Abstract
Neurotransmission in the hippocampus is modulated variously through presynaptic metabotropic glutamate receptors (mGluRs). To establish the precise localization of presynaptic mGluRs in the rat hippocampus, we used subtype-specific antibodies for eight mGluRs (mGluR1–mGluR8) for immunohistochemistry combined with lesioning of the three major hippocampal pathways: the perforant path, mossy fiber, and Schaffer collateral. Immunoreactivity for group II (mGluR2) and group III (mGluR4a, mGluR7a, mGluR7b, and mGluR8) mGluRs was predominantly localized to presynaptic elements, whereas that for group I mGluRs (mGluR1 and mGluR5) was localized to postsynaptic elements. The medial perforant path was strongly immunoreactive for mGluR2 and mGluR7a throughout the hippocampus, and the lateral perforant path was prominently immunoreactive for mGluR8 in the dentate gyrus and CA3 area. The mossy fiber was labeled for mGluR2, mGluR7a, and mGluR7b, whereas the Schaffer collateral was labeled only for mGluR7a. Electron microscopy further revealed the spatial segregation of group II and group III mGluRs within presynaptic elements. Immunolabeling for the group III receptors was predominantly observed in presynaptic active zones of asymmetrical and symmetrical synapses, whereas that for the group II receptor (mGluR2) was found in preterminal rather than terminal portions of axons. Target cell-specific segregation of receptors, first reported for mGluR7a (Shigemoto et al., 1996), was also apparent for the other group III mGluRs, suggesting that transmitter release is differentially regulated by 2-amino-4-phosphonobutyrate-sensitive mGluRs in individual synapses on single axons according to the identity of postsynaptic neurons.
- metabotropic glutamate receptor
- hippocampus
- perforant path
- mossy fiber
- Schaffer collateral
- axon terminal
- preterminal
- immunohistochemistry
- lesion
Metabotropic glutamate receptors (mGluRs) have various modulatory functions on neuronal excitability, transmitter release, and synaptic plasticity in the CNS (Pin and Duvoisin, 1995). These functions have been studied most extensively in the hippocampus because of its roles in learning and memory and of its architecture, which is compartmentalized well with the three major excitatory pathways: the perforant path, mossy fiber, and Schaffer collateral. The mGluRs consist of at least eight subtypes that are classified into three groups (Nakanishi and Masu, 1994; Pin and Duvoisin, 1995). Group I mGluRs (mGluR1/mGluR5) are selectively activated by 3,5-dihydroxyphenylglycine (DHPG) (Schoepp et al., 1994) and coupled to inositol phospholipid hydrolysis. On the other hand, group II mGluRs (mGluR2/mGluR3) and group III mGluRs (mGluR4/mGluR6/mGluR7/mGluR8), which are linked to inhibition of the cAMP cascade in receptor-transfected cell lines, are selectively activated by 2-(2,3-dicarboxycyclopropyl)glycine (DCG-IV) (Hayashi et al., 1993) and 2-amino-4-phosphonobutyrate (L-AP4), respectively.
Excitability of hippocampal neurons is modulated directly through group I mGluRs (Davies et al., 1995; Gereau and Conn, 1995b) coupled to various calcium, potassium, and nonselective cationic channels (Swartz and Bean, 1992; Crépel et al., 1994; Guérineau et al., 1994, 1995). This is consistent with the postsynaptic location of mGluR1/mGluR5 immunoreactivity in hippocampal neurons (Luján et al., 1996). On the other hand, presynaptic mGluRs are thought to suppress transmitter release in various regions (Pin and Duvoisin, 1995) by inhibiting voltage-dependent calcium channels (Takahashi et al., 1996) and/or interfering directly with the release machinery (Scanziani et al., 1995). In the hippocampus, group I and group III mGluRs mediate the inhibition of excitatory transmission in the Schaffer collateral–CA1 cell synapses (Gereau and Conn, 1995a), whereas the group II and group III mGluRs are involved in the presynaptic inhibition in the perforant path–granule cell synapses (Bushell et al., 1996a; Macek et al., 1996). Furthermore, recent studies with mGluR-deficient mutant mice have indicated that not only postsynaptic but also presynaptic mGluRs have roles in hippocampal synaptic plasticity (Bushell et al., 1996b; Yokoi et al., 1996).
The mRNAs for all mGluRs except mGluR6 are expressed in the hippocampus and entorhinal cortex (Shigemoto et al., 1992; Ohishi et al., 1993a,b,1995a; Fotuhi et al., 1994; Saugstad et al., 1994). Immunolabeling for mGluR2/3 and mGluR7a was found in presynaptic elements in the hippocampus using subtype-specific antibodies (Shigemoto et al., 1995,1996; Bradley et al., 1996; Petralia et al., 1996; Yokoi et al., 1996). We also developed antibodies specific to mGluR4a and mGluR8 and found these immunoreactivities in axon terminals in other brain regions (Kinoshita et al., 1996a,b). In the present study, we systematically used 10 subtype-specific mGluR antibodies, including a newly developed mGluR7b-specific antibody, to examine the precise localization of presynaptic mGluRs in the rat hippocampus by light and electron microscopy, in combination with lesion experiments to establish the origins of presynaptic mGluR-bearing pathways.
MATERIALS AND METHODS
Preparation of affinity-purified antibodies against mGluRs. Antibodies for mGluR1α, mGluR1, mGluR2/3, mGluR2, mGluR5, and mGluR7a were raised against bacterial fusion proteins containing mGluR sequences (amino acid residues 859–1199 of mGluR1α, 104–154 of mGluR1, 87–134 and 813–872 of mGluR2, 863–1171 of mGluR5a, and 874–915 of mGluR7a) as described previously (Shigemoto et al., 1993, 1994, 1996; Ohishi et al., 1994, 1995b; Neki et al., 1996). One mGluR1 antibody (G18) raised against extracellular amino acid residues 104–154 is specific to all spliced forms of mGluR1 (pan mGluR1 antibody) (Shigemoto et al., 1994), whereas another (A52) raised against intracellular C-terminal residues 859–1199 of mGluR1α is specific to mGluR1α (see Results). The antibody (H12) raised against intracellular C-terminal residues 813–872 of mGluR2 is reactive to both mGluR2 and mGluR3 (mGluR2/3 antibody) (Ohishi et al., 1994), whereas another mGluR2 monoclonal antibody (mG2Na-5) raised against putative extracellular amino acid residues 87–134 is mGluR2-specific (Neki et al., 1996). The mGluR5 antibody is reactive to the C-terminal domain common for mGluR5a and mGluR5b (Minakami et al., 1993). Antibodies for mGluR4a (K44), mGluR6, and mGluR8 (K88) were raised against synthetic peptides corresponding to C-terminal sequences (amino acid residues 890–912 of mGluR4a, 853–871 of mGluR6, and 886–908 of mGluR8) as described previously (Nomura et al., 1994; Kinoshita et al., 1996a,b). The antibodies for mGluR1, mGluR1α, mGluR2/3, mGluR5, mGluR6, and mGluR7a are polyclonal antibodies raised in rabbits, whereas those for mGluR4a and mGluR8 are polyclonal antibodies raised in guinea pigs. An antibody for mGluR7b (K74) was newly raised against a synthetic peptide corresponding to the human mGluR7b-specific C-terminal sequence (NCIPPVRKSVQKSVTWYTIPPTV) (Flor et al., 1997) as described previously (Kinoshita et al., 1996a). The amino acid sequence used for the antibody production is identical between the human and rat mGluR7b (F. Ferraguti, personal communication). After conjugation with maleimide-activated bovine serum albumin (Pierce, Rockford, IL), the peptide was injected subcutaneously in rabbits and guinea pigs (0.5–1.0 mg of peptide/animal). The immunized animals were boosted every 4 weeks and bled 1–2 weeks after each boost. The collected antisera were purified by sodium sulfate fractionation, followed by affinity chromatography on a SulfoLink (Pierce) coupled to the C-terminus peptide. The purified mGluR7b antibodies derived from rabbits and guinea pigs gave identical results.
Immunoblot analysis. Immunoblot analysis was performed as described previously (Shigemoto et al., 1994). The crude membrane preparations from rat hippocampus and mGluR4-, mGluR6-, mGluR7a- and mGluR7b-expressing Chinese Hamster Ovary (CHO) cells (Tanabe et al., 1992; Nakajima et al., 1993; Okamoto et al., 1994; Flor et al., 1997) were separated by 7% SDS-PAGE and transferred to polyvinylidene difluoride (PVDF) membranes. The membranes were blocked with Block-Ace (Dainippon Pharmaceutical) and then reacted with the affinity-purified mGluR antibodies (0.2–1.0 μg/ml) in the absence or presence of respective fusion proteins. Alkaline phosphatase-labeled secondary antibodies (Chemicon, Temecula, CA) were used to visualize the reacted bands.
Surgery. At least three adult male Wistar rats (250–300 gm) were used for each series of experiments. All surgical manipulations were performed using a David Kopf stereotaxic apparatus under anesthesia with sodium pentobarbital (50 mg/kg, i.p.). A lesion generator (Radionics Inc.) was used at the setting of 60°C for 2 min to make lesions in the entorhinal cortex and subiculum. For destruction of dentate granule cells, colchicine (Sigma, St. Louis, MO) (3 μg in 0.9 μl of 25 mm PBS, pH 7.3) was injected through a 1 μl Hamilton microsyringe into the dorsal and ventral hilus of the left hippocampus as described previously (McGinty et al., 1983). For destruction of CA3 pyramidal cells, kainic acid (Sigma) was injected into the CA areas of the left hippocampus or bilateral ventricles at the dose of 0.2 μg in 0.2 μl PBS or 0.6 μg in 1.2 μl PBS, respectively. In some experiments, PBS alone was injected into the corresponding sites of the right hippocampus or bilateral ventricles to serve as controls. Seven days after the lesioning or injections of colchicine or kainic acid, the rats were killed and processed for immunohistochemistry.
Immunohistochemistry. Immunohistochemical staining was performed by the ABC and double-immunofluorescence methods as described previously (Shigemoto et al., 1993, 1996). For light microscopy, adult male Wistar rats as well as wild-type and mGluR-deficient mice were deeply anesthetized and perfused transcardially with 3.5% paraformaldehyde, 1% picric acid, and 0.05% glutaraldehyde in 0.1m phosphate buffer (PB), pH 7.3. For immunolabeling with the mGluR2 antibody (mG2Na-5), brains were further fixed for 3 d at 4°C in a mixture containing 2% formaldehyde and 1% picric acid in 0.1 m PB, pH 7.3 (Neki et al., 1996). Tissue blocks containing the hippocampus were cryoprotected in 20% sucrose in 0.1m PB overnight at 4°C and cut on a freezing microtome into 40-μm-thick sections. The sections were incubated with 0.5–1.0 μg/ml antibodies for mGluRs in PBS containing 2% normal goat serum and 0.1% Triton X-100 overnight at 15°C. After washes in PBS, the sections were incubated with biotinylated goat anti-rabbit, goat anti-guinea pig, or goat anti-mouse IgG (Vector Laboratories, Burlingame, CA). The sections were then washed again, reacted with the ABC kit (Vector), and finally incubated with 0.05% diaminobenzidine and 0.0006% hydrogen peroxide. For double-immunofluorescence histochemistry, 20-μm-thick sections were reacted with antibodies to mGluRs (0.5–1.0 μg/ml) and then with fluorescein isothiocyanate-conjugated anti-[rabbit IgG] antibody and biotinylated anti-[guinea pig IgG] antibody combined with Texas Red-conjugated avidin. When either of the primary antibodies was omitted, no fluorescence signal for the omitted primary antibody was observed (not shown). For electron microscopy, rats were perfused with 4% paraformaldehyde, 0.2–1.0% picric acid, and 0.05–0.1% glutaraldehyde in 0.1 m PB, pH 7.3. Tissue blocks were then processed by two separate methods. In the first method, 50-μm-thick sections were cut on a vibratome and processed as described above for light microscopy, except that 0.2% photoflo (Kodak) was used instead of Triton X-100. In the second method, tissue blocks were freeze-thawed in liquid nitrogen and PBS at room temperature, and 50-μm-thick sections were cut on a vibratome. The sections from freeze-thawed tissues were incubated with mGluR antibodies in PBS containing 2% normal goat serum without Triton X-100 or photoflo. After washes in PBS, sections were incubated with biotinylated or 1.4 nm gold-labeled (Nanoprobes, Stony Brook, NY) secondary antibodies and then reacted with the ABC or HQ Silver kit (Nanoprobes), respectively. After osmification, the immunostained sections were block-stained with uranyl acetate, dehydrated, and flat-embedded in Epon. Ultrathin sections were then prepared and examined with a Hitachi H-7100 electron microscope. Some sections with immunogold labeling were counterstained with lead citrate.
RESULTS
Immunoblot analysis of mGluRs in the hippocampus
Specificity of the antibodies used in the present study was verified with immunoblot analysis of a crude membrane fraction prepared from the rat hippocampus (Fig.1A). Pan mGluR1 antibody (G18) gave rise to two immunoreactive products with estimated molecular masses of 145 and 97 kDa. The former corresponds to mGluR1α (Masu et al., 1991) and the latter to mGluR1β (Tanabe et al., 1992), mGluR1c (Pin et al., 1992), and mGluR1d (Laurie et al., 1996). Only the former was detected with another mGluR1 antibody (A52) raised against C-terminal residues of mGluR1α, indicating that A52 is specific to mGluR1α. Two immunoreactive products of 98 kDa and ∼200 kDa were observed with the mGluR2/3 (H12) and mGluR2 (mG2Na-5) antibodies. The former product corresponds to mGluR2, and the latter probably represents dimeric forms of mGluR2/3 proteins (Hayashi et al., 1993;Ohishi et al., 1994). Presumed dimeric forms were found for most mGluRs (Baude et al., 1993; Shigemoto et al., 1993; Nomura et al., 1994;Petralia et al., 1996; Romano et al., 1996) (also see the present results for mGluR4a, mGluR7a, mGluR7b, and mGluR8). The extracellular mGluR2-specific antibody (mG2Na-5) gave a similar immunoreactive product of 98 kDa but only weakly reacted with the product of ∼200 kDa. This result may be attributed to low accessibility of the extracellular epitope in the dimeric form (Romano et al., 1996). In the present study, the mGluR3-immunoreactive product of 106 kDa observed in the cerebral cortex (Hayashi et al., 1993) and whole brain (Ohishi et al., 1994) was scarcely detected in the hippocampus. Immunoreactive bands of molecular masses around 100 kDa were observed for mGluR4a, mGluR7a, and mGluR8, and that of 145 kDa was found for mGluR5, as reported previously (Shigemoto et al., 1993, 1996; Kinoshita et al., 1996a,b). Immunoreactivity for mGluR5 and mGluR7a was strong in the hippocampus, whereas that for mGluR4a or mGluR8 was much weaker in the hippocampus than in the cerebellum (Kinoshita et al., 1996b) or in the piriform cortex (Kinoshita et al., 1996a), respectively. The newly developed mGluR7b antibody gave rise to an immunoreactive doublet with estimated molecular masses of 102 and 96 kDa. These molecular masses agree well with that of the cloned human mGluR7b (103,082 Da) (Flor et al., 1997). Two such immunoreactive bands with slightly different molecular masses were also observed for mGluR6 in the retina (Nomura et al., 1994) and may result from different post-translational modification, such as glycosylation and proteolytic cleavage. All immunoreactivities described above disappeared after preadsorption of the antibodies with the corresponding fusion proteins or synthetic peptides (Fig. 1A; shown only for mGluR7b). The homology between the amino acid sequences used for the production of the mGluR antibodies was highest among group III mGluRs (52% for mGluR4a and mGluR8, 35% for mGluR4a and mGluR7a, and 30% for mGluR7a and mGluR8). To exclude the possibility of cross-reactivity to other group III mGluRs, the mGluR4a, mGluR7a, and mGluR8 antibodies were incubated with excess amounts (10 times more antigens than those used for the homologous preadsorption controls) of heterologous antigens for other group III mGluRs. The preincubated antibodies gave results (data not shown) identical to those shown in Figure 1A. The mGluR7a antibody was purified with a column coupled to a glutathioneS-transferase-fusion protein containing 20 amino acid residues from the C-terminal (Ohishi et al., 1995b) that have four amino acid residues (896–899) in common with mGluR7b (Flor et al., 1997). To exclude possible cross-reactivity of the mGluR7a and mGluR7b antibodies to each other and to other group III mGluRs, membrane fractions prepared from cDNA-transfected cell lines expressing mGluR4a, mGluR7a, mGluR7b, and mGluR8 were subjected to immunoblot analysis. Both the mGluR7a and mGluR7b antibodies as well as mGluR4a and mGluR8 antibodies reacted specifically with the corresponding cell lines (Fig.1B). These results indicate that the mGluR antibodies react specifically with their respective mGluRs.
Immunohistochemistry of mGluRs in normal hippocampus
All mGluR antibodies revealed specific and distinct patterns of immunoreactivity in the normal rat hippocampus (Figs.2, 3, 4, 5, 6). All of these immunostaining patterns were abolished by preadsorption of the antibodies with the homologous but not the heterologous antigens (data not shown). For example, mGluR7a immunolabeling, which overlaps with immunolabeling for mGluR4a/7b/8, was abolished after preadsorption of the antibody with the mGluR7a fusion protein and an mGluR7a-specific synthetic peptide (residues 900–915), but it was not affected by corresponding C-terminal peptides for mGluR4a/7b/8. Specificity of the immunostaining for mGluR1, mGluR1α, mGluR2, mGluR5, mGluR7a, and mGluR7b was further verified in the mice lacking the respective mGluR genes (Aiba et al., 1994; Bushell et al., 1996b; Yokoi et al., 1996; Lu et al., 1997). In wild-type mice, immunolabeling patterns similar to those in rat were observed for these receptors in the hippocampus, but they were totally absent in the respective mGluR-deficient mice (data not shown). Immunolabeling of mGluR4a in the hippocampus of wild-type mice had a laminar distribution different from that in the rat (R. Shigemoto, unpublished result), but it was also absent in mGluR4-deficient mice (Pekhletski et al., 1996). Moreover, cross-reactivity of the antibodies for mGluR7a/7b/8 to mGluR4 and of those for mGluR4a/8 to mGluR7 were excluded by unaltered immunostaining patterns observed in mGluR4- and mGluR7-deficient mice, respectively (data not shown).
Immunoreactivity for the group I mGluRs was observed in neuropil of the dendritic fields of the hippocampal principal cells as described previously (Luján et al., 1996), whereas immunoreactivity for the group II and group III mGluRs was observed more or less in a laminated fashion corresponding to the terminal zones of the major hippocampal pathways (Fig. 2). All hippocampal fields were immunopositive for mGluR5 and mGluR7a, whereas immunoreactivity for the other mGluRs was restricted to some areas or layers in the hippocampus. Immunoreactivity for mGluR6 was hardly detected in the hippocampus (Fig.2G).
For the group I mGluRs, we used the antibodies reactive to all splice variants of mGluR1 (pan mGluR1) and mGluR5, as well as the mGluR1α-specific antibody. In CA1 dendritic fields, only the mGluR5 antibody showed intense immunolabeling of neuropil, whereas the pan mGluR1 and mGluR5 antibodies revealed similar patterns of immunolabeling in CA3 dendritic fields and dentate molecular layer (Figs. 2A,F, 3A,B). Cell bodies of the granule and CA3 pyramidal cells showed moderate to strong labeling for mGluR1 but only very weak labeling for mGluR5 (Fig.3A,B). These labelings with the pan mGluR1 antibody were not detected at all with the mGluR1α-specific antibody (Fig. 2B), indicating that the mGluR1 immunoreactivity in CA3 pyramidal cells is ascribable to mGluR1β, mGluR1c, and/or mGluR1d. Strong labeling for pan mGluR1 was also observed in cell bodies and dendrites of interneurons scattered in the hilus (Fig. 3A) and CA areas, being densest in the border zone between CA1 stratum oriens and the alveus (Fig.2A). These interneurons were the only cells that were also immunopositive for mGluR1α (Fig. 2B). A double-immunofluorescence labeling confirmed that all of the interneurons labeled with the pan mGluR1 antibody were also immunopositive for mGluR1α throughout the hippocampus (data not shown). In the hilus, mGluR5 immunolabeling was seen in many dendritic processes (Fig. 3B). The somatodendritic profiles labeled for mGluR1 and mGluR5 were observed less frequently in CA3 stratum lucidum.
For the group II mGluRs, we used the antibody reactive to both mGluR2 and mGluR3, as well as the mGluR2-specific antibody. The immunostaining patterns with the mGluR2/3 and mGluR2 antibodies were similar (Fig.2C,D), but some differences were seen in the strata oriens and radiatum of the CA areas, where diffuse and weak immunostaining was detected only with mGluR2/3 antibody (Fig. 2C). Such mGluR2/3 immunoreactivity was also detected in mice lacking the mGluR2 gene (Yokoi et al., 1996) and ascribed to mGluR3 immunoreactivity of glial cells (see the results of electron microscopy). The density of the mGluR2/3 and mGluR2 immunolabeling was highest in neuropil of CA1 stratum lacunosum moleculare (Figs. 2C,D, 3C). In the CA3 area, labeling was stronger in the inner than in the outer layer of the stratum lacunosum moleculare, and in the dentate gyrus, it was stronger in the middle than in the outer one-third of the molecular layer (Figs. 2C,D, 3C). The strongly labeled layers correspond to the medial perforant path (Steward, 1976). A clear boundary of the strong labeling was observed between the inner and middle thirds of the molecular layer, whereas the other boundary between the outer and middle thirds of the layer was less clear (Fig.3C). This observation again agrees well with the reported pattern of the medial perforant path projection (Steward, 1976). Immunoreactivity for mGluR2/3 and mGluR2 was also observed in neuropil of the mossy fiber terminal zone (Fig. 2C,D). Labeling of axon bundle-like profiles was apparent in CA3 stratum lucidum (see Fig.5A) as well as in the fimbria (Fig. 2C,D). In mice lacking the mGluR2 gene, these mGluR2/3 immunolabelings were almost absent (Yokoi et al., 1996), indicating that most of the immunoreactivity in the perforant path and mossy fiber terminal zones is ascribable to mGluR2.
Among the group III mGluRs, mGluR4a, mGluR7a, mGluR7b, and mGluR8 were expressed in the hippocampus. In the CA1 area, strong neuropil labeling was observed only for mGluR7a, being strongest in the strata oriens and radiatum, followed by the stratum lacunosum moleculare (Figs.2H, 3D). Labeling in the pyramidal cell layer was very weak. In CA3 dendritic fields, very strong mGluR7a labeling was observed in CA3 stratum lacunosum moleculare, especially in the inner layer adjacent to the dentate molecular layer (Fig.2H). The medial perforant path terminal zone in the dentate gyrus, namely the middle third of the molecular layer, was also prominently immunopositive for mGluR7a (Fig. 3D). The distribution of immunoreactivity for other group III mGluRs was much more restricted in the hippocampus. Labelings for mGluR4a and mGluR8 were weak and diffuse compared with those for mGluR2/3 and mGluR7a; however, prominent staining for mGluR4a and mGluR8 was still observed in neuropil of the inner and outer thirds of the dentate molecular layer, respectively (Figs. 2E,J,4A,C). The former corresponds to the terminal zone of the associational/commissural fibers (Swanson et al., 1978) and the latter to that of the lateral perforant path (Steward, 1976). The mGluR8 immunolabeling was stronger in the inner than in the outer blade of the dentate gyrus (Figs.2J, 7H); this pattern is in good accordance with that of preferential projections of the lateral perforant path (Wyss, 1981). The lateral perforant path terminal zone in CA3 stratum lacunosum moleculare (superficial portion of the layer) was also prominently immunopositive for mGluR8, making the staining pattern apparently complementary to that for mGluR2/3 (Fig.2C). In these neuropil stainings, some dendritic profiles showed up being decorated with many axon terminals that were intensely labeled for the group III mGluRs (Fig. 4) (also see the results of electron microscopy). They were most frequently observed for mGluR7a followed by mGluR8, and only occasionally observed for mGluR4a in the molecular layer. Most of these dendrites decorated with labeled axon terminals seemed to originate from interneurons in the hilus or granule cell layer. For mGluR7a and mGluR7b, the decoration of many dendritic processes and some cell bodies of interneurons were observed in the hilus (Figs. 2H,I, 3D,6A). In CA3 stratum lucidum, the somatodendritic decoration was observed more strongly for mGluR7b than for mGluR7a (Fig. 5B,C). The strong terminal labeling for mGluR7a on the somatodendritic profiles of interneurons was distributed most densely in the stratum oriens/alveus border zone in the CA1 area and less densely in other CA areas, as described previously (Shigemoto et al., 1996). Because these decorated interneurons were mGluR1α-immunopositive (Shigemoto et al., 1996), we also examined, by a double-immunofluorescence labeling, whether the decoration with mGluR7b correlates with the mGluR1α-immunopositive interneurons in the mossy fiber terminal zone (Fig.6A,A’). As in mGluR7a labeling, mGluR7b-labeled puncta were mostly found on mGluR1α-labeled interneurons. Colocalization of mGluR7a and mGluR7b was also examined (Fig. 6B,B’). Virtually all mGluR7b-labeled structures were labeled for mGluR7a; however, the mGluR7a-labeled axon terminals decorating interneurons in strata oriens and radiatum of the hippocampus could be labeled only very slightly for mGluR7b.
Effects of unilateral and bilateral lesions in the entorhinal cortex on immunoreactivity for mGluRs in the hippocampus
The light microscopic findings on the distribution of mGluRs in the hippocampus support the idea that the group I and group II/III mGluRs are localized in postsynaptic and presynaptic elements, respectively. It is not always possible, however, to distinguish between the pre- and postsynaptic immunolabelings by light microscopy, especially if receptors are highly targeted to postsynaptic sites receiving particular presynaptic elements (Nusser et al., 1996) or to presynaptic sites terminating on particular postsynaptic elements (Shigemoto et al., 1996). Furthermore, in addition to the major excitatory pathways, the hippocampus contains many types of extrinsic and intrinsic afferent fiber groups that have selective termination areas (Frotscher and Leranth, 1985; Bakst et al., 1986; Wouterlood et al., 1990; Han et al., 1993; Maglóczky et al., 1994). To clarify the origins of axon terminals showing mGluR immunoreactivity in the hippocampus, we next generated various lesions in the sites of origin of the major hippocampal excitatory pathways.
First, massive unilateral lesions were placed in the entorhinal cortex to damage the perforant path, a major excitatory afferent path to the hippocampus (Amaral and Witter, 1995). In the rats with lesion involving most of the unilateral entorhinal cortex as well as a part of the adjacent perirhinal area and subicular complex (Fig.7A–C,E,G, asterisks), immunoreactivity for mGluR1 and mGluR5 in the hippocampus ipsilateral to the lesion (Fig. 7A,B) was not different from that on the contralateral side (not shown). On the other hand, immunoreactivity for mGluR2/3, mGluR7a, and mGluR8 was markedly reduced ipsilaterally in the terminal zones of the perforant path (Fig. 7C–H). In the CA1 stratum lacunosum moleculare, the inner layer of CA3 stratum lacunosum moleculare, and the middle third of the dentate molecular layer, mGluR2/3 and mGluR7a immunoreactivity was greatly reduced (Fig.7C,E). In the outer layer of CA3 stratum lacunosum moleculare and the outer third of the dentate molecular layer, mGluR7a and mGluR8 immunoreactivity was reduced (Fig. 7E,G). In a sector of CA1 near the CA1–CA2 transition, moderate mGluR2/3 immunoreactivity remained in stratum lacunosum moleculare (Fig.7C, arrow). The mGluR2/3 labeling in this region, however, disappeared in the rats with massive lesions in the bilateral entorhinal cortices (not shown), indicating that mGluR2/3 immunoreactivity in this region originates not only from the ipsilateral but also from the contralateral entorhinal cortex. This observation is consistent with that of the previous tracer study showing the contralateral projection of the perforant path to the CA1 sector (Steward, 1976). Labeling for mGluR7a in the inner molecular layer remained intact (Fig. 7E). In accordance with the reduction of the mGluR7a immunoreactivity in neuropil, the decoration of interneuron dendrites in the molecular layer disappeared in the outer two-thirds of the layer but remained in the inner third of the layer (not shown). Moderate immunoreactivity for mGluR7a also remained in a superficial layer of CA1 stratum lacunosum moleculare in the ipsilateral hippocampus (Fig. 7E), which may suggest additional sources, such as the nucleus reuniens thalami (Wouterlood et al., 1990), for mGluR7a-immunoreactive afferent fibers in this layer. Thus, immunoreactivity for mGluR2/3, mGluR7a, and mGluR8 in the perforant path terminal zone originates mostly from the ipsilateral and partly from the contralateral entorhinal cortex.
Effects of unilateral colchicine injection in the hilus on immunoreactivity for mGluRs in the hippocampus
To examine the contribution of the dentate granule cells to the mGluR immunoreactivity in the hippocampus, we next used colchicine, which is known to preferentially degenerate the dentate granule cells (Goldschmidt and Steward, 1980). At the seventh day after unilateral colchicine injection (3 μg in 0.9 μl of 25 mmPBS, pH 7.3) into the hilus of the dorsal and ventral hippocampus, a massive degeneration of the granule cells and mod-erate atrophy of the whole hippocampus were observed in the dentate gyrus ipsilateral to the injection (Fig. 8A,B). Immunoreactivity for mGluR1 and mGluR5 almost disappeared in the ipsilateral molecular layer, but was affected only slightly in the hilus and CA3 area (Fig. 8C,D,G,H). On the other hand, immunoreactivity for mGluR2/3, mGluR7a (Fig.8I, arrows), and mGluR7b was markedly reduced in the ipsilateral mossy fiber terminal zone, namely, the hilus and CA3 stratum lucidum (Fig. 8E,F,I–L), whereas mGluR2/3 labeling in the molecular layer was reduced only slightly (Fig. 8E,F). Although immunoreactivity for mGluR7a was moderately reduced in the molecular layer (Fig.8I,J), the prominent labeling in the middle third of the layer was preserved. The reduction of mGluR7a immunolabeling was observed in the decoration of the dendritic profiles as well as in neuropil.
Effects of local and intraventricular kainate injections on immunoreactivity for mGluRs in the hippocampus
It has been known that local kainate injection degenerates only postsynaptic elements in the injection site (Coyle and Schwarcz, 1976) and that intraventricular kainate injection selectively degenerates CA3 pyramidal cells in the hippocampus (Nadler et al., 1980). At the seventh day after the local kainate injections into the CA3 area (0.2 μg in 0.2 μl of PBS), pyramidal cells in the restricted regions degenerated with gliosis (Fig.9A). Immunoreactivity for mGluR1 and mGluR5 was markedly reduced in the dendritic fields of the degenerative pyramidal cells (Fig. 9B,D), whereas that for mGluR2/3 and mGluR7a was unaffected (Fig. 9C,E). The local kainate injection directed to CA1 pyramidal cells also reduced mGluR5 immunoreactivity but not mGluR7a immunoreactivity in the dendritic fields of the degenerative pyramidal cells (data not shown). After the bilateral kainate injection (0.6 μg in 1.2 μl of PBS), severe epileptic response was observed for several hours, as reported previously (Nadler et al., 1980). At the seventh day after the injection, massive degeneration of CA3 pyramidal cells and hilar neurons was observed bilaterally, with most of the CA1 pyramidal cells and granule cells being preserved (Fig. 9F). Some interneurons, including those in CA1 stratum oriens/alveus, also disappeared, as clearly shown by the lack of the dense mGluR1-immunoreactive dendritic plexus (Fig. 9G, open arrows; also see Fig. 2A). This might be ascribable to susceptibility of these neurons to excitotoxicity after prolonged stimulation (cf. Ouardouz and Lacaille, 1995). Immunoreactivity for mGluR1 and mGluR5 in the hilus and dendritic fields of CA3 pyramidal cells was also markedly reduced (Fig.9G,I). In CA1 strata oriens and radiatum, which are the dendritic fields receiving Schaffer collaterals from CA3 pyramidal cells, mGluR5 immunoreactivity remained intact (Fig.9I), whereas mGluR7a immunoreactivity was markedly reduced (Fig. 9J). Labeling for mGluR7a was also reduced in CA1 stratum lacunosum moleculare (Fig. 9J, arrows) but not in CA3 stratum lacunosum moleculare and the middle third of the dentate molecular layer (Fig. 9J). The same pattern of reduced immunostaining in the perforant path terminal zone was also apparent for mGluR2/3 immunoreactivity (Fig. 9H, arrows). This effect of the bilateral intraventricular kainate injection is probably attributable to preferential degeneration of the entorhinal layer III neurons (Nadler et al., 1980) projecting to CA1 stratum lacunosum moleculare (Steward and Scoville, 1976). In fact, Nissl staining showed massive degeneration of neurons in layer III but not in layer II of the entorhinal cortex (data not shown). No changes in immunoreactivity for mGluR2/3 and mGluR7a were detected in CA3 stratum lacunosum moleculare and the outer two-thirds of the dentate molecular layer, which receive projection fibers from layer II neurons (Steward and Scoville, 1976). In the inner third of the molecular layer, labeling for mGluR7a appeared to be reduced, probably because of loss of associational/commissural projections from the hilar neurons (Amaral and Witter, 1995). Immunoreactivity for mGluR2/3 and mGluR7a in the mossy fiber terminal zone remained (Fig. 9H,J), despite the massive degeneration of postsynaptic elements in this region.
Localization of immunoreactivity for mGluRs as detected by electron microscopy
As a final step, we performed immunoelectron microscopy in the hippocampus with the antibodies for mGluR2/3, mGluR2, mGluR4a, mGluR7a, mGluR7b, and mGluR8 (Figs.10, 11, 12, 13). The previous study revealed that immunolabeling for mGluR1 and mGluR5 in neuropil of the CA areas is attributable to staining of dendrites and dendritic spines of pyramidal and granule cells (Luján et al., 1996). Immunoreactivity for the group I mGluRs in presynaptic elements, however, was not detected in the hippocampus. In the present study, immunolabeling for all of the group II/III mGluRs was observed in presynaptic elements, with differential patterns of location between the group II and group III mGluRs.
Immunoreactivity for mGluR2/3 was frequently found in small unmyelinated axons, especially in preterminal rather than terminal portions of axons, and most densely in CA1 lacunosum moleculare (Fig.10A,C). Even in axon terminals, peroxidase and immunogold labelings were often found along extrasynaptic membrane and only rarely detected in the presynaptic membrane specialization. Labeling detected with the mGluR2 antibody, which was raised against amino acid residues 87–134, was found in the extracellular space (Fig.10B), supporting the predicted transmembrane model for mGluRs (Masu et al., 1991). This situation sometimes made it difficult to decide which side of the space was the site of the immunoreaction. In many cases, however, the peroxidase reaction end product accumulated along the surface of small unmyelinated axons and terminals in CA1 lacunosum moleculare (Fig.10B). Around terminals, mGluR2 labeling was not detected in the synaptic clefts, confirming the results obtained with the mGluR2/3 antibody. In CA3 stratum lucidum, immunoreactivity for mGluR2/3 was often observed in axon bundles of the mossy fibers (Fig.10D) and occasionally in the giant mossy fiber terminals, but again was not associated with the presynaptic junctional sites. The mGluR2/3 labeling in the axons seemed to be concentrated on certain spots rather than distributed evenly along the axonal membrane. Glial processes were also immunopositive for mGluR2/3 everywhere in the hippocampus (Fig. 10E), probably reflecting a cross-reactivity of the antibody to mGluR3 (Ohishi et al., 1994). Consistently, mGluR3 mRNA expression was also observed in glial cells in the hippocampus (Ohishi et al., 1993b)
Ultrastructural localization of immunoreactivity for the group III mGluRs had quite a different pattern from that for mGluR2/3. Peroxidase reaction end products for mGluR4a, mGluR7a, mGluR7b, and mGluR8 were predominantly present in axon terminals, often attached to the presynaptic sites of asymmetrical and symmetrical synapses in the hippocampus (Figs. 11, 12, 13). Immunogold particles for these mGluRs were concentrated in the presynaptic membrane specialization (Figs. 11B, 12C, and inset to Fig. 13B). Peroxidase reaction products also accumulated less frequently in axonal profiles, and single immunoparticles were found occasionally on axonal membranes.
In the dentate molecular layer, terminals making asymmetrical synapses on spines were immunoreactive for mGluR4a (Fig. 11A), mGluR7a, and mGluR8 (Fig. 13A). Most of the asymmetrical synapses on spines of granule cells are formed by perforant path terminals in the outer molecular layer (Matthews et al., 1976) and by associational/commissural terminals in the inner one-third of the layer (Kishi et al., 1980). Less frequently, symmetrical synapses on dendrites were also labeled for mGluR4a (Fig. 11C), mGluR7a, and mGluR8. The decoration of dendritic profiles observed with light microscopy (Fig. 4) originated from many immunopositive terminals making asymmetrical synapses on dendrites of interneurons (Fig.13B). Virtually all of the terminals making asymmetrical synapses on the particular interneurons were immunopositive for mGluR7a, whereas the proportion of immunopositive terminals was lower for the decoration with mGluR4a and mGluR8. A few terminals with labeled symmetrical synapses were also in contact with the decorated dendrites. Occasionally, axon terminals with labeled asymmetrical synapses on the decorated dendrites made other, unlabeled asymmetrical synapses on spines. The segregation of receptors in single terminals was also apparent between two synapses on dendrites (Figs.11D, 13D). Although the identity of the postsynaptic dendrites receiving labeled and unlabeled synapses remains elusive, they seemed to originate from different interneurons.
In the dendritic fields of the CA areas, large numbers of asymmetrical synapses on spines were immunoreactive for mGluR7a (Fig.12A). The decoration of somatodendritic profiles with many intensely labeled asymmetrical synapses was scattered in the CA areas, as described previously (Bradley et al., 1996; Shigemoto et al., 1996). For mGluR4a and mGluR8, labeled synapses decorated dendrites (Fig. 11B) and cell bodies (Fig. 13C) only occasionally in the CA areas. In CA3 stratum lucidum and hilus, immunoreactivity for mGluR7a and mGluR7b was observed in numerous small axon terminals surrounding dendrites and long spines (Fig.12C) of interneurons with asymmetrical synapses. Labeling was found much less frequently in symmetrical synapses on dendrites (Fig. 12D). On the other hand, cell bodies of the interneurons were surrounded by many mGluR7a/b-labeled symmetrical synapses (Fig. 12B). Occasionally, labeling was found in the giant mossy fiber terminals; however, reaction end products were accumulated only in the presynaptic sites to presumed mGluR1α-positive interneuron dendrites but not in the presynaptic sites to CA3 pyramidal cell spines (Fig. 12E).
DISCUSSION
The present study revealed the differential distribution of presynaptic mGluRs in the major excitatory pathways in the hippocampus (Table 1). Type 2/7a/8, type 2/7a/7b, and type 7a mGluRs are localized in the perforant path, mossy fibers, and Schaffer collaterals, respectively. Electron microscopy further revealed predominant localization of group II and group III mGluRs in the extrasynaptic and synaptic sites, respectively. Finally, each group III receptor in individual synapses of single presynaptic elements was found to be segregated in correlation with postsynaptic target neurons.
Presynaptic mGluRs in the hippocampal pathways
Massive degeneration of postsynaptic elements after lesions may induce morphological changes in presynaptic elements in the same region (Nadler et al., 1981), and vice versa (Matthews et al., 1976). Nonetheless, in the present study, complementary results obtained with lesions of pre- and postsynaptic elements unequivocally indicated the major origins of mGluR immunoreactivity in the hippocampus. For example, the kainate injection into CA1 depleted mGluR5 immunoreactivity in the dendritic fields of the degenerated pyramidal cells but had no effect on mGluR7a immunoreactivity. Conversely, extensive lesions made in the entorhinal cortex or CA3 reduced mGluR7a immunoreactivity in CA1 terminal zones that receive fibers from the degenerated regions, but exerted no effects on mGluR5 immunoreactivity. These results clearly indicate that immunoreactivity for mGluR5 and mGluR7a in CA1 originates primarily from pyramidal cell dendrites and perforant path/Schaffer collateral axons, respectively.
In the perforant path terminating in the CA3 area and the dentate gyrus, we found complementary localization of mGluR2 and mGluR8 being enriched in the medial and lateral perforant path, respectively. Consistent with this finding, expression of mGluR2 and mGluR8 mRNAs was prominent in layer II of the medial and lateral entorhinal cortex, respectively (Ohishi et al., 1993a; A. Kinoshita, unpublished observation). DCG-IV potently reduced field excitatory postsynaptic potentials in the medial but not in the lateral perforant path, whereas micromolar concentrations of L-AP4 reduced those in the lateral but not in the medial perforant path (Macek et al., 1996). These electrophysiological data are compatible with the complementary localization of mGluR2 and mGluR8 in the dentate molecular layer. Enrichment of mGluR7a in the medial perforant path also agrees with the inhibitory effect of millimolar concentrations of L-AP4 in this path (Koerner and Cotman, 1981; Macek et al., 1996) because mGluR7a has an exceptionally high EC50 value (1 mm) for glutamate (Okamoto et al., 1994). Although mRNA for mGluR4 is strongly expressed in layers II and III of the entorhinal cortex (Saugstad et al., 1994; Ohishi et al., 1995a), mGluR4a immunoreactivity was not clearly detected in the perforant path terminal zones in the present study. This may be attributable to the preferential expression of another splice variant mGluR4b (Thomsen et al., 1997) in this pathway; however, mGluR4 may not be involved in the synaptic depressant effects in the lateral perforant path, because different pharmacology was found between cloned mGluR4a and L-AP4-sensitive receptors mediating such effects (Johansen et al., 1995). In fact, no changes were observed in the L-AP4 effects on this pathway in mGluR4-deficient mice (Baskys et al., 1996).
Labeling for mGluR4a was found in asymmetrical synapses on spines and dendrites and in symmetrical synapses on dendrites in the inner one-third of the molecular layer, which receives projections from neurons in the hilus (Amaral and Witter, 1995), septal cholinergic neurons (Frotscher and Leranth, 1985), and supramammillary neurons (Maglóczky et al., 1994). The mossy cells in the hilus and supramammillary neurons make asymmetrical synapses with granule cells (Maglóczky et al., 1994; Buckmaster et al., 1996), but mGluR4 mRNA is strongly expressed only in the hilus (Ohishi et al., 1995a), supporting the mossy cells as the origin of the mGluR4a-labeled axon terminals. Axon terminals making both mGluR4a-labeled symmetrical synapses and unlabeled asymmetrical synapses may originate from septal cholinergic neurons, because they form both types of synapses in the dentate gyrus (Frotscher and Leranth, 1985).
In the mossy fiber synapses on CA3 pyramidal cells, DCG-IV but not L-AP4 suppressed excitatory transmission in the rat (Lanthorn et al., 1984; Yokoi et al., 1996). This effect was reduced to ∼50% of the control level in mice lacking mGluR2 (Yokoi et al., 1996), indicating the involvement of mGluR2 as well as other DCG-IV-sensitive receptors. In the present study, mGluR7a and mGluR7b were found in the mossy fiber but not in synapses on CA3 pyramidal cells. They are present almost exclusively in synapses on mGluR1α-positive interneurons, which correspond to somatostatin/GABA-immunoreactive interneurons (Baude et al., 1993). These interneurons are heavily innervated by mossy fiber collaterals (Leranth et al., 1990), and virtually all asymmetrical synapses made on the interneurons had high densities of mGluR7a/b, showing up as almost continuous profiles of dendrites in light microscopy (Fig. 6). Cell bodies also showed up with many symmetrical synapses labeled for mGluR7a/b. The somatostatin-immunoreactive interneurons constitute symmetrical synapses on their cell bodies and dendrites with septal cholinergic (Leranth and Frotscher, 1987) and GABAergic (Milner and Bacon, 1989) axon terminals, and mGluR7 mRNA is strongly expressed in the medial septal and hilar neurons (Ohishi et al., 1995a). Smaller numbers of symmetrical synapses on interneurons were also labeled for mGluR4a and mGluR8 in the present study. Although depression of inhibitory synaptic transmission is mediated by group II mGluRs in the hippocampal pyramidal cells (Poncer et al., 1995), no such effects mediated by group III mGluRs have been reported so far.
Several lines of evidence have suggested that group I and III mGluRs are involved in presynaptic inhibition of excitatory transmission from Schaffer collaterals to CA1 pyramidal cells in the adult rat (Gereau and Conn, 1995a; Manzoni and Bockaert, 1995). In the Schaffer collateral terminal zones in CA1, mGluR5 and mGluR7a immunoreactivity was strongly detected in the present study. Although the presynaptic location of mGluR7a is consistent with the reported effects of millimolar concentrations of L-AP4, we found no evidence for the presence of presynaptic mGluR5 (also see Luján et al., 1996). It should be noted, however, that the inhibitory effect of DHPG depends on NMDA receptor activation in these synapses (Harvey et al., 1996). This finding raises the possibility of a synergistical mechanism involving postsynaptic mGluR5 and NMDA receptors to depress presynaptic glutamate release through another messenger, such as adenosine (Manzoni et al., 1994; Di Iorio et al., 1996) or nitric oxide (Boulton et al., 1994).
Extrasynaptic versus synaptic localization of group II and group III mGluRs
One of the most striking observations in the present study is the segregation of group II and group III mGluRs in presynaptic elements. The difference in mGluR localization in relation to glutamate release sites suggests that effector mechanisms as well as the sources of glutamate activating these receptors may be distinct from each other. It is conceivable that the group III mGluRs in the presynaptic active zone act as autoreceptors activated with glutamate released from the very synapse to which the receptors are localized. Patch-clamp recordings from the presynaptic terminals directly indicated that L-AP4-sensitive mGluRs are coupled to P/Q-type voltage-sensitive calcium channels to suppress excitatory postsynaptic currents in the trapezoid body nucleus (Takahashi et al., 1996). In the present study, the group III mGluRs were found also in symmetrical synapses, which have much lower glutamate concentrations than asymmetrical synapses in the hippocampus (Bramham et al., 1990). For such nonglutamatergic synapses, a major question would be the source of glutamate that activates the presynaptic mGluRs. GABA release may be inhibited by glutamate spilled over from nearby synapses (Hayashi et al., 1993;Ohishi et al., 1994) or released from dendrosomatic regions (Glitsch et al., 1996). The functional significance of presynaptic mGluR7a/b in nonglutamatergic synapses is unclear, however, because it is unlikely that receptors with such a low affinity to glutamate are activated by diluted signals from remote synapses.
In contrast to group III mGluRs enriched at synaptic sites, mGluR2 is mainly localized apart from synaptic sites. Localization of mGluR3 in neuronal cells is inconclusive in the present study; only a small portion of mGluR2/3 immunoreactivity is ascribable to mGluR3 because of weak cross-reactivity of this antibody to mGluR3 (Hayashi et al., 1993). Extrasynaptic mGluR2 may be activated not only with glutamate released from homologous presynaptic elements but also with glutamate from heterologous presynaptic elements that make asymmetrical synapses near the mGluR2-bearing axons. Recent studies showed that glutamate accumulated by repeated stimulations with short intervals, but not by single stimulations, activates presynaptic group II mGluRs in mossy fibers to induce long-term depression (Yokoi et al., 1996) and to suppress excitatory transmission (Scanziani et al., 1997). Although these studies are suggestive of the autoreceptor function for mGluR2, it is also possible that mGluR2 is activated by prolonged glutamate release from nearby synapses to cause heterosynaptic interaction. For the effectors of group II mGluRs, N- and L-type calcium channels were reported in cultured hippocampal neurons (Sahara and Westbrook, 1993) and in heterologous expression systems (Ikeda et al., 1995). Each type of neuron, however, expresses a distinct set of calcium channel subtypes in certain subcellular compartments (Sakurai et al., 1996), and it is not clear whether mGluR2 is coupled to these channels in the preterminal axons. An alternative possible effector mechanism for the axonal mGluR is reducing efficacy of axonal signal transmission by facilitating potassium channels. In the perforant path, which was most strongly labeled for mGluR2 in the present study, voltage-dependent potassium channel subunits Kv1.2/1.4 (Sheng et al., 1993) and G-protein-coupled inwardly rectifying potassium channels (Ponce et al., 1996) are abundant, and the latter is efficiently coupled to mGluR2 in a Xenopus oocyte expression system (Saugstad et al., 1996). High-resolution colocalization of mGluR2 and these channel/effector molecules in axons would help to clarify the physiological implication of this receptor.
Target-specific segregation of group III mGluRs in single axons
A target cell-specific concentration of receptor proteins in the presynaptic active zone was first reported for mGluR7a in the hippocampus (Shigemoto et al., 1996). This type of receptor segregation seems to be a general feature of the group III mGluRs. In the present study, mGluR7b was concentrated, even more exclusively than mGluR7a, in synapses making contacts with presumed mGluR1α-positive interneurons in the mossy fiber terminal zone. Synapses on CA3 pyramidal cells made by the same mossy fiber had very little labeling for mGluR7b. Not only glutamatergic synapses but also nonglutamatergic synapses on cell bodies of the mGluR1α-positive interneurons were labeled for mGluR7a/b. Although it is not known whether nonglutamatergic neurons also locate these receptors according to distinct targets along single axons, this finding is suggestive of some postsynaptic influence common to axon terminals of different types. A similar segregation according to postsynaptic targets was found for mGluR4a and mGluR8, but not all of the synapses on the interneurons were labeled. This may be attributable to the lack of expression of these mGluRs in some neurons providing afferents to those interneurons, or to unknown local third factor(s) governing the selective distribution of these mGluRs in individual synapses. In any case, such a segregation should be regulated in a spatially restricted way, probably through nondiffusable membrane-bound molecules. Different regulation of transmitter release mediated by L-AP4-sensitive mGluRs may result in differential transmission of time-coded signals to principal neurons and to interneurons (Shigemoto et al., 1996). In mGluR4- and mGluR7-deficient mice, smaller EPSCs than in wild-type mice were detected in the second or third response to high-frequency stimulation (Bushell et al., 1996b;Pekhletski et al., 1996). This implies that synapses equipped with these mGluRs transmit high-frequency signals with higher efficiencies than do synapses without them. It is interesting to note that all cells decorated with synapses heavily labeled for group III mGluRs seem to be interneurons. This situation may allow effective feedback for high-frequency signals through interneuron subtypes that have selective targets (Buhl et al., 1994). Thus, the physiological significance of the differential synaptic regulation should be understood in light of identified neuronal connections in the complex circuitry.
Footnotes
This work was supported by research grants from the Inamori Foundation and the Ministry of Education, Science, Sports and Culture of Japan. We thank Peter Somogyi for helpful discussion, David Roberts for technical assistance, and Akira Uesugi for photographic assistance. We are grateful to Atsu Aiba, David Hampson, John Roder, and Herman van der Putten for providing us with mGluR1-, mGluR4-, mGluR5-, and mGluR7-deficient mice, respectively, and to Corrado Corti and Francesco Ferraguti for sharing rat mGluR8 cDNA and unpublished results.
Correspondence should be addressed to Dr. Ryuichi Shigemoto, Department of Morphological Brain Science, Faculty of Medicine, Kyoto University, Yoshida, Sakyo-ku, Kyoto 606, Japan.