Alternative Splicing of the C-Terminal Domain Regulates Cell Surface Expression of the NMDA Receptor NR1 Subunit

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The Journal of Neuroscience, September 15, 1999, 19(18):7781-7792

Alternative Splicing of the C-Terminal Domain Regulates Cell Surface Expression of the NMDA Receptor NR1 Subunit
Shigeo Okabe¹^,², Akiko Miwa³, and Haruo Okado³
¹ Laboratory of Molecular Neurobiology, National Institute of Bioscience and Human Technology, Tsukuba, Ibaraki 305-8566, Japan, ² Department of Anatomy and Cell Biology, School of Medicine, Tokyo Medical and Dental University, Bunkyo-ku, Tokyo, 113-8519, Japan, and ³ Department of Neurobiology, Tokyo Metropolitan Institute for Neuroscience, Fuchu, Tokyo 183-8526, Japan

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subcellular localization of the NMDA receptor NR1 splice forms was studied by expressing individual splice variants and theirepitope-tagged derivatives in mouse fibroblasts and in hippocampalneurons. When NR1 splice variants were expressed in fibroblasts,the amount of NR1 molecules expressed on the cell surface variedamong forms with different C-terminal cytoplasmic domains. Thesplice forms with the longest C-terminal cytoplasmic tail (NR1-1aand NR1-1b) showed the lowest amount of cell surface expression,and the splice forms with the shortest C-terminal cytoplasmictail (NR1-4a and NR1-4b) showed the highest cell surface expression.Cell surface expression of NR1 was enhanced by the coexpressionof the NR2 subunit. We measured the glutamate-induced increaseof calcium concentration in fibroblasts expressing one of theNR1 splice forms and the NR2B subunit. The increase of calciumconcentration after glutamate application had a positive correlationwith the amount of NR1 splice forms expressed on the cell surface.When epitope-tagged NR1 splice variants were expressed in primaryhippocampal neurons using recombinant adenoviruses, we also observedthe differential expression on the cell surface between splicevariants. These results suggest that the splicing of the C-terminaldomain of the NR1 subunit regulates the cell surface expressionof the functional NMDAreceptors.

Key words: NMDA receptor; alternative splicing; fluorescent antibody technique; calcium imaging; membrane proteins; neurons

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Glutamate is the major excitatory neurotransmitter in the vertebrate CNS. Ionotropic glutamate receptors are divided intoAMPA, kainate, and NMDA subclasses according to the specific agoniststhat activate these receptor subclasses. NMDA receptors are expressedwidely in the mammalian CNS and play a central role in synapticplasticity, circuit formation, and excitotoxicity (Nakanishi,1992). NMDA receptors are comprised of NR1 and NR2 subunits. Bothsubunits have a transmembrane topology that is similar to thatof other AMPA and kainate receptors (Hollmann et al., 1994; Woodet al., 1995; Hirai et al., 1996). They have three transmembraneregions and one membrane-associated region with the N-terminalextracellular domain and the C-terminal cytoplasmic domain. NR1subunits exist in eight alternatively spliced forms derived froma single gene product (Sugihara et al., 1992; Hollmann et al.,1993), and NR2 subunits are the products of four different genes,NR2A-NR2D (Kutsuwada et al., 1992; Monyer et al., 1994). Althoughextensive electrophysiological and biophysical studies have revealedthe properties of the agonist binding domains and the channelforming domains of the NMDA receptor complex, little is knownabout the mechanism of cell surface expression and accumulationat thesynapse.

Several recent immunocytochemical and biochemical studies have shed light on the distribution of the NMDA receptor moleculeson the neuronal cell surface and the relationship between thesubunit assembly and cell surface expression. Only 40-50% of theNR1 molecules are expressed on the cell surface in cultured hippocampalneurons, whereas most of the NR2B molecules are expressed on thecell surface (Hall and Soderling, 1997). Cell surface stainingexperiments have shown that the NR1-1a splice form requires NR2Amolecules for efficient cell surface expression (McIlhinney etal., 1996). Identification of a family of proteins containingmultiple postsynaptic density 95/Discs large/zona occludens 1[PSD-95/Discs large/ZO-1 (PDZ)] domains, such as PSD-95 and chapsyn-110(PSD-93), has revealed the receptor clustering activity of theseproteins when expressed in a heterologous system (Kornau et al.,1995; Kim et al., 1996). Furthermore, splice variant-specificformation of receptor clustering was observed in cells expressingNR1 molecules without other receptor-associated proteins (Ehlerset al., 1995). These observations indicate that the NMDA receptorexpression and clustering on the cell surface is a complexprocess.

To elucidate the mechanisms of formation of the NMDA receptor complex on the cell surface, subcellular distributions of theeight splice variants of the NR1 subunit were analyzed in boththe absence and presence of the NR2 subunit in fibroblasts. Differentialefficiency of the cell surface expression among splice variantswas further tested by Ca²⁺ imaging in fibroblasts and by expressing epitope-tagged NR1 moleculesin primary hippocampal neurons. The results suggest a possibleregulation of the cell surface expression of the NMDA receptorcomplex by the alternative splicing of the C-terminal domain ofthe NMDA receptor NR1subunit.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Construction of NR1 subunit expression vectors. cDNAs encoding NR1 splice variants were provided by Dr. M. Hollmann (Gottingen,Germany). cDNAs were cloned into the mammalian expression vectorpCMV $beta$ (Clontech, Palo Alto, CA) after removal of the $beta$ -galactosidasecDNA. Human c-myc tag (EQKLISEEDL) or influenza hemagglutininprotein (HA) tag (YPYDVPDYA) was inserted between Ile26 and Val27of the NR1 cDNAs, and the cDNAs were cloned into the pCMV $beta$ vector.

Transfection of 3T3 cells. Transfection of 3T3 cells was performed using lipofectamine (Life Technologies, Grand Island, NY)reagent at 40-50% confluence. Cells were plated onto polyornithine-coatedcoverslips for immunofluorescence microscopy or onto 60 mm tissueculture dishes for immunoelectron microscopy and for preparationof cell extracts, or they were plated onto poly-L-lysine-coatedcoverslips attached to the bottom of 35 mm tissue culture disheswith holes of 10 mm diameter for Ca²⁺ imaging. Cells were assayed 2 d aftertransfection.

Antibodies. We obtained monoclonal anti-NR1 antibody (clone 54.1) from PharMingen (San Diego, CA) and used it at a concentrationof 1:100 for immunofluorescence and 1:1000 for immunoblotting.Monoclonal anti-HA antibody (clone 12CA5) came from BoehringerMannheim (Indianapolis, IN) and were used at a concentration of1:100. We obtained polyclonal anti-synaptophysin antibody fromZymed (San Francisco, CA) and monoclonal anti- $alpha$ -tubulin (DM-1A)from Seikagaku Corporation (Tokyo, Japan). Mouse hybridoma cellline 9E10 was obtained from Developmental Studies Hybridoma Bank(Iowa City, IA). Anti-myc monoclonal antibody was purified fromhybridoma supernatant by protein G-Sepharose column and used atthe concentration of 1 µg/ml.

Fluorescein-conjugated anti-mouse IgG antibody and rhodamine-conjugated anti-rabbit IgG were obtained from Dako (Glostrup,Denmark). Rhodamine-conjugated anti-mouse IgG antibody was fromCappel (West Chester, PA), fluorescein-conjugated goat Fab' anti-mouseIgG was from Protos Immunoresearch (San Francisco, CA), and Cy3-conjugatedgoat anti-mouse IgG was from Jackson ImmunoResearch (West Grove,PA).

Cell surface staining of 3T3 cells, COS7 cells, and PC12 cells. We added anti-myc antibody directly to the culture mediumat a concentration of 1 µg/ml and incubated the cells for 20 minat 37°C. Cells were washed with prewarmed culture medium and thenreacted with fluorescein-conjugated IgG or Fab' against mouseIgG for 10 min. Cells were rinsed in HBSS (Life Technologies)and fixed with 2% paraformaldehyde in PBS for 25 min at room temperature.In some experiments, samples were further processed for the detectionof intracellular antigens after permeabilization in 0.2% TritonX-100. We also performed cell surface labeling of cells afterfixation with 2% paraformaldehyde in PBS and obtained basicallyidentical stainingpattern.

Immunoblotting and immunoprecipitation. Immunoblotting and immunoprecipitation were done as described previously (Okabe etal., 1998a). For immunoblotting, cells were directly dissolvedin SDS gel sample buffer (2% SDS, 50 mM Tris-HCl, pH 7.5, 0.75%DTT, 5% glycerol, Bromophenol blue) and heated to 95°C for 5 min.Immunoprecipitation of NR1 from brain extract was performed usingmonoclonal anti-NR1 in combination with protein A-Sepharose (AmershamPharmacia Biotech, Uppsala,Sweden).

Immunofluorescence microscopy. Cells were washed in PBS and fixed in 2% paraformaldehyde in PBS for 20 min at room temperature.After the brief wash in PBS, cells were permeabilized in 0.1-0.2%of Triton X-100 for 5 min, and then nonspecific binding was blockedby incubation in 5% normal goat or horse serum in PBS for 30 min.Then, the cells were washed in PBS and incubated with primaryantibodies in PBS for 30 min at room temperature. After washingin PBS three times, samples were incubated with fluorescein orrhodamine-conjugated secondary antibodies in PBS plus 2% normalgoat or horse serum for 30 min. Cells on the coverslips were washedin PBS three times, mounted in 70% glycerol in PBS, and examinedunder a Zeiss (Oberkochen, Germany) Axiophoto microscope or aZeiss LSM501 confocal laser scanning microscope. Quantitationof fluorescence was done using a Zeiss LSM501 confocal laser scanningmicroscope. We made optical sections through the depth of thecells for each preparation, and the fluorescence intensity wascalculated from the single optical slice at the cell surface forcell surface intensity and from summation and averaging of thetotal z-axis stack for total cellularintensity.

Calcium imaging of transfected 3T3 cells. We performed imaging of intracellular Ca²⁺ by calculating the background-corrected fluorescence ratio offura-2 at 340 and 380 nm excitation, using an Axon Imaging Workbenchsystem (Axon Instruments, Foster City, CA). The exposure timeat each wavelength was 132 msec, with a single frame pair capturedevery second. We estimated the free calcium concentration froma standard curve between the F₃₄₀/F₃₈₀ ratio and [Ca²⁺], using the established calibration method (Grynkiewicz et al.,1985). 3T3 cells were loaded with fura-2 by incubation in fura-2AM (Molecular Probes, Eugene, OR) at a concentration of 5 µM inHEPES-buffered saline (HBS) (in mM: 20 Na-HEPES, pH 7.4, 115 NaCl,5.4 KCl, 1 CaCl₂, and 13.8 glucose) for 30 min at room temperature.Experiments were performed at room temperature in a perfusionchamber. HBS was used as a recording saline. L-glutamate and glycinewere dissolved in recording solution at 10 and 1 µM, respectively.Application of drugs was accomplished by complete bath exchange.Pseudocolor images were created from raw eight-bit images usingNIH Imagesoftware.

Calcium concentrations were calculated by averaging intracellular calcium of cells expressing a red-shifted variant of greenfluorescent protein (eGFP), that is, those cells of which averageintensity of eGFP signal was >30 (on a scale of 0-256 eight-bitdigital images) after background subtraction. In most transfectionexperiments, one microscopic field (under a 40× oil immersionlens) contained 10-20 eGFP-positive 3T3 cells. Four fura-2 imagepairs before perfusion and seven fura-2 image pairs 20-26 secafter perfusion of 0.5 ml of glutamate-containing HBS were recorded.No large fluctuation of fura-2 signals was observed during theperiod of 20-27 sec after perfusion ingeneral.

Primary culture of mouse hippocampal neurons. Mouse hippocampal cells were prepared from embryos at the age of embryonic day17 (E17). The method of dissection and dissociation was basicallyidentical to the method of rat hippocampal cell culturing describedpreviously (Okabe et al., 1998b). The cell suspension was platedonto glass coverslips in 24-multiwell plates, coated with 1 mg/mlpoly-L-lysine, at a density of 200-500 cells/mm². Cells were incubated at 37°C under 5% CO₂ in an MEM medium (LifeTechnologies) containing 2% B-27 supplement (Life Technologies),5% fetal bovine serum (Equitech-Bio, Ingram, TX), and 0.2 mM L-glutamine.Ara-C (10 µM) was added 2 d after plating to prevent glial proliferation.One-fifth of the medium was replaced every 3-4d.

Generation of recombinant adenoviruses. Construction of replication-deficient adenovirus was performed using the cosmid-terminalprotein complex (COS-TPC) method described previously (Miyakeet al., 1996). Recombinant adenoviruses expressing NR1 molecules(AxCMV-NR1-1b or AxCMV-NR1-4b) are human adenoviruses serotype5, removing sequences in the E1A, E1B, and E3 regions, with aninsertion of an NR1-1b or NR1-4b expression unit (Kanegae et al.,1995). The NR1-1b or NR1-4b expression unit contains an NR1-1bor NR1-4b coding region under the control of the cytomegalovirusimmediate early gene promoter, together with the rabbit $beta$ -globinpolyadenylation signal. The recombinant viruses were purifiedby CsCl step gradients and were stored at $-$ 80°C (Kanegae et al.,1994).

Adenovirus infection. Day 16-18 hippocampal neurons, COS7 cells, or PC12 cells were exposed for 60 min to viruses at a multiplicityof infection of 100. Cells were then washed, reincubated in thepreviously removed media, and after 48 hr, assayed by immunocytochemistryorimmunoblotting.

Cell surface labeling of primary neurons. Primary neurons were incubated in HBS containing 1 µg/ml anti-myc antibody for 20min at room temperature, washed with HBS three times, and thenfixed by methanol at $-$ 20°C for 10 min. Fixed cells were treatedwith 5% normal horse serum to block nonspecific binding, and thefirst antibody was visualized by secondary antibody staining usinggoat anti-mouse IgG conjugated to Cy3. Cells were then reactedwith either anti-myc antibody again to detect total myc-taggedNR1 protein or anti-synaptophysin antibody to detect the presynapticstructure, using fluorescein-conjugated secondary antibody. Whencells were fixed before cell surface labeling, similar distributionof cell surface NR1 molecules were detected by successive reactionwith Cy3-conjugated secondary antibody. However, the intensityof staining was weaker, possibly because of the reduction of antigenicityof the mycepitope.

Expression of the results of cell counting. To determine the number of cells, a total of 10-30 randomly chosen fields percoverslip was counted using 200 or 400× magnification under afluorescence microscope. Results of double-staining experiments(see Figs. 3, 7) were expressed as the percentage of cells positivewith cell surface staining in the population of cells positivewith total cellular staining. All numerical values were the mean± SEM of data from three to four independent cultureexperiments.

Immunofluorescence microscopy of transfected 3T3 cells using anti-NR1 or anti-myc antibody revealed that >30% of cells weretransfected and expressed NR1 molecules. Because cells havingfaint staining of total NR1 molecules were included in cell counting,proportion of cells showing surface staining fell in a range of4.0-35% of transfected cells. However, cell surface expressionof NR1 splice variants was not a rare event, because most of thecells expressing large amount of NR1 molecules showed cell surfaceexpression, except cells expressing NR1-1 spliceforms.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Immunofluorescence analysis of subcellular distribution of NMDA receptor NR1 subunits

The anti-NMDA receptor NR1 antibody (clone 54.1) recognizes the NMDAR1 residues 660-811 [according to Moriyoshi et al. (1991)],which correspond to the extracellular loop between M3 and M4 (Broseet al., 1994) (Fig. 1). Human c-myc or influenza HA tag was addedto the N-terminal domain of the eight splice variants of the NR1molecules to detect extracellular epitopes distinct from the epitopeof clone 54.1. Native NR1 splice variants or their epitope-taggedderivatives were expressed in mouse 3T3 fibroblasts, and transfectedcells were examined by immunofluorescence microscopy using anti-NR1monoclonal antibody (clone 54.1), anti-myc monoclonal antibody(clone 9E10), or anti-HA monoclonal antibody (clone 12CA5).

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Figure 1. Membrane topology and location of three exon cassettes of the NMDA receptor NR1. NMDA receptor NR1 molecules have three membrane-spanning domains (M1, M3, and M4) and one membrane-associated domain (M2). A human c-myc and influenza HA tag was inserted at the N-terminal extracellular region of the NR1 molecule. Monoclonal anti-NR1 (clone 54.1) recognizes the extracellular region between M3 and M4. Exon cassettes N, C1, and C2 are shown as open boxes. The NR1-3 and NR1-4 splice forms lack a C2 exon cassette, and this results in the creation of an additional coding region of 22 amino acids (C2' cassette). Eight splice variants are formed by the presence and absence of these three exon cassettes. We used the nomenclature of NR1 splice forms by Hollmann et al. (1993) in this study.

We examined total cellular distribution of NR1 splice variants by immunolabeling detergent-treated 3T3 cells (Fig. 2A-L).Localization of NR1-1a and NR1-1b splice forms was distinct fromthe other six splice variants. NR1-1a and NR1-1b proteins formeddiscrete subcellular domains that were closely associated withthe plasma membrane. The other six splice variants were distributedthroughout the cells and did not form discrete clusters. Cellcounting of 3T3 cells transfected with "b" splice forms, and theirmyc-tagged molecules confirmed that only NR1-1 splice forms formeddiscrete clusters (Fig. 2M).

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Figure 2. Subcellular localization of NR1 splice forms in 3T3 fibroblasts. 3T3 cells were transfected with eight splice forms of NR1 molecules and their epitope-tagged derivatives and examined by immunofluorescence. A-L, NR1-2a (C), NR1-2b (D), NR1-3a (E), NR1-3b (F), NR1-4a (G), NR1-4b (H), and their epitope-tagged molecules [NR1-2amyc (J), 2aHA (L)] were localized throughout the cytoplasm. In contrast, NR1-1a (A), NR1-1b (B), and their epitope-tagged molecules [NR1-1amyc (I), 1aHA (K)] formed distinct subcellular domains (arrows). M, Percentage of cells having distinct domains of anti-NR1 or anti-myc immunoreactivity in cells transfected with four splice variants of NR1 (NR1-1b to NR1-4b) and their myc-tagged derivatives (NR1-1bmyc to NR1-4bmyc). More than 200 cells immunopositive with anti-NR1 or anti-myc antibodies were examined for the presence of distinct receptor-rich domains in each transfection experiment. Four independent experiments were performed. Scale bar, 20 µm.

To detect NR1 molecules expressed on the cell surface, live 3T3 cells transfected with NR1 splice forms were labeled withanti-NR1, anti-myc, or anti-HA antibody, and the cells were subsequentlyreacted with fluorescein-conjugated anti-mouse IgG antibody. Cellsurface expression of the NR1 molecules was found in the cellsexpressing NR1-2a, NR1-2b, NR1-3a, NR1-3b, NR1-4a, NR1-4b (Fig.3A-F), or their epitope-tagged derivatives (Fig. 3I, 4bmyc) (datanot shown for other myc-tagged splice forms). In contrast, nocell surface staining was detected in the cells expressing NR1-1a,NR1-1b, NR1-1amyc, or NR1-1bmyc (Fig. 3G, 1bmyc). The presenceor absence of the N-terminal exon cassette did not influence thecell surface expression of the NR1 molecules.

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Figure 3. Cell surface expression of NR1 splice forms in 3T3 fibroblasts. 3T3 cells were transfected with eight splice forms of NR1 molecules and their epitope-tagged derivatives, and NR1 molecules on the cell surface were detected by reacting live 3T3 cells with primary antibodies and fluorescein-conjugated secondary antibodies. A-F, Cell surface staining was detected in cells transfected with NR1-2a (A), NR1-2b (B), NR1-3a (C), NR1-3b (D), NR1-4a (E), and NR1-4b (F). Similar cell surface staining was detected in cells transfected with corresponding myc-tagged derivatives. G-J, Transfected cells reacted with anti-myc antibody and fluorescein-conjugated secondary antibody were fixed, permeabilized, and further processed for the detection of total myc-epitopes by anti-myc antibody and rhodamine-conjugated secondary antibody. Cells transfected with NR1-1bmyc did not show cell surface staining (G), even in the presence of abundant total cellular staining (H). Cells transfected with NR1-4bmyc had both strong cell surface staining (I) and total cellular staining (J). K, Quantitation of cell surface expression of NR1 splice variants. Cells were double-labeled for cell surface staining and total cellular staining, as shown in G-J, and we then determined the percentages of cells having cell surface staining with either anti-NR1 or anti-myc. More than 100 cells immunopositive with anti-NR1 or anti-myc antibodies were examined for the presence of cell surface staining in each transfection experiment. Four independent experiments were performed. Scale bar, 20 µm.

To quantitate the difference of the cell surface expression of the NR1 splice variants, percentages of cells showing cellsurface staining of NR1 molecules were calculated by labelingboth cell surface and total cellular NR1 molecules with differentchromophores and subsequently analyzing them with immunofluorescencemicroscopy (Fig. 3G-J). The most striking difference was thatthe cells expressing the NR1-1b or NR1-1bmyc splice form did notshow any surface staining, whereas 4.0-35% of transfected cells(corresponding to 2.0-15% of total cell population) expressingthe other three splice forms showed cell surface expression ofthe NR1 molecules (Fig. 3K). The proportion of cells having theNR1 molecules on the cell surface was statistically differentamong the NR1-2b, NR1-3b, and NR1-4b subunits (NR1-2b, NR1-3b,NR1-4b, one-way ANOVA; F = 39.35; p < 0.004; NR1-2bmyc, NR1-3bmyc,NR1-4bmyc, F = 24.8; p < 0.001). A similar amount of the NR1 proteinwas detected in samples from cells transfected with differentsplice variants by immunoblotting (Fig. 4A-C). This result showsthat the differential cell surface expression cannot be explainedby the differential amount of the expressed proteins.

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Figure 4. SDS-PAGE analysis of the amount of NR1 molecules. A-C, The amount of NR1 proteins in 3T3 cells transfected with NR1 splice variants NR1-1b (lane 1), NR1-2b (lane 2), NR1-3b (lane 3), NR1-4b (lane 4), and their myc-tagged derivatives. Total proteins were solubilized in sample buffer and detected with anti-NR1 antibody (A) or anti-myc antibody (B). Anti-NR1 antibody detects 120 kDa NR1 polypeptides in cells transfected with authentic NR1 splice forms and their myc-tagged derivatives. Anti-myc antibody specifically detects 120 kDa proteins in cells transfected with myc-tagged NR1 splice variants. The similar amount of proteins loaded on the gel was confirmed by blotting using anti-tubulin antibody (C). Arrowheads indicate the positions of molecular weight markers (120, 90, 48, and 35 kDa). Lane B in A shows the electrophoretic mobility of native NR1 molecules immunoprecipitated from brain extract. D, E, The amount of NR1 protein in 3T3 cells transfected with NR1 splice variants NR1-1b, NR1-2b, NR1-3b, and NR1-4b together with NR2B. Cells were maintained for 2 d with or without NMDA receptor antagonist D,L-APV, and total proteins were extracted in sample buffer. The amount of NR1 protein in cells maintained with D,L-APV was higher than that in cells maintained without NMDA antagonist. A similar amount of NR1 protein was detected among different splice variants in the presence of D,L-APV (D). The similar amount of proteins loaded on the gel was confirmed by blotting using anti-tubulin antibody (E). F, The amount of NR1 protein in COS7 cells infected with recombinant adenoviruses. Infected cells were maintained for 2 d after viral infection, and total proteins were extracted in sample buffer. Blotting using anti-NR1 antibody and anti-myc antibody revealed similar amounts of NR1-1bmyc (lane 1) and NR1-4bmyc (lane 4). Arrowheads indicate the positions of molecular weight markers (120, 90, 48, and 35 kDa).

Interaction between NR1 splice variants

To see how different splice variants interact with each other in a single cell, 3T3 cells were cotransfected with either NR1-1aplus NR1-2amyc or NR1-4b plus NR1-1bmyc, and the distributionsof myc-tagged splice forms were examined. When NR1-2amyc was coexpressedwith NR1-1a, NR1-2amyc molecules formed distinct receptor-richdomains and were colocalized with NR1-1a molecules (Fig. 5A,B,E).No subcellular clustering of NR1-2amyc was observed without NR1-1a.This result suggests that NR1 splice variants can interact witheach other in the intracellular membrane organelles, because NR1-1a-richdomains are the intracellular structure.

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Figure 5. Interaction between NR1 splice variants. A, B, 3T3 cells transfected with NR1-1a and NR1-2amyc and reacted with anti-myc antibody (A) for the detection of NR1-2amyc and with anti-NR1 antibody (B) for the detection of total NR1 molecules. NR1-2amyc was colocalized with NR1-1a to form distinct subcellular domains (arrows in A and B). C, 3T3 cells were transfected with NR1-4b and NR1-1bmyc. NR1-1bmyc molecules were detected by surface staining with anti-myc antibody. Intense surface staining was observed in the presence of NR1-4b. D, 3T3 cells transfected with NR1-4b and NR1-4bmyc. Cell surface NR1-4bmyc molecules were detected by anti-myc antibody. E, Cell counting of 3T3 cells transfected with either NR1-1amyc or NR1-2amyc with or without NR1-1a. Without NR1-1a, no 3T3 cells formed distinct NR1-2a-rich domains. With NR1-1a, NR1-2a-rich domains were observed in >4% of transfected cells. More than 100 cells were counted for each transfection experiment; three independent transfection experiments were performed. F, Cell counting of 3T3 cells transfected with either NR1-1bmyc or NR1-4bmyc with or without NR1-4b. Without NR1-4b, no 3T3 cells transfected with NR1-1bmyc showed cell surface staining with anti-myc antibody. With NR1-4b, NR1-1bmyc was present on the cell surface in 8% of transfected cells. More than 100 transfected cells were examined for each transfection experiment; three independent transfection experiments were performed. Scale bar, 20 µm.

To see whether the coexpression of NR1-4b facilitates the cell surface expression of the NR1-1bmyc, 3T3 cells were cotransfectedwith NR1-4b and NR1-1bmyc, and the NR1-1bmyc expressed on thesurface was detected by anti-myc antibody (Fig. 5C,D). Eight percentof cotransfected cells showed unambiguous surface staining withanti-myc antibody (Fig. 5F). Control cells expressing NR1-1bmycalone did not show any surface staining. This result suggeststhat the association of the NR1-1b subunit with the NR1-4b subunitenhances the cell surface expression of NR1-1bmolecules.

Enhancement of cell surface expression of NR1 splice variants by NR2B

To see whether the coexpression of NR2 subunits alters the cell surface expression of NR1 splice variants, 3T3 cells werecotransfected with myc-tagged NR1 splice variants and NR2B. Aftertransfection, cells were maintained in a medium containing 1 mMD-2-amino-5-phosphonovaleric acid (D,L-APV) to suppress activationof NMDA receptors by glutamate present in the culture medium (Anegawaet al., 1995; Raymond et al., 1996). Immunoblotting experimentshave confirmed that the cells maintained without NMDA antagonistsshowed reduced amounts of the NR1 protein and that the amountof the NR1 protein in transfected cells was maintained to be similarin the presence of D,L-APV (Fig. 4D,E).

The presence of NR2B significantly enhanced the cell surface expression of myc-tagged NR1-1b molecules (Fig. 6A-D). The countingof immunostained cells confirmed that the proportion of cellshaving myc-tagged NR1-1b molecules on the cell surface increasedup to 6.7% of the transfected cells in the presence of NR2B (Fig.6E). The coexpression of NR2B also enhanced the proportion ofcells showing surface staining of NR1-2bmyc (t test; p < 0.05)but not that of NR1-3bmyc and NR1-4bmyc (NR1-3bmyc, t test; p= 0.17; NR1-4bmyc, p = 0.09). The relative fluorescence intensitiesof cell surface labeling and the total cellular labeling weremeasured separately (Fig. 6F). The presence of NR2B specificallyincreased the fluorescence intensity of the cell surface stainingof NR1-2bmyc (t test; p < 0.05) but not that of NR1-3bmyc andNR1-4bmyc (NR1-3bmyc, t test; p = 0.12; NR1-4bmyc, p = 0.09).The fluorescence intensity of the total cellular staining wasnot different among the splice variants (among cells transfectedwith NR1-1bmyc, NR1-2bmyc, NR1-3bmyc, and NR1-4bmyc plus or minusNR2B, one-way ANOVA; F = 0.328, p = 0.91). Although the coexpressionof NR2B enhanced the cell surface expression of NR1-1bmyc andNR1-2bmyc, the differences of the amount of NR1 on the cell surfaceamong splice variants were preserved. There were differences inboth the number of cells positive with surface staining (amongcells transfected with NR1-1bmyc, NR1-2bmyc, NR1-3bmyc, and NR1-4bmycplus NR2B, one-way ANOVA; F = 19.68; p < 0.0001) and the intensityof the cell surface staining (among cells transfected with NR1-1bmyc,NR1-2bmyc, NR1-3bmyc, and NR1-4bmyc plus NR2B, one-way ANOVA;F = 10.77, p < 0.001).

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Figure 6. Interaction between NR1 splice variants and NR2B. A-D, 3T3 cells transfected with NR1-1bmyc (A), NR1-2bmyc (B), NR1-3bmyc (C), or NR1-4bmyc (D) together with NR2B. Cell surface myc epitopes were detected by immunofluorescence microscopy. All four NR1 splice variants were detected on the cell surface. E, Cell counting of 3T3 cells having cell surface staining against anti-myc antibody. Cells were transfected with either NR1-1bmyc, NR1-2bmyc, NR1-3bmyc, or NR1-4bmyc with or without NR2B. Without NR2B, no cell surface expression of NR1-1bmyc was observed. Coexpression of NR2B enhanced the surface expression of NR1-1bmyc. More than 100 transfected cells were examined for each transfection experiment; three independent transfection experiments were performed. F, Quantitation of fluorescence intensity of cell surface staining and total cellular staining of 3T3 cells transfected with either NR1-1bmyc, NR1-2bmyc, NR1-3bmyc, or NR1-4bmyc with or without NR2B. Coexpression of NR2B enhanced the amount of NR1-1bmyc and NR1-2bmyc on the cell surface. Similar total cellular staining was observed with or without NR2B. Fluorescence intensities of 25 transfected cells were measured for each transfection experiment. The presented data are derived from a single transfection experiment. Two other independent experiments showed a similar difference of fluorescence intensity. Scale bar, 20 µm.

Correlation between the cell surface expression of NR1 splice variants and the increase of intracellular calcium concentrations after glutamate application

To see whether there is any differences of the amount of calcium influx after glutamate application among 3T3 cells expressingdifferent NR1 splice variants, calcium imaging experiments wereperformed. 3T3 cells were transfected with each NR1 splice variantstogether with NR2B and eGFP (Levy et al., 1996). Two differentmolar ratios (1:1 and 1:16) of NR1 and NR2B plasmids were chosenfor transfection experiments. Fluorescent signals from eGFP werefirst visualized to confirm the similar number of transfectedcells per microscopic field, and the intracellular calcium concentrationsof eGFP positive cells were measured before and after applicationof 10 µM L-glutamate (Fig. 7). Figure 8, A and B, shows the summaryof calcium imaging experiments. At the ratio of 1:1 of NR1 toNR2B, increases of calcium concentrations were highest with NR1-4band lowest with NR1-1b. The other two variants showed the valueintermediate between NR1-4b and NR1-1b. By reducing the ratioto 1:16, the difference between NR1-4b and other three variantsincreased. The differences of the increases of calcium concentrationamong splice variants were statistically significant (ratio of1:1, one-way ANOVA; F = 4.14; p < 0.01; ratio of 1:16, F = 13.91;p < 0.000001). It is likely that the amount of NR1 molecules onthe cell surface becomes a limiting factor for the amount of functionalreceptor complex when the ratio of NR1 to NR2B is reduced. Significantreduction of calcium influx with NR1-1b, NR1-2b, and NR1-3b variantsat the lower NR1/NR2B ratio supports the idea that NR1-4b variantis most efficiently expressed on the cell surface.

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Figure 7. Calcium imaging of 3T3 cells transfected with NR1 splice variants, NR2B, and eGFP. 3T3 cells were transfected with expression plasmids of NR1 splice variants (NR1-1b in A, C, E: NR1-4b in B, D, F) together with NR2B and eGFP, and the increase of intracellular calcium was measured. Microscopic fields containing 10-20 eGFP-positive cells were selected (A, B), and fluorescence ratio images were obtained before (C, D) and 20 sec after (E, F) application of 10 µM glutamate. A few cells transfected with NR1-1b and NR2B at the molar ratio of 1:1 showed >200 nM calcium increase (E). In contrast, more than half of the cells transfected with NR1-4b and NR2B at the molar ratio of 1:1 showed >200 nM of calcium increase (F).

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Figure 8. Quantitation of calcium increase in 3T3 cells expressing NR1 splice variants and NR2B after glutamate application. A, B, Intracellular calcium concentration before and after 10 µM glutamate application. NR1 splice variants and NR2B were transfected at the molar ratio of 1:1 (A) and 1:16 (B). 3T3 cells positive with eGFP fluorescence were selected, and the calcium concentrations were determined and averaged. The result is the summary of two independent transfection experiments. Three culture dishes for each splice variant were examined in each transfection experiment. Transfected cells (10-20) were measured in each culture dish. C, Similar increase of intracellular calcium after 10 µM glutamate application in 3T3 cells transfected with either NR1-4b or NR1-4bmyc together with NR2B. The result is the summary of two independent transfection experiments. Four culture dishes were examined for either NR1-4b or NR1-4bmyc. Transfected cells (10-20) were measured in each culture dish.

Increases of calcium concentrations in cells transfected with NR1-4bmyc were also measured and found to be similar to thevalue of native NR1-4b molecules, suggesting that NR1-4bmyc formsfunctional NMDA receptors in combination with NR2B (Fig. 8C).

Cell surface expression of myc-tagged NR1-1b and NR1-4b in COS7 cells and PC12 cells

We generated recombinant adenovirus to express myc-tagged NR1-1b and NR1-4b in various cell types. When COS7 cells (kidneyfibroblast-like cells) were infected with recombinant adenovirusesat the same multiplicity of infection, similar amounts of NR1-1bmycand NR1-4bmyc proteins were detected by immunoblotting (Fig. 4F).We next examined the subcellular distribution of NR1-1bmyc andNR1-4bmyc in COS7 cells and PC12 cells (rat pheochromocytoma cellline). In both cell types, we could detect cell surface expressionof NR1-4bmyc molecules. However, there were few NR1-1bmyc moleculeson the surface of infected cells (Fig. 9). This result indicatesthat differential cell surface expression of NR1 splice formstakes place in a variety of cell types and is not a particularphenomenon in specific cell types. Figure 9, A and B, shows aCOS7 cell having discrete subcellular domain of NR1-1bmyc withoutdetectable cell surface expression. This further supports thenotion that the NR1-1b clusters are not on the cell surface.

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Figure 9. Cell surface expression of NR1-1bmyc and NR1-4bmyc in COS7 cells and PC12 cells. A, B, A COS7 cell expressing myc-tagged NR1-1b molecules using recombinant adenoviruses. Total NR1-1bmyc molecules (A) and molecules expressed on the cell surface (B) were detected by anti-myc antibody and fluorescein- or Cy3-conjugated secondary antibody in COS7 cells. Distinct subcellular domains of NR1-1bmyc molecules were observed (arrows in A), but there were few molecules on the cell surface (B). C, D, A COS7 cell expressing myc-tagged NR1-4b molecules using recombinant adenoviruses. Total NR1-4bmyc staining revealed diffuse intracellular distribution (C). Arrowheads in C indicate the region of strong perinuclear staining. Cells expressing NR1-4bmyc showed strong cell surface expression (D). E, F, A PC12 cell expressing myc-tagged NR1-1bmyc molecules using recombinant adenoviruses. Cells expressing NR1-1bmyc did not show cell surface staining (F), even in the presence of abundant total cellular NR1-1bmyc (E). G, H, A PC12 cell expressing myc-tagged NR1-4b. Cells expressing NR1-4bmyc showed both strong cell surface staining (H) and total cellular staining (G). Scale bar: A-D, 7 µm; E-H, 5 µm.

Cell surface expression of myc-tagged NR1-1b and NR1-4b in primary hippocampal neurons

To evaluate the function of the C-terminal domain of NR1 molecules in a native environment, we expressed myc-tagged NR1 splicevariants NR1-1b and NR1-4b in primary neurons using recombinantadenoviruses. Hippocampal neurons were maintained more than 2weeks in culture before infection. Both NR1-1bmyc and NR1-4bmycwere selectively localized to the cell body and dendrites of infectedneurons, but they were not localized to the axon (data not shown).Intracellular distribution of NR1-1bmyc and NR1-4bmyc was diffuse,and no large distinct subcellular domains were detected in cellsexpressing myc-tagged NR1 (Fig. 10B,E).

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Figure 10. Cell surface expression of NR1-1bmyc and NR1-4bmyc molecules in primary hippocampal neurons. A-C, A hippocampal neuron expressing NR1-1bmyc using recombinant adenoviruses. A, Cell surface staining detected by Cy3-conjugated secondary antibody. B, Total NR1-1bmyc staining detected by FITC-conjugated secondary antibody in the same dendrite. C, The superimposed image of A and B. Diffuse intracellular staining and punctate cell surface staining of NR1-1bmyc were observed. D-F, A hippocampal neuron expressing NR1-4bmyc using recombinant adenoviruses. D, Cell surface staining. E, Total NR1-4bmyc staining. F, The superimposed image of D and E. The amount of NR1-4bmyc molecules on the cell surface is higher than that of NR1-1bmyc. G-L, Colocalization of cell surface NR1-4bmyc puncta and synaptophysin immunoreactivity. G, J, Cell surface staining using anti-myc antibody of distal (G) and proximal (J) dendrites. H, K, Anti-synaptophysin staining of the same dendrites. I, L, The superimposed image of G and H, or J and K, respectively. NR1-4bmyc-positive puncta were in apposition to the presynaptic structure detected by anti-synaptophysin antibody (arrows). M, N, Fluorescence quantitation of hippocampal neurons. M, Fluorescence intensity (Cy3 fluorescence for cell surface NR1 and FITC fluorescence for total NR1) within a region of 50 µm² was measured from 20 randomly selected neurons expressing myc-tagged NR1-1b or NR1-4b. The differences between NR1-1b and NR1-4b were significant for surface staining (t test; p < 0.005) but not for total staining (t test; p > 0.05). N, Fluorescence intensity ratio (cell surface NR1/total NR1) calculated from the data shown in M. Scale bar: A-F, 10 µm; G-L, 5 µm.

We examined cell surface expression of NR1-1bmyc and NR1-4bmyc by reacting live neurons with anti-myc antibody. Detectableamounts of NR1-1bmyc and NR1-4bmyc molecules were present on thecell surface, and the staining pattern was punctate on the cellbody and the dendrites (Fig. 10A-F). Colocalization of cell surfaceNR1 clusters and presynaptic structure was examined by doubleimmunofluorescence microscopy. Sixty-two percent of NR1-4bmyc-positivepuncta were in apposition to presynaptic structure detected byanti-synaptophysin immunoreactivity (Fig. 10G-L, 10 dendritic segmentsof 10 neurons counted). Nonsynaptic clusters of NR1-1bmyc or NR1-4bmycwere also evident. Similar nonsynaptic clusters of native NR1molecules were reported previously (Rao and Craig, 1997). To estimatethe efficiency of the surface expression of the myc-tagged NR1,cell surface myc-tagged NR1 and total myc-tagged NR1 were labeledwith different chromophores and the fluorescence intensities werequantitated separately. Figure 10M shows that the density of cellsurface NR1-4bmyc is significantly higher than that of cell surfaceNR1-1bmyc (t test; p < 0.01), despite the slightly lower expressionlevel of total NR1-4bmyc in infected cells. We calculated theratio of fluorescence intensity between cell surface and totalmyc-tagged NR1 (Fig. 10N) and found that the difference betweensplice variants was significant (t test; p < 0.001). This experimentsuggests that the efficiency of the NR1-4b splice form to be expressedon the cell surface is higher than that of the NR1-1b splice formin the native environment of the primaryneurons.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This study shows that the splicing of the C-terminal domain of the NR1 subunit plays an important role on the cell surfaceexpression of the NMDA receptor complex. This differential cellsurface expression was also modulated by the coexpression of NR2subunits.

Regulated cell surface expression of NR1 splice variants

A previous study has shown that the presence of NR2A is necessary for the efficient cell surface expression of the NR1-1asubunit (McIlhinney et al., 1996). This observation is consistentwith the acetylcholine receptor expression on the cell surfacein which the cell surface expression requires all four principalsubunits (Gu et al., 1991). However, the present study indicatesthat the requirement of both NR1 and NR2 subunits holds true onlyin the case of the NR1-1 splice variants and that the other threeC-terminal splice forms can be expressed on the cell surface withoutNR2. Acetylcholine receptor and NMDA receptors have differentmembrane topology, and the regulation of intracellular processingand sorting might differ substantially. In this sense, AMPA-kainatereceptors have similar membrane topology with NMDA receptors,and single subunits of AMPA receptors are expressed on the cellsurface and correctly oriented in the plasma membrane (Verdoornet al., 1991; Hall et al., 1997). This suggests that the familyof ionotropic glutamate receptors can be expressed on the cellsurface as single subunits in general, with the exception of theNR1-1 spliceform.

The mechanism of the retention of the NR1-1 splice form within the cell is currently unknown. In the case of the shaker (Kv1) $alpha$ subunit of K⁺ channels, the association of the Kv $beta$ 2 subunit with the N-terminalcytoplasmic domain of the Kv1 $alpha$ chain enhances cell surface expressionof the channel complex (Shi et al., 1996). The effect of the Kv $beta$ 2subunit is interpreted to enhance proper folding of the N-terminaldomain of the Kv1 $alpha$ subunit. The NR1-1 has the longest C-terminalcytoplasmic domain among the four C-terminal splice variants,and the correct folding of this largest cytoplasmic tail mightrequire the association of NR2 subunits or other NR1 splice variants.The observation that the coexpression of NR1-4b or NR2B resultedin the appearance of NR1-1 on the cell surface supports thisview.

Another possibility is that the interaction of cytoplasmic proteins with the domain of the C1 or C2 exon cassette inhibitsproper cell surface sorting of NR1 splice variants. Several proteinsare identified as interacting with specific sequences in the C-terminaltail of the NR1 subunit. Among these, a recently cloned cytoplasmicprotein, yotiao, specifically interacts with the region correspondingto the C1 exon cassette (Lin et al., 1998). Another protein thatinteracts with the region of the C1 exon cassette is the neurofilamentL protein (NF-L) (Ehlers et al., 1998). Because yotiao is a proteincontaining many putative coiled-coil domains and the interactionof NF-L to NR1 is mediated by the coiled-coil domain of NF-L,it is likely that the region of the C1 exon cassette preferentiallyassociates with the coiled-coil motif of several proteins. Itis possible that one of these proteins has a higher affinity forthe C-terminal domain of the NR1-1 splice variant and inhibitsthe proper sorting of the NR1-1. This hypothesis could explainthe formation of receptor-rich intracellular domains in NR1-1transfected cells by possible cross-linking of NR1-1 with theassociated proteins (Ehlers et al., 1995).

Regulated calcium influx by the C-terminal splicing of the NR1 subunit

In the presence of NR2B subunit, all the C-terminal splice variants of NR1 were expressed on the cell surface and formed functionalNMDA receptors. The cell counting and fluorescence measurementanalyses indicate that there was still a difference in the amountof cell surface NR1 subunits among splice variants. The orderof the amount of NR1 on the surface was estimated to be NR1-1< NR1-2 and NR1-3 < NR1-4. It is likely that the difference ofNR1 splice forms on the cell surface regulates the amount of functionalNMDA receptor complex, because the calcium imaging experimentsshowed that the difference of the calcium increase was also inthe order of NR1-1 < NR1-2 and NR1-3 < NR1-4.

NMDA receptor is inactivated by intracellular calcium (Legendre et al., 1993), and this inactivation is regulated by the bindingof Ca²⁺-calmodulin to the C-terminal domain of the NR1 subunit (Ehlerset al., 1996). Because one of the binding site of Ca²⁺-calmodulin is localized within the alternatively spliced C1 exoncassette, it is possible that NR1 splice variants containing theC1 exon cassette (NR1-1 and NR1-3) are specifically sensitiveto this type of inactivation. In this sense, it is possible thatour Ca²⁺ imaging experiments underestimated the amount of functional receptorscontaining NR1-1 and NR1-3. However, when the comparison was madewithin splice forms having C1 exon cassette (between NR1-1 andNR1-3) or within splice forms lacking C1 exon cassette (betweenNR1-2 and NR1-4), there still remained substantial differencesin the Ca²⁺ increase. These differences still hold a positive correlationwith the amount of the surface NR1 subunits. Furthermore, recentstudies have shown that C1 exon cassette is not a critical regionfor Ca²⁺-dependent inactivation (Zang et al., 1998; Krupp et al., 1999).Therefore, we conclude that differential efficiency of cell surfaceexpression of NR1 splice forms is one of the critical factorsregulating the amount of Ca²⁺ influx by glutamatestimulation.

Biological roles of the C-terminal splicing of the NR1 subunit

We observed differential cell surface expression of NR1 splice variants when NR1-1bmyc and NR1-4bmyc were expressed in primaryhippocampal neurons using recombinant adenoviruses. Cell surfaceNR1 molecules were correctly sorted to the synaptic sites. Thisresult was consistent with a previous report using HA-tagged NR1molecules expressed in hippocampal neurons (Lissin et al., 1998).It is likely that the C-terminal splicing of NR1 molecules regulatescell surface expression of NMDA receptor complex in a nativeenvironment.

Studies using probes and antibodies specific to the C-terminal exon cassettes have shown that the expression of each splicevariant follows a complex spatiotemporal pattern (Tolle et al.,1993, 1995; Laurie and Seeburg, 1994; Laurie et al., 1995). Arecent immunohistochemical study has shown that nNOS-positiveneurons in the forebrain lack the immunoreactivity for the C1exon cassette and are selectively positive for the antibody againstthe C2' exon cassette (Weiss et al., 1998). This result indicatesthat nNOS-positive neurons are enriched with the NR1-4 splicevariant and lack the NR1-1 and NR1-3 splice variants. The presentstudy predicts that nNOS-positive neurons have a higher densityof NMDA receptors on their surface and are likely to be more sensitiveto glutamate. Because glutamate acting through NMDA receptorsis one of the most potent activators of nNOS (Iadecola, 1997),a higher sensitivity of nNOS-positive neurons to glutamate shouldhave an important role in the nitric oxide-mediated signalingsystem.

Our experiments have revealed that the presence of NR2B subunit attenuates the difference of the amount of cell surface receptorsamong splice variants. In this sense, it is likely that neuronsexpressing less amounts of NR2 subunits are more sensitive tothe differential composition of NR1 splice forms. Previous studieshave shown that certain populations of spinal cord neurons containvery low amount of transcripts for NR2 subunits (Tolle et al.,1993, 1995). Interestingly, these neurons express higher amountof NR1-2 and NR1-4 splice forms. It is possible that the preferentialexpression of NR1-2 and NR1-4 splice forms compensates the lowamount of NR2 molecules in these neurons and facilitates sortingof functional NMDA receptors to the cellsurface.

Iwasato et al. (1997) have reported that the expression of the NR1-1a splice form can rescue the lethal phenotype of NR1 nullmice. Rescued mice were not completely healthy and became wastedand spastic with age, suggesting the deteriorative effects oflacking other splice forms of NR1. Mice expressing only the NR1-1asplice form showed a normal ratio of NMDA and AMPA responses incortical neurons. The present study predicts less NMDA responsein neurons containing only NR1-1a subunits. The reason for thisdiscrepancy is not clear at present. One possibility is that thedensity of NMDA receptors at the synaptic site is controlled byadditional cellular mechanisms. Another possibility is that amajor NR1 splice form in cortical neurons is indeed NR1-1. A previousdirect cloning study has suggested that NR1-1a and NR1-1b aremajor NR1 splice forms in the forebrain (Sugihara et al., 1992).

In this study, the cell surface expression of NMDA receptors was analyzed in both non-neuronal and neuronal cells. The resultssuggest that the splicing of the C-terminal domain of the NR1subunit regulates the cell surface expression. Further analysisof the cell surface sorting and retrieval of the NMDA receptorcomplex in neuronal cells may shed light on the cellular mechanismsof the formation and maintenance of the excitatory synapses intheCNS.

  FOOTNOTES

Received Feb. 24, 1999; revised June 10, 1999; accepted June 28, 1999.

This work was supported by Special Coordination Funds of the Science and Technology Agency of the Japanese Government. Wethank Dr. Michael Hollmann for providing NMDA NR1 cDNAs, Dr. StephenHeinemann for NMDA NR2B cDNA, and Drs. Yumi Kanegae and IzumuSaito for providing materials for constructing recombinantadenoviruses.
Correspondence should be addressed to Shigeo Okabe, Department of Anatomy and Cell Biology, School of Medicine, Tokyo Medicaland Dental University, 1-5-45, Yushima, Bunkyo-ku, Tokyo, 113-8519,Japan.

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