D-Serine as a Neuromodulator: Regional and Developmental Localizations in Rat Brain Glia Resemble NMDA Receptors

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Volume 17, Number 5, Issue of March 1, 1997 pp. 1604-1615
Copyright ©1997 Society for Neuroscience

D-Serine as a Neuromodulator: Regional and Developmental Localizations in Rat Brain Glia Resemble NMDA Receptors

Michael J. Schell¹, Roscoe O. Brady Jr.¹, Mark E. Molliver¹, and Solomon H. Snyder¹^,²^,³
Departments of ¹ Neuroscience, ² Pharmacology and Molecular Sciences, and ³ Psychiatry, Johns Hopkins University School of Medicine, Baltimore, Maryland 21205

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

D-Serine is localized in mammalian brain to a discrete population of glial cells near NMDA receptors, suggesting that D-serineis an endogenous agonist of the receptor-associated glycine site.To explore this possibility, we have compared the immunohistochemicallocalizations of D-serine, glycine, and NMDA receptors in ratbrain. In the telencephalon, D-serine is concentrated in protoplasmicastrocytes, which are abundant in neuropil in close vicinity toNMDA receptor 2A/B subunits. Ultrastructural examination of theCA1 region of hippocampus reveals D-serine in the cytosolic matrixof astrocytes that ensheath neurons and blood vessels, whereasNR2A/B is concentrated in dendritic spines. By contrast, glycineimmunoreactivity in telencephalon is the lowest in brain. Duringpostnatal week 2, D-serine levels in cerebellum are comparableto those in adult cerebral cortex but fall to undetectable levelsby day 26. During week 2, we observe parallel ontogeny of D-serinein Bergmann glia and NR2A/B in Purkinje cells, suggesting a rolefor astrocytic D-serine in NMDA receptor-mediated synaptogenesis.D-Serine in the radial processes of Bergmann glia is also wellpositioned to regulate NMDA receptor-dependent granule cell migration.In the inner granule layer, D-serine is found transiently in protoplasmicastrocytes surrounding glomeruli, where it could regulate developmentof the mossy fiber/granule cell synapse. D-Serine seems to bethe endogenous ligand of glycine sites in the telencephalon anddeveloping cerebellum, whereas glycine predominates in the adultcerebellum, olfactory bulb, and hindbrain.
Key words: D-serine; glycine; NMDA receptor; glia; D-amino acid; cerebellum

INTRODUCTION

Activation of NMDA receptor channels requires both glutamate and stimulation of a "glycine site" (Johnson and Ascher, 1987;Reynolds et al., 1987; Kemp and Leeson, 1993). Neurophysiologicalstudies of expressed NMDA receptors indicate that with certaincombinations of NR1 and NR2 subunits, D-serine is up to threetimes more potent than glycine at the glycine site (Matsui etal., 1995; Priestley et al., 1995). Although D-amino acids havelong been known to exist in bacteria, worms, and insects (Corrigan,1969), only very recently have high levels of D-serine been demonstratedin mammalian tissues, especially in the brain (Hashimoto et al.,1992a, 1993a,b; Nagata, 1992; Chouinard et al., 1993; Nagata etal., 1994).

We have mapped D-serine immunohistochemically in rat brain and observed a pattern that parallels the localization of D-serinebinding sites associated with NMDA receptors in the forebrain(Schell et al., 1995). D-Serine is concentrated in gray matterregions enriched in NMDA receptors and is selectively localizedto protoplasmic astrocytes. We have also demonstrated that agonistsof non-NMDA receptors enhance the efflux of preloaded D-serinefrom cultures of cortical type 2 astrocytes. These data suggestthat D-serine is an endogenous ligand at the glycine site of manyNMDA receptors and that glutamate releases D-serine from glialcells in the vicinity of NMDA receptors to synergize with synapticglutamate (Cull-Candy, 1995; Schell et al., 1995).

To compare the candidacies of glycine and D-serine as endogenous ligands for NMDA receptors, we have studied their immunohistochemicallocalizations in serial sections of rat brain. We report a closesimilarity in the localizations of NMDA receptor 2A/B subtypesand D-serine, including a parallel transient ontogeny in the cerebellum,whereas the disposition of glycine differs substantially. We havealso localized D-serine at the ultrastructural level, where itis concentrated in astrocytic foot processes and glial elementsin neuropil.

MATERIALS AND METHODS
Antibodies. A polyclonal antibody to D-serine was raised in rabbits against a reduced glutaraldehyde conjugate of D-serineand bovine serum albumin (BSA) and negatively purified againstglutaraldehyde-treated BSA as described (Schell et al., 1995).In dot blot experiments, the antibody readily detects 0.01 nmolof D-serine conjugated to brain protein and is 100-fold less sensitiveto L-serine. This antiserum was used at a dilution of 1:3000 inthe presence of 200 µM L-serine-glutaraldehyde liquid phase conjugate.In dot blots and in tissue sections, immunoreactivity is abolishedby preincubation with 200 µM of the D-serine conjugate. The antibodyrecognizing NMDA receptor 2A and 2B subunits (Chemicon, Temechula,CA) was generated against a C-terminal peptide of NR2A and hasbeen characterized thoroughly (Petralia et al., 1994a). The polyclonalantibody to glycine was raised against a reduced glutaraldehydeconjugate of glycine and BSA and has at least a 100-fold selectivityover $beta$ -alanine and a 1000-fold selectivity over other amino acidstested. This antiserum was purchased commercially (Chemicon) andthen negatively purified against glutaraldehyde-treated BSA asdescribed for the D-serine antibody; it was used at a dilutionof 1:3000 in the presence of the L-serine liquid-phase conjugate.

Immunohistochemistry. Sprague Dawley rats were obtained from Sasco (Wilmington, MA). Juvenile rats were littermates housedwith their mother, whereas adult animals were males housed fourto a cage at the Johns Hopkins Animal Care Facility. Animals wereanesthetized with an overdose of sodium pentobarbitol and then[on postnatal days 7 (P7), 9, 11, 13-19, 21, 50, 60) perfusedthrough the aorta with 37°C oxygenated Krebs-Henseleit buffer(118 mM NaCl, 4.7 mM KCl, 2 mM CaCl₂, 1.2 mM MgSO₄, 1.2 mM KH₂PO₄,25 mM NaHCO₃, and 1 mM glucose) for ~45 sec and then with 250-450ml of 37°C 5% glutaraldehyde (Electron Microscopy Sciences, FortWashington, PA), 0.5% paraformaldehyde, 0.2% Na₂S₂0₅, 0.1 M sodiumphosphate, pH 7.4. After a 20 min delay, brains were removed,trimmed, and post-fixed for 2 hr at room temperature. Brains werethen placed in 4°C cryoprotection buffer (20% glycerol, 1% NaCl,0.01% thimerosal, 50 mM sodium phosphate, pH 7.4) for at least2 d before they were frozen-sectioned (20-40 µm) on a slidingmicrotome. Sections were reduced for 20 min in 0.5% NaBH₄ (Kosakaet al., 1986) and immunostained using the Vectastain Elite kit(Vector Labs, Burlingame, AC) as described (Schell et al., 1995).

Electron microscopy. Vibratome sections (50 µm) were prepared as for light microscopy, except that Triton X-100 was omittedfrom the primary antibody incubation. After visualization of thelabeling with diaminobenzidine, sections were incubated in 1%osmium tetraoxide/0.1 M sodium phosphate for 90 min, washed inwater, and then incubated for 45 min in 1.5% uranyl acetate. Sectionswere washed again in water and dehydrated in graded ethanols,followed by propylene oxide, and then equilibrated overnight inincreasing concentrations of Medcast-Aldralite 502 (Ted Pella,Inc., Redding, CA). Sections were embedded flat between acetatesheets, polymerized overnight, and examined with light microscopyto identify regions of interest; these were excised and mountedflat in plastic capsules. Semithin (1 µm) sections were cut andplaced onto slides and examined; well-stained regions were identifiedby light microscopy and trimmed before 70 nm sections were cutand placed onto 200-mesh copper grids. To maximize contrast betweenstained and unstained areas, grids were not counterstained beforebeing viewed with a Zeiss EM10 electron microscope at 80 kV witha large objective aperture.

HPLC analysis. Whole cerebella were sonicated in 10 vol of ice-cold 5% trichloroacetic acid and centrifuged to remove protein.Soluble fractions were extracted three times with water-saturatedether before HPLC analysis of amino acid enantiomers as described(Hashimoto et al., 1992b).

RESULTS
Although the glycine binding site is present on the NR1 subunit (Moriyoshi et al., 1991; Lynch et al., 1994), NMDA receptorchannels exist physiologically as multimers composed of NR1 andone or more of the other subtypes (Kutsuwada et al., 1992; Meguroet al., 1992; Monyer et al., 1992). The vast majority of NMDAreceptors in the forebrain include NR2A and/or 2B subtypes, andprevious localization studies (Watanabe et al., 1992; Monyer etal., 1994) show that these subtypes most closely resemble D-serinebinding sites (Schell et al., 1995). To visualize functional NMDAreceptors most likely to be modulated by D-serine in vivo, wehave used an antibody specific for subtypes 2A and 2B.

D-Serine and NR2A/B display similar locations throughout the forebrain
In 21-d-old rats, both D-serine and NR2A/B are concentrated in the gray matter of the telencephalon (Fig. 1, top and middle).In the cerebral cortex, D-serine staining appears patchy and ismost abundant around blood vessels. D-Serine staining is observedin all cortical layers but is concentrated in deeper regions.Intense labeling is apparent in the amygdaloid nuclei and theclaustrum. The intense cortical staining for NR2A/B concentratesin the frontal and parietal lobes and appears layered, with densestlabeling in layers II-IV. NR2A/B staining is also dense in corticallayer I, the temporal lobes, the piriform cortex, and amygdala.Higher-power examination of the amygdala (Fig. 2, top and middle)confirms that both D-serine and NR2A/B concentrate in this region,with the D-serine in astrocytes and NR2A/B in pyramidal neurons.Glycine staining in the amygdala is extremely low by comparisonand has a pattern that is a virtual negative image of that forNR2A/B (Fig. 1, bottom). The most intense staining for glycineoccurs in the hindbrain and hypothalamus, two regions where NR2A/Bis in low abundance. In the olfactory bulb, hindbrain, and spinalcord, we readily observe the known inhibitory glycinergic pathways(Campistron et al., 1986; van den Pol and Gorcs, 1988; Pourchoet al., 1992).
Fig. 1. P21 serial brain sections stained for D-serine, NR2A/B, or glycine. Am, Amygdala; Cl, claustrum; Cx, cortex; EPL, externalplexiform layer; Hb, habenula; Hp, hippocampus; Hy, hypothalamus;PM, pons/medulla; Sn, substantia nigra; Sp, spinal cord; WM, whitematter; VNL, vomeronasal nerve layer.
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Fig. 2. P21 amygdala stained for D-serine, NR2A/B, or glycine. Both D-serine and NR2A/B appear concentrated near blood vessels.
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Throughout the subiculum and hippocampus (Fig. 3), high densities of D-serine occur in molecular layers. The stratum radiatum,the area with the highest density of NMDA receptor associatedD-serine binding sites in brain (Schell et al., 1995), containsan abundance of D-serine. The pyramidal cell layers are unstained,as is the granule cell layer of the dentate gyrus. The molecularlayer of the dentate gyrus, especially the lower blade region,is stained densely, as is the hilus. Similar to D-serine, densestaining for NR2A/B is observed in molecular layers of the subiculumand CA1 and CA3 regions. The pyramidal cell layers are also denselylabeled, but the granule cells of the dentate gyrus are not. Thehilus and inner third of the dentate gyrus molecular layer areweakly stained, whereas the outer two thirds is strongly stained.Glycine staining is generally low in the hippocampus, especiallyin the CA1 region, and is localized differently than NR2A/B. Twodiscrete bands of higher glycine density are observed. One isin the stratum lucidum of the CA3 region, associated with terminalsof the mossy fibers. The other is in the deep hilus, includinga dense, thin layer just inside the dentate granule cells. Bothregions are notable for their very low densities of NMDA receptorsrelative to other areas of the hippocampus (Cotman et al., 1987),and long-term potentiation at the mossy fiber synapses is presynapticand does not involve NMDA receptors (Zalutsky and Nicoll, 1990).Overall, glycine in the hippocampus is distributed virtually theopposite of NR2A/B, although substantial labeling for both isobserved in the outer third of the dentate gyrus molecular layer.
Fig. 3. P21 hippocampus stained for D-serine, NR2A/B, or glycine. DG, Dentate gyrus; Hi, hilus; L, stratum lacunosum molecular; Lu,stratum lucidum of CA3 region; Mol, molecular layer of dentategyrus; O, stratum oriens; P, stratum pyramidale; R, stratum radiatum;S, subiculum; WM, white matter.
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In certain brain regions outside of telencephalic gray matter, NR2A/B and D-serine are not similarly localized, or NR2A/Blocalizations more closely resemble glycine than D-serine. Forexample, D-serine is present in a band of subcallosal white matterthat includes the alveus and the subependymal zone (Fig. 1, toparrows), where NR2A/B is not detected. NR2A/B labeling is densein the substantia nigra pars reticulata, where D-serine stainingis weak and glycine staining is intense.

Olfactory bulb contains both D-serine and glycine
The highest densities of D-serine staining in the brain occur in the nerve layer of the accessory olfactory bulb (AOB), whichis composed of unique glia that ensheath incoming axons from thevomeronasal organ. NR2A/B occurs in this layer, as reported previouslyfor NR1 (Petralia et al., 1994b), as well as moderate glycinelabeling. In the AOB, the most intense NR2A/B staining occursin the plexiform layer, in the dendrites of mitral cells. BothD-serine and glycine are observed in this layer, with D-serinefound in astrocytes and glycine concentrated around mitral celldendrites and cell bodies. The AOB is notable because it is oneof only a few brain regions with high densities of D-serine andglycine together.

D-serine staining in the main olfactory bulb is much lower than in the telencephalon, but its layering pattern resembles NR2A/B.Both are most concentrated in the external plexiform layer. D-Serineconcentrates in protoplasmic astrocytes near mitral and tuftedcell dendrites, which are intensely stained for NR2A/B (Petraliaet al., 1994a). Lesser amounts of both D-serine and NR2A/B occurin the periglomerular region, olfactory nerve layer, and innerplexiform layer. In the inner plexiform layer, NR2A/B appearsas scattered dots. D-Serine also occurs in the ependymal layer,where NR2A/B is not detected. We observe high densities of glycinestaining in all layers of the main olfactory bulb, especiallythe external plexiform layer, as reported previously (van denPol and Gorcs, 1988). Glycine is an inhibitory transmitter inthis region, and most olfactory bulb neurons, especially mitraland tufted cells, express strychnine-sensitive glycine receptors(Trombley and Shepherd, 1994). Glycine staining is densely concentratedin neuropil surrounding mitral cell bodies and proximal processes,but is not inside mitral cell somata. Glycine is also prominentin periglomerular cells. Thus, in the main olfactory bulb, glycineappears enriched near both inhibitory and excitatory glycine receptors.

Cellular and ultrastructural localization of D-serine and NR2A/B in hippocampal CA1 region
We focused on the hippocampus for a more detailed description of the relationship between D-serine and NR2A/B, because ithas one of the highest D-serine-to-glycine ratios (Hashimoto etal., 1993b), and densities of D-serine binding sites in the CA1molecular layers are the highest in brain (Schell et al., 1995).Figure 4 reveals the overlapping distributions of D-serine andNR2A/B in the stratum radiatum of the CA1 region of hippocampus.D-Serine is concentrated in the cell bodies and processes of glia,which are prominent throughout all molecular layers and also inthe overlying white matter. The densest staining for D-serineoccurs in glia processes surrounding blood vessels (Fig. 4C),whereas the densest staining for NR2A/B occurs around the baseof the pyramidal cell dendrites. In neuronal layers, D-serine-containingprocesses of glial cells course between neuronal cell bodies (Fig.4C), which are densely labeled for NR2A/B. In contrast, the verylight glycine staining in CA1 is restricted to widely scatteredcell bodies in the molecular layer, which resemble small interneuronsor glia.
Fig. 4. Detailed comparison of D-serine and NR2A/B in P21 hippocampal CA1 region. A, B, D-Serine concentrates in the glia of molecularlayers, especially near blood vessels (asterisks), whereas NR2A/Bis found in pyramidal neurons and all layers of neuropil. C, D,Higher-power magnification of regions near blood vessels.
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At the ultrastructural level, we confirm the similar localizations of NR2A/B and D-serine. In the stratum radiatum of CA1,D-serine is most concentrated in astrocytic foot processes, whichabut unstained endothelial cells and pericytes (Fig. 5, left).Immunoreactivity appears as black clumps throughout the cytosolicmatrix but not in mitochondria. High densities of D-serine arealso observed in the thin glial elements of neuropil known tosurround the dendrites and spines of neurons. No structures thatcan be identified definitively as neurons are labeled for D-serine.Labeling for NR2A/B is strong in many neurons, especially in dendriticspines (Fig. 5, right), as reported previously (Petralia et al.,1994a).
Fig. 5. Ultrastructural comparison of D-serine and NR2A/B in hippocampal CA1 region. Brain sections were stained with the immunoperoxidasetechnique and then processed for electron microscopy. D-Serineconcentrates in the cytosolic matrix of astrocytes (Ast) in neuropiland in foot processes ensheathing blood vessels (BV), whereasendothelial cells (En) are unstained. NR2A/B concentrates in dendriticspines (arrows). 10,000× magnification.
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D-Serine and NR2A/B have parallel ontogeny in the cerebellum
We observed previously that D-serine staining in the cerebella of 50-d-old rats is much lower than in the forebrain and isrestricted to the molecular layer (Schell et al., 1995). Biochemicalassays indicate high levels of D-serine in the cerebella of juvenilerats (Hashimoto et al., 1995a). We monitored cerebellar levelsof D-serine and glycine during the first 3 postnatal weeks (Fig.6). D-Serine is detectable at birth and remains at a level of~0.1 µmol/gm until the end of week 1. During week 2, levels morethan double, reaching a peak of ~0.25 µmol/gm at P12. D-Serinelevels then decline, reaching undetectable levels by P26. Levelsof glycine exceed those of D-serine at all ages, with a surprisinglylarge rat-to-rat variation: between 0.5 and 0.9 µmol/gm. UnlikeD-serine, substantial amounts of glycine are detected in maturerats.
Fig. 6. Levels of free D-serine and glycine in cerebellum during postnatal development. Cerebella were analyzed by HPLC for free aminoacids. Values are mean ± SEM; n = 3.
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Immunohistochemical analysis confirms and extends these findings (Fig. 7). At P7, D-serine is concentrated in glial cell bodiesscattered throughout the white matter, deep nuclei, inner granulecell layer, and the growing molecular layer. NR2A/B staining isobserved in the deep nuclei, and the first indications of labelingin Purkinje cell bodies appear around this age. Strongly glycinergicGolgi neurons appear to have moved upward from deep layers andlocalize to the inner granule layer by P7 (not shown).
Fig. 7. Transient staining for D-serine and NR2A/B in developing cerebellum. The cell bodies of D-serine glia (Ast) are well labeledby P7, when Purkinje cells (P) begin to stain for NR2A/B. Oneweek later, both D-serine and NR2A/B concentrate in the molecularlayer, with D-serine in Bergmann glia (BG) and NR2A/B throughoutthe dendritic tree of Purkinje cells. In the P14 granule layer,many protoplasmic astrocytes stain intensely for D-serine, whereasa few Golgi neurons (Go) are lightly stained for NR2A/B. By P21,staining for both has decreased, but substantial amounts of D-serinepersist in the radial process of BG and in the cell bodies ofprotoplasmic astrocytes (Ast). NR2A/B at P21 has become less prominentin Purkinje cells and has appeared in some basket cell pinceau(Pi). In mature adults, D-serine occurs weakly in Bergmann gliacell bodies, whereas NR2A/B is restricted to basket cell pinceau.
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By P14, staining for D-serine is diminished in the deep nuclei, remains in the deep white matter, and has become strongerin the processes of multipolar glia scattered in the inner granulecell layer. Even more striking are the Bergmann glia in the molecularlayer, which stain intensely in their cell bodies and radial processes.The outer granule layer is unstained, except for fine radial glialprocesses, which extend to the pia. At P14, NR2A/B has disappearedfrom the deep nuclei and become prominent in the cell bodies anddendrites of the Purkinje cells extending into the growing molecularlayer. Also, a few large NR2A/B neurons appear scattered in theinner granule layer at this age; these are likely to be Golgineurons. We observe no NR2A/B staining in inner or outer granulecell bodies. By P14, the cellular pattern for glycine resemblesthe adult, with intense staining in Golgi cells and lesser stainingin a subset of basket cells; however, staining of the molecularlayer appears substantially lower than in the adult.

By the end of week 3, the distributions of D-serine and NR2A/B begin to take on their adult patterns. D-serine labeling atP21 is greatly reduced compared with that at P14 and is observedmainly in Bergmann glia cell bodies and thin radial processes,although some lightly stained glial cells are still observed inthe granule cell layer. NR2A/B remains detectable in Purkinjecells in the molecular layer but has receded from the more distaldendrites. Around P21 we also observe the first labeling of thepinceau, the axon terminals of the basket cells, which form aloose plexus around the proximal dendrites of Purkinje cells.Although some reports suggest that migrating granule cells transientlyexpress NR2A/B receptors (Farrant et al., 1994), we do not observeany granule cells labeled with the NR2A/B antibody. Glycine labelingat P21 resembles P14, except that many more immunoreactive punctatenerve processes fill the molecular layer; these are probably dendritesof Golgi and basket cells.

In the adult cerebellum (Fig. 8, right), weak staining for D-serine is observed only in Bergmann glia. In some cases, stainingis concentrated in the cell bodies located between Purkinje cellsat the inner edge of the molecular layer. In other cases, smallgroups of Bergmann glia appear instead to be stained preferentiallyin their distal processes. Low levels of NR2A/B immunoreactivitycan be detected in some but not all Purkinje cell bodies throughthe second month of postnatal life. We observe no labeling ofadult granule cells, which express the NR2C subunit. In matureadults, labeling for NR2A/B appears to be restricted absolutelyto basket cell pinceau, many of which are also strongly immunoreactivefor glycine (Fig. 8).
Fig. 8. High magnification of adult cerebellum near Purkinje cell bodies. D-Serine is restricted to Bergmann glia (BG) in the molecularlayer (Mol), especially in glial cell bodies that reside betweenPurkinje cells (P). The granule layer (Gr) is not stained forD-serine. NR2A/B still occurs in a minority of Purkinje cell dendrites,but the most intense staining occurs in basket cell pinceau (Pi),which also stain for glycine. Golgi neurons (Go), whose cell bodiesreside in the granule layer, are the major glycinergic elementof the cerebellum.
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DISCUSSION
In the present study we confirm and extend substantially our initial finding that D-serine is localized in rat brain to astrocytesthat are selectively concentrated in the gray matter, with a distributionclosely resembling that of NMDA receptors, specifically the NR2A/Bsubtypes; these are the principal subtypes of NMDA receptors inthe forebrain, the area of greatest NMDA receptor density. Inthe CA1 region of the hippocampus, where NMDA receptor neurotransmissionis prominent, D-serine-containing astrocytes are found in closeproximity to the NR2A/B-enriched dendrites of pyramidal cells,consistent with a role for D-serine in regulating the glycinesite of these receptors during long-term potentiation (Fig. 9,left).
Fig. 9. Models depicting the proposed modulatory roles for D-serine and glycine in the CA1 region of hippocampus (left) and the AOB(ACCES. OLF BULB, right). D-Serine is black; glycine is gray.Stars indicate localizations of NMDA receptors. In the hippocampus,D-serine-containing protoplasmic astrocytes (Ast) are localizednear NMDA receptors located on pyramidal cell (Py) dendrites,whereas glycinergic cells are rare. In the AOB, both D-serineand glycine appear concentrated near NMDA receptors located onmitral cells (Mi), with the D-serine found in superficial bulbarglia (SBG) surrounding the vomeronasal nerve (VN) and in protoplasmicastrocytes (Ast) in the plexiform layer. Glycine concentratesin interneurons (I) and periglomerular cells (PG).
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In our earlier study we mapped D-serine in 50-d-old rats, whereas the present study used 21-d-old rats. Although the greatmajority of the D-serine localizations are the same at the twoages, we observe some discrete differences. At P21 we observeprominent D-serine staining in a subcallosal band of white matterjust superficial to the hippocampus, which is greatly diminishedin P50 animals. This intensely stained area is demarked caudallyby the splenium of the corpus callosum and extends rostrally tothe subcallosal regions of the striatum and subependymal layer.These are regions of active cell proliferation and migration inyoung adults. In older rats, D-serine is more abundant in superficialas contrasted to deeper layers of the cerebral cortex. We haveobtained evidence that these variations relate to the migrationof astrocytes from the site of their initial proliferation andmigration in subcortical white matter near the subventricularzone to their localization in the gray matter of mature brain(M. J. Schell and S. H. Snyder, unpublished observations). Theantibody to NR2A/B used in this study was developed and used extensivelyin a previous study (Petralia et al., 1994a). The labeling patternswe obtain are in generally good agreement with this work, withthe modest differences explained by our use of younger animalsand a high-glutaraldehyde fixative. When we stain P50 animalsusing the fixative of Petralia et al., (1994a), we faithfullyreproduce their results.

Glycine localizations differ dramatically from those of D-serine and NR2A/B and instead resemble cloned glycine transporters(Zafra et al., 1995; Jursky and Nelson, 1996), with very low orundetectable levels in hippocampus and cortex. Glycine is localizedinversely to the glycine cleavage enzyme, which is enriched inthe mitochondria of telencephalic gray matter astrocytes (Satoet al., 1991). Autoradiographic studies of hippocampus sliceshave demonstrated that glycine is taken up into astrocytes (Fedeleet al., 1993), where the degradation of two glycine moleculesproduces serine (Daly et al., 1976). This pathway may be relevantto D-serine synthesis, because D-serine is probably concentratedin many of the same protoplasmic astrocytes, and the ontogenyof glycine cleavage activity in cerebellum (Lahoya et al., 1980)closely follows that of D-serine (Fig. 6). On the other hand,we do not observe D-serine staining in mitochondria, where theglycine cleavage enzyme is thought to be localized exclusively.

At the ultrastructural level, D-serine is concentrated in astrocyte foot processes. The hippocampal CA1 region contains highdensities of D-serine in the cytosolic matrix of glia, which ensheathNR2A/B-enriched spines as well as blood vessels. Non-NMDA receptorsare present in astrocyte end feet (Matute et al., 1994) and arewell positioned to regulate D-serine release. D-Serine stainingat the ultrastructural level strongly resembles staining for glycogenphosphorylase, the enzyme of the cytosolic matrix that controlsglycogen breakdown (Richter et al., 1996). The preferential glycolyticactivity of astrocytes is reflected by their almost exclusiveability to make and store glycogen in brain. It is thought thatglucose from blood enters astrocytes, whose glycolysis leads tothe formation of metabolic substrates in the cytosol, such aslactate, that pass into nearby dendrites to facilitate Krebs cyclemetabolism (Tsacopoulos and Magistretti, 1996). How metaboliccoupling might influence D-serine synthesis or release is unclear.NMDA receptor-mediated neurotransmission may occur in neuropilnear blood vessels, with the high demand for energy during excitatoryneurotransmission fueled by rapid exchange of metabolites throughastrocytes. Astrocytic D-serine would activate glycine sites onthe spines of neurons near blood vessels to regulate this process.

The highest densities of D-serine in the brain occur in the AOB, in specialized glia that surround axons of the vomeronasalfibers that project from the vomeronasal organ to olfactory glomeruli(Raisman, 1985; Ramon-Cueto and Valverde, 1995). This fiber systemmediates the actions of pheromones on reproductive behavior (Halpern,1987). Olfactory nerve layer glia promote the growth of primaryreceptor neuron axons and allow the reestablishment and maintenanceof connections with the olfactory bulb (Raisman, 1985). Olfactorynerve layers stain moderately for NR1 (Petralia et al., 1994b),and we detect NR2A/B in both main and accessory nerve layers.NMDA receptors promote and regulate neurite outgrowth (Zheng etal., 1996) and play crucial roles in the establishment of neuronalconnectivity throughout the brain. If glutamatergic transmissionoccurs among the thin, unmyelinated neurites inside the vomeronasalnerve layer, then D-serine released from the superficial bulbarglial cells would excite NMDA receptors on primary receptor axonswithin the nerve. In and near glomeruli, glial-derived D-serinewould modulate NMDA receptors located on dendrites of mitral ortufted cells (Ennis et al., 1996) and regulate synaptic connectivity(Fig. 9, right).

Ontogenic roles of D-serine in the cerebellum
NMDA receptors are expressed transiently on Purkinje cells but are absent from adults (Dupont et al., 1987; Garthwaite etal., 1987). The transient staining we observe probably reflectsthe NR2B subtype (Watanabe et al., 1994; Portera-Cailliau et al.,1996). Between P5 and P15, parallel fibers and climbing fibersestablish connections with Purkinje cells (Altman, 1972). NMDAreceptors are required for proper synapse formation and elimination,because blockers of NMDA receptors prevent the establishment ofnormal connectivity (Rabacchi et al., 1992). During this criticalperiod, Bergmann glia are intensely stained for D-serine, andthe processes of these cells envelop the Purkinje cell dendritictree (Palay and Chan-Palay, 1974). After the critical period,D-serine levels drop rapidly, because Bergmann glia begin expressingD-amino oxidase (Weimar and Neims, 1977a,b; Horiike et al., 1987).Therefore, astrocytic D-serine is both spatially and temporallypositioned to modulate NMDAR-dependent synaptogenesis with Purkinjecells (Fig. 10, left).
Fig. 10. Models contrasting the proposed roles for D-serine and glycine in developing and adult cerebellum. D-Serine is black; glycineis gray. Stars indicate localizations of NMDA receptors. In developingmolecular layer (left), astrocytic D-serine is found in Bergmannglia (BG), which ensheath Purkinje cells expressing NMDA receptorsand also guide migrating granule cells (Gr) expressing NMDA receptors.D-Serine released from Bergmann glial processes might synergizewith glutamate released by parallel fibers (PF) and climbing fibers(CF). In the developing inner granule layer, protoplasmic astrocytes(Ast) might release D-serine near the developing glomerular synapseto synergize with glutamate from mossy fibers (MF), whereas glycinergicbasket (Ba) and Golgi neurons (Go) have not yet established connectionswith NMDA receptor-containing synapses. In contrast, in adultcerebellum (right), no D-serine is present, and NMDA receptorshave disappeared from Purkinje cells. NMDA receptor-associatedglycine sites located on the basket cell pinceau and granule cellsmight be modulated exclusively by glycinergic basket (Ba) andGolgi (Go) neurons.
[View Larger Version of this Image (28K GIF file)]

Another prominent feature of cerebellar development is the migration of the granule cells from the external to the internalgranule cell layers along the processes of Bergmann glia, whichserve as a scaffold. This migration is dependent on NMDA receptorsbeing blocked by the NMDAR antagonist MK801 and stimulated byglycine (Komuro and Rakic, 1993; Rossi and Slater, 1993). Startingaround P7, radial processes of D-serine-producing Bergmann gliaappear in the molecular layer, coincident with the migration ofgranule cells. Low levels of glycine staining also occur in proximityto migrating granule cells, in the dendrites of Golgi neurons;however, the Golgi cell staining becomes more intense at the endof week 3, after granule cell migration is completed. D-Serinein the radial processes of Bergmann glia is the better candidateregulator for glycine sites involved in granule cell migration.

In the inner granule layer, NMDA receptors are present on the dendrites of granule cells at synapses with mossy fibers (D'Angeloet al., 1993). Synaptogenesis here occurs during a critical period,approximately P8-28 (Garthwaite and Brodbelt, 1989). During thisperiod, mossy fiber synapses segregate into rosettes with granulecell dendrites to form glomeruli. D-Serine occurs transientlyin the granule layer, in the cell bodies and processes of protoplasmicastrocytes in close vicinity to glomeruli. Astrocytes are believedto be involved in the compartmentalization and segregation ofglomerular units (Palay and Chan-Palay, 1974), and glial D-serinecould help define the boundaries of each unit (Steindler, 1993).

The glomerular synapse is also believed to be where NMDA neurotransmission stimulates granule cells to produce nitric oxide.In P5-14 cerebellar slices, glycine sites involved in nitric oxideproduction are saturated, because exogenously added D-serine doesnot enhance cGMP production (Southam et al., 1991). Beginningaround P21, these glycine sites are not saturated, because theNMDA-stimulated cGMP response is enhanced by exogenous D-serine.In adult cerebellum, in vivo studies have demonstrated that theglycine site involved in nitric oxide production is not saturated(Wood et al., 1989). We find that D-serine levels in the P7-14cerebellum are 10-40 times higher than in adults. The productionof astrocytic D-serine and its subsequent destruction by D-aminoacid oxidase concentrated near glomerular synapses (Weimar andNeims, 1977a,b) seems to account for the change in glycine sitesaturation. D-Serine release from astrocytes is not stimulatedby KCl depolarization, but rather occurs by stimulation of non-NMDAreceptors and sodium-dependent transporter-reversal (Schell etal., 1995). The endogenous glycine site agonist regulating nitricoxide production in cerebellum acts in a tetrodotoxin (TTX)-independentmanner during development, but in a TTX-dependent manner in adults(Southam et al., 1991). The principal glycinergic cell in thecerebellum is the Golgi neuron (Ottersen et al., 1988). Thesedata are consistent with a model by which glomerular synapsesare established through mechanisms involving the release of D-serinefrom astrocytes but are modulated in adults by glycine releasedby Golgi neurons (Fig. 10).

In adult cerebellum, the principal NMDA receptor subtype is 2C, located on granule cell dendrites. Glycine seems to be theendogenous agonist of this receptor in the adult, with D-serinepresent at very low levels only in Bergmann glia. Glycine coexistswith GABA in Golgi neurons (Ottersen et al., 1988), consistentwith a role as an inhibitory neurotransmitter. Yet glycine bindingin the cerebellum is strychnine-insensitive (Wilkin et al., 1981).It is well established that Golgi neuron terminals release GABAat glomeruli and inhibit the mossy fiber/granule cell synapse(Palay and Chan-Palay, 1974). Glycine co-released with GABA insteadmay activate or shape the NMDA receptor response of granule cells.

NR2A/B in adult cerebellum occurs almost exclusively in the pinceau structures composed of basket cell terminals surroundingthe initial segments of Purkinje cells (Fig. 8). Glycine-containingterminals are concentrated in these pinceau, which also containGABA (Liu et al., 1989). What glutamatergic fibers are most likelyto activate NMDA receptors located on basket cell terminals? Tendrilcollaterals of climbing fibers project to Purkinje cell bodiesnear their axons (Palay and Chan-Palay, 1974). Physiological studieshave demonstrated that glutamate or aspartate from parallel fibersacts on NMDA receptors located on basket cell dendrites to increaseGABA release, because the application of NMDA onto adult cerebellarPurkinje cells produces inhibitory responses that are blockableby bicuculline (Crepel et al., 1982; Quinlan and Davies, 1985;Llano et al., 1991). Climbing fiber tendril collaterals near NMDAreceptors on basket cell axons could mediate a similar response.

Some researchers have suggested that endogenous levels of glycine are sufficient to fully saturate the glycine site of NMDAreceptors. Because D-serine levels in the extracellular spaceof many brain regions are similar to those of glycine (Hashimotoet al., 1995b), the same could be said for D-serine. Moreover,D-serine is about three times more potent than glycine at many"glycine sites," so lower levels of D-serine would suffice tosaturate the sites. A substantial number of studies suggest thatglycine sites are not always saturated, because exogenous D-serineand glycine potentiate responses to NMDA in vivo (Salt, 1989;Wood et al., 1989; Thiels et al., 1992; Schmitt et al., 1995).Moreover, pretreating intact rats with D-serine increases thepotency of exogenous NMDA as a convulsant (Larson and Beitz, 1988;Singh et al., 1990).

D-Serine fulfills the principal criteria for a neuromodulator at the glycine site of NMDA receptors. It is localized at thesesites and faithfully mimics actions of the endogenous ligand.We showed previously that D-serine is released by glutamatergicstimulation. [³H]D-Serine is accumulated into cerebral cortical synaptosome preparationsand type II astrocyte cultures only ~5% as well as [³H]L-serine or [³H]glycine (M. J. Schell and S. H. Snyder, unpublished observations).Thus, released D-serine would be present in the synaptic spacelonger than glycine, with a greater opportunity to stimulate adjacentNMDA receptors, and any saturated "glycine sites" are more likelyto be saturated with D-serine.

In summary, the detailed comparisons of glycine, D-serine, and NR2A/B support our previous conclusions that D-serine is theendogenous ligand for the glycine site of telencephalic NMDA receptors.D-Serine also seems to be important in NMDAR-mediated developmentof the cerebellum. In the brainstem and spinal cord, where noD-serine is found and functional NMDA receptors are known to exist,endogenous glycine most likely modulates these sites. Why natureshould use D-serine at certain synapses and glycine at othersis a mystery. Differences in dynamics of the two transmitters,one in glia and the other in neurons, may be relevant.

FOOTNOTES

Received Oct. 24, 1996; revised Dec. 16, 1996; accepted Dec. 19, 1996.

This work was supported by United States Public Health Service Grant MH 18501, a gift from the Theodore and Vada Stanley Foundation,Research Scientist award DA 00074 from the National Instituteon Drug Abuse, and The Alan McAfee Baldwin Memorial Fund for Schizophreniato S.H.S. M.E.M. was supported by Grant 5RO1DA04431 from the NationalInstitute on Drug Abuse. We thank Mike Delannoy and Jiao Li forassistance with electron microscopy.

Correspondence should be addressed to Solomon H. Snyder, Department of Neuroscience, Johns Hopkins University School of Medicine,725 N. Wolfe Street, Baltimore, MD 21205.

Dr. Schell's present address: Department of Pharmacology, Tennis Court Road, University of Cambridge, Cambridge CB2 1QJ, UK.

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