Hereditary spastic paraplegia and amyotrophy associated with a novel locus on chromosome 19.

We identified a family in Mali with two sisters affected by spastic paraplegia. In addition to spasticity and weakness of the lower limbs, the patients had marked atrophy of the distal upper extremities. Homozygosity mapping using single nucleotide polymorphism arrays showed that the sisters shared a region of extended homozygosity at chromosome 19p13.11-q12 that was not shared by controls. These findings indicate a clinically and genetically distinct form of hereditary spastic paraplegia with amyotrophy, designated SPG43.

Dephosphorylation by calcineurin regulates translocation of Drp1 to mitochondria.

Changes in mitochondrial morphology that occur during cell cycle, differentiation, and death are tightly regulated by the balance between fusion and fission processes. Excessive fragmentation can be caused by inhibition of the fusion machinery and is a common consequence of dysfunction of the organelle. Here, we show a role for calcineurin-dependent translocation of the profission dynamin related protein 1 (Drp1) to mitochondria in dysfunction-induced fragmentation. When mitochondrial depolarization is associated with sustained cytosolic Ca(2+) rise, it activates the cytosolic phosphatase calcineurin that normally interacts with Drp1. Calcineurin-dependent dephosphorylation of Drp1, and in particular of its conserved serine 637, regulates its translocation to mitochondria as substantiated by site directed mutagenesis. Thus, fragmentation of depolarized mitochondria depends on a loop involving sustained Ca(2+) rise, activation of calcineurin, and dephosphorylation of Drp1 and its translocation to the organelle.

Protein targeting and calcium signaling microdomains in neuronal cells.

Over the last several years, a number of optical imaging, physiological, and molecular studies have clarified the mechanisms underlying differential calcium signaling in the postsynaptic neuron. These studies have revealed the existence of membrane-associated calcium microdomains, which are often specifically coupled to distinct protein signaling pathways. In this review, we discuss how these signaling microdomains are organized and regulated, emphasizing the structural and molecular features of synaptic protein complexes containing the metabotropic and N-methyl-D-aspartate (NMDA) glutamate receptors and the L-type voltage-dependent calcium channels (VDCCs). We conclude with a discussion of how these different signaling complexes may interact with one another, relationships which may be important in orchestrating the complex calcium signaling underlying developmental and activity-dependent changes in synaptic function.

AMPA receptor protein in developing rat brain: glutamate receptor-1 expression and localization change at regional, cellular, and subcellular levels with maturation.

We tested the hypothesis that the regional, cellular, and synaptic localizations of the glutamate receptor 1 (GluR 1) subunit of the alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptor are regulated developmentally in rat brain. By immunoblotting, GluR1 was first detected in whole brain at embryonic day E15.5, and levels increased progressively during late embryonic (E20) and early postnatal (P2-P11) days. Regionally, GluR1 increased in cerebral cortex but decreased in striatum with postnatal maturation. These changes occurred in the presence of increased presynaptic maturation, as determined by synaptophysin detection. By immunocytochemistry, distinct cellular populations showed different temporal profiles of GluR1 expression during postnatal maturation. The neocortex and hippocampus showed a progressive maturation-related enrichment of GluR1, whereas the striatum showed a gradual reduction in GluR1 during maturation. In cerebellum, GluR1 protein was expressed transiently at restricted times postnatally by granule cells (P0-P11) and Purkinje cells (P13-P19), but by P21 and thereafter these neurons had sparse GluR1 immunoreactivity. By immunoelectron microscopy. GluR1 was found in neurites, specifically in both dendritic and axon terminal components of developing synapses. GluR1 was clustered at the plasma membrane of apparent growth cone appositions, neuronal cell bodies, and dendrites of developing neurons. The presence of GluR1 at presynaptic sites dissipated with synaptic maturation, as GluR1 became confined to the somatodendritic compartment as maturation progressed. We conclude that the regional expression as well as the cellular and synaptic localizations of the GluR1 are developmentally regulated and are different in immature and mature brain. Differences in glutamate receptor expression and synaptic localization in immature and mature brain may be relevant to the phenomenon that the perinatal and adult brain differ in their regional vulnerability to hypoxia-ischemia and excitotoxicity.

Immunocytochemical localization of the mGluR1 alpha metabotropic glutamate receptor in the dorsal cochlear nucleus.

We demonstrate that the metabotropic glutamate receptor mGluR1 alpha is enriched in two interneuron cell populations in the dorsal division of the cochlear nucleus. Electron microscopic analysis confirms that mGluR1 alpha immunoreactivity is concentrated in the dendritic spines of cartwheel cells and in dendrites of the recently described unipolar brush cells. The cartwheel cells, which have many similarities to the Purkinje cells of the cerebellum, participate in a local neuronal circuit that modulates the output of the dorsal cochlear nucleus. Immunostained unipolar brush cells were observed in granule cell regions of the cochlear nucleus and the vestibulocerebellum. The presence of analogous cell types with similar patterns of immunolabeling in the cerebellum and in the dorsal cochlear nucleus suggests that a shared but as yet unknown mode of processing may occur in both structures.

Distribution of glutamate receptor subtypes in the vertebrate retina.

The distribution of glutamate receptor subunit/subtypes in the vertebrate retina was investigated by immunocytochemistry using anti-peptide antibodies against AMPA (GluR1-4), kainate (GluR6/7) and metabotropic (mGluR1 alpha) receptors. All receptor subtypes examined are present in the mammalian retina, but they are distributed differentially. GluR1 is present in the inner plexiform layer as well as amacrine and ganglion cell bodies. GluR2 is present mainly in the outer plexiform layer and bipolar cells. An anti-GluR2/3 antibody labels both plexiform layers and various cell bodies in the inner nuclear layer and the ganglion cell layer. GluR4 is present on Müller glial cells. In the goldfish retina, GluR2 immunoreactivity is prominent in the Mb type of ON-bipolar cells, including the dendrites and the large synaptic terminal. The putative dendritic localization is surprising, because no depolarizing conductance increase induced by glutamate is thought to be present in these cells. An AMPA receptor at a presynaptic terminal is also unusual, and probably provides feedback control of glutamate release. GluR6/7 is most widespread in the retina, being present in horizontal, bipolar, amacrine and ganglion cells. Ion channels composed of GluR6 are now known to be phosphorylated by protein kinase A, resulting in current potentiation. This property and our present observation together suggest that the glutamate receptors previously studied electrophysiologically by others in horizontal cells may contain GluR6. mGluR1 alpha is found mostly in the inner plexiform layer; its localization partially overlaps with that of the inositol trisphosphate receptor in the retina. Our results suggest that, in the retina, glutamate receptor subtypes may be expressed in selective cell types according to their specific functions.

Non-NMDA glutamate receptors are present throughout the primate hypothalamus.

To determine the distributions of glutamate receptors throughout the macaque hypothalamus, we utilized highly specific antipeptide antibodies to visualize alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptor subunits (GluR1, GluR2 and GluR3 [designated as GluR2/3], and GluR4); kainate receptor subunits (GluR6 and GluR7, [designated as GluR6/7]), and a metabotropic receptor (mGluR1 alpha). The results indicate that these glutamate receptors are distributed differentially throughout the monkey hypothalamus. alpha-Amino-3-hydroxy-5-methyl-4-isoxazole propionate receptors are the dominant non-N-methyl-D-aspartate glutamate receptors within the monkey hypothalamus, and the GluR2 subunit is most abundant. GluR1-immunoreactive neurons and neuropil are observed predominantly in the tuberal and mammillary nuclei. GluR2/3-immunoreactive neurons and neuropil have a broader distribution within preoptic, anterior, tuberal, and caudal regions. Separate (but partially overlapping) distributions of GluR1- and GluR2/3-immunoreactive neurons were found, suggesting that the GluR1, GluR2, and/or GluR3 subunits may be coexpressed in subsets of hypothalamic neurons. In contrast, GluR4 immunoreactivity was expressed minimally within monkey hypothalamus. GluR6/7 immunoreactivity was enriched selectively within the suprachiasmatic nucleus. mGluR1 alpha immunoreactivity was present in the mammillary complex. The localization of non-N-methyl-D-aspartate glutamate receptor subunits to neurons throughout the macaque hypothalamus provides further evidence for the glutamatergic regulation of neuroendocrine, autonomic, and limbic circuits. Differential distributions of glutamate receptor subunits may increase the dynamic range of the effects of presynaptic glutamate, allowing for the regulation of several distinct functions subserved by hypothalamic neurons.

The AMPA glutamate receptor GluR3 is enriched in oxytocinergic magnocellular neurons and is localized at synapses.

The cellular localization of alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate glutamate receptor, GluR3, was identified using antibodies that recognize the N-terminus of the predicted polypeptide sequence of GluR3. Regional immunoblot analysis of monkey brain homogenates identified a protein of approximately 102,000 mol. wt that was enriched in hypothalamus. Immunocytochemistry demonstrated that GluR3 was enriched within the hypothalamic magnocellular neurosecretory nuclei and axons of the hypothalamo-neurohypophysial tract in rat and monkey. GluR3 immunoreactivity co-localized to oxytocin-containing, but not vasopressin-containing, neurons of the hypothalamic paraventricular nucleus, supraoptic nucleus and accessory magnocellular nuclei. Ultrastructurally, GluR3 immunoreactivity was enriched throughout cytoplasm of the somatodendritic compartment and was associated with postsynaptic and presynaptic structures. GluR3 immunoreactivity was frequently observed to be clustered at the plasma membrane of the somatodendritic compartment, consistent with the predicted localization of a membrane-bound ion channel. Additionally, GluR3-immunoreactive axon terminals in synaptic contact with unlabeled dendrites within the retrochiasmatic area and bed nucleus of the stria terminalis were observed, providing morphological evidence for a presynaptic alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptor. By immunoblot analysis and immunocytochemistry using antibodies directed against a specific alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptor in rat and monkey brain, our findings suggest a highly selective hypothalamic distribution of the GluR3 subunit that may have functional significance in the glutamatergic regulation of oxytocinergic neurons.

Down-regulation of AMPA receptor subunit GluR2 in amygdaloid kindling.

Alterations in glutamatergic transmission are postulated to be important in kindling and epilepsy. The levels of alpha-amino-3-hydroxy- 5-methylisoxazole-4-propionic acid (AMPA) receptor subunits (GluR1, 2, and 4) were compared in amygdala-kindled and sham-operated animals using subunit-specific antibodies and quantitative western blotting. Four limbic regions were examined: limbic forebrain, piriform cortex/amygdala, hippocampus, and entorhinal cortex. When subunit levels were examined 24 h after the last stage 5 seizure, levels of GluR2 were found to be selectively reduced in limbic forebrain (30%) and piriform cortex/amygdala (25%), with no changes in other regions examined. In addition, no changes in the other subunits were observed in any region. The decrease in GluR2 that was observed in kindled animals at 24 h was no longer present at 1 week and 1 month after the last stage 5 seizure. Because the GluR2 subunit uniquely determines the calcium permeability of these receptors and because the piriform cortex has been implicated as a source of excitatory drive for limbic seizures, reduced GluR2 expression may be important in increasing neuronal excitability in kindling-induced epilepsy, or may reflect a compensatory mechanism resulting from kindling.

Selective clustering of glutamate and gamma-aminobutyric acid receptors opposite terminals releasing the corresponding neurotransmitters.

Several immunocytochemical and physiological studies have demonstrated a concentration of neurotransmitter receptors at postsynaptic sites on neurons, but an overall picture of receptor distribution has not emerged. In particular, it has not been clear whether receptor clusters are selectively localized opposite terminals that release the corresponding neurotransmitter. By using antibodies against the excitatory glutamate receptor subunit GluR1 and the inhibitory type A gamma-aminobutyric acid (GABA) receptor beta 2/3 subunits, we show that these different receptor types cluster at distinct postsynaptic sites on cultured rat hippocampal neurons. The GABAA receptor beta 2/3 subunits clustered on cell bodies and dendritic shafts opposite GABAergic terminals, whereas GluR1 clustered mainly on dendritic spines and was associated with glutamatergic synapses. Chronic blockade of evoked transmitter release did not block receptor clustering at postsynaptic sites. These results suggest that complex mechanisms involving nerve terminal-specific signals are required to allow different postsynaptic receptor types to cluster opposite only appropriate presynaptic terminals.

Cyclic AMP and synaptic activity-dependent phosphorylation of AMPA-preferring glutamate receptors.

Several studies have suggested that the function of glutamate receptor channels can be regulated by protein phosphorylation. Furthermore, a basal level of phosphorylation may be necessary to maintain receptor function. Little is known, however, about the phosphorylation state of glutamate receptor channels in neurons and how it is regulated by synaptic activity. In this study, we have investigated the phosphorylation of the AMPA-preferring glutamate receptor subunit GluR1 in cortical neurons in primary culture. These neurons elaborate extensive processes, form functional synapses, and exhibit spontaneous 4-8 sec bursts of synaptic activity every 15-20 sec. In cultures in which this synaptic activity was suppressed by tetrodotoxin and MK-801, the GluR1 protein was phosphorylated on serine residues within a single tryptic phosphopeptide, as determined by phosphoamino acid analysis and phosphopeptide mapping. This same peptide was basally phosphorylated in recombinant GluR1 receptors transiently expressed in human embryonal kidney 293 cells. Treatment of these synaptically inactive cortical neurons with the adenylyl cyclase activator forskolin resulted in a robust increase in phosphorylation on serine residues on a phosphopeptide distinct from the basally phosphorylated peptide. Again, this same phosphopeptide was observed in recombinant GluR1 receptors isolated from 293 cells coexpressing the catalytic subunit of cAMP-dependent protein kinase. Spontaneous synaptic activity in cultures of cortical neurons resulted in a consistent, rapid (within 10-30 sec) increase in phosphorylation on serine and threonine residues. Interestingly, these phosphopeptides were also phosphorylated when neurons from inactive cultures were stimulated with phorbol esters, which activate protein kinase C. These results indicate that AMPA receptors containing the GluR1 subunit may be regulated by extracellular signals working through the cAMP second messenger system as well as by synaptic activity, possibly acting through protein kinase C. Such regulation by protein phosphorylation may be involved in short-term changes in synaptic efficacy thought to involve the functional modulation of AMPA receptors.

Developmental regulation of the hypothalamic metabotropic glutamate receptor mGluR1.

The expression of the metabotropic glutamate receptor mGluR1 was studied with Northern and Western blot analysis, with immunocytochemistry, and with Ca2+ digital imaging in the developing rat hypothalamus. mGluR1 is coupled to a G protein and activation by glutamate and related agonists leads to intracellular phosphotidylinositol hydrolysis and Ca2+ mobilization. mGluR1 RNA could be detected in embryonic hypothalamus, and by the day of birth and prior to the primary period of synaptogenesis, both mGluR1 RNA and protein were strongly expressed. In parallel experiments with digital imaging of cultured hypothalamic cells, some embryonic day 18 hypothalamic neurons and many astrocytes after 3 d in vitro showed Ca2+ responses to quisqualate and t-ACPD, and to glutamate in the absence of extracellular Ca2+. A greater number of embryonic neurons responded to NMDA than to agonists of the metabotropic receptor. With increased development time in culture, the number of neurons that responded to metabotropic glutamate receptor agonists increased. In the adult hypothalamus, mGluR1-immunoreactive neurons were widespread, and particularly dense in the dorsomedial, lateral, and anterior hypothalamus/preoptic areas, and in the mammillary body. Strongly immunoreactive cells were interspersed among neurons with no immunoreactivity. In developing neurons a diffuse immunostaining appeared along dendrites and somata. With time, beginning in the first week after birth, strongly stained puncta appeared, possibly associated with synaptic specializations. These puncta were numerous on dendrites of some adult neurons, and were the most strongly stained regions of neurons. Neurons developing in vitro at low neuron densities showed a development of mGluR1 immunoreactivity similar to that of neurons in vivo, but with a delayed progression of immunostaining. We found no obvious staining of axons or of astrocytes. A strong expression of mGluR1 protein was found in the hypothalamus during the first 2 postnatal weeks; this expression was partially reduced in adults. In contrast, cerebellum showed no reduction in mGluR1 protein in adults. Together these data suggest a complex regulation of mGluR1 during development, with sufficient expression of functional receptors in the developing hypothalamus to modulate morphogenesis and synaptogenesis, and later to play a role in transduction of glutamate signals in the adult. Different regions of the brain showed dramatic differences in the way each expresses mGluR1 during development.

Regulation of GABAA receptor function by protein kinase C phosphorylation.

GABAA receptors possess consensus sequences for phosphorylation by PKC that are located on the presumed intracellular domains of beta and gamma 2 subunits. PKC phosphorylation sites were analyzed using purified receptor subunits and were located on up to 3 serine residues in beta 1 and gamma 2 subunits. The role of phosphorylation in receptor function was studied using recombinant receptors expressed in kidney cells and Xenopus oocytes and was compared with native neuronal GABAA receptors. For recombinant and native GABAA receptors, PKC phosphorylation caused a reduction in the amplitudes of GABA-activated currents without affecting the time constants for current decay. Selective site-directed mutagenesis of the serine residues reduced the effects of phorbol esters and revealed that serine 343 in the gamma 2 subunit exerted the largest effect on the GABA-activated response. These results indicate that PKC phosphorylation can differentially modulate GABAA receptor function.

Human GluR6 kainate receptor (GRIK2): molecular cloning, expression, polymorphism, and chromosomal assignment.

Glutamate receptors mediate the majority of excitatory neurotransmission in the brain, and molecular cloning studies have revealed several distinct families. Because neuropathological states and possibly human disorders may involve kainate-preferring glutamate receptors, we have isolated a cDNA clone for the human GluR6 kainate-preferring receptor. This clone shows a very high sequence similarity with that of the rat, except for a part of the 3' untranslated region in which there is a TAA triplet repeat. When the protein was overexpressed in human embryonic kidney 293 cells, it had a molecular weight, an antibody recognition, and a glutamate ligand-binding profile similar to those of the rat GluR6 receptor. Northern analysis showed expression in both human cerebral and cerebellar cortices. By PCR analysis of rodent-human monochromosomal cell lines, the human GluR6 could be assigned to chromosome 6. The length of the TAA triplet repeat was polymorphic in the normal population, with at least four alleles and an observed heterozygosity of about 45%. These studies should provide the basis for expression or linkage studies of the GluR6 kainate receptor in human disease or neuropathologic states.

Transmembrane topology of the glutamate receptor subunit GluR6.

Ionotropic glutamate receptors mediate most rapid excitatory synaptic transmission in the mammalian central nervous system. These receptors are divided into alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA), kainate, and N-methyl-D-aspartate receptors based on pharmacological and electrophysiological characteristics. Ionotropic receptor subunits are integral membrane proteins that have been proposed to have a large extracellular ligand-binding N-terminal domain, four hydrophobic transmembrane domains, and an extracellular C-terminal domain. In this study we have shown that both AMPA receptor subunits (GluR1-4) and kainate receptor subunits (GluR6/7) are glycosylated in adult rat brain; however, the kainate receptor subunits are glycosylated to a greater extent. Examination of the sequences of AMPA and kainate receptors revealed that kainate receptors have several additional consensus sites for N-linked glycosylation; interestingly, one of these is located in the proposed major intracellular loop of the receptor subunits. To test the proposed transmembrane topology model for these receptors, we have used site-specific mutagenesis of the GluR6 subunit to remove the consensus glycosylation site located within the proposed intracellular loop. Mutagenesis of this site demonstrates that it is glycosylated in transiently transfected human embryonic kidney cells, which express functional kainate receptors. Since N-linked glycosylation has only been found to occur on extracellular domains of plasma membrane proteins, these results suggest that the proposed transmembrane topology model for the glutamate receptor subunits is incorrect. Combining these results with other recent data, we have proposed an alternative transmembrane topology model.

Glutamate receptor modulation by protein phosphorylation.

Glutamate-gated ion channels mediate most excitatory synaptic transmission in the mammalian central nervous system and play major roles in synaptic plasticity, neuronal development, and in some neuropathological conditions. Recent studies have suggested that protein phosphorylation of neuronal glutamate receptors by cyclic AMP-dependent protein kinase (PKA) and protein kinase C (PKC) may regulate their function and play a role in some forms of synaptic plasticity. To test whether these protein kinase effects are due to direct phosphorylation of the receptors and to further examine the sites and mechanisms by which the receptors are modulated, we transiently expressed recombinant glutamate receptors in HEK-293 cells and studied their biochemical and biophysical properties. Our results indicate that the kainate-preferring receptor GluR6 is phosphorylated by PKA, primarily on a single serine in the proposed major intracellular loop. Moreover, using the whole cell patch clamp recording technique, we have shown that phosphorylation at this site increases the amplitude of the GluR6-mediated glutamate current without significantly altering its dose-response, current-voltage relation or desensitization kinetics. In other experiments, we have demonstrated that the NMDA receptor subunit NR1 is phosphorylated by PKC on several distinct sites, and most of these sites are located within a single alternatively spliced exon in the C-terminal domain. These findings suggest that RNA splicing can regulate NMDA receptor phosphorylation and that, contrary to the previously proposed membrane topology model, the NR1 C-terminus is intracellular. Furthermore, in HEK-293 cells co-transfected with NR2A and NR1 subunits containing the C-terminal exon with the PKC phosphorylation sites, our preliminary studies indicate that the NMDA-evoked current is potentiated by intracellular PKC. We are currently examining PKC effects on the NMDA-evoked current responses of mutant NR1 receptors that lack the C-terminal phosphorylation sites. These studies provide evidence that glutamate receptors are directly phosphorylated and functionally modulated by protein kinases. Moreover, by identifying phosphorylation sites within the receptor proteins, our results provide information about the structure and membrane topology of these receptors.

Localization of non-N-methyl-D-aspartate glutamate receptors in normal and Alzheimer hippocampal formation.

The hippocampi and adjacent temporal cortices of 24 human brains were examined with antibodies to the GluR1, GluR2/3, and GluR4 subunits of the D,L-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid-preferring glutamate receptor. GluR1 immunoreactivity was most dense in the dentate gyrus, with lower densities in other hippocampal and cortical regions. GluR2/3 immunoreactivity was the most intense of the three antibodies, with high levels throughout most hippocampal subfields, where it was localized to cell bodies, proximal axons, and dendrites. GluR4 immunoreactivity was very sparse in all regions. In Alzheimer's disease brains, the general pattern of staining was similar to that seen in control brains. GluR1 and GluR4 immunoreactivity was seen in some but not all neuritic plaques. All three antibodies recognized some neurons undergoing neurofibrillary degeneration.

The distribution of glutamate receptors in cultured rat hippocampal neurons: postsynaptic clustering of AMPA-selective subunits.

The distribution of several glutamate receptor subunits was investigated in cultured rat hippocampal neurons by in situ hybridization and immunocytochemistry. The AMPA/kainate-selective receptors GluR1-6 exhibited two patterns of mRNA expression: most neurons expressed GluR1, R2, and R6, whereas only about 20% expressed significant levels of GluR3, R4, and R5. By immunocytochemistry, the metabotropic glutamate receptor mGluR1 alpha was detectable only in a subpopulation of GABAergic interneurons. GluR1 and GluR2/3 segregated to the somatodendritic domain within the first week in culture, even in the absence of synaptogenesis. Glutamate receptor-enriched spines developed later and were present only on presumptive pyramidal cells, not on GABAergic interneurons. Clusters of GluR1 and GluR2/3 completely colocalized and were restricted to a subset of postsynaptic sites. Thus, glutamate receptor subunits exhibit both a cell type-specific expression and a selective subcellular localization.

Cellular localizations of AMPA glutamate receptors within the basal forebrain magnocellular complex of rat and monkey.

The cellular distributions of alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) receptors within the rodent and nonhuman primate basal forebrain magnocellular complex (BFMC) were demonstrated immunocytochemically using anti-peptide antibodies that recognize glutamate receptor (GluR) subunit proteins (i.e., GluR1, GluR4, and a conserved region of GluR2, GluR3, and GluR4c). In both species, many large GluR1-positive neuronal perikarya and aspiny dendrites are present within the medial septal nucleus, the nucleus of the diagonal band of Broca, and the nucleus basalis of Meynert. In this population of neurons in rat and monkey, GluR2/3/4c and GluR4 immunoreactivities are less abundant than GluR1 immunoreactivity. In rat, GluR1 does not colocalize with ChAT, but, within many neurons, GluR1 does colocalize with GABA, glutamic acid decarboxylase (GAD), and parvalbumin immunoreactivities. GluR1- and GABA/GAD-positive neurons intermingle extensively with ChAT-positive neurons. In monkey, however, most GluR1-immunoreactive neurons express ChAT and calbindin-D28 immunoreactivities. The results reveal that noncholinergic GABAergic neurons, within the BFMC of rat, express AMPA receptors, whereas cholinergic neurons in the BFMC of monkey express AMPA receptors. Thus, the cellular localizations of the AMPA subtype of GluR are different within the BFMC of rat and monkey, suggesting that excitatory synaptic regulation of distinct subsets of BFMC neurons may differ among species. We conclude that, in the rodent, BFMC GABAergic neurons receive glutamatergic inputs, whereas cholinergic neurons either do not receive glutamatergic synapses or utilize GluR subtypes other than AMPA receptors. In contrast, in primate, basal forebrain cholinergic neurons are innervated directly by glutamatergic afferents and utilize AMPA receptors.