Abstract
Molecular cloning has recently identified a vertebrate brain-specific Na+-dependent inorganic phosphate transporter (BNPI). BNPI has strong sequence similarity to EAT-4, aCaenorhabditis elegans protein implicated in glutamatergic transmission. To characterize the physiological role of BNPI, we have generated an antibody to the protein. Immunocytochemistry of rat brain sections shows a light microscopic pattern that is suggestive of reactivity in nerve terminals. Excitatory projections are labeled prominently, and ultrastructural analysis confirms that BNPI localizes almost exclusively to terminals forming asymmetric excitatory-type synapses. Although BNPI depends on a Na+ gradient and presumably functions at the plasma membrane, both electron microscopy and biochemical fractionation show that BNPI associates preferentially with the membranes of small synaptic vesicles. The results provide anatomic evidence of a specific presynaptic role for BNPI in glutamatergic neurotransmission, consistent with the phenotype of eat-4 mutants. Because an enzyme known as the phosphate-activated glutaminase produces glutamate for release as a neurotransmitter, BNPI may augment excitatory transmission by increasing cytoplasmic phosphate concentrations within the nerve terminal and hence increasing glutamate synthesis. Expression of BNPI on synaptic vesicles suggests a mechanism for neural activity to regulate the function of BNPI.
- inorganic phosphate transport
- BNPI
- synaptic vesicle
- asymmetric synapse
- excitatory neurotransmission
- glutamate release
Neurons exhibit multiple transport activities that contribute to synaptic transmission. Reuptake across the plasma membrane terminates the action of classical neurotransmitters in the synaptic cleft, and transport into synaptic vesicles packages the transmitter for subsequent release by exocytosis. Neurons also actively transport a number of compounds and ions not generally considered to participate directly in signaling. These ions include inorganic phosphate (Pi), which has been found to accumulate in both squid and frog neurons (Mullins, 1954;Caldwell and Lowe, 1970). More recent studies show that cortical neurons, cerebellar granule cells, and synaptosomes prepared from the rat also demonstrate Pi transport, and this activity depends on a Na+ gradient (Ni et al., 1994; Glinn et al., 1995; Furman et al., 1997). Although Pi transport has been observed in these systems, the biological role of Piuptake by neurons remains unknown.
In the kidney, Na+-dependent Pitransport is essential for the maintenance of phosphate homeostasis (for review, see Murer and Biber, 1996). Renal brush-border epithelial cells of the proximal tubule exhibit Na+-dependent reabsorption of Pi that is controlled by both hormonal and nonhormonal mechanisms. The proteins that mediate renal Pitransport activity belong to a family of Na+/Pi cotransporters that includes liver as well as kidney isoforms (Werner et al., 1991; Li and Xie, 1995). Interestingly, a sequence induced by subtoxic levels of NMDA in cerebellar granule cells also belongs to this family of transport proteins (Ni et al., 1994). Analysis of the mRNA shows that the expression of this sequence is restricted to the brain and, in particular, to neurons (Ni et al., 1994). Injection of mRNA for this brain-specific Na+-dependent Pitransporter (BNPI) into Xenopus oocytes confirms that BNPI transports Pi in a Na+-dependent manner (Ni et al., 1994). BNPI therefore may contribute to the Na+-dependent Pi transport activity observed in cultured primary cortical neurons, cerebellar granule cells, and synaptosomes prepared from rat brain (Glinn et al., 1995;Furman et al., 1997).
Although Na+-dependent Pi uptake may act simply to replenish ATP stores, a function that presumably would be required for all neuronal populations, in situ hybridization indicates that the expression of BNPI mRNA is restricted to a subset of neurons, including cortical cells, hippocampal pyramidal cells, granule cells of the dentate gyrus, and cerebellar granule cells (Ni et al., 1995), neurons that all use glutamate as a neurotransmitter. This restricted pattern of BNPI mRNA expression supports a function for BNPI specific to glutamatergic neurons. Moreover, BNPI shows strong sequence similarity to EAT-4, a Caenorhabditis elegans protein that appears to have a specific presynaptic role in glutamatergic transmission (Avery, 1993; Dent et al., 1997; Li et al., 1997; R. Y. N. Lee, E. R. Sawin, M. Chalfie, H. R. Horvitz, and L. Avery, unpublished observations).
To assess the physiological role of BNPI, we have generated a polyclonal antibody to the protein and used it to determine the location of the transporter in the rat brain. At the light microscopic level, immunocytochemistry shows that BNPI localizes to nerve terminals that release glutamate as a neurotransmitter. Consistent with a role for BNPI in excitatory transmission, electron microscopic immunolabeling shows that BNPI localizes predominantly to axon terminals at asymmetric synapses. The results thus provide anatomical evidence of a specific presynaptic role for BNPI in glutamatergic transmission, as suggested by the phenotype of eat-4mutants. Further, although the Na+ dependence of BNPI suggests that BNPI functions at the plasma membrane, electron microscopic immunolabeling indicates that the majority of BNPI resides on synaptic vesicles. Biochemical analysis by differential centrifugation and velocity gradient fractionation confirms this localization, raising the possibility that exocytosis induced by neural activity may regulate BNPI function at the plasma membrane.
MATERIALS AND METHODS
BNPI-pGEX-3X plasmid construction and expression. The pGEX bacterial expression system (Pharmacia Biotech, Alameda, CA) was used to produce a glutathione S-transferase (GST) fusion protein containing the last 68 amino acids (residues 493–560) of rat BNPI (Ni et al., 1994). First, the 3′ end of the protein coding region (nucleotides 1600–1806) was amplified from BNPI cDNA, using PCR and primers (5′-CGCGGATCCTGGAGAAACAGCCGTGGGCAGAG and 5′-CGGAATTCTCAGTAGTCCCGGACAGGGGGTGG) engineered to contain BamHI and EcoRI sites that facilitate subcloning into pGEX-3X. To produce the fusion protein, we inducedEscherichia coli expressing the recombinant plasmid with isopropyl β-d-thiogalactoside (IPTG) for ∼4 hr at room temperature (RT) and then sonicated it. The fusion protein was purified by chromatography over glutathione Sepharose (Pharmacia Biotech).
Polyclonal antibody production. Two female New Zealand white rabbits were immunized with the GST-BNPI fusion protein. First, the animals were inoculated intradermally with ∼200 μg of fusion protein emulsified in Freund’s complete adjuvant, and then they were boosted 4 weeks later by a subcutaneous injection of ∼100 μg of fusion protein emulsified in Freund’s incomplete adjuvant. Blood was obtained 9 and 14 d after the boost. The serum was adsorbed with rat liver acetone powder (LAP; Cappel, Organon Teknika, West Chester, PA) to reduce nonspecific immunoreactivity.
Cell transfection and membrane preparation. Rat BNPI cDNA in pcDNA I/Amp (Invitrogen, San Diego, CA) was transfected into COS1 cells by electroporation (Finn and Edwards, 1997). Briefly, COS1 cells grown in DMEM containing 10% Cosmic calf serum (HyClone Laboratories, Logan, UT) were harvested and then electroporated at 0.4 kV and 960 μF with 15 μg of DNA. At 3 d after electroporation the transfected COS cells were harvested, resuspended in 200 μl of buffer A [(in mm) 150 NaCl, 50 Tris-HCl, 5 EGTA, and 10 EDTA, pH 7.4 on ice] containing protease inhibitors [(in μg/ml) 1 E64, 2 leupeptin, 2 pepstatin, 20 PMSF], and disrupted in a water bath sonicator. Cell debris was removed by sedimentation at 1300 ×g for 5 min at 4°C.
Western analysis. Equal amounts of protein were loaded into each lane, except in the case of velocity sedimentation through glycerol, in which case equal volumes from each fraction were loaded. In all cases the proteins were separated by electrophoresis via 10% SDS-polyacrylamide and transferred to nitrocellulose. The nitrocellulose membranes were blocked in PBS containing 0.1% Tween-20 and 5% nonfat dry milk and then incubated with the relevant primary antibody in PBS containing 0.1% Tween-20 and 1% nonfat dry milk (PBS-TM) for 2 hr at RT or overnight at 4°C. BNPI was detected with a 1:2000 dilution of the C-terminal polyclonal antibody preadsorbed with LAP. Synaptophysin was detected with a monoclonal antibody (clone SVP-38; Sigma, St. Louis, MO) at a dilution of 1:5000, syntaxin with a monoclonal antibody (clone HPC-1; Sigma) at 1:2000, and the Na+/K+ ATPase α1subunit with a polyclonal antibody (Upstate Biotechnology, Lake Placid, NY) at 1:1000. After incubation with primary antibody the blots were washed three times in PBS-TM, incubated for 45 min in PBS-TM containing a 1:2000 dilution of the appropriate secondary antibody conjugated to horseradish peroxidase (Amersham, Arlington Heights, IL), and washed in PBS containing 0.1% Tween-20. The deposits were detected by enhanced chemiluminescence (Pierce, Rockford, IL).
Preparation of brain extracts. The brains of adult male Sprague Dawley rats were removed after decapitation and homogenized for 10 strokes at ∼750 rpm in cold buffer B [(in mm) 50 Tris-HCl, pH 7.4, 5 EGTA, and 10 EDTA] containing protease inhibitors [(in μg/ml) 2 aprotinin, 1 E64, 2 leupeptin, 2 pepstatin, and 20 PMSF] by using a Wheaton glass/Teflon homogenizer (clearance 0.1–0.15 mm; Fisher Scientific, Santa Clara, CA). Cell debris was removed from this homogenate by centrifugation at 1075 ×gmax in a Sorvall SS34 rotor (DuPont, Newtown, CT) for 20 min at 4°C and was resuspended in buffer B with protease inhibitors to yield the pellet P1. The postnuclear supernatant (PNS) was sedimented at 152,000 × gmax in an SW41 rotor (Beckman, Palo Alto, CA) for 1 hr at 4°C. After the addition of protease inhibitors the resulting high-speed supernatant (HSS1) was centrifuged again under the same conditions to ensure the removal of all membranes from the supernatant. The resulting second high-speed supernatant (HSS2) also was supplemented with protease inhibitors. The high-speed pellets from both centrifugations were resuspended in buffer B with protease inhibitors and pooled to yield a high-speed pellet fraction (HSP).
Preparation of kidney extracts. The kidneys were removed from an adult male Sprague Dawley rat, frozen on liquid nitrogen, and crushed to a fine powder on dry ice. After its addition to 0.32m sucrose and 10 mm HEPES, pH 7.4 [containing 5 mm Mg-EGTA, 0.4 μmdiisopropylfluorophosphate (DFP), and (in μg/ml) 2 aprotinin, 2 E64, 5 leupeptin, and 2 pepstatin], the mixture was homogenized at ∼750 rpm for 12 strokes in a Wheaton glass/Teflon homogenizer (clearance 0.1–0.15 mm; Fisher Scientific), and the cell debris was removed by centrifugation at 1600 × g for 10 min at 4°C.
Synaptosome preparation. Synaptosomes were prepared by standard methods (Huttner et al., 1983) with minor modifications. Briefly, the cerebral cortices of male Sprague Dawley rats were homogenized in cold buffer C (0.32 m sucrose, 4 mm HEPES-NaOH, pH 7.4, and 1 mm EGTA) containing protease inhibitors [(in μg/ml) 2 aprotinin, 1 E64, 2 leupeptin, 2 pepstatin, and 20 PMSF] by 10 strokes at 900 rpm in a Kontes number 22 glass/Teflon homogenizer (clearance 0.13–0.18 mm; Fisher Scientific) at 4°C. The homogenate was centrifuged in an SS34 rotor (DuPont) for 10 min at 1000 × gmaxto yield a pellet (P1) and a supernatant (S1). P1 was resuspended in buffer C with protease inhibitors and EGTA. Then S1 was centrifuged at 12,000 × gmax in an SS34 rotor for 15 min. The resulting supernatant (S2) was removed. The pellet (P2) was washed by being resuspended in buffer C containing protease inhibitors and then was centrifuged at 14,500 × gmax for 15 min to yield a supernatant (S2′) and pellet (P2′). P2′, the crude synaptosomal fraction, was resuspended in buffer C containing protease inhibitors, transferred to a Kontes number 22 glass/Teflon homogenizer (clearance 0.13–0.18 mm), mixed by inversion with 9 vol of cold water containing 1 mm EGTA and protease inhibitors, and immediately disrupted by three strokes of homogenization at 3000 rpm. HEPES-NaOH, pH 7.4, was added to a final concentration of 8.5 mm, and the mixture was centrifuged at 33,000 ×gmax in an SS34 rotor for 20 min to yield a lysate pellet (LP1) and lysate supernatant (LS1). LP1 was resuspended in a 1:10 dilution of buffer C containing protease inhibitors and HEPES-NaOH, pH 7.4 (final concentration 8.5 mm). Protease inhibitors then were added to LS1, and this fraction was centrifuged at 251,500 × gmax in a 70.1 Ti rotor (Beckman) for 2 hr to yield a supernatant (LS2) and pellet (LP2). LP2 was resuspended in 40 mm sucrose containing 1 mm EGTA and protease inhibitors.
Glycerol velocity sedimentation. Velocity sedimentation through glycerol was performed by the procedure of Clift-O’Grady et al. (1990) with minor modifications. Glycerol gradients (5–25%) were prepared in (in mm) 10 HEPES-NaOH, pH 7.4, 150 NaCl, 1 EGTA, and 0.1 MgCl2 with protease inhibitors [(in μg/ml) 2 aprotinin, 1 E64, 2 leupeptin, 2 pepstatin, and 20 PMSF] over a pad of 2 m sucrose. LS1 samples (∼130 μg), containing intraterminal components such as synaptic vesicles (Huttner et al., 1983), were layered onto the glycerol gradients and centrifuged at 195,600 × gmax in an SW 50.1 rotor (Beckman) for 1 hr at 5°C. Fractions were collected from the top of the gradient.
Immunohistochemistry. Adult male Sprague Dawley rats were anesthetized and perfused with PBS, followed by 4% paraformaldehyde in PBS. The brains were dissected, immersed in the same fixative overnight at 4°C, cryoprotected in 30% sucrose at 4°C, and sectioned at 40 μm on a freezing microtome. Floating brain sections were incubated in PBS containing 1% normal goat serum (NGS) and 0.3% Triton X-100 (wash buffer) for 30 min, rinsed, incubated in PBS containing 0.3% H2O2 for 30 min, rinsed, blocked for 1.5 hr in PBS containing 3% NGS and 0.3% Triton X-100, and incubated overnight at 4°C in wash buffer containing a 1:2000 dilution of primary BNPI antibody preadsorbed with LAP. To confirm the specificity of the reaction, we included 10 μg of either GST-BNPI or the control fusion protein GST-VGAT (Chaudhry et al., 1998) in the preadsorption of the BNPI antiserum with LAP. The sections were washed, incubated for 30 min at RT with biotinylated goat anti-rabbit secondary antibody (Vector, Burlingame, CA) diluted 1:200, washed again, and incubated in a 1:400 dilution of avidin–biotin complex conjugated to horseradish peroxidase (Vector) for 30 min. After being washed, the peroxidase reaction was visualized with 3,3′-diaminobenzidine and H2O2and 0.27% NiSO4 to enhance the reaction. Sections were dehydrated in graded ethanols and xylene and then coverslipped with Permount (Fisher Scientific).
Electron microscopy. The methods for tissue preparation and immunocytochemical labeling were based on those of Leranth and Pickel (1989). Adult male Sprague Dawley rats were anesthetized with sodium pentobarbital (50 mg/kg, i.p.) and perfused in rapid succession with (1) 10 ml of phosphate buffer (PB), pH 7.4, containing 1000 U/ml heparin and 0.15 m NaCl; (2) 50 ml of 3.75% acrolein and 2% paraformaldehyde in PB; and (3) 200 ml of 2% paraformaldehyde in PB. The brains were removed and post-fixed in 2% paraformaldehyde for 30 min and then sectioned at 40 μm coronal sections with a Lancer Vibratome. Sections of tissue through forebrain regions were incubated for 30 min in PB containing 1% sodium borohydride. Then all sections were cryoprotected for 15 min in 0.05 m PB containing 25% sucrose and 3.5% glycerol, rapidly frozen in chlorodifluoromethane followed by liquid nitrogen, and thawed in PB at RT. The free-floating tissue sections were incubated overnight at RT in 0.1% bovine serum albumin (BSA)–Tris saline (TS; 0.9% NaCl in 0.1 m Tris, pH 7.6) with BNPI C-terminal antiserum diluted 1:6000 for peroxidase and 1:3000 for immunogold labeling, respectively. In tissue that was prepared for peroxidase labeling, the sections were incubated for 30 min in biotinylated goat anti-rabbit immunoglobulin diluted 1:400 in 0.1% BSA, for 30 min in avidin–biotin peroxidase complex diluted 1:100, and then for 6 min in a solution containing 22 mg of 3,3′-diaminobenzidine and 10 μl of 30% H2O2in 100 ml of 0.1 m TS, pH 7.6. The sections used for silver-enhanced immunogold labeling (Chan et al., 1990) were incubated for 2 hr in a 1:50 dilution of colloidal gold (1 nm) conjugated to anti-rabbit IgG (Amersham), fixed in PBS containing 2% glutaraldehyde for 10 min, and reacted with a silver solution by using a light stable intenSEM kit (Amersham) for 5–8 min. The immunolabeled tissue sections were fixed in 2% osmium tetroxide for 60 min, dehydrated in a series of graded ethanols and propylene oxide, and flat-embedded in Embed 812 between two pieces of Aclar plastic.
Ultrathin sections were collected from the outer surface of the plastic-embedded tissue with an LKB ultramicrotome. These were taken from three regions: the stratum lucidum of CA3, the polymorphic or hilar layer of the dentate gyrus in the dorsal hippocampus, and the dorsolateral caudate nucleus at the level of the crossing of the anterior commissure (Paxinos and Watson, 1986). The sections were counterstained with uranyl acetate and lead citrate and then examined with a Philips electron microscope (Mahwah, NJ).
Primary hippocampal cultures. Hippocampi from E19 Sprague Dawley rats were dissociated by trypsinization, and the cells were plated on poly-d-lysine-coated coverslips (12 mm in diameter) at a density of ∼300/mm2 in B27/Neurobasal medium (Brewer et al., 1993). After 14 d in vitro the coverslips were dipped in PBS with Ca2+ and Mg2+, fixed in 4% paraformaldehyde, washed in PBS, blocked in PBS containing 2% BSA, 1% fish skin gelatin, and 0.02% saponin (blocking buffer) for 1.5 hr at RT, and incubated at RT for 1.5 hr or 4°C overnight in primary antibody diluted in blocking buffer. The primary antibodies included a monoclonal antibody to synaptophysin (clone SVP-38; Sigma) at a dilution of 1:100, as well as the C-terminal BNPI polyclonal antiserum at 1:2000, preadsorbed with LAP as described above. Then the coverslips were washed with blocking buffer and incubated for 1 hr at RT in goat anti-mouse or goat anti-rabbit secondary antibodies conjugated to fluorescein-5-isothiocyanate (FITC) or tetramethyl rhodamine isothiocyanate fluorophores (ICN Biomedicals, Costa Mesa, CA) diluted 1:100 in blocking buffer. After three washes in blocking buffer (10 min each) followed by two brief washes in PBS, the coverslips were mounted with a ProLong Antifade kit (Molecular Probes, Eugene, OR) and viewed by epifluorescence under oil at 63× magnification.
RESULTS
To determine the distribution of BNPI, we raised an antibody to a bacterial fusion protein containing the C terminus of the transporter. The antiserum recognizes a broad ∼60 kDa band in COS cells transfected with rat BNPI cDNA, but not in control cells (Fig.1A), consistent with the 560 residue protein predicted by the cDNA (Ni et al., 1994). In addition, the antibody recognizes a single broad ∼60 kDa band in subcellular fractions of rat brain (Fig. 1B); confirming the specificity of the antibody, preadsorption with the GST fusion protein used as immunogen prevents the detection of this ∼60 kDa species (Fig. 1C). An ∼85 kDa immunoreactive species also occurs in both BNPI-transfected and control COS cells, but this background band does not occur in rat brain. COS cells transfected with the BNPI cDNA contain additional ∼175, 52, and 50 kDa immunoreactive species that do not appear in control cells or in the brain, suggesting that these bands may result only from expression in a heterologous system. Consistent with the brain-specific expression of BNPI, rat kidney does not express the ∼60 kDa immunoreactive species (Fig.1B). As anticipated for an integral membrane protein, the ∼60 kDa immunoreactive species in brain sediments with membranes in a high-speed pellet (HSP) rather than with soluble proteins in the high-speed supernatants (HSS1 and HSS2; Fig. 1B). Furthermore, the inability to pellet a large proportion of BNPI in the initial low-speed centrifugation (P1) indicates that most of the transporter in the brain does not associate tightly with the cytoskeleton.
Glutamatergic projections express BNPI
With the use of light microscopy, immunocytochemistry shows the expression of BNPI protein in gray matter, including cortex and basal ganglia (Fig. 2A,B). White matter such as the corpus callosum shows no detectable labeling for BNPI, consistent with the exclusive expression of BNPI mRNA by neurons. The cortex does not show a laminar pattern of labeling, and both cortex and caudate putamen lack immunoreactive cell bodies. Within the neuropil of the cortex and caudate putamen nucleus, BNPI exhibits a punctate pattern of immunoreactivity suggestive of neuronal processes (Fig. 2C,D). Preadsorption of the antibody with the GST fusion protein used as immunogen completely abolishes the immunoreactivity in brain sections, confirming the specificity of the antibody (Fig. 2E).
Sections through the hippocampus show a distinctive laminar pattern of immunoreactivity (Fig. 3A,B). Dense immunoreactivity occurs in the polymorphic and molecular layers of both the dentate gyrus and the hippocampus proper. Examination of the CA3 region under higher magnification reveals coarse granular labeling at the periphery of the pyramidal cell layer (Fig.3D) strongly suggestive of mossy fiber synapses (Haug et al., 1971; Amaral and Dent, 1981). Stratum oriens of CA3 exhibits weaker but still intense immunoreactivity that occurs in nerve terminal-like puncta, and stratum radiatum of CA3 shows even less intense BNPI immunoreactivity (Fig. 3B,D). The results thus indicate the heterogeneity of BNPI expression at different excitatory connections. In CA1, strata oriens and radiatum also show diffuse granular labeling suggestive of BNPI localization to the terminals of Schaffer collaterals (Fig. 3E), and this labeling substantially exceeds the labeling observed in stratum lacunosum moleculare (Fig. 3B), further supporting the heterogeneity of BNPI expression. In the dentate gyrus the outer two-thirds of the molecular layer label more strongly for BNPI than does the inner one-third (Fig. 3B), indicating preferential localization to the perforant path inputs from the entorhinal cortex relative to inputs from the ipsilateral associational/commissural projection (Matthews et al., 1976; Johnston and Amaral, 1998). Similar to cell bodies in the cortex and striatum, cell bodies in the hippocampus, including hippocampal pyramidal cells, dentate gyrus granule cells, and hilar interneurons, show no detectable BNPI immunoreactivity (Fig.3B,D,E). Considered as a whole, the distribution of BNPI immunoreactivity in the hippocampus strongly resembles that for glutamate, suggesting the preferential expression of BNPI at excitatory synapses (Storm-Mathisen et al., 1983).
Sections through the midbrain and rostral pons show immunoreactivity for BNPI in gray matter such as the periaqueductal gray and pontine nuclei (Fig. 4A). White matter such as the corticospinal tracts (in the cerebral peduncle), the decussation of the superior cerebellar peduncle, the lateral lemnisci, and the lateral tegmental tracts shows no labeling. Similar to other brain regions, BNPI is not detectable in cell bodies of the substantia nigra and tectum (Fig. 4B,D). Rather, BNPI immunoreactivity is distributed uniformly in terminal-like puncta throughout both regions.
In the cerebellum, BNPI immunoreactivity has a laminar distribution (Fig. 5A,B). The molecular layer shows dense punctate labeling suggestive of localization to climbing or parallel fibers that synapse onto Purkinje cell dendrites (Fig. 5D). Within the granule cell layer, BNPI immunoreactivity appears much less dense but has a punctate appearance similar to that observed in the molecular layer. These large punctate structures strongly resemble the rosettes formed by excitatory mossy fiber terminals on granule cells (Palay and Chan-Palay, 1974;Llinás and Walton, 1998). The pattern of labeling does not resemble that observed for inhibitory connections made by GABAergic cells (Esclapez et al., 1994; Chaudhry et al., 1998), further supporting the specific localization of BNPI to excitatory terminals. As in other brain regions, cell bodies in the cerebellum, including granule and Golgi cells of the granule layer, basket and stellate cells of the molecular layer, and Purkinje cells, show no immunoreactivity for BNPI (Fig. 5D).
BNPI localizes to nerve terminals in hippocampal cultures
To determine whether BNPI localizes to nerve terminals, we immunolabeled 2-week-old primary hippocampal cultures with antibodies to both BNPI and the synaptic vesicle marker synaptophysin (Jahn et al., 1985). Similar to synaptophysin (Fig.6A,C), BNPI distributes in a punctate pattern along neuronal processes within the cultures (Fig. 6B,D). Double labeling confirms that BNPI colocalizes with synaptophysin (Fig. 6). However, many varicosities that contain synaptophysin lack detectable BNPI, indicating that BNPI localizes only to a subset of nerve terminals. Some neuronal cell bodies also stain weakly for BNPI, and all of these cell bodies stain for the phosphate-activated glutaminase, PAG (data not shown), a protein highly expressed in many glutamatergic neurons (Najlerahim et al., 1990; Aoki et al., 1991; Kaneko and Mizuno, 1994; Torgner et al., 1998).
Localization of BNPI to synaptic vesicles at excitatory synapses
To determine the subcellular localization of BNPI, we used electron microscopic immunolabeling. As a confirmation of the light microscopic analysis of the hippocampus, electron microscopic immunoperoxidase labeling in stratum lucidum of CA3 shows prominent reaction product in large axon terminals having the morphological characteristics of mossy fiber boutons (Fig.7A) (Amaral and Dent, 1981). In the hilar layer of the dentate gyrus, where mossy fiber collaterals terminate, a few large terminals similar to those in the CA3 region contain BNPI immunoreactivity (data not shown). Many smaller terminals in the dentate gyrus that form asymmetric excitatory-type synapses with dendritic spines also label for BNPI (Fig. 7B). Thus, except for rare dendritic spines and isolated glial processes, BNPI localizes exclusively to axon terminals.
Nerve terminals in the hippocampus show heterogeneous expression of BNPI. In processes in which membrane specializations are observed, the labeled terminals form asymmetric synapses with unlabeled dendritic spines (Fig. 7B). Symmetric synapses do not contain detectable BNPI (data not shown), supporting a specific role for the protein in excitatory transmission. In addition, many terminals forming asymmetric synapses do not contain detectable BNPI, indicating expression only at a subset of excitatory synapses (Fig.7B). Within the labeled terminals the peroxidase reaction product distributes diffusely along the membranes of small synaptic vesicles (Fig. 7A,B). Intense reaction product also associates with the dense core vesicles found in mossy fiber terminals of CA3 (Fig. 7A) and in terminals within the hilar region of the dentate gyrus (Fig. 7B). BNPI therefore appears to localize to specialized secretory vesicles within a subset of excitatory nerve terminals.
We also have used electron microscopic immunoperoxidase labeling to examine the distribution of BNPI in the dorsal caudate putamen nuclei (Fig. 7C). Reaction product densely distributes to nerve terminals and small unmyelinated axons adjacent to other unlabeled processes. As in the hippocampus the terminals forming asymmetric synapses show intense labeling, but symmetric synapses contain no reaction product (data not shown). Within the labeled nerve terminals and axons, BNPI immunoreactivity surrounds the membranes of small vesicles (Fig. 7C).
Because the immunoperoxidase method cannot resolve the precise subcellular location of BNPI, we used electron microscopic labeling with immunogold-silver (Fig. 8). Similar to the peroxidase reaction product, silver-intensified immunogold particles localize to nerve terminals only at asymmetric synapses in the caudate putamen. However, not all terminals forming asymmetric synapses were labeled, and some of these unlabeled terminals form asymmetric synapses onto the same dendrites that receive input from BNPI-labeled terminals. Within the labeled terminals, BNPI localizes to the membrane of small synaptic vesicles. The labeling appears more intense over synaptic vesicles distant from the active zone, although we did not evaluate this rigorously. In addition, a few gold particles directly contact the plasma membrane, but only in the vicinity of synaptic vesicles at regions of the terminal distant from the active zone. Therefore, despite the Na+ dependence of BNPI activity, BNPI localizes predominantly to synaptic vesicles at asymmetric excitatory-type synapses.
Biochemical fractionation demonstrates BNPI on synaptic vesicles
Because either the tissue preparation required for immunoelectron microscopy or the interaction of BNPI with another protein may limit the access of BNPI antibody at sites such as the plasma membrane, we also examined the distribution of the transporter, using biochemical methods. Biochemical fractionation followed by immunoblot analysis obviates problems related to fixation or protein interaction and hence may identify plasma membrane BNPI not detectable by immunoelectron microscopy.
To distinguish synaptic vesicles from plasma membrane, we first prepared synaptosomes from the rat cortex. BNPI initially sediments with plasma membrane proteins such as the Na+/K+ ATPase and syntaxin (Bennett et al., 1993) in the insoluble debris (P1) and in the crude synaptosomal pellets, P2 and P2′ (Fig.9A). However, the synaptic vesicle protein synaptophysin also appears in these same fractions. After hypo-osmotic lysis of the synaptosomes, Na+/K+ ATPase and syntaxin sediment with the heavy lysed synaptosomal membranes (LP1), whereas BNPI and synaptophysin fractionate together into the lighter membrane fractions, LS1 and LP2 (Fig. 9A). Thus, BNPI cofractionates with synaptic vesicles by differential centrifugation.
Velocity sedimentation through glycerol separates synaptic vesicles from essentially all other membranous organelles (Clift-O’Grady et al., 1990). We used LS1 as the starting material because it contains synaptic vesicles (Fig. 9A), and sedimentation through glycerol shows that BNPI cofractionates with synaptophysin in the middle of the gradient (Fig. 9B). The synaptic plasma membrane protein syntaxin resides predominantly in heavy membranes but also occurs at low levels on synaptic vesicles (Fig. 9B) (Walch-Solimena et al., 1995). Importantly, the heavy membrane fractions contain very little BNPI when compared with the synaptic vesicle fractions, indicating extremely low levels of expression at the plasma membrane. Thus, BNPI localizes to synaptic vesicles by biochemical fractionation as well as by immunoelectron microscopy.
DISCUSSION
The antibody to BNPI that we describe here specifically recognizes a protein of the anticipated size in both transfected cells and the rat brain. Although rat kidney expresses distinct Na+-dependent Pi transporters (Li and Xie, 1995), their sequences diverge substantially from BNPI at the C terminus used to produce antigen, making it unlikely that the BNPI antibody cross-reacts with these proteins.
BNPI localizes to nerve terminals at excitatory synapses
The results indicate that BNPI localizes to nerve terminals. By light microscopy it has been shown that the BNPI antibody selectively labels structures that resemble nerve terminals and does not label cell bodies or dendritic structures. Electron microscopy confirms the presynaptic expression of BNPI. Further, essentially all BNPI immunoreactivity colocalizes with that of synaptophysin in primary hippocampal cultures. However, many varicosities in the cultures express synaptophysin, but not BNPI. BNPI thus appears to localize only to a subset of nerve terminals.
Previous in situ hybridization localizing BNPI to a subset of cell groups in the brain (Ni et al., 1995) was consistent with the expression of BNPI mRNA by glutamatergic neurons. Localization of BNPI protein now indicates a specific role in glutamatergic transmission. The outer two-thirds of the molecular layer in the dentate gyrus show strong immunoreactivity, suggesting the expression of BNPI by glutamatergic inputs from the perforant pathway (Matthews et al., 1976;Johnston and Amaral, 1998). Indeed, the entorhinal cortex, which gives rise to the perforant path, expresses substantial amounts of BNPI mRNA. Light and electron microscopy show that BNPI localizes to excitatory mossy fiber terminals in stratum lucidum of CA3 of the hippocampus, consistent with the expression of BNPI mRNA by dentate gyrus granule cells (Ni et al., 1995). In addition, BNPI localizes to excitatory Schaffer collaterals in strata oriens and radiatum of CA1, and the hippocampal neurons in CA3 from which these collaterals derive express BNPI mRNA (Ni et al., 1995). The laminar pattern of BNPI immunoreactivity in the hippocampus strongly resembles that previously observed for glutamate (Storm-Mathisen et al., 1983). Further, electron microscopic immunolabeling confirms that high levels of BNPI occur at asymmetric excitatory-type terminals in both the hippocampus and caudate putamen nuclei, strongly supporting a role for BNPI in excitatory transmission. Additionally, in hippocampal cultures the neuronal cell bodies express low levels of BNPI, and all of the immunoreactive cells also express PAG, a protein essentially restricted to glutamatergic neurons (Najlerahim et al., 1990; Aoki et al., 1991;Kaneko and Mizuno, 1994; Torgner et al., 1998).
BNPI protein also localizes to excitatory connections in the cerebellum. Excitatory synapses made by climbing and parallel fiber inputs onto Purkinje cell dendrites occur in the molecular layer, and the molecular layer contains high levels of BNPI, consistent with the expression of BNPI mRNA by inferior olivary neurons and granule cells from which climbing and parallel fibers arise. In the granule cell layer the excitatory mossy fiber terminals, which derive from pontine nuclei expressing BNPI mRNA, also label heavily for BNPI. Thus, BNPI protein occurs at glutamatergic synapses (Storm-Mathisen and Ottersen, 1988) in multiple brain regions.
The results also indicate that BNPI does not function in inhibitory transmission. By light microscopy it has been shown that BNPI immunoreactivity differs dramatically from that of GABA and such GABAergic markers as glutamic acid decarboxylase and the vesicular GABA transporter (Storm-Mathisen and Ottersen, 1983; Esclapez et al., 1994;Chaudhry et al., 1998). Consistent with this observation, inhibitory cell populations express no BNPI mRNA (Ni et al., 1995). Electron microscopy confirms that symmetric, presumably inhibitory, synapses do not express detectable BNPI protein. BNPI immunoreactivity in such regions as the caudate putamen that contain abundant GABAergic neurons thus presumably derives from other brain regions, such as the cortex, which do express BNPI mRNA (Ni et al., 1995).
Although restricted to glutamatergic terminals, BNPI expression does not occur at all glutamatergic synapses. In stratum lucidum of the CA3 region of the hippocampus, structures having the light microscopic features of mossy fiber terminals show strong immunoreactivity for BNPI. However, Schaffer collaterals in strata oriens and radiatum of both CA3 and CA1 show much less intense immunoreactivity, indicating heterogeneity of BNPI expression by glutamatergic afferents. Consistent with these observations, thalamic nuclei use glutamate as their neurotransmitter but conspicuously lack BNPI mRNA (Ni et al., 1995). Electron microscopic immunolabeling of both the hippocampus and caudate putamen also shows many nerve terminals forming asymmetric synapses that do not contain BNPI. Thus, BNPI appears to have a specific role only at certain excitatory synapses.
Potential physiological roles for BNPI at excitatory synapses
Plasma membrane Pi transport mediated by BNPI may maintain the level of ATP required for neuronal function (Glinn et al., 1995, 1997). Indeed, a substantial proportion of externally applied32Pi incorporates into ATP after Na+-dependent uptake into cultured cortical neurons, and the levels of ATP, NADPH, and intracellular-free Pi in these cells also depend on extracellular Pi. However, the restricted expression of BNPI to particular neuronal populations suggests that BNPI does not have a general role in neuronal function. Rather, BNPI appears to function specifically in a subset of excitatory neurons. Further, the presynaptic localization of BNPI suggests a role in the regulation of glutamate synthesis, accumulation, or release.
Although BNPI belongs to a family of Na+-dependent Pi transporters, it shows particularly strong sequence similarity to EAT-4, a C. elegans gene product recently implicated in glutamatergic neurotransmission. Originally isolated in screens for genes involved in feeding (Avery, 1993), eat-4mutants show defects in a number of behaviors, many of which involve the transmitter glutamate (Raizen and Avery, 1994; Dent et al., 1997;Li et al., 1997; Lee, Sawin, Chalfie, Horvitz, and Avery, unpublished observations). However, the iontophoretic application of glutamate at a glutamatergic synapse elicits a normal postsynaptic response (Dent et al., 1997; Li et al., 1997), strongly suggesting a specific presynaptic role for BNPI. Importantly, neurotransmission by serotonin, acetylcholine, and GABA appears normal in eat-4 mutants (Lee, Sawin, Chalfie, Horvitz, and Avery, unpublished observations). Thus, both EAT-4 and its vertebrate homolog BNPI appear to have a specific presynaptic function at glutamatergic connections.
How does BNPI influence glutamate release? BNPI may function specifically in glutamate transport, but a large family of plasma membrane glutamate transporters has been identified already (Arriza et al., 1994; Robinson and Dowd, 1997), and BNPI shows no sequence similarity to these proteins. Although the proteins responsible for vesicular glutamate transport have not yet been identified and we find that BNPI localizes to synaptic vesicles, BNPI clearly functions as a Pi transporter (Ni et al., 1994, 1996). Furthermore, the dependence on Na+ makes it unlikely that BNPI functions in vesicles, where a proton electrochemical gradient provides the principal driving force for the packaging of classical neurotransmitters (for review, see Liu and Edwards, 1997). It seems more likely that BNPI contributes to the synthesis of glutamate at the nerve terminal.
An isoform of the enzyme glutaminase synthesizes a majority of the glutamate available for Ca2+-dependent synaptic release (Bradford et al., 1978; Hamberger et al., 1979a,b; Ward et al., 1983; Szerb and O’Regan, 1985). This glutaminase localizes to a subset of glutamatergic fibers (Aoki et al., 1991; Kaneko and Mizuno, 1994;Torgner et al., 1998). Within neurons, the glutaminase associates with mitochondria and synaptic vesicles (Aoki et al., 1991) and also occurs in a soluble form (Torgner et al., 1998). Interestingly, Piprominently activates this glutaminase, accounting for its designation as PAG (EC 3.5.1.2) (Curthoys and Watford, 1995). Because PAG has a K½ for Pi of 10–25 mm, physiological changes in cytoplasmic Pihave the potential to regulate PAG activity (for review, see Erecinska and Silver, 1990). CSF contains ∼100-fold lower levels of Pi (Fishman, 1992) than theK½ for Pi, suggesting that the active accumulation of Pi catalyzed by BNPI may elevate cytoplasmic levels substantially. BNPI therefore may regulate glutamate synthesis and release. This role is consistent with both the glutamatergic phenotype of the eat-4 mutant inC. elegans and the localization of vertebrate BNPI to excitatory nerve terminals.
In addition to glutamate, PAG produces ammonia. In the kidney, PAG contributes to the elimination of acid from the body by producing ammonia, which diffuses into the lumen of the nephron and buffers the protons secreted into the urine (Lote, 1994; Curthoys and Watford, 1995). Protonation of ammonia in the lumen of the nephron yields ammonium ions for which the charge prevents diffusion back across the renal epithelium. Similarly, the ammonia produced by PAG in glutamatergic neurons may diffuse into synaptic vesicles, and the protonation occurring in this acidic compartment presumably would prevent diffusion back to the cytoplasm. Ammonia produced by PAG thus may reduce the pH gradient across the vesicle membrane and increase the electrical component of the proton electrochemical gradient. Importantly, the transport of glutamate into synaptic vesicles differs from the transport of other classical transmitters: glutamate transport depends more on the electrical component of the proton electrochemical gradient than on the pH gradient (Maycox et al., 1988; Carlson et al., 1989). PAG therefore has the potential to facilitate glutamate release by producing ammonia as well as glutamate.
Localization of BNPI to synaptic vesicles suggests regulation of BNPI function
Although its dependence on Na+ suggests that BNPI functions at the plasma membrane, the results indicate that the majority of BNPI resides on synaptic vesicles. Immunoelectron microscopy demonstrates that the vast majority of BNPI localizes to synaptic vesicles in axon terminals forming asymmetric synapses. In addition, the localization of BNPI to synaptic vesicles by biochemical methods excludes the possibility that we have failed to detect BNPI at the plasma membrane because of problems associated with fixation or protein–protein interactions. Because the dependence of BNPI on a Na+ rather than H+ gradient makes it unlikely that the transporter functions in synaptic vesicles, we presume that the localization to synaptic vesicles provides a mechanism for precisely regulated cell-surface expression and function. In particular, the appearance of BNPI at the plasma membrane on synaptic vesicle exocytosis would allow neural activity to increase glutamate synthesis via the activation of PAG. Interestingly, unlike neuronal populations that use other neurotransmitters, glutamatergic neurons appear to lack a presynaptic reuptake system to replenish released transmitter (Rothstein et al., 1994; Lehre et al., 1995;Velaz-Faircloth et al., 1996; Arriza et al., 1997). BNPI therefore may provide an alternative mechanism to replenish glutamate stores after massive exocytosis. The low steady-state level of BNPI at the plasma membrane also suggests that protracted increases in cytoplasmic Pi, and hence glutamate synthesis, may be deleterious.
In conclusion, we show that BNPI localizes specifically to the presynaptic element at excitatory synapses, consistent with the defect in glutamate release observed in eat-4 mutants in C. elegans. Although the function of BNPI in glutamatergic transmission remains unknown, BNPI may serve to stimulate phosphate-activated glutaminase and hence increase the synthesis of glutamate. Surprisingly, BNPI resides on synaptic vesicles rather than on the plasma membrane, suggesting precise temporal regulation of its cell-surface expression and function by neural activity.
Footnotes
This work was supported by Grants MH00078 and MH40342 from the National Institute of Mental Health (to V.M.P.), by a Howard Hughes Predoctoral Fellowship (to E.E.B.), and by National Institute of Mental Health Grant MH01365 and National Institute of Neurological Diseases and Stroke Grant NS16033 (to R.H.E.). We thank R. Y. N. Lee and L. Avery for thoughtful discussion and for communicating unpublished observations; S. E. Craven and D. S. Bredt for assistance with the hippocampal cultures; F. Chaudhry, H. J. Ralston III, and D. H. Lowenstein for help with the anatomy; R. J. Reimer for help with the graphics and review of this manuscript; and the members of the Edwards lab for technical assistance and thoughtful discussion.
Correspondence should be addressed to Dr. Robert H. Edwards, Departments of Neurology and Physiology, University of California San Francisco School of Medicine, 513 Parnassus Avenue, Box 0435, San Francisco, CA 94143-0435.