14A/C20S/C122S/C780S mutant, which has no cysteines accessible from the extracellular face of the membrane, we suggest that the covalent modification of intracellular cysteines is responsible for the impaired Na+-Ca2+ exchange activity. Further studies are required to identify which and how many of the intracellular cysteines are sensitive to the sulfhydryl reagents.

    ACKNOWLEDGEMENTS

We thank Doron Rozenzweig for his assistance with some of the experiments and for preparation of some of the figures and Dr. Arie Dagan for his suggestion to use TCEP.

    FOOTNOTES

* This work was supported in part by a fellowship (X. R.) from the Bernard Katz Minerva Center for Cell Biophysics.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.

Dagger To whom correspondence should be addressed. Tel.: 972-2-6758511; Fax: 972-2-6784010; E-mail: Hannah@cc.huji.ac.il.

Published, JBC Papers in Press, December 27, 2000, DOI 10.1074/jbc.M007823200

2 The numbering corresponds to the amino acid sequence of RBE-2 (NCX1.5).

    ABBREVIATIONS

The abbreviations used are: NEM, N-ethylmaleimide; RBE-1 (NCX1.4) and RBE-2 (NCX1.5), rat brain exchanger 1 and 2 (GenBankTM accession no. X68812 and x68813, respectively); RHE-1 (NCX 1.1), rat heart exchanger 1 (GenBankTM accession no. X68191); WT, wild type exchanger; MTS, methanethiosulfonate; MTSEA, (2-aminoethyl)methanethiosulfonatehydrobromide; MTSET, [2-(trimethylammonium)ethyl]methanethiosulfonatebromide; MTSES, sodium(2-sulfonatoethyl)methanethiosulfonate; FN, N-terminal Flag (DYKDDDDK)-tagged; MB, 3-(N-maleimidylpropionyl)biocytin; TCEP, Tris(2-carboxyethyl)phosphine; SLO, streptolysin O.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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