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Volume 16, Number 23, Issue of December 1, 1996 pp. 7407-7415
Copyright ©1996 Society for NeuroscienceCloning and Characterization of Postsynaptic Density 93, a Nitric Oxide Synthase Interacting Protein
Jay E. Brenman, Karen S. Christopherson, Sarah E. Craven, Aaron W. McGee, and David S. Bredt Department of Physiology and Programs in Biomedical Sciences and Neuroscience, University of California at San Francisco School of Medicine, San Francisco, California 94143-0444
ABSTRACT
Nitric oxide (NO) formation in brain is regulated by the calcium/calmodulin dependence of neuronal NO synthase (nNOS). Calcium influx through NMDA-type glutamate receptors is efficiently coupled to nNOS activity, whereas many other intracellular calcium pathways are poorly coupled. To elucidate possible mechanisms responsible for this coupling, we performed yeast two-hybrid screening to identify proteins that interact with nNOS. Two nNOS interacting proteins were identified: the postsynaptic density proteins PSD-93 and PSD-95. Here, we report the cloning and characterization of PSD-93. PSD-93 is expressed in discrete neuronal populations as well as in specific non-neuronal cells, and it exhibits complex molecular diversity attributable to tissue-specific alternative splicing. PSD-93, like PSD-95, binds to nNOS and to the NMDA receptor 2B. PSD-93, however, is unique among PSD-95/SAP-90 family members in its expression in Purkinje neuron cell bodies and dendrites. We also demonstrate that the PDZ domain at the N terminus of nNOS is required, but it is not sufficient for interaction with PSD-93/95. Given that PSD-93 and PSD-95 each contain multiple potential binding sites for nNOS and the NMDA receptor, complexes involving oligomers of PSD-93/95 may help account for the functional as well as the physical coupling of nNOS to NMDA receptors.
Key words: neuronal nitric oxide synthase; NMDA receptor; postsynaptic density; Purkinje neurons; glutamate; calcium
INTRODUCTION
Nitric oxide (NO) functions as a messenger molecule in numerous neuronal pathways in brain and periphery (Bredt and Snyder, 1992
; Vincent and Hope, 1992
Recently, NMDA receptor subunits have been shown to bind to the postsynaptic density protein PSD-95 (Kornau et al., 1995
To determine which protein-protein interactions participate in coupling NMDA receptors to NO formation in brain, we screened for nNOS binding proteins using the yeast two-hybrid system (Fields and Song, 1989
MATERIALS AND METHODS
Generation of PSD-93 and PSD-95 antiserum. Glutathione-S-transferase fusion proteins encoding amino acids 77-453 of PSD-93 and amino acids 1-386 of PSD-95 were expressed and purified from Escherichia coli. Guinea pigs were immunized with the PSD-93 fusion, and rabbits were immunized with the PSD-95 fusion. Antigens were emulsified in complete and incomplete Freund's adjuvant. Serum bleeds were evaluated by ELISA.
cDNA cloning and analysis. A human PSD-93 cDNA encoding amino acids 116-421 isolated as an nNOS interacting fragment was used to screen a rat brain cDNA library (Stratagene, La Jolla, CA). Ten hybridizing cDNAs were isolated from a screen of 106 phage. Clones were sequenced on both strands using the dideoxy chain termination method (U.S. Biologicals). The GenBank accession number for PSD-93 is U50717[GenBank].
mRNA isolation and Northern blot analysis. RNA was isolated using the guanidine isothiocyanate/CsCl method, and mRNA was selected using oligo-dT Sepharose. For Northern blotting, mRNA was separated on a formaldehyde agarose gel and transferred to a nylon membrane. The filter was sequentially hybridized with random-primed 32P probes that were generated using PSD-93 cDNAs as template. The common probe corresponded to nucleotides 237-927 of PSD-93. Transcript specific probes, 5 a and 5
70°C.
Fig. 1. Predicted amino acid sequence and alternative splicing of PSD-93. A, Alignment of PSD-93 with PSD-95 and HDLG-SAP97 indicates an overall amino acid identity of ~70%. Identical amino acids are indicated by black boxes, and conserved amino acid changes are shaded by gray boxes. B, The N terminus of PSD-93 is alternatively splice prone. Sequences of the four alternative N-terminal transcripts (5
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In situ hybridization. Adult rats were perfused with 4% paraformaldehyde, and brains were harvested, post-fixed at 4°C for 3 hr, and cryoprotected in 20% sucrose overnight. Twenty micrometer sections were cut on a cryostat and melted onto glass slides (Plus, Fisher Scientific, Houston, TX). Embryonic day 15 rats were delivered by Cesarean section, fixed in paraformaldehyde, and processed in parallel with adult brain. In situ hybridization used 35S-labeled RNA probes as described (Sassoon and Rosenthal, 1993
Immunohistochemistry. Sprague Dawley rats were anesthetized with pentobarbital and perfused with 4% freshly depolymerized paraformaldehyde in 0.1 M phosphate buffer. Tissues were removed and post-fixed in paraformaldehyde for 1 hr at 4°C. Tissues were cryoprotected overnight in 20% sucrose. Free-floating sections (40 µm) were cut on a sliding microtome. Sections were blocked for 1 hr in PBS containing 1.5% normal goat serum and then incubated overnight in the same buffer containing diluted antiserum. For indirect immunofluorescence, secondary goat anti-rabbit FITC- and donkey anti-guinea pig Cy-3-conjugated antibodies were used according to the manufacturer's specifications (1:200; Jackson Laboratories, Bar Harbor, ME).
Fusion-protein affinity chromatography. Fusion protein of GST fused to amino acids 77-453 of PSD-93 or amino acids 1-100, 1-150, or 1-195 of nNOS were expressed in E. coli and purified on glutathione-Sepharose beads as described (Brenman et al., 1995
RESULTS
Molecular cloning of PSD-93
To determine the molecular structure of PSD-93, we screened a rat brain library with a fragment of human PSD-93 isolated as an nNOS interacting gene product (Brenman et al., 1996
Analysis of multiple PSD-93 cDNAs indicated three sites for putative alternative splicing. Certain cDNA clones isolated from the library had either a 102 base pair (bp) (34 amino acid) or a 45 bp (15 amino acid) insert between amino acids K624 and R625 (Fig. 1C). Another example of alternative splicing was found by RT-PCR amplification of rat brain cDNA using primers that flank the large insert that is unique to PSD-93. In these amplifications, we consistently found two bands, one corresponding to the PSD-93 clones isolated from the library and another that lacked 156 nucleotides (52 amino acids) between PDZ-2 and PDZ-3 (noted as a deletion in Fig. 1D).
The greatest degree of heterogeneity was found at the N terminus of PSD-93 where we isolated cDNA clones with four distinct sequences (Fig. 1B). The most commonly obtained transcript, 5 Expression of PSD-93 mRNA
We evaluated the overall distribution of PSD-93 by Northern blotting using a probe to sequences that are present in all of the alternatively spliced forms. PSD-93 mRNA occurred as a single band of ~7.5 kb in poly(A+) RNA from brain (Fig. 2A). Under these conditions, PSD-93 could not be detected in poly(A+) RNA from kidney, spleen, liver, heart, or skeletal muscle. We also evaluated the distribution of PSD-93 in various brain regions. Highest levels were found in cerebral cortex and cerebellum, with somewhat lower densities in striatum and hippocampus, and essentially no PSD-93 could be detected in brain stem. The PSD-93 hybridizing bands in forebrain regions migrated as ~7.5 kb bands, whereas that in cerebellum migrated just slightly faster (Fig. 2B).
Fig. 2. Tissue expression and alternative splicing of PSD-93. A, Northern blotting of adult rat tissues indicates that PSD-93 is expressed as an ~7.5 kb transcript that occurs in brain (Br) but not in kidney (Ki), spleen (Sp), liver (Li), heart (He), or skeletal muscle (Sk). C, Northern blotting of brain regions demonstrates that PSD-93 is present in cerebellum (Cb), cortex (Cx), hippocampus (Hi), and striatum (St) but is absent from brainstem (BS). Note that the band in cerebellum migrates slightly faster than that in other brain regions. For A and B, a probe common to all of the alternatively spliced forms of PSD-93 was used. D, E, The blot in B was sequentially rehybridized with probes corresponding to two of the alternatively spliced N-terminal regions of PSD-93. C, Probing with 5
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The altered migration of PSD-93 mRNA in cerebellum raised the possibility that the message is alternatively spliced in a tissue-specific manner. To evaluate this, we rehybridized the blot with probes corresponding to the two large alternative N termini. The first probe, 5
We next evaluated the cellular distribution of PSD-93 mRNA by in situ hybridization. As reported previously (Brenman et al., 1996 
Fig. 3. Cellular localization of PSD-93 mRNA in adult brain and E15 embryo. In situ hybridization was used to localize transcripts for PSD-93 (A, C, E, G) or sense control (B, D, F, H). a, In adult brain, PSD-93 seems to be neuron-specific and is highly expressed in Purkinje neurons in the cerebellum (Cb) and also occurs in pyramidal and granule cells in hippocampus (H). b, In E15 embryo, PSD-93 is abundantly expressed in neurons of spinal cord (SC), dorsal root ganglia (DRG), and intestine (In). PSD-93 is also observed in cells of the thymus (Thy) and submandibular gland (SG).
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To determine expression of PSD-93 in peripheral tissues, we conducted in situ hybridization on E15 rat embryo (Fig. 3b). We found highest densities of PSD-93 in developing brain and spinal cord. Several neuronal populations in the periphery also showed strong hybridization, including myenteric neurons of the intestine and sensory neurons of the dorsal root ganglia and trigeminal ganglia. Unlike PSD-95, certain non-neuronal tissues contained PSD-93. Particularly high levels of PSD-93 were noted in several glands, including the adrenal, thymus, and submandibular glands. PSD-93 is present in Purkinje cell bodies and dendrites in cerebellum
To compare the cellular localization of PSD-93 and PSD-95 in brain, we developed affinity-purified antisera to PSD-93 and PSD-95 in guinea pig and rabbit, respectively. Immunoblotting of total brain homogenate demonstrates that antiserum to PSD-93 predominantly recognizes a protein product that migrates at ~103 kDa (Fig. 4). The antiserum to PSD-95 recognizes a protein that migrates at ~95 kDa. Longer exposure of the PSD-95 Western blot reveals a second reactive band of ~75 kDa. This lower band has been noted previously by others (Cho et al., 1992
Fig. 4. Specificity of antisera to PSD-93 and PSD-95. Western blot analysis reveals that the predominant PSD-93 protein product in rat brain migrates at 103 kDa, whereas the major PSD-95 reactive band migrates at 95 kDa. Crude adult rat brain homogenates (50 µg of protein/lane) were size-fractionated by SDS-PAGE and analyzed by immunoblotting with affinity-purified antiserum to either PSD-93 (lane 1) or PSD-95 (lane 2). Size markers are in kilodaltons.
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Although PSD-95 is postsynaptic in forebrain (Hunt et al., 1996 
Fig. 5. PSD-93 is postsynaptic, whereas PSD-95 is predominantly presynaptic in rat cerebellum. A sagittal section of rat cerebellum was processed for indirect immunofluorescent double-labeling using a guinea pig antiserum to PSD-93 and a rabbit antiserum to PSD-95. A, PSD-93 immunoreactivity, visualized in the red channel, is present in Purkinje cell somata and molecular layer (M) of cerebellum (100× magnification). B, PSD-95, visualized in the green channel, is present in the synaptic plexus of basket cell axons beneath the Purkinje cell layer (P) (100× magnification). C, Higher-power double exposure shows that PSD-93 immunoreactivity (orange) is confined to Purkinje neurons (arrow), whereas PSD-95 immunoreactivity (green) primarily labels the presynaptic basket cell pinceaus (arrowhead) (400× magnification). Note that the orange color observed on double exposure is attributable to the longer exposure times required by FITC filters.
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nNOS binds to PSD-93
PSD-93 was identified in a yeast two-hybrid screen as an nNOS interacting protein (Brenman et al., 1996
Fig. 6. The PDZ repeats of PSD-93 interact with nNOS and the tSXV motif of NMDA receptor 2B. Glutathione-Sepharose beads bound to GST or to a PSD-93 protein fragment (amino acids 77-453) fused to GST (G-P93) were incubated with brain extracts. After the beads were washed extensively, retained proteins were eluted with 0.2% SDS and separated by SDS/PAGE. Western blotting indicates that nNOS is selectively retained by G-P93 (lane 3) but not by GST alone (lane 2). Binding assays performed in parallel indicate that an NMDA receptor 2B C-terminal peptide displaces nNOS from G-P93 completely at 10 µM (lanes 4 and 5), substantially at 5 µM (lanes 6 and 7), and negligibly at 0.1 µM (lanes 8 and 9). A control peptide had no effect on nNOS binding to G-P93 at 10 µM (lanes 10 and 11). Input = 10% of the protein loaded onto the fusion-protein columns.
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The PDZ domain of nNOS is contained within the first 100 amino acids, whereas the first 195 amino acids of nNOS were originally used to identify PSD-93 in a two-hybrid screen. We therefore asked whether the PDZ domain of nNOS was sufficient for interaction with PSD-93. To address this question, we engineered overlapping constructs spanning the amino terminal 195 amino acids of nNOS and screened for interaction with PSD-93 by the yeast two-hybrid system (Table 1). We found that constructs containing the first 150 amino acids of nNOS were necessary and sufficient for association with PSD-95. Deletion of sequences on either side of this 150 amino acid domain produced fusions that failed to interact with PSD-93. Importantly, an N-terminal 100 amino acid construct encoding the entire consensus PDZ domain of nNOS did not associate with PSD-93.
Table 1. Interactions of nNOS and PSD-93
Gal4 DNA binding hybrid Gal4 activation hybrid -Galactosidase units
nNOS (amino acids 1-100) PSD-93 (116-421) 1.23 nNOS (40-150) PSD-93 (116-421) 1.64 nNOS (40-195) PSD-93 (116-421) 1.51 nNOS (100-195) PSD-93 (116-421) 1.06 nNOS (1-150) PSD-93 (116-421) 14.7 nNOS (1-195) PSD-93 (116-421) 17.2 Lamin C (66-230) PSD-93 (116-421) 0.430 Yeast Y187 cells were cotransformed with expression vectors encoding various Gal4 DNA binding domain and Gal4 activation domain fusion proteins. Each transformation mixture was plated on synthetic dextrose plates lacking tryptophan and leucine. Interaction was measured by the liquid culture Values are representative of experiments repeated twice with similar results.
To verify that the PDZ domain of nNOS is not sufficient for interaction with PSD-93, we biochemically evaluated binding using affinity chromatography. GST fusion proteins encoding amino acids 1-100, 1-150, and 1-195 were linked to columns of glutathione-Sepharose beads and were incubated with solubilized brain extracts (Fig. 7). After the columns were washed, retained proteins were identified by Western blotting. Again, we found that amino acids 1-150 of nNOS potently interacted with PSD-93 but that amino acids 1-100 are not sufficient for association. In parallel experiments, we found that amino acids 1-150 of nNOS are necessary and sufficient for interaction with PSD-95 (data not shown). 
Fig. 7. The 100 amino acid PDZ domain of nNOS is not sufficient to bind to PSD-93. Glutathione-Sepharose beads bound to GST alone or to GST fusion-protein fragments encoding various N-terminal domains of nNOS (G-nNOS) were incubated with brain extracts. After the beads were washed extensively, retained proteins were eluted with 0.2% SDS and separated by SDS/PAGE. Western blotting with PSD-93 antiserum reveals that PSD-93 does not bind to either GST alone (lane 2) or to G-nNOS1-100 (lane 3) but is selectively retained by G-nNOS1-150 (lane 4) and G-nNOS1-195 (lane 5). Input = 10% of the protein loaded onto the fusion-protein columns (lane 1).
[View Larger Version of this Image (29K GIF file)]
DISCUSSION
These studies identify PSD-93 as a novel member of a growing family of proteins with both PDZ motifs and homology to guanylate kinases. These proteins seem to organize signaling molecules at membrane junctions. The PDZ motif contains ~100 amino acids and is present in a diverse family of enzymes and structural proteins. The first identified member of this group, discs-large (dlg) tumor suppressor protein of Drosophila, is localized to septate junctions of epithelial cells in Drosophila larvae. The absence of dlg in mutant flies results in disruption of the septate junctions, loss of cell-cell adhesion, and neoplastic growth of epithelial cells in the larval imaginal disks (Woods and Bryant, 1991
PSD-95/SAP-90 was identified independently by two laboratories as an abundant and detergent-insoluble protein enriched in brain synaptosomal fractions (Cho et al., 1992
In brain, nNOS is enriched in membrane fractions (Hecker et al., 1994
In central neurons, NO formation is functionally coupled to NMDA receptor activity, and nNOS protein is colocalized with PSD-95 in some, but not all, neuronal populations (Brenman et al., 1996 -conotoxin-sensitive channels (Daniel et al., 1994
PDZ domains seem to be modular motifs capable of diverse modes of protein-protein interaction. One class of ligands for PDZ domains is the terminal tSXV motif that occurs in certain ion channels and receptors. Recent x-ray crystallography studies of a single PDZ domain demonstrate that the terminal carboxylate group of the tSXV is cradled by the main chain amides as well as an arginine side chain of the PDZ domain (Doyle et al., 1996
Other studies have shown that PDZ domains can interact with transmembrane proteins, which entirely lack tSXV motifs (Shieh and Zhu, 1996
Cloning of PSD-93 identifies a significant heterogeneity of transcripts. Our molecular studies identified six examples of putative alternative splicing, and it seems likely that additional heterogeneity exists. Alternative splicing within the open reading frame regulates the expression of inserted sequences between the second and third PDZ motifs and between the SH3 and guanylate kinase domains. These alternative splicing events may modify the protein-binding properties of the PDZ and SH3 domains. A more complex level of alternative splicing occurs at the N terminus of PSD-93, where the alternative 5
FOOTNOTES
Received July 8, 1996; revised Sept. 4, 1996; accepted Sept. 9, 1996.
This work was supported by grants from the National Science Foundation, National Institutes of Health, the Lucille P. Markey Charitable Trust, the Chicago Community Trust, the McKnight Endowment Fund for Neuroscience, and the Esther A. and Joseph Klingenstein Fund to D.S.B. We thank Paul Ulrich for assistance with sequence alignments.
Correspondence should be addressed to Dr. David S. Bredt, Department of Physiology, University of California at San Francisco School of Medicine, 513 Parnassus Avenue, San Francisco, CA 94143-0444.
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Inhibition of nNOS expression in the macula densa by COX-2-derived prostaglandin E2
Am J Physiol Renal Physiol, July 1, 2004; 287(1): F152 - F159.
[Abstract] [Full Text] [PDF]
M. A. Morabito, M. Sheng, and L.-H. Tsai
Cyclin-Dependent Kinase 5 Phosphorylates the N-Terminal Domain of the Postsynaptic Density Protein PSD-95 in Neurons
J. Neurosci., January 28, 2004; 24(4): 865 - 876.
[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]
X. Jiang, D. Mu, R. A. Sheldon, D. V. Glidden, and D. M. Ferriero
Neonatal Hypoxia-Ischemia Differentially Upregulates MAGUKs and Associated Proteins in PSD-93-Deficient Mouse Brain
Stroke, December 1, 2003; 34(12): 2958 - 2963.
[Abstract] [Full Text] [PDF]
S. Nada, T. Shima, H. Yanai, H. Husi, S. G. N. Grant, M. Okada, and T. Akiyama
Identification of PSD-93 as a Substrate for the Src Family Tyrosine Kinase Fyn
J. Biol. Chem., November 28, 2003; 278(48): 47610 - 47621.
[Abstract] [Full Text] [PDF]
M. Fang, Y.-X. Tao, F. He, M. Zhang, C. F. Levine, P. Mao, F. Tao, C.-L. Chou, S. Sadegh-Nasseri, and R. A. Johns
Synaptic PDZ Domain-mediated Protein Interactions Are Disrupted by Inhalational Anesthetics
J. Biol. Chem., September 19, 2003; 278(38): 36669 - 36675.
[Abstract] [Full Text] [PDF]
ABSTRACT
