(Received for publication, August 1, 1996, and in revised form, September 26, 1996)
From the Department of Biochemistry, Hadassah Medical School, Hebrew University, Jerusalem, Israel 91120
The membrane topology of GAT-1, a sodium- and
chloride-coupled -aminobutyric acid transporter from rat brain, has
been probed using N-glycosylation scanning mutagenesis.
Overall, the results support the theoretical 12-transmembrane segment
model. This model (based on hydropathy analysis) was originally
proposed for GAT-1 and adopted for all other members of the sodium- and
chloride-dependent neurotransmitter transporter
superfamily. However, our data indicate that the loop connecting
putative transmembrane domains 2 and 3, which was predicted to be
located intracellularly, can be glycosylated in vivo.
Furthermore, studies with permeant and impermeant methanesulfonate reagents suggest that cysteine 74, located in the hydrophilic loop
connecting transmembrane domains 1 and 2, is intracellular rather than
extracellular. We present a model in which the topology deviates from
the theoretical one in the amino-terminal third of the transporter. It
also contains 12 transmembrane segments, but the highly conserved
domain 1 does not form a conventional transmembrane
-helix.
Sodium-coupled transporters of neurotransmitters, located in presynaptic and glial membranes, are thought to play a major role in maintaining low synaptic levels of the transmitter (for a review, see Ref. 1). Recently, this has been shown directly for the dopamine transporter using homozygous mice in which the transporter was disrupted (2). Transporters of many neurotransmitters, including GABA,1 norepinephrine, serotonin, dopamine, and glycine, belong to a large superfamily of sodium- and chloride-dependent neurotransmitter transporters (see Refs. 3 and 4 for reviews). GAT-1 is a GABA transporter that was reconstituted, purified to homogeneity (5), and cloned (6). It is the first identified member of the superfamily and catalyzes the electrogenic transport of GABA with one chloride and two sodium ions (7, 8, 9).
Knowledge of the membrane topology is one of the first steps toward the
elucidation of the structural basis of transporter function. The
topology of GAT-1 has been predicted using hydropathy plots (6), and
this interpretation has been adopted for the other members of the
superfamily. The theoretical model predicts that the transporter spans
the membrane 12 times in -helical stretches, with amino and carboxyl
termini both at the intracellular side of the membrane. GAT-1 is
modified by asparagine-linked glycosylation (5, 10, 11), and the model
predicts a large extracellular loop between transmembrane helices 3 and
4 containing three N-linked glycosylation sites (see Fig. 1)
(6). Even though experimental support has been obtained recently for a
few aspects of this model and predictions by hydropathy plots usually
provide a reasonable first approximation, it is imperative to verify
the topology experimentally.
In this report, we describe an experimental evaluation of the topology mainly by N-glycosylation scanning mutagenesis. Since glycosylation occurs on the luminal side of the endoplasmic reticulum only, this method can be used to determine which domains of the protein are located extracellularly. After showing that all three predicted N-linked glycosylation sites are used in vivo, we have inserted such sites independently into each of the putative hydrophilic domains of an aglyco-GAT-1 mutant. Glycosylation and transport activity have been monitored in these transporter constructs upon their expression in HeLa cells. This approach has been applied recently to several transporters and channels (cf. Refs. 12, 13, 14). Our studies indicate that the predicted topology is correct in the carboxyl-terminal two-thirds of the transporter, but suggest a significant deviation from it in the remaining amino-terminal part.
[3H]GABA (47.6 Ci/mmol) was
obtained from the Nuclear Research Center (Negev, Israel). Molecular
mass markers were from Pharmacia Biotech Inc. Solutions of
acrylamide/bisacrylamide were obtained from Bio-Rad. Restriction
enzymes were from New England Biolabs Inc. and Boehringer Mannheim.
T4 polynucleotide kinase, T4 DNA polymerase,
T4 DNA ligase, and the transfection reagent DOTAP were also
from Boehringer Mannheim. Sequenase Version 2.0 kits were obtained from
U. S. Biochemical Corp., and kits for plasmid DNA preparation were
from QIAGEN Inc. [35S]dATPS and
EXPRE35S35S protein labeling mixture (1000 Ci/mmol) were from DuPont NEN. Tissue culture medium, serum, and
antibiotics were from Biological Industries (Kibbutz Beit HaEmek,
Israel). PCOOH, a peptide located in the carboxyl terminus
of GAT-1 (residues 571-586, IQPSEDIVRPENGPEQ) was
synthesized by Dr. Lea Goldberg (Weizmann Institute, Rehovot, Israel)
on an Applied Biosystems Model 430A peptide synthesizer. The antibody
against PCOOH was raised in a rabbit as described (15).
MTSEA and MTSET were generous gifts from Dr. Arthur Karlin. All other
reagents were obtained from Sigma.
Removal and insertion of N-linked
glycosylation sequences were performed using site-directed mutagenesis
according to the method of Kunkel as described (16, 17). To alleviate
the sequencing burden, the mutations were planned so as to include
recognition sequences of restriction enzymes (six cutters). Mutants
were identified by restriction analysis. The first step was to make the
deglycosylated form of the GABA transporter. This was done by
sequential removal of the three native N-glycosylation sites
located in the extracellular area of the protein. The resulting aglyco
construct (DDD) was then used as the basis for inserting
N-linked glycosylation sequences into putative hydrophilic
loops and tails. The important mutants, including all those displayed
in the figures, were subcloned back into the wild type (see Figs. 2 and
6) or into aglyco-GAT-1 (see Figs. 3, 4, 5) using unique restriction
sites. The inserts were then sequenced in both directions. In the case
of all other mutants (listed in Tables I and II), at least two
independent Escherichia coli colonies harboring the mutant
plasmids were characterized by transport activity. In two cases (out of
the 44 mutants), no transporter was detected upon immunoprecipitation.
However, when additional colonies were examined, immmunoprecipitation
showed a full-length transporter.
Analysis of GAT-1 transporters from which the
N-glycosylation consensus sites in EL2 have been removed
sequentially. A, nucleotide and amino acid sequences of the
mutations. The number on the right-hand side of the protein
sequence indicates the position of the last amino acid shown.
WT, wild type. Italics indicate the mutations.
B, immunoprecipitation of the wild-type (NNN) and mutant
transporters synthesized in HeLa cells. HeLa cells were infected with
recombinant vaccinia/T7 virus and transfected with pBluescript
containing the wild type, the indicated mutants lacking consensus
N-glycosylation sites (see A), or the vector
without insert (SK). The cells were preincubated with (+) or
without () tunicamycin, labeled with [35S]methionine,
lysed, and immunoprecipitated with anti-PCOOH antibody as
described under "Experimental Procedures." The
arrowheads indicate the positions of 94- and 67-kDa
standards on the gel. C. sodium-dependent [3H]GABA uptake in HeLa cells infected with recombinant vaccinia/T7 virus and transfected with the above cDNA
constructs. Results are given as percent of transport of the mutants
relative to that of the wild type (NNN). Each bar is the
mean ± S.E. of three to five different experiments.
Effects of MTSEA and MTSET on wild-type and
C74S transporters. A, HeLa cells expressing wild-type
(WT) GAT-1 (filled symbols) and C74S-GAT-1
(open symbols) were incubated for 5 min in a solution
containing 150 mM NaCl, 0.5 mM
MgSO4, 0.3 mM CaCl2, and 5 mM potassium Pi, pH 7.4, supplemented with 0, 0.8, and 1.6 mM concentrations of either MTSEA
(circles) or MTSET (squares). Sodium-dependent [3H]GABA transport was
assayed as described under "Experimental Procedures." Data are the
means ± S.E. of triplicate samples from a representative
experiment. B, several incubations were set upcontaining 60 nmol of 5,5-dithiobis(2-nitrobenzoic acid) and 40 nmol of DL-dithiothreitol in 1 ml of 50 mM
sodium Pi and 0.25 mM EDTA, pH 7.4. After 10 min, the indicated amounts of p-hydroxymercuriphenylsulfonic acid (filled squares) or the test reagents MTSEA and MTSET
were added (open triangles), and the alkylation of the
reduced 5,5
-dithiobis(2-nitrobenzoic acid) was followed by the
reduction of the absorbance at 420 nm. C, HeLa cells
expressing the wild-type transporter were solubilized and incubated on
ice for 10 min with cholate (1%) and liposomes (17). Subsequently,
aliquots of this mixture were incubated on ice for 5 min with a 1 mM concentration of either MTSEA or MTSET or without
additions (control). After reconstitution by centrifugation through
spin columns, sodium-dependent GABA transport was
measured.
|
|
Heterologous expression of wild-type or mutant transporters was performed exactly as described (11). Briefly, HeLa cells were infected with the recombinant vaccinia/T7 virus vTF7-3. Subsequently, they were transfected with the desired cDNA (pBluescript SK with the transporter insert downstream of the T7 promoter) using the transfection reagent DOTAP. Immunoprecipitation was done as described (11) with the following modifications. Cells were plated on 12-well plates (2.5-cm diameter) and transfected with the cDNA encoding wild-type or mutant transporters (11). 16-20 h post-transfection, cells were incubated for 1-2 h in methionine-free Dulbecco's modified Eagle's medium with or without the glycosylation inhibitor tunicamycin (10 µg/ml). The subsequent [35S]methionine labeling (1-2 h) was also carried out in the presence and absence of tunicamycin, respectively. The cells were washed three times with 2 ml of ice-cold phosphate-buffered saline and lysed by the addition of 200 µl of a solution containing 150 mM NaCl, 5 mM EDTA, 10 mM sodium Pi, pH 7.4, and 0.25 mM phenylmethylsulfonyl fluoride, supplemented with 1% SDS. After the mixture was gently agitated with the micropipette tip, 1 ml of the same solution, now supplemented with 1% Triton X-100, was added. All subsequent steps were done at 4 °C. After a 15-min centrifugation in a microcentrifuge, the DNA was removed, and each of the supernatants was precleared by end-over-end shaking with 10 mg of protein A-Sepharose CL-4B to which preimmune serum had been bound previously. After a 5-min centrifugation, the supernatants were incubated overnight with 10 mg of the beads, this time prebound to 10 µl of PCOOH antiserum. After extensive washing and elution (11), samples were analyzed by SDS-polyacrylamide gel electrophoresis (10% gel, 2.6% C). Each lane depicted in the figures represents the processed material from a 2.5-cm well. To obtain maximal resolution, electrophoresis was continued for 1-1.5 h after the dye front ran out. The glycosylation state of each of the mutants shown was verified in at least three independent experiments.
Reconstitution of the transporters into liposomes was done exactly as described (17). Briefly, the cells were concentrated and mixed with cholate and liposomes, and after a 10-min incubation on ice, the proteoliposomes were formed by centrifugation of the mixtures on spin columns. Transport in intact cells (11) and in proteoliposomes (17) was measured as described.
The theoretical model of GAT-1 with its putative hydrophilic domains is shown in Fig. 1. The transmembrane domains are connected by six extracellular loops (EL1-6) and five intracellular loops (IL1-5). Amino- and carboxyl-terminal tails (Fig. 1, NT and CT, respectively) are both located in the cytoplasm. The three glycosylation consensus sequences located in the large EL2 are indicated, but an additional one, located in transmembrane domain 9 (unlikely to be used), is not. Using site-directed mutagenesis, we have eliminated these sites consecutively by converting the asparagines of each of the NX(S/T) sequences into aspartate residues (Fig. 2A). After heterologous expression in HeLa cells and in vivo labeling with [35S]methionine, the synthesized transporters have been immunoprecipitated with an antibody directed against an epitope located in the carboxyl-terminal tail (18). The wild-type transporter is detected in three forms: a monomer running as a band of ~70 kDa, a more abundant dimer, and a high molecular mass aggregate (Fig. 2B). The specificity of the antibody is illustrated by the fact that no bands are detected when the cells are transfected with the vector alone (Fig. 2B, SK). Upon removal of one (NDN), two (NDD and DDN), and three (DDD) of the consensus sites, a stepwise increase in the mobility of the monomer forms of the mutant transporters is observed (Fig. 2B). To some extent, this can also be seen for the dimer forms, but the effect is less pronounced due to the lower resolution of the gel at higher molecular masses (Fig. 2B). When cells expressing the transporters are incubated with the N-linked glycosylation inhibitor tunicamycin (Fig. 2B, + lanes), an increased mobility is detected for the wild type, NDN, NDD, and DDN, which is identical to that for DDD (Fig. 2B). The mobility of DDD is not affected by preincubation with tunicamycin. This indicates that all three N-glycosylation consensus sites are used in vivo and that there are no additional ones. The removal of one or two glycosylation sites has little effect on the expression of transport activity (Fig. 2C). When all three sites are removed, there is a reduction of transport activity. This seems to be due at least in part to reduced trafficking to the plasma membrane since, upon solubilization of the HeLa cells expressing the DDD transporter followed by its reconstitution into liposomes, the activity (compared with that of the wild type) increases from 38% (Fig. 2C) to 62 ± 16% (n = 3). Notwithstanding this, the deglycosylated DDD transporter exhibits significant intrinsic transport activity and has been used as the starting point for introducing consensus glycosylation sites in the putative hydrophilic loops of the transporter.
N-Glycosylation Scanning MutagenesisFig. 3
documents the glycosylation status and transport activity of constructs
of the deglycosylated DDD transporter into which N-linked
glycosylation consensus sequences have been inserted at different
positions in EL3. Replacement of the two amino acids phenylalanine
276 and arginine 277 with isoleucine and threonine creates, together
with asparagine 275, a glycosylation site (Fig. 3A,
275). In the absence of tunicamycin, this transporter has a
lower mobility than in its presence (Fig. 3B). This suggests that the created site is in fact glycosylated. The reproducibility of
the method is demonstrated in Fig. 3B. It shows the results of separate immunoprecipitations of this transporter from HeLa cells
transfected in parallel with the 275 construct. The transport activity
of this construct is similar to that of the DDD transporter (Fig.
3D). It should be noted that the activity in this and in all
subsequent figures is expressed as percent of wild-type (NNN) activity
rather than of DDD activity. The latter, of course, will result in a
much larger percentage of activity. For comparison, the activity of the
DDD construct is also included in all figures. The functionality of the
275 transporter indicates that the mutation does not result in a
transporter with an altered topology. The above data prove that EL3 is
in fact an extracellular loop, in harmony with the theoretical model.
When a double glycosylation site is created by insertion of four amino
acid residues (NSSR) after asparagine 275 (Fig. 3A,
275), no glycosylation is detected (Fig. 3C)
even though transport activity is not compromised (Fig. 3D).
Insertion of a consensus site at position 265 (Fig. 3A) also yields a glycosylated transporter (Fig. 3C). In this case,
the glycosylated transporter is inactive, both in intact cells (Fig. 3D) and in reconstituted proteoliposomes (data not shown).
No glycosylation is observed when a site is inserted at position 281 of
EL3 (Fig. 3, A and C), and this transporter is
inactive (Fig. 3D). Similar results are seen when sites are
inserted at positions 276 and 283 (data not shown). This indicates that
some of the domains in EL3 are important for the expression of
transport activity.
The results shown in Fig. 4 indicate that EL6 is also an extracellular loop. Thus, consensus sites generated by insertion of two (NA) or five (NNSSR) amino acid residues at position 525 (Fig. 4A) are glycosylated in vivo (Fig. 4B), and these glycosylated transporters are functional (Fig. 4C).
Fig. 5 documents results on transporters with glycosylation sites inserted at the amino and carboxyl termini. As anticipated, no glycosylation is observed in these cases, and the insertions do not impair function. Interestingly, glycosylation is observed when the sequence NNSST is inserted at position 110 in IL1 (Fig. 5, A and B). The insertion gives rise to an inactive transporter protein (Fig. 5C). Creation of a site at the same position by substitution rather than addition of amino acids also largely abolishes the activity (Table I), but in this case, no glycosylation is observed. Despite intensive efforts to preserve activity by introducing sites for N-glycosylation at many positions in IL1, none of the mutants was active (Table I).
Probing of the topology of the remaining putative hydrophilic domains is documented in Table II. The insertion of an N-glycosylation site into EL1 at position 78 does not compromise the transport activity, but the site is not glycosylated. Creation of sites in EL4 and EL5 does not compromise activity in many cases, but glycosylation could not be detected (Table II). In all cases, creation of N-linked glycosylation sites at IL2, IL4, and IL5 yields nonfunctional, nonglycosylated transporters. Creation of a site at position 316 in IL3 yields a functional, albeit nonglycosylated, transporter.
Reactivity of Cysteine 74 toward Permeant and Nonpermeant Methylthiosulfonate ReagentsBecause of the indication of an external location for IL1, it was of special interest to determine on which side of the membrane EL1 is located. The lack of glycosylation in this loop may be due to accessibility problems of the N-oligosaccharyltransferase. Therefore, we have used small, very hydrophilic methylthiosulfonate derivatives, which react covalently with free cysteines (19, 20, 21, 22, 23, 24) and are expected to be very accessible to short and possibly buried loops.
In preliminary experiments, we have observed that MTSEA inhibits GABA
transport in HeLa cells expressing GAT-1. This inhibition can be
reversed by DL-dithiothreitol (data not shown). According to the theoretical model, three cysteine residues are exposed to the
outside. These are cysteine 74, located in EL1, and cysteines 164 and
173, both located in EL2. In the dopamine transporter, the two
cysteines at comparable positions to Cys164 and
Cys173 are important for targeting the transporter to the
plasma membrane (25). They probably form a disulfide bond, as has
recently been demonstrated in the related serotonin
transporter.2 Thus, according to the
theoretical model, cysteine 74 is the only free cysteine exposed to the
outside and is a prime candidate for modification by MTSEA. Evidence
consistent with this idea is presented in Fig.
6A. When cysteine 74 is mutated to a serine residue (C74S), the transporter becomes more resistant to inhibition by
MTSEA. It is of interest to note that C74S is still sensitive to the
sulfhydryl reagent, suggesting that other cysteines located on the
transporter may also participate in the inhibition. However, the
remaining 13 cysteine residues in GAT-1 are predicted to be in the
membrane or to face the interior of the cell. A possible explanation
for this is that MTSEA can permeate the membrane. While this work was
in progress, several groups have obtained experimental evidence for the
membrane permeability of MTSEA (26, 39). In the same studies, it was
found that MTSET is impermeant. This sulfhydryl reagent does not
inhibit GABA transport either in the wild-type transporter or in the
C74S transporter (Fig. 6A), even though it is more reactive
toward sulfhydryl groups than MTSEA (23). Reactivity of our MTSET
reagent was ascertained by checking its ability to react with reduced
5,5-dithiobis(2-nitrobenzoic acid) (Fig. 6B). Furthermore,
when the permeability barrier is taken away by solubilization, MTSET is
able to inactivate the transporter as monitored after reconstitution
(Fig. 6C). Thus, cysteine 74 appears to be located
intracellularly.
The data presented in this paper show unambiguously that the three
hydrophilic stretches EL2, EL3, and EL6 are extracellular. The
extracellular location of EL2 was anticipated since it is the only loop
throughout the superfamily of (Na+ + Cl)-coupled transporters (excluding the so-called orphan
transporters) containing N-glycosylation consensus sites.
This is also in harmony with similar data obtained with the
transporters for serotonin (27) and norepinephrine (28) as well as the
glycine transporter GLYT-1 (29). No experimental evidence on the
location of EL3 and EL6 in any transporter of the superfamily has been
presented in the literature to date. Earlier studies using this
approach on other transporting proteins had indicated that insertion of glycosylation sites into hydrophilic linker loops is very well tolerated (12, 13). However, our results (Figs. 2, 3, 4, 5 and Tables I and
II) and those presented in the accompanying paper on GLYT-1 (32)
indicate that the approach is not straightforward, as is also seen in
the case of the Na+-coupled glucose transporter (14). The
ability to undergo glycosylation is critically dependent on the
position of the site in the loop and on the nature of the insert (Fig.
3). In some cases, transport is abolished, but glycosylation is not
(Figs. 3 and 5). In other cases, the opposite is true (Table II). The
accessibility of an external loop to the glycosylating enzymes may be
limited because it may participate in the formation of the
transporter's pore. This would also explain loss of function upon
insertion and/or replacement of amino acids. Also, from the importance
of hydrophilic loops for transport and substrate specificity (30, 31),
it can be predicted that any perturbation may result in impaired transport. It is therefore not surprising that we were unable to obtain
active and glycosylated mutants in EL4 and EL5. Glycosylation in these
two loops has been observed in the accompanying paper on the topology
of GLYT-1, although this resulted in impaired function (32). Good
supporting evidence for an external location of EL4 has been obtained
in the case of the human norepinephrine transporter (28).
With the method of N-glycosylation scanning mutagenesis, internal loops score negative. Because of the problem of steric hindrance of glycosylation, negative results may also be observed for external loops. Thus, there is an inherent problem in proving the location of internal loops by this method. This is perhaps less critical in the amino- and carboxyl-terminal tails as they are much more hydrophilic than the loops. They do not participate in the transport process (15, 33) and therefore probably do not intercalate between the transmembrane domains. Were they located on the outside, they would probably be accessible to N-oligosaccharyltransferase. The lack of glycosylation observed in both tails (Fig. 5) is consistent with their predicted internal localization. Independent evidence supporting this is available for transporters of glycine, GLYT-1, and GLYT-2 (34) and of dopamine (35). We conclude that the theoretical model is by and large correct between EL2 and the carboxyl-terminal tail.
The glycosylation in IL1 at position 110 results in a nonfunctional transporter. We cannot rule out the explanation that the insertion has scrambled the topology. However, in the case of the sodium-coupled glucose transporter, this problem has been observed with large inserts (48 amino acids), but not with small ones like we have used here. The most straightforward explanation is that this glycosylation is due to the external location of IL1. The loss of transport activity probably means that this loop is critical for GABA transport. In fact, all the modifications in IL1 (even those without a change in the number of amino acids) impair activity (Table I). It should also be noted that glutamate 101, located in this loop, has been found to be essential for transport activity (36). As shown in the accompanying paper (32), glycosylation of IL1 has also been observed in the related transporter GLYT-1.
An external location of IL1 and an internal location of the
amino-terminal tail implies that one of the first two transmembrane domains does actually not span the membrane. Inspection of the hydropathy plots throughout the superfamily indicates that the first
domain does not score very well as a transmembrane -helix. In fact,
our results with permeant and impermeant methylthiosulfonate reagents
(Fig. 6) suggest that cysteine 74 in EL1 is located intracellularly. The lack of glycosylation of this loop (Table II) is consistent with
this. These findings can be accommodated in the topological model shown
in Fig. 7. The former transmembrane
-helix 1 (Fig. 1)
does not cross the membrane. Since it is highly conserved, has
considerable hydrophobicity, and contains the critical arginine 69 (37), we have depicted it as a "pore loop" associated with the
membrane. Such pore loops are involved in ion permeation through voltage- or ligand-dependent ion channels (see Ref. 38 for
a review). Evidence for a membrane association of domain 1 is presented in the accompanying paper (32). However, there are other possibilities. For instance, the domain could be cytoplasmic and might serve as an
intracellular plug on the transporter's pore. Transmembrane
-helix
2 in the theoretical model (Fig. 1) is now the first true transmembrane
domain. EL2 has been shortened at the amino-terminal side to make a
place for an additional transmembrane domain (domain 3*). This is
required so that the natural glycosylation sites still face outside.
Theoretically, this is feasible, as around the former transmembrane
helix 3, there is a hydrophobic stretch of 44 amino acids, from
residues 118 to 161 (legend to Fig. 7) (6). This could easily
accommodate two transmembrane domains. Moreover, experimental evidence
for such an additional transmembrane domain has been obtained in the
case of GLYT-1, as reported in the accompanying paper (32). It should
be emphasized that although the model is consistent with the
experimental data obtained, it will be important to carry out studies
with independent methods to test if all of its aspects are
accurate.
We anticipate that the modified topological model presented here will be relevant not only for GAT-1 and GLYT-1, but for all members of the superfamily. The results reported here are a first step toward further experiments designed to clarify the structural basis of the transport mechanism.
We thank Annie Bendahan for help in some of the preliminary experiments; Dr. Arthur Karlin for gifts of the methylthiosulfonate reagents; Dr. Bernard Moss for the recombinant vaccinia/T7 virus vTF7-3; Dr. Shimon Schuldiner for critical reading of the manuscript; Drs. Etana Padan, Gary Rudnick, and Gary Yellen for sharing data prior to publication; and Beryl Levene for expert secretarial assistance.