Characterization of Guanylate Kinase-Associated Protein, a Postsynaptic Density Protein at Excitatory Synapses That Interacts Directly with Postsynaptic Density-95/Synapse-Associated Protein 90

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (74)

Citing Articles via Google Scholar

Google Scholar

Articles by Naisbitt, S.

Articles by Sheng, M.

Search for Related Content

PubMed

PubMed Citation

Articles by Naisbitt, S.

Articles by Sheng, M.

Pubmed/NCBI databases
Gene GEO Profiles
HomoloGene Protein
UniGene

Previous Article  |  Next Article

Volume 17, Number 15, Issue of August 1, 1997 pp. 5687-5696
Copyright ©1997 Society for Neuroscience

Characterization of Guanylate Kinase-Associated Protein, a Postsynaptic Density Protein at Excitatory Synapses That Interacts Directly with Postsynaptic Density-95/Synapse-Associated Protein 90

Scott Naisbitt¹, Eunjoon Kim², Richard J. Weinberg³, Anuradha Rao⁴, Fu-Chia Yang¹, Ann Marie Craig⁴, and Morgan Sheng¹
¹ Howard Hughes Medical Institute and Department of Neurobiology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachussetts 02114, ² Department of Pharmacology, Pusan National University, Kumjeong-ku, Pusan 609-735, South Korea, ³ Department of Cell Biology and Anatomy, University of North Carolina at Chapel Hill, Chapel Hill, North Carolina 27599, and ⁴ Department of Cell and Structural Biology, University of Illinois, Urbana-Champaign, Illinois 61801

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The structure of central synapses is poorly understood at the molecular level. A recent advance came with the identificationof the postsynaptic density-95 (PSD-95)/synapse-associated protein90 family of proteins as important mediators of the synaptic clusteringof certain classes of ion channels. By yeast two-hybrid screening,a novel protein termed guanylate kinase-associated protein (GKAP)has been isolated that binds to the GK-like domain of PSD-95 (Kimet al., 1997). Here we present a detailed characterization ofGKAP expression in the rat brain and report the cloning of a novelGKAP splice variant. By Northern blot, GKAP mRNAs (4, 6.5, and8 kB) are expressed predominantly in the rat brain. By in situhybridization, GKAP is expressed widely in neurons of cortex andhippocampus and in the Purkinje and granule cells of the cerebellum.On brain immunoblots, two prominent bands of 95 and 130 kDa aredetected that correspond to products of short and long N-terminalsplice variants of GKAP. Two independent GKAP antibodies labelsomatodendritic puncta in neocortical and hippocampal neuronsin a pattern consistent with synaptic elements. Immunogold electronmicroscopy reveals GKAP to be predominantly postsynaptic and presentat asymmetric synapses and in dendritic spines. The distributionof GKAP immunogold particles is uniform in the lateral plane ofthe PSD but peaks in the perpendicular axis ~20 nm from the postsynapticmembrane. In cultured hippocampal neurons GKAP immunoreactivepuncta colocalize with the AMPA receptor subunit Glu receptor1 but not with the GABA_A receptor subunits $beta$ 2 and $beta$ 3. Thus GKAPis a widely expressed neuronal protein localized specificallyin the PSD of glutamatergic synapses, consistent with its directinteraction with PSD-95 family proteins.
Key words: Postsynaptic density; excitatory synapse; PSD-95/SAP90; immunogold electron microscopy; glutamate receptor; guanylate kinase domain; MAGUK

INTRODUCTION

Proper synaptic function depends on the synaptic localization of a variety of ion channels, receptors, and signaling molecules.Synaptic targeting of these molecules is thought to be mediatedby their interactions with specific intracellular anchoring orclustering proteins (for review, see Froehner, 1993; Hall andSanes, 1993). A growing body of evidence implicates the PSD-95family of ion channel clustering proteins as playing such a rolein synaptic organization. Mammalian PSD-95 family members so faridentified include Postsynaptic density-95 (PSD-95)/synapse-associatedprotein 90 (SAP90) (Cho et al., 1992; Kistner et al., 1993), SAP97/hdlg(Lue et al., 1994; Müller et al., 1995), chapsyn-110/PSD-93 (Brenmanet al., 1996b; Kim et al., 1996), and SAP102 (Müller et al.,1996). All these proteins have a common domain structure includingthree N-terminal PDZ domains, a central Src homology 3 domain,and a C-terminal guanylate kinase (GK) domain (Sheng, 1996). Inheterologous cells and in vitro the PDZ domains in PSD-95 familymembers bind directly to the C-terminal ET/SDV motif of NMDA receptorand Shaker K⁺ channel subunits, resulting in channel clustering (Kim et al.,1995, 1996; Kornau et al., 1995; Müller et al., 1996; Niethammeret al., 1996; for review, see Sheng, 1996). Loss of function mutationsin Disks large (Dlg), a tumor suppressor protein, and the Drosophilahomolog of the PSD-95 family of proteins (Woods and Bryant, 1991),result in abnormal synaptic morphology and loss of the normalsynaptic clustering of Shaker K⁺ channels (Lahey et al., 1994; Tejedor et al., 1997). These resultssupport the idea that the PSD-95 family of proteins functionsto cluster and localize their binding partners at synaptic junctions.

PSD-95 family members have been shown to interact with intracellular signaling molecules in addition to integral membraneproteins. PSD-95 and chapsyn-110/PSD-93 interact with the cytoplasmicenzyme neuronal nitric oxide synthase (Brenman et al., 1996a),and hdlg/SAP97 can bind to the adenomatous polyposis coli tumorsuppressor protein (Matsumine et al., 1996). Thus PSD-95 familyproteins may function as molecular scaffolds for coupling synapticreceptors and ion channels to downstream signaling molecules.

Recently, a novel protein, guanylate kinase-associated protein (GKAP), was identified by its interaction with the GK domainof PSD-95 using the yeast two-hybrid system (Kim et al., 1997).GKAP coimmunoprecipitates with PSD-95 from rat brain extractsand forms a ternary complex with PSD-95 and K⁺ channels or NMDA receptors in heterologous cells. GKAP has anovel primary structure that includes five 14 amino acid repeatsthat are involved in binding to the GK domain of PSD-95 familyproteins (Kim et al., 1997). Alternative splicing occurs in atleast three (N-terminal, central, and C-terminal) locations inGKAP mRNA. Unfortunately, little of functional relevance can beinferred from the GKAP amino acid sequence. Furthermore, littleis known about GKAP in the brain, except that it biochemicallypurifies in the PSD fraction (Kim et al., 1997). Understandingthe physiological functions of GKAP requires a comprehensive knowledgeof GKAP expression patterns in vivo. We now present a detailedcharacterization of GKAP expression in rat brain at both the RNAand protein levels, including electron microscopic (EM) localizationof GKAP in the PSD of excitatory synapses. In addition, we describea novel N-terminal splice variant of GKAP, GKAP_L, the proteinproduct of which can account for the 130 kDa GKAP band seen onrat brain immunoblots previously unexplained.

MATERIALS AND METHODS
Cloning of splice variant GKAP_L. Hybridization screening of ~3 × 10⁵ pfu from $lambda$ ZAP II rat cortical and hippocampal cDNA libraries(Stratagene, La Jolla, CA) using digoxigenin-labeled GKAP clone2.1 (Kim et al., 1997) as probe and chemiluminescent detectionyielded three phage clones (2.1-1, 2.1-2, and 2.1-6) that overlappedeach other and GKAP clone 2.1. In addition, these clones overlappedtwo 5 $'$ extensions (2.1-7 and 2.1-7n3) of GKAP clone 2.1 generatedby 5 $'$ rapid amplification of cDNA ends (RACE) using a Marathon-Readyrat brain cDNA library (Clontech, Palo Alto, CA). Clone 2.1-2contained an in-frame stop codon 14 codons 5 $'$ of the presumedinitiating methionine of GKAP_L. The complete intact GKAP_L codingsequence was constructed by PCR as follows: two cycles using overlappingtemplates as primers [ $lambda$ ZAP clone 2.1-2 HindIII 2.7 kb 5 $'$ fragmentand GKAP clone 2.18 (Kim et al., 1997) HincII 1.4 kb 3 $'$ fragment],followed by 28 cycles after the addition of oligonucleotide primersflanking the GKAP_L coding region (including KpnI sites for subcloning).

Antibodies. Purified hexahistidine fusion proteins of nonoverlapping regions of GKAP were used to immunize rabbits (Kim etal., 1997). GKAP-N1564 antibodies were raised against GKAP_L aminoacids (aa) 305-732 (clone 2.1; Kim et al., 1997), and GKAP-C9589antibodies were raised against GKAP_L aa 744-964 (clone 2.18, aa446-666; Kim et al., 1997). GKAP-specific antibodies were purifiedusing affinity columns (Sulfolink, Pierce, Rockford, IL) coupledwith thioredoxin fusions of the respective proteins. Because bothantibodies were raised against antigens containing central regionscommon to all GKAP splice forms, they should recognize all GKAPvariants.

Expression constructs and Western blotting. GKAP expression constructs were prepared by subcloning GKAP or GKAP_L into theEcoRI or KpnI site, respectively, of the mammalian expressionvector GW1 (British Biotechnology, Oxford, UK). COS-7 cells weretransfected using the Lipofectamine method (Life Technologies,Inc., Gaithersburg, MD), and preparation and immunoblotting ofCOS-7 cell lysates and brain membranes were performed as described(Kim et al., 1997).

Northern and in situ hybridization. Rat poly-A mRNA Multi Tissue Northern (Clontech, Palo Alto, CA) was probed with ³²P-labeled GKAP (clone 2.18; Kim et al., 1997) under high-stringencywash conditions and exposed 5 hr at $-$ 80 C on XAR-5 (Kodak). Insitu was performed on rat brain slices as described (Standaertet al., 1996), using a ³⁵S-labeled 579 nucleotide riboprobe corresponding to GKAP aminoacid ~46-238.

Immunohistochemistry on brain and cultured neurons. Immunohistochemistry on floating 50 µm brain sections was performed asdescribed (Kim et al., 1996) and visualized using the VectastainABC kit (Vector Labs, Burlingame, CA) and diaminobenzidine (DAB)or Cy3- or FITC-conjugated secondary antibodies (Jackson ImmunoResearch,West Grove, PA). Hippocampal neuronal cultures were prepared fromembryonic day 18 rats and maintained in serum-free medium abovea glial monolayer as described (Banker and Cowan, 1977). Fixationand double-label immunostaining with GluR1 or GABA-R antibodieswas performed as described (Craig et al., 1994; Kim et al., 1997)using GKAP-N1564 at 1 µg/ml. DAB brain sections and cultured hippocampalneurons were viewed using a Zeiss Axioskop microscope; fluorescentbrain images were examined using a Bio-Rad MRC 1000 confocal microscope.

Electron microscopy.Male Sprague Dawley rats (200-350 gm) were anesthetized with pentobarbital (50 mg/kg) and perfused intracardiallywith 500 ml of mixed aldehyde fixative (1-2.5% glutaraldehyde/4%paraformaldehyde) in 0.1 M phosphate buffer, pH 7.4. Sectionsof forebrain were cut with a Vibratome and embedded without osmiumaccording to the method of Phend et al. (1995). Briefly, 40-50µm sections were rinsed in 0.1 M maleate buffer (MB), pH 6.0 ,incubated over ice sequentially with 1% tannic acid, 1% uranylacetate, 0.5% iridium tetrabromide (all solutions in MB), and1% para-phenylene diamine (in 70% ethanol), dehydrated in gradedethanols and propylene oxide, and infiltrated overnight with Epon-Spurrresin. The next day, sections were sandwiched between strips ofACLAR plastic and polymerized 36 hr at 60°C. The same method wasadapted for Lowicryl HM-20; sections were treated as describedabove until dehydration. Alcohol dehydration and resin infiltrationwere performed according to standard progressive lowering of temperaturemethods (Newman and Hobot, 1993), and UV polymerization was performedin the cold.

Chips from cerebral cortex (layers II-III) were glued onto plastic blocks, and thin sections (~100 nm) collected on nickelmesh grids were processed for postembedding immunocytochemistry(Phend et al., 1995). Briefly, grids were washed with Tris-bufferedsaline, pH 7.6, containing 0.005% Tergitol NP-10 (TBS/T), preincubatedin 0.2% normal goat serum, rinsed in TBS/T, incubated overnightin primary antibody (1:300-1:1000 dilution), rinsed in TBS/T,transferred to TBS/T, pH 8.2, incubated in secondary antibody(goat anti-rabbit IgG conjugated to 18 nm gold particles, 1:20;Jackson ImmunoResearch, West Grove, PA), rinsed, and dried. Gridswere then poststained with uranyl acetate and Sato's lead andexamined with a JEOL 200CX transmission electron microscope at80 kV. Virtually no gold particles were seen if the primary antibodywas omitted from the procedure; labeling was weak if preimmunerabbit serum was substituted; labeling in this case was not selectivefor synapses.

To evaluate antigen distribution at synapses, grids of neocortex (layers II-III) prepared from two animals were examined.Random electron micrographs (at 20,000-40,000×) were taken fromfields in which at least one gold particle seemed associated witha synaptic active zone. EM negatives were then digitized witha flatbed scanner at 300 dots/inch resolution. The captured imageswere displayed on a computer screen; all gold particles within100 nm of clearly definable active zones were analyzed onlineusing National Institutes of Health Image software. The data presentedare from 84 active zones (mean length of synaptic apposition,338 nm; SD, 81 nm). Normalized lateral distance is defined asthe absolute value of [(distance from center of particle to oneedge of active zone) $-$ (distance to other edge of active zone)]/(totallength of active zone).

RESULTS

GKAP_L, a ~130 kDa GKAP splice variant
On immunoblots of rat brain membranes prepared from cerebral cortex, hippocampus, or cerebellum, GKAP antibodies label proteinbands at ~95 and ~130 kDa (Kim et al., 1997). Both of these bandsalmost certainly represent GKAP protein, because they are recognizedspecifically by two independent antibodies, N1564 and C9589, raisedagainst nonoverlapping N- and C-terminal regions of GKAP (Fig.1A). The 95 kDa band can be accounted for by the published GKAPcDNA sequence, the expression of which in heterologous cells producesa protein that comigrates with the 95 kDa brain band (Kim et al.,1997 and Fig. 1A). We were interested in determining the molecularnature of the 130 kDa GKAP band, which cannot be explained byknown GKAP cDNAs.
Fig. 1. Specificity of GKAP antibodies and primary structure of GKAP_L N-terminal splice variant. A, Two independent GKAP antibodiesrecognize recombinantly expressed GKAP and identical 95 and 130kDa bands in rat brain membranes. COS-7 cells transfected withGKAP cDNA, and rat cortical membranes (10 µg protein) were immunoblottedwith GKAP antibodies N1564 and C9589, as indicated. Heterologouslyexpressed GKAP comigrates with the 95 kDa immunoreactive brainprotein. Ctx, Cortical membranes. B, Comparison of heterologouslyexpressed GKAP, GKAP_L, and rat hippocampal membranes, immunoblottedwith N1564 antibodies. Heterologously expressed GKAP_L comigrateswith the ~130 kDa immunoreactive brain protein. The same resultwas obtained with C9589 antibodies (data not shown). Hpc, Hippocampalmembranes. C, Amino acid sequence alignment comparing the N-terminalGKAP splice variant GKAP_L to GKAP. Splice, Presumed alternativesplice site.
[View Larger Version of this Image (48K GIF file)]

Five different GKAP cDNA clones were originally isolated when the GK domain of PSD-95 was used as bait in a yeast two-hybridscreen, including three N-terminal splice variants (Kim et al.,1997). Because these clones lacked upstream stop codons, we hypothesizedthat the 130 kDa immunoreactive species in rat brain might bethe product of a GKAP splice variant with a longer N-terminalextension than those found in known GKAP cDNA clones.

By using both 5 $'$ RACE and conventional hybridization screening to search for N-terminal extensions, we isolated a GKAP isoformtermed GKAP_L (Fig. 1C). GKAP_L represents the 5 $'$ extension of clone2.1, a partial GKAP cDNA (Kim et al., 1997) described previously.When the complete GKAP_L coding sequence was transfected into COS-7cells, a GKAP immunoreactive polypeptide was expressed efficientlythat comigrates with the 130 kDa band seen on brain Western blots(Fig. 1B). As with the shorter GKAP isoform (95 kDa), the recombinantlyexpressed GKAP_L (130 kDa) is recognized by both N1564 and C9589antibodies (Fig. 1B and data not shown). Thus the GKAP describedpreviously and the newly isolated GKAP_L cDNAs can account forthe 95 and 130 kDa GKAP proteins in rat brain. It should be emphasized,however, that the alternative splicing of GKAP is complex (Kimet al., 1997); hence the 95 and 130 kDa bands in rat brain arelikely to be heterogeneous in composition with respect to GKAPsplice forms.

Distribution of GKAP mRNA
A rat multitissue Northern blot probed under high-stringency conditions revealed three species of GKAP mRNA (4, 6.5, and 8kB) expressed predominantly in brain (Fig. 2). All three variantsare also present in testis, in similar proportions, at much lowerlevels. The 4 and 6.5 kB transcripts are also weakly detectablein lung. GKAP mRNA was undetectable in heart, spleen, liver, skeletalmuscle, and kidney. Thus although GKAP is expressed at much higherlevels in brain than in other tissues, it is not brain-specific.
Fig. 2. Tissue distribution of GKAP mRNA in rat. PolyA mRNA multitissue Northern blot probed with ³²P-labeled GKAP DNA. Positions of RNA molecular size markers areshown.
[View Larger Version of this Image (46K GIF file)]

In situ hybridization was used to examine the distribution of GKAP mRNA in rat brain at cellular resolution. GKAP transcriptsare expressed abundantly in cortex, hippocampus, the granularlayer of cerebellum, and the olfactory bulbs (Fig. 3A). GKAP mRNAis also present in lesser amounts in thalamus, the lateral septalnuclei, and several brain stem nuclei. Dark-field microscopicexamination reveals GKAP mRNA expression in cells throughout allsix cortical layers (Fig. 3B). In hippocampus, GKAP transcriptsare abundant in the pyramidal cell somata of CA1-CA3 and in thegranule cell layer of the dentate gyrus (Fig. 3B,D). A populationof interneurons, most conspicuous in the hilus of the dentategyrus and in the stratum (st.) oriens, are also strongly positivefor GKAP mRNA. In cerebellum, GKAP transcripts are present inPurkinje and granule cells (Fig. 3C).
Fig. 3. Distribution of GKAP mRNA in adult rat brain analyzed by in situ hybridization. A, Horizontal (top) and sagittal (bottom)rat brain sections probed with ³⁵S-labeled antisense GKAP cRNA. B-D, Dark-field microscopy of sagittalin situ hybridization sections. B, Hippocampal area CA1 and overlyingcortex. Ctx, Cerebral cortex, so, st. oriens; cc, corpus callosum.C, Cerebellar cortex. The arrow points to a Purkinje cell. m,Molecular layer; g, granular layer; w, white matter. D, Hippo-campalformation. dg, Dentate gyrus; h, hilus. Note prominent expressionof GKAP mRNA by interneurons in the hilar region of the dentategyrus and the st. oriens of CA1. Scale bars: A, 5 mm; B-D, 0.3mm.
[View Larger Version of this Image (133K GIF file)]

Immunohistochemical distribution of GKAP protein in rat brain
GKAP protein is widely expressed in neurons of rat brain in a punctate somatodendritic pattern. Similar results were obtainedwith both GKAP antibodies, strong evidence that the immunostainingpattern corresponds to actual GKAP distribution. Furthermore,this staining pattern was abolished by antibody preabsorptionwith the appropriate fusion protein antigen (data not shown).In addition, the regional and cellular distribution of GKAP immunoreactivitycorrelates well with the distribution of GKAP mRNA expressionrevealed by in situ hybridization.

In hippocampus, GKAP immunoreactivity is prominent in a population of interneurons (Fig. 4A-C) the distribution of which isstrikingly reminiscent of the in situ hybridization pattern (Fig.3B,D). The interneurons in the hilus of the dentate gyrus, forexample, positive for GKAP mRNA, are highly immunoreactive forthe GKAP protein (Fig. 4A,C,G). The st. oriens stains darkly andcontains many GKAP immunoreactive interneurons (Fig. 4A,B), againcorrelating with GKAP mRNA distribution (Fig. 3B,D). GKAP immunoreactiveinterneurons are also present within and around the pyramidalcell body layer; an interneuron from area CA1 is shown at highpower in Figure 4F. Many, although not all, of these GKAP-positiveinterneurons are also immunoreactive for glutamic acid decarboxylase(data not shown) and therefore presumably represent GABAergicinhibitory neurons.
Fig. 4. Immunohistochemical localization of GKAP protein in the hippocampus. A-C, Coronal sections were immunolabeled with GKAP antibodyC9589, and visualized by DAB. A, Hippocampal formation. The dendriticfields of pyramidal neurons and dentate granule cells and a populationof interneurons, are heavily labeled. B, Region CA1 of the hippocampus.Note the relative absence of staining in pyramidal cell bodies,and the darkly stained interneurons and their dendrites. The dendritesof pyramidal neurons in the st. radiatum and st. oriens are alsolabeled, st. oriens more strongly than st. radiatum. C, Hilarregion of the dentate gyrus, filled with GKAP immunoreactive interneuronsand dendrites. Note the relative absence of staining in the granulecell body layer. D-G, Coronal sections immunolabeled by GKAP antibodyN1564 (D-E), or C9589 (F, G) followed by Cy3- or FITC-conjugatedsecondary antibody, and visualized by confocal microscopy. D,CA1 st. radiatum. Dendrites of pyramidal neurons are decoratedby striking GKAP puncta. There is very slight labeling of pyramidalcell bodies. E, 2× magnification of the dendrites in D. F, Anisolated interneuron in area CA1. G, Interneurons and their dendritesin the hilar region of the dentate gyrus, covered in bright GKAPimmunoreactive puncta. sr, St. radiatum; other abbreviations asshown in Figure 3. Scale bars: A, 0.5 mm; B, C, 125 µm; D, G,60 µm; E, F, 30 µm.
[View Larger Version of this Image (158K GIF file)]

The principal neurons of hippocampus also show prominent dendritic GKAP labeling. The dendritic fields of pyramidal neuronsin CA1-CA3, and of dentate granule cells, are stained by bothN1564 and C9589 antibodies, whereas the soma are relatively spared(Fig. 4A,B). This immunostaining pattern corroborates the presenceof GKAP mRNA in these neurons and emphasizes the dendritic localizationof GKAP protein. Pyramidal cell dendrites are best visualizedby confocal microscopy, which shows GKAP immunoreactivity concentratedin puncta along dendrites in a pattern consistent with synapticlocalization (Fig. 4D,E). This is true not only in pyramidal celldendrites, but in the brightly stained interneurons as well (Fig.4F,G). Although their staining patterns are qualitatively similar,the two independent GKAP antibodies show some quantitative differencesin staining. Pyramidal dendrites are seen better using GKAP antibodyN1564, whereas interneurons and their dendrites are labeled morestrongly by C9589. This could be attributable to cell type-specificdifferences in GKAP protein-protein interactions, which may differentallyaffect accessibility of antibodies directed against distinct regionsof the molecule.

In cerebral cortex (Fig. 5A), GKAP staining is found in all six cortical layers. Apical dendrites of pyramidal neurons anddendrites of nonpyramidal neurons show a punctate pattern of GKAPimmunoreactivity suggestive of synaptic elements (Fig. 5D-F).In the cerebellum, Purkinje cell bodies and proximal dendritesare stained. Granule cells show GKAP immunoreactivity on theirsurface and more prominently in the glomeruli of the granule celllayer (Fig. 5B,C,G). Scattered interneurons are lightly stained.This cellular distribution of GKAP immunoreactivity in cerebellumand neocortex is also consistent with the in situ hybridizationfindings (Fig. 3B,C).
Fig. 5. Immunohistochemical localization of GKAP protein in cerebral cortex and cerebellum. A-C, Coronal sections labeled with GKAPantibody C9589 and visualized via DAB histochemistry. A, Cerebralcortex, showing widespread and diffuse neuropil staining. B, C,Cerebellar Purkinje and granule cell staining in cerebellum. Purkinjecell bodies and glomeruli of the granular cell layer are stained.D-G, Sections labeled with GKAP antibody N1564 (D) or C9589 (E-G)and Cy3- or FITC-conjugated secondary antibody and visualizedby confocal microscopy. D, Apical dendrites of pyramidal neuronsin cerebral cortex decorated by GKAP immunoreactive puncta. E,F, Bright GKAP puncta on dendrites of neocortical neurons. G,High-power view of the Purkinje cell layer in the cerebellum.p, Purkinje cell; other abbreviations as in Figure 3. Scale bars:A, B, 0.5 mm; C, 125 µm; D, E, G, 60 µm; F, 30 µm.
[View Larger Version of this Image (155K GIF file)]

Immunogold electron microscopic localization of GKAP
Electron microscopy reveals GKAP immunogold labeling mainly at synapses, although occasional dendrites are immunopositive.Synaptic staining is virtually exclusively at asymmetric (presumablyexcitatory) contacts and seems stronger at spines than on dendriticshafts. Figure 6A-C show examples of immunolocalization of GKAPover the PSD of dendritic spines, although an occasional particlelies within the cytoplasm, possibly associated with cytoskeletalelements (Fig. 6B). Occasional dendritic profiles have high levelsof cytoplasmic labeling (data not shown), perhaps correspondingto the strongly stained dendrites of interneurons seen by lightmicroscopy (see Figs. 4, 5).
Fig. 6. Immunogold EM localization of GKAP in dendritic spines and PSD. A-C, Postembedding 18nm immunogold labeling of GKAP in sectionsfrom cerebral cortex layers II-III. *Presynaptic terminals. A,An asymmetric synapse showing gold particles associated with PSD;some particles lie against the plasma membrane, and others lieat the cytoplasmic face of the PSD. B, Three immunopositive synapsesin the same field, each with gold particles overlying the PSD.One particle (just below the B) seems to lie within the cytoplasm,perhaps in association with a cytoskeletal element. C, An immunopositivespine cut in a longitudinal plane, permitting visualization ofthe spine apparatus (arrowheads) and spine neck. Scale bar, 500nm. D-E, Quantitative analysis of the distribution of GKAP immunogoldparticles at synapses. Grids of neocortex (layers II-III) preparedfrom two animals were examined. Random electron micrographs weremade of fields in which at least one gold particle seemed associatedwith a synaptic active zone. EM negatives were digitized, andall gold particles within 100 nm of clearly definable active zoneswere analyzed. The data were from 85 active zones (mean lengthof synaptic apposition, 338 nm; SD, 81 nm). D, Distribution ofgold particles across the synapse, axis perpendicular to the synapticcleft ("0" corresponds to the cytoplasmic leaflet of the postsynapticmembrane). GKAP-immunogold distribution peaks at 10-30 nm on theintracellular side of the postsynaptic membrane. E, Lateral distributionof gold particles. Normalized lateral distance is defined as theabsolute value of [(distance from center of particle to one edgeof active zone) $-$ (distance to other edge of active zone)]/(totallength of active zone). GKAP is distributed evenly along the activezone.
[View Larger Version of this Image (140K GIF file)]

Quantitative EM analysis shows that GKAP immunogold particles are concentrated on the intracellular side of the postsynapticmembrane, at a mean distance of 23 ± 2 nm from the postsynapticmembrane (Fig. 6D). Whereas material embedded in Epon-Spurr showedslightly higher levels of GKAP labeling than material embeddedin Lowicryl, localization of gold particles in brain sectionsembedded in both plastics was similar. In the lateral plane (parallelto the synaptic cleft), GKAP seems to be distributed uniformlythroughout the PSD up to a point close to the edge of the density(Fig. 6E).

Specific localization of GKAP in glutamatergic synapses of cultured hippocampal neurons
Neurons typically have different types of synapses on the same dendrite. The light and electron microscopic studies suggestthe presence of GKAP predominantly at excitatory synapses. Todetermine whether GKAP is specific for excitatory glutamatergicsynapses, cultured hippocampal neurons were double-labeled withGKAP and AMPA receptor GluR1 antibodies, or with GKAP and GABA_Areceptor $beta$ 2 and $beta$ 3 subunit antibodies. GKAP immunoreactive punctacolocalize exactly with GluR1, both on dendritic shafts in GABAergiccells (data not shown) and on dendritic spines in pyramidal cells(Fig. 7A,B). However, GKAP does not colocalize with the GABA_Areceptor $beta$ 2 and $beta$ 3 subunits (Fig. 7C,D), a marker for GABAergicinhibitory synapses.
Fig. 7. GKAP colocalizes at excitatory synapses with GluR1. In hippocampal neurons at 3 weeks in culture, GKAP (A) is distributedin puncta that colocalize with clusters of GluR1 (B) at dendriticspines in pyramidal cells. Punctate GKAP immunoreactivity (C)does not colocalize with clusters of the GABA-R $beta$ 2 and $beta$ 3 subunits(D), markers of GABAergic inhibitory synapses. Scale bar, 10 µm;inset, 5 µm.
[View Larger Version of this Image (98K GIF file)]

DISCUSSION
The identification of GKAP as a novel protein that binds to the GK domain of PSD-95 (Kim et al., 1997) represented a majorstep in our efforts to identify the specific components and protein-proteininteractions that underlie the structure of the synapse. In thispaper we characterize GKAP expression at the RNA and protein levels,including EM localization of GKAP in the PSD of asymmetric synapses.Furthermore, by double-labeling experiments in cultured hippocampalneurons, we show GKAP to be apparently specific for glutamatergicsynapses. Both these lines of evidence indicate that GKAP is localizedin excitatory rather than in inhibitory synapses. This specificlocalization is consistent with the direct association betweenGKAP and the PSD-95 family of proteins, which in turn interactspecifically with the NMDA subclass of glutamate receptors. Thespecificity of GKAP for excitatory synapses illustrates that themolecular heterogeneity of synapses extends beyond the natureof the neurotransmitter and neurotransmitter receptor to includethe proteins of the postsynaptic specialization. Presumably severaldistinct sets of proteins are involved in the organization ofdifferent classes of postsynaptic sites, as exemplified by thespecific association of PSD-95/GKAP, gephyrin, and rapsyn withglutamatergic, glycinergic, and cholinergic synapses, respectively.It should be emphasized that GKAP is specifically localized inglutamatergic synapses, rather than specifically expressed inglutamatergic neurons, because GKAP, like GluR1 (Kharazia et al.,1996), is highly expressed in inhibitory interneurons as wellas in glutamatergic neurons.

An important part of this study is the EM immunogold localization of GKAP. The higher resolution of this method allows usto localize GKAP in the PSD, within which there is a peak of GKAPlabeling at 10-30 nm intracellular to the postsynaptic membrane.Considering the dimensions of the gold particles and IgG molecules,there is an expected error in the localization of labeling ofapproximately ±10 nm (Matsubara et al., 1996). These errors shouldbe unbiased, so the mean position of GKAP, ~23 nm from the postsynapticmembrane, should be considerably more accurate than this. However,given the PSD thickness of ~40 nm, it cannot be established fromthe present data whether GKAP molecules are concentrated in anarrow band of the PSD ~20 nm from the plasma membrane, or areinstead uniformly distributed throughout the thickness of thePSD. Either would be consistent with the observed mean and distribution.Nevertheless, this GKAP immunogold distribution is distinct fromthat of NMDA receptor 1 (NMDAR1). NMDAR1 exhibits a similarlyeven "lateral" distribution along the active zone, but it liesconsiderably closer to the postsynaptic membrane (Kharazia etal., 1995). This differential subsynaptic distribution is consistentwith GKAP being separated from NMDA receptors by PSD-95. Basedon biochemical criteria, GKAP is a core component of the PSD (Kimet al., 1997), but its localization in the deeper part of thePSD places it in a position to potentially link PSD-95 to cytosolicsignaling pathways or to cytoskeleton. Isolation of GKAP-interactingproteins may therefore yield interesting molecules that lie atthe interface between PSD and the dendritic cytoplasm.

Although we conclude a predominantly postsynaptic localization for GKAP by LM and EM studies, a minor distribution of GKAPat other subcellular sites cannot be excluded. Indeed, occasionalGKAP immunoreactivity was seen by EM in presynaptic and nonsynapticsites. This is a pertinent issue because GKAP binds in vitro tothe GK domains of all known members of the PSD-95 family (Kimet al., 1997), including SAP97, which has a presynaptic and axonaldistribution (Müller et al., 1996). Whether GKAP or GKAP variantsshow differential association with the various members of thePSD-95 family in vivo remains to be determined.

Obviously, the most outstanding question regarding GKAP is one of function. It is widely expressed in the brain and localizesto the PSD in neurons, but what is the role of GKAP in synapticstructure or function? The known interaction of GKAP with thechannel-clustering proteins of the PSD-95 family suggests someinteresting possibilities. Perhaps GKAP is involved in the synaptictargeting of PSD-95 family members and their associated molecules(NMDA receptors, Shaker K⁺ channels, and neuronal NOS)? This seems unlikely to be an essentialfunction, because a Dlg mutant missing most of the GK domain (allelev59), can still appropriately localize Shaker channels to synapticsites (Tejedor et al., 1997). Because the GK domain of Dlg alsobinds to GKAP, this suggests that the GK domain (and by extrapolation,GKAP) is not essential for synaptic localization of Dlg. However,v59 mutants have abnormal postsynaptic morphology in the larvalneuromuscular junction (Lahey et al., 1994; Guan et al., 1996)and exhibit neoplastic overgrowth of epithelial cells of imaginaldisks (Woods and Bryant, 1991), suggesting that the GK domain,and proteins that interact with the GK domain, might more likelybe involved in intracellular signaling pathways. The isolationof GKAP-interacting proteins, in combination with genetic or dominantnegative approaches, will be necessary to clarify further thecell biological and physiological functions of GKAP.

The in vivo functions of GKAP may be somewhat heterogeneous, however, given the complex alternative splicing of the GKAP gene.In addition to splice variants noted previously (Kim et al., 1997),we have now identified a major N-terminal variant, GKAP_L, thatadds an unusually large (298 amino acids and ~35 kDa) extensionto the GKAP described previously. The large N-terminal extensionis presumably important for the specific functions of GKAP_L, butunfortunately its primary sequence contains no region of homologyto known proteins. Splice variant-specific probes and antibodieswill be helpful to determine whether the various isoforms of GKAPare differentially expressed during development or in a cell type-specificmanner. Such studies may yield clues to GKAP function and areunderway.

Note added in proof. During review of this work, Takeuchi et al. (J Biol Chem 272:11943-11951, 1997) isolated several SAP90/PSD-95associated proteins, including an alternatively spliced isoformof GKAP/GKAP_L, SAPAP1.

FOOTNOTES

Received March 17, 1997; revised May 12, 1997; accepted May 13, 1997.

This work was supported by National Institutes of Health Grants NS35050 (M.S.) and NS29879 (R.W.). M.S. is an Assistant Investigatorof the Howard Hughes Medical Institute. We thank Jai Up Kim forexcellent technical assistance, and we are especially gratefulto Ingrid K. Friberg and David G. Standaert for the in situ hybridization.

Correspondence should be addressed to Dr. Morgan Sheng, Howard Hughes Medical Institute (Wellman 423), Massachussetts GeneralHospital, 50 Blossom Street, Boston, MA 02114.

REFERENCES

Banker GA, Cowan WM (1977) Rat hippocampal neurons in dispersed cell culture. Brain Res 126:397-425[Web of Science][Medline].
Brenman JE, Chao DS, Gee SH, McGee AW, Craven SE, Santillano DR, Wu Z, Huang F, Xia H, Peters MF, Froehner SC, Bredt DS (1996a) Interaction of nitric oxide synthase with the postsynaptic density protein PSD-95 and $alpha$ 1-syntrophin mediated by PDZ domains. Cell 84:757-767[Web of Science][Medline].
Brenman JE, Christopherson KS, Craven SE, McGee AW, Bredt DS (1996b) Cloning and characterization of postsynaptic density 93, a nitric oxide synthase interacting protein. J Neurosci 16:7407-7415[Abstract/Free Full Text].
Cho K-O, Hunt CA, Kennedy MB (1992) The rat brain postsynaptic density fraction contains a homolog of the drosophila discs-large tumor suppressor protein. Neuron 9:929-942[Web of Science][Medline].
Craig AM, Blackstone CD, Huganir RL, Banker G (1994) Selective clustering of glutamate and $gamma$ -aminobutyric acid receptors opposite terminals releasing the corresponding neurotransmitters. Proc Natl Acad Sci USA 91:12373-12377[Abstract/Free Full Text].
Froehner SC (1993) Regulation of ion channel distribution at synapses. Annu Rev Neurosci 16:347-368[Web of Science][Medline].
Guan B, Hartmann B, Kho Y-H, Gorczyca M, Budnik V (1996) The Drosophila tumor suppressor gene, dlg, is involved in structural plasticity at a glutamatergic synapse. Curr Biol 6:695-706[Web of Science][Medline].
Hall Z, Sanes JR (1993) Synaptic structure and development: the neuromuscular junction. Neuron 10:99-122.
Kharazia VN, Phend K, Wenthold R, Weinberg RJ (1995) Synaptic localization of AMPA & NMDAR1 receptor subunits in rat cerebral cortex. Soc Neurosci Abstr 21:1837.
Kharazia VN, Wenthold RJ, Weinberg RJ (1996) GluR1-immunoreactive interneurons in rat neocortex. J Comp Neurol 368:399-412[Web of Science][Medline].
Kim E, Cho K-O, Rothschild A, Sheng M (1996) Heteromultimerization and NMDA receptor-clustering activity of chapsyn-110, a member of the PSD-95 family of proteins. Neuron 17:103-113[Web of Science][Medline].
Kim E, Naisbitt S, Hsueh Y-P, Rao A, Rothschild A, Craig AM, Sheng M (1997) GKAP, a novel synaptic protein that interacts with the guanylate kinase-like domain of the PSD-95/SAP90 family of channel clustering molecules. J Cell Biol 136:669-678[Abstract/Free Full Text].
Kim E, Niethammer M, Rothschild A, Jan YN, Sheng M (1995) Clustering of Shaker-type K⁺ channels by interaction with a family of membrane-associated guanylate kinases. Nature 378:85-88[Medline].
Kistner U, Wenzel BM, Veh RW, Cases-Langhoff C, Garner AM, Appeltauer U, Voss B, Gundelfinger ED, Garner CC (1993) SAP90, a rat presynaptic protein related to the product of the Drosophila tumor suppressor gene dlg-A. J Biol Chem 268:4580-4583[Abstract/Free Full Text].
Kornau H-C, Schenker LT, Kennedy MB, Seeburg PH (1995) Domain interaction between NMDA receptor subunits and the postsynaptic density protein PSD-95. Science 269:1737-1740[Abstract/Free Full Text].
Lahey T, Gorczyca M, Jia X-X, Budnik V (1994) The Drosophila tumor suppressor gene dlg is required for normal synaptic bouton structure. Neuron 13:823-835[Web of Science][Medline].
Lue RA, Marfatia SM, Branton D, Chishti AH (1994) Cloning and characterization of hdlg: the human homologue of the Drosophila discs large tumor suppressor binds to protein 4.1. Proc Natl Acad Sci USA 91:9818-9822[Abstract/Free Full Text].
Matsubara A, Laake JH, Davanger S, Usami S-I, Ottersen OP (1996) Organization of AMPA receptor subunits at a glutamate synapse: a quantitative immunogold analysis of hair cell synapses in the rat organ of corti. J Neurosci 16:4457-4467[Abstract/Free Full Text].
Matsumine A, Ogai A, Senda T, Okumura N, Satoh K, Baeg G-H, Kawahara T, Kobayashi S, Okada M, Toyoshima K, Akiyama T (1996) Binding of APC to the human homolog of the Drosophila discs large tumor suppressor protein. Science 272:1020-1023[Abstract].
Müller BM, Kistner U, Veh RW, Cases-Langhoff C, Becker B, Gundelfinger ED, Garner CC (1995) Molecular characterization and spatial distribution of SAP97, a novel presynaptic protein homologous to SAP90 and the Drosophila discs-large tumor suppressor protein. J Neurosci 15:2354-2366[Abstract].
Müller BM, Kistner U, Kindler S, Chung WJ, Kuhlendahl S, Lau L-F, Veh RW, Huganir RL, Gundelfinger ED, Garner CC (1996) SAP102, a novel postsynaptic protein that interacts with the cytoplasmic tail of the NMDA receptor subunit NR2B. Neuron 17:255-265[Web of Science][Medline].
Newman GR, Hobot JA (1993) In: Resin microscopy and on-section immuno-cytochemistry. Berlin: Springer.
Niethammer M, Kim E, Sheng M (1996) Interaction between the C-terminus of NMDA receptor subunits and multiple members of the PSD-95 family of membrane-associated guanylate kinases. J Neurosci 16:2157-2163[Abstract/Free Full Text].
Phend KD, Rustioni A, Weinberg RJ (1995) An osmium-free method of Epon embedment that preserves both ultrastructure and antigenicity for postembedding immunocytochemistry. J Histochem Cytochem 43:283-292[Abstract].
Sheng M (1996) PDZs and receptor/channel clustering: rounding up the latest suspects. Neuron 17:575-578[Web of Science][Medline].
Standaert DG, Landwehrmeyer GB, Kerner JA, Penney Jr JB, Young AB (1996) Expression of NMDAR2D glutamate receptor subunit mRNA in neurochemically identified interneurons in the rat neostriatum, neoxortex, and hippocampus. Mol Brain Res 42:89-102[Medline].
Tejedor FJ, Bokhari A, Rogero O, Gorczyca M, Zhang J, Kim E, Sheng M, Budnik V (1997) Essential role for dlg in synaptic clustering of shaker K⁺ channels in vivo. J Neurosci 17:152-159[Abstract/Free Full Text].
Woods DF, Bryant PJ (1991) The discs-large tumor suppressor gene of Drosophila encodes a guanylate kinase homolog localized at septate junctions. Cell 66:451-464[Web of Science][Medline].

Copyright ©1997 Society for Neuroscience   0270-6474/1997/175687-10$05.00/0

This article has been cited by other articles:

S. Romorini, G. Piccoli, M. Jiang, P. Grossano, N. Tonna, M. Passafaro, M. Zhang, and C. Sala
A Functional Role of Postsynaptic Density-95-Guanylate Kinase-Associated Protein Complex in Regulating Shank Assembly and Stability to Synapses
J. Neurosci., October 20, 2004; 24(42): 9391 - 9404.
[Abstract] [Full Text] [PDF]

M. J. Parker, S. Zhao, D. S. Bredt, J. R. Sanes, and G. Feng
PSD93 Regulates Synaptic Stability at Neuronal Cholinergic Synapses
J. Neurosci., January 14, 2004; 24(2): 378 - 388.
[Abstract] [Full Text] [PDF]

T. Okabe, T. Nakamura, Y. N. Nishimura, K. Kohu, S. Ohwada, Y. Morishita, and T. Akiyama
RICS, a Novel GTPase-activating Protein for Cdc42 and Rac1, Is Involved in the beta -Catenin-N-cadherin and N-Methyl-D-aspartate Receptor Signaling
J. Biol. Chem., March 7, 2003; 278(11): 9920 - 9927.
[Abstract] [Full Text] [PDF]

A. Yoshii, M. H. Sheng, and M. Constantine-Paton
Eye opening induces a rapid dendritic localization of PSD-95 in central visual neurons
PNAS, February 4, 2003; 100(3): 1334 - 1339.
[Abstract] [Full Text] [PDF]

I. Yao, J. Iida, W. Nishimura, and Y. Hata
Synaptic and Nuclear Localization of Brain-Enriched Guanylate Kinase-Associated Protein
J. Neurosci., July 1, 2002; 22(13): 5354 - 5364.
[Abstract] [Full Text] [PDF]

V. Heidinger, P. Manzerra, X. Q. Wang, U. Strasser, S.-P. Yu, D. W. Choi, and M. M. Behrens
Metabotropic Glutamate Receptor 1-Induced Upregulation of NMDA Receptor Current: Mediation through the Pyk2/Src-Family Kinase Pathway in Cortical Neurons
J. Neurosci., July 1, 2002; 22(13): 5452 - 5461.
[Abstract] [Full Text] [PDF]

S. Levi, R. M. Grady, M. D. Henry, K. P. Campbell, J. R. Sanes, and A. M. Craig
Dystroglycan Is Selectively Associated with Inhibitory GABAergic Synapses But Is Dispensable for Their Differentiation
J. Neurosci., June 1, 2002; 22(11): 4274 - 4285.
[Abstract] [Full Text] [PDF]

F. Imamura, S. Maeda, T. Doi, and Y. Fujiyoshi
Ligand Binding of the Second PDZ Domain Regulates Clustering of PSD-95 with the Kv1.4 Potassium Channel
J. Biol. Chem., January 25, 2002; 277(5): 3640 - 3646.
[Abstract] [Full Text] [PDF]

M. Sheng
Molecular organization of the postsynaptic specialization
PNAS, June 19, 2001; 98(13): 7058 - 7061.
[Abstract] [Full Text] [PDF]

S. Naisbitt, J. Valtschanoff, D. W. Allison, C. Sala, E. Kim, A. M. Craig, R. J. Weinberg, and M. Sheng
Interaction of the Postsynaptic Density-95/Guanylate Kinase Domain-Associated Protein Complex with a Light Chain of Myosin-V and Dynein
J. Neurosci., June 15, 2000; 20(12): 4524 - 4534.
[Abstract] [Full Text] [PDF]

R. S. Walikonis, O. N. Jensen, M. Mann, D. W. Provance Jr, J. A. Mercer, and M. B. Kennedy
Identification of Proteins in the Postsynaptic Density Fraction by Mass Spectrometry
J. Neurosci., June 1, 2000; 20(11): 4069 - 4080.
[Abstract] [Full Text] [PDF]

H. Shin, Y.-P. Hsueh, F.-C. Yang, E. Kim, and M. Sheng
An Intramolecular Interaction between Src Homology 3 Domain and Guanylate Kinase-Like Domain Required for Channel Clustering by Postsynaptic Density-95/SAP90
J. Neurosci., May 15, 2000; 20(10): 3580 - 3587.
[Abstract] [Full Text] [PDF]

M Sheng and E Kim
The Shank family of scaffold proteins
J. Cell Sci., January 6, 2000; 113(11): 1851 - 1856.
[Abstract] [PDF]

R. Dingledine, K. Borges, D. Bowie, and S. F. Traynelis
The Glutamate Receptor Ion Channels
Pharmacol. Rev., March 1, 1999; 51(1): 7 - 62.
[Abstract] [Full Text] [PDF]

I. M. Ethell and Y. Yamaguchi
Cell Surface Heparan Sulfate Proteoglycan Syndecan-2 Induces the Maturation of Dendritic Spines in Rat Hippocampal Neurons
J. Cell Biol., February 8, 1999; 144(3): 575 - 586.
[Abstract] [Full Text] [PDF]

J. E. Brenman, J. R. Topinka, E. C. Cooper, A. W. McGee, J. Rosen, T. Milroy, H. J. Ralston, and D. S. Bredt
Localization of Postsynaptic Density-93 to Dendritic Microtubules and Interaction with Microtubule-Associated Protein 1A
J. Neurosci., November 1, 1998; 18(21): 8805 - 8813.
[Abstract] [Full Text] [PDF]

K. Hirao, Y. Hata, N. Ide, M. Takeuchi, M. Irie, I. Yao, M. Deguchi, A. Toyoda, T. C. Sudhof, and Y. Takai
A Novel Multiple PDZ Domain-containing Molecule Interacting with N-Methyl-D-aspartate Receptors and Neuronal Cell Adhesion Proteins
J. Biol. Chem., August 14, 1998; 273(33): 21105 - 21110.
[Abstract] [Full Text] [PDF]

Y.-P. Hsueh, F.-C. Yang, V. Kharazia, S. Naisbitt, A. R. Cohen, R. J. Weinberg, and M. Sheng
Direct Interaction of CASK/LIN-2 and Syndecan Heparan Sulfate Proteoglycan and Their Overlapping Distribution in Neuronal Synapses
J. Cell Biol., July 13, 1998; 142(1): 139 - 151.
[Abstract] [Full Text] [PDF]

A. Rao, E. Kim, M. Sheng, and A. M. Craig
Heterogeneity in the Molecular Composition of Excitatory Postsynaptic Sites during Development of Hippocampal Neurons in Culture
J. Neurosci., February 15, 1998; 18(4): 1217 - 1229.
[Abstract] [Full Text] [PDF]

M. Wyszynski, V. Kharazia, R. Shanghvi, A. Rao, A. H. Beggs, A. M. Craig, R. Weinberg, and M. Sheng
Differential Regional Expression and Ultrastructural Localization of alpha -Actinin-2, a Putative NMDA Receptor-Anchoring Protein, in Rat Brain
J. Neurosci., February 15, 1998; 18(4): 1383 - 1392.
[Abstract] [Full Text] [PDF]

H.-J. Kreienkamp, H. Zitzer, E. D. Gundelfinger, D. Richter, and T. M. Bockers
The Calcium-independent Receptor for alpha -Latrotoxin from Human and Rodent Brains Interacts with Members of the ProSAP/SSTRIP/Shank Family of Multidomain Proteins
J. Biol. Chem., October 13, 2000; 275(42): 32387 - 32390.
[Abstract] [Full Text] [PDF]

S. E. Craven and D. S. Bredt
Synaptic Targeting of the Postsynaptic Density Protein PSD-95 Mediated by a Tyrosine-based Trafficking Signal
J. Biol. Chem., June 23, 2000; 275(26): 20045 - 20051.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (74)

Citing Articles via Google Scholar

Google Scholar

Articles by Naisbitt, S.

Articles by Sheng, M.

Search for Related Content

PubMed

PubMed Citation

Articles by Naisbitt, S.

Articles by Sheng, M.

Pubmed/NCBI databases
Gene GEO Profiles
HomoloGene Protein
UniGene