Ultrastructure of GABA-neurons in cultures of rat neostriatum

Dynorphin is a downstream effector of striatal BDNF regulation of ethanol intake

We recently identified brain-derived neurotrophic factor (BDNF) in the dorsal striatum to be a major component of a homeostatic pathway controlling ethanol consumption. We hypothesized that ethanol-mediated activation of the BDNF signaling cascade is required for the ethanol-related function of the neurotrophic factor. Here, we demonstrate that exposure of striatal neurons to ethanol results in the activation of the BDNF receptor TrkB, leading to the activation of the mitogen-activated protein kinase (MAP kinase) signaling pathway and the subsequent increase in the expression of preprodynorphin (Pdyn) via BDNF. Finally, we show that activation of the dynorphin receptor, the kappa opioid receptor (KOR), is required for the BDNF-mediated decrease in ethanol intake, illustrating a function of dynorphin in BDNF's homeostatic control of ethanol consumption. Taken together, these results demonstrate that BDNF regulates ethanol intake by initiation of MAP kinase signaling and the ensuing production of downstream gene products, including Pdyn.

GABAergic innervation in cerebral blood vessels: an immunohistochemical demonstration of L-glutamic acid decarboxylase and GABA transaminase

The presence of GABAergic innervation in cerebral arteries of several species was investigated by an immunohistochemical method using antibodies against glutamic acid decarboxylase (GAD) and GABA transaminase (GABA-T). Both GAD and GABA-T immunoreactivities were found to be associated with large bundles and single fibers in the adventitial layer of arteries examined. The density and distribution pattern of both GAD- and GABA-T-immunoreactive fibers were found to be comparable at most regions examined. Both fibers were found to be most dense in the anterior cerebral artery and its adjacent part of the circle of Willis. Several peripheral arteries were found to receive very sparse or no GAD- and GABA-T-immunoreactive fibers. Superior cervical ganglionectomy did not appreciably affect the distribution of both fibers. Cold-storage denervation, however, resulted in a drastic decrease in both fibers. At ultrastructural levels, both GAD- and GABA-T-immunoreactive nerve profiles were found to be very close to the smooth muscle cells. These results demonstrate the presence of a potentially functional GABAergic innervation in cerebral circulation. On few occasions, GAD immunoreactivities were also found in some endothelial cells, suggesting that a nonneuronal GABA system may also be present in cerebral arteries.

Parvalbumin-containing GABAergic interneurons in the rat neostriatum

Antibodies to the intracellular calcium binding protein parvalbumin were shown to label specifically a distinct group of neostriatal GABAergic neurons. These neurons corresponded to the intensely staining subclass of neostriatal GABAergic neurons that have previously been shown to be a class of aspiny interneurons in the neostriatum. The parvalbumin neurons were aspiny neurons with varicose dendrites distributed throughout the neostriatum in a pattern identical to the intensely stained GABA neurons, and both populations of neurons showed increased numbers in the lateral part of the neostriatum. Double labeling of single neurons with both the GABA and parvalbumin antisera showed that all parvalbumin neurons were positive for GABA, but some GABA labelled neurons were not immunoreactive for parvalbumin. These parvalbumin-negative GABAergic neurons were morphologically similar to the spiny projection neurons, which are GABAergic but usually are not so heavily stained. The relationship of the GABA-containing parvalbumin neurons to the striatal mosaic organization was determined by using immunocytochemistry for another calcium binding protein, calbindin D28K, to label the matrix compartment of the striatum. The distribution of parvalbumin-positive neurons relative to the calbindin-positive matrix and calbindin-poor patches was determined by using pairs of adjacent sections stained with the calbindin and parvalbumin antisera. This analysis showed that the somata of the parvalbumin neurons were present in both patch and matrix compartments, and their axons and dendrites crossed the boundaries between compartments. A quantitative analysis of the number of neurons in each compartment revealed that the neurons showed no preferential distribution in either compartment, but instead were present according to the area occupied by that compartment.(ABSTRACT TRUNCATED AT 250 WORDS)

Development of GABAergic synaptic connections in vivo and in cultures from the rat superior colliculus

Synaptic activity in the superficial (i.e. visual) layer of the superior colliculus was investigated with intracellular microelectrodes using a preparation of the isolated superfused tectum from neonatal rat. It was found that by postnatal day 9 (i.e. before eye opening) the majority of neurons in the superficial gray layer (SGS, stratum griseum superficiale) were already capable of generating Cl(-)-dependent inhibitory postsynaptic potentials (IPSPs) in response to intracollicular stimulation. Properties and development of GABAergic synaptic connections were further characterized in a dissociated cell culture from the SGS. The cultures were prepared from E21 rat embryos and studied between 1 and 38 days in vitro (DIV). gamma-[3H]aminobutyric acid ([3H]GABA) uptake served to identify GABAergic neurons and to estimate their relative density. Axon terminals were labeled by indirect immunostaining for glutamic acid decarboxylase (GAD) and examined with light (LM) and electron microscopy (EM). Responsiveness to exogenous and endogenous GABA was investigated by recording ionic currents with patch clamp techniques. [3H]GABA uptake-positive neurons constituted about 40% of the whole cellular population dissociated from the SGS of E21 rats. After 2 weeks in culture, [3H]GABA uptake was observed in 45-60% of the cells with neuronal features. The relative number of GAD-immunoreactive neuronal perikarya ranged from 28 to 39%, after 2 weeks in vitro. Responsiveness to exogenous GABA was found in all freshly plated neurons. Release of GABA could be demonstrated after 2 DIV by recording spontaneous bicuculline-sensitive Cl- currents. These currents had the characteristics of GABAA receptor-mediated synaptic currents. However, even as late as DIV 6, very few vesicle-containing axonal terminals apposing postsynaptic specializations were revealed with EM. GAD-labeled puncta became clearly visible only after DIV 10-12. Between DIV 14 and 21, the intensity of immunostaining and the density of GAD-labeled synaptic contacts increased, reaching a maximum around DIV 28. GAD-positive puncta covered both neurons and non-neuronal cells. At the level of EM, GAD-positive terminals were shown to establish synaptic contacts with neuronal somata and processes, forming in the majority of cases (22 out of 32 stained terminals) symmetrical contacts. It is concluded that in the SGS of the rat superior colliculus GABAergic neurons and GABAA receptors are present before birth. In dissociated cell cultures ionic currents can be generated in response to endogenous GABA before axonal terminals of GABAergic neurons fully mature. Finally, our experiments show that visual activity is not a prerequisite for the formation of GABAergic synapses between neurons of the SGS.

The adhesive and neurite-promoting molecule p30: analysis of the amino-terminal sequence and production of antipeptide antibodies that detect p30 at the surface of neuroblastoma cells and of brain neurons

A membrane-bound adhesive protein that promotes neurite outgrowth in brain neurons has been isolated from rat brain (Rauvala, H., and R. Pihlaskari. 1987. J. Biol. Chem. 262:16625-16635). The protein is an immunochemically distinct molecule with a subunit size of approximately 30 kD (p30). p30 is an abundant protein in perinatal rat brain, but its content decreases rapidly after birth. In the present study the amino-terminal sequence of p30 was determined by automated Edman degradations. A single amino-terminal sequence was found, which is not present in previously studied adhesive molecules. This unique sequence has a cluster of five positive charges within the first 11 amino acid residues: Gly-Lys-Gly-Asp-Pro-Lys-Lys-Pro-Arg-Gly-Lys. Antisynthetic peptide antibodies that recognize this sequence were produced in a rabbit, purified with a peptide affinity column, and shown to bind specifically to p30. The antipeptide antibodies were used, together with anti-p30 antibodies, to study the localization of p30 in brain cells and in neuroblastoma cells as follows. (a) Immunofluorescence and immunoelectron microscopy indicated that p30 is a component of neurons in mixed cultures of brain cells. The neurons and the neuroblastoma cells expressed p30 at their surface in the cell bodies and the neurites. In the neurites p30 was found especially in the adhesive distal tips of the processes. In addition the protein was detected in ribosomal particles and in intracellular membranes in a proportion of cells. (b) The antibodies immobilized on microtiter wells enhanced adhesion and neurite growth indicating that p30 is surface exposed in adhering neural cells. (c) Immunoblotting showed that p30 is extracted from suspended cells by heparin suggesting that a heparin-like structure is required for the binding of p30 to the neuronal cell surface. A model summarizing the suggested interactions of p30 in cell adhesion and neurite growth is presented.

The expression of gamma-aminobutyric acid and Leu-enkephalin immunoreactivity in primary monolayer cultures of rat striatum

Primary monolayer cultures of rat striatum were examined for gamma-aminobutyric acid (GABA) and leucine-enkephalin (L-ENK) immunoreactivity. Cultures were established on polycation-treated glass coverslips from the striata of gestational day 17 rat embryos using a serum and insulin-supplemented medium. The proportion of GABA-immunoreactive (GABA-IR) neurons increased during the first week in vitro from approximately one third to nearly one half and remained relatively constant thereafter. On the other hand, the proportion of L-ENK-IR neurons increased gradually over the culturing period, increasing from about one-fifth of the neurons initially to one-half after 3-4 weeks in vitro. The changes in the proportions of GABA- and L-ENK-IR neurons appeared to be largely a consequence of the death of non-immunoreactive neurons, not delayed expression or induction of GABA or L-ENK traits. Light microscopic analysis of somatic-proximal neuritic morphology led to a partitioning of the neuronal population into 4 groups. GABA- and L-ENK-IR groups were heterogeneous in this regard and differed only modestly.

GABAergic elements in the neuronal circuits of the monkey neostriatum: a light and electron microscopic immunocytochemical study

An antibody raised in rabbits against a GABA-BSA conjugate was used together with the PAP technique to label elements in the neostriatum of three Old World monkeys. Light microscopy revealed numerous immunoreactive medium-size neurons of various staining intensities, some of which had indented nuclei, as well as an occasional large cell. The neuropil showed a plexus of fine processes with frequent puncta. Ultrastructurally, the medium-size GABA-positive neurons were of two types: one with smooth nuclei and scanty cytoplasm, similar to spiny I cells, the other with invaginated nuclear envelopes and more abundant perikaryon, resembling the aspiny type. Correspondingly, labeled dendrites were either spiny or varicose. Some stained axons were myelinated, and the boutons had either large and ovoid, or small and pleomorphic vesicles. All of these boutons formed symmetric synapses, the former type with GABA-positive dendritic shafts but also with unlabeled dendrites; the latter type usually with GABA-negative elements, either dendrites, dendritic spines, or somata. Synapses were also observed between unreactive boutons and immunostained dendrites. Terminals with densely packed, small round vesicles that established asymmetric synapses with spines were always GABA-negative. Glial elements were consistently unlabeled, save for some astroglial endfeet. These findings provide positive evidence for the existence of two classes of GABAergic striatal neurons corresponding to a long-axoned spiny I type and an aspiny interneuron. Furthermore, the simultaneous labeling of GABA-immunoreactive presynaptic and postsynaptic profiles offers possible morphologic bases for the various kinds of intrastriatal inhibitory processes, including the feedforward, feedback, and "autaptic" types.

Neurotransmitters in the mammalian striatum: neuronal circuits and heterogeneity

The major input and output pathways of the mammalian striatum have been well established. Recent studies have identified a number of neurotransmitters used by these pathways as well as by striatal interneurons, and have begun to unravel their synaptic connections. The major output neurons have been identified as medium spiny neurons which contain gamma-aminobutyric acid (GABA), endogeneous opioids, and substance P. These neurons project to the pallidum and substantia nigra in a topographic and probably chemically organized manner. The major striatal afferents from the cerebral cortex, thalamus, and substantia nigra terminate, at least in part, on these striatal projection neurons. Striatal interneurons contain acetylcholine, GABA, and somatostatin plus neuropeptide Y, and appear to synapse on striatal projection neurons. In recent years, much activity has been directed to the neurochemical and hodological heterogeneities which occur at a macroscopic level in the striatum. This has led to the concept of a patch-matrix organization in the striatum.

Distribution of GABA-immunoreactive neurons in the basal ganglia of the squirrel monkey (Saimiri sciureus)

The distribution of GABA-immunoreactive neurons was visualized in the basal ganglia of the squirrel monkey (Saimiri sciureus), by using a highly specific antiserum raised against GABA-glutaraldehyde-lysyl-protein conjugate and revealed by the indirect peroxidase-antiperoxidase immunohistochemical method. In the dorsal striatum, GABA-immunoreactive nerve cell bodies were small to medium in size (sectional area ranging from 90 to 125 microns2), but some larger ones (500-600 microns2) were also found. These cells displayed no obvious clustering but were significantly more numerous in the caudate nucleus than in the putamen; their number was also markedly greater at caudal than at rostral striatal levels. A moderate number of evenly distributed positive axon terminals were visible in both the caudate nucleus and the putamen. In the ventral striatum, GABA-immunoreactive nerve cell bodies and axon terminals were seen in fair number within the nucleus accumbens and in the deep layers of the olfactory tubercle. Many positive terminals but no somata were found in the islands of Calleja. In the globus pallidus, virtually all nerve cell bodies were GABA-immunoreactive and the neuropil exhibited a multitude of positive terminals. In the substantia innominata, clusters of small, globular GABA-immunoreactive somata were scattered among aggregates of larger, nonimmunoreactive neurons belonging to the nucleus basalis, and the whole region showed a low to moderate number of evenly spread GABA-positive terminals. In the subthalamic nucleus, nerve cell bodies were generally surrounded by several GABA-positive terminals but were not themselves immunoreactive. The substantia nigra showed many GABA-immunoreactive somata, which predominated in the pars lateralis and diminished progressively in number along the lateromedial axis of the pars reticulata. These cells formed a rather pleomorphic group comprising round, fusiform, or polygonal elements of relatively large size (sectional area ranging from 200 to 800 microns2). In the pars compacta and ventral tegmental area, a few GABA-immunoreactive neurons of small size were dispersed among larger, unreactive neurons. In both pars lateralis and pars reticulata of the substantia nigra, the number of GABA-positive terminals was high and their distribution was rather uniform; a smaller number were visible in the pars compacta of the substantia nigra and in the ventral tegmental area. The present results demonstrate that GABA-containing neurons are widely and heterogeneously distributed in the various components of the squirrel monkey's basal ganglia.(ABSTRACT TRUNCATED AT 400 WORDS)

Localization of L-glutamate decarboxylase and GABA transaminase immunoreactivity in the sympathetic ganglia of the rat

The location of L-glutamate decarboxylase and gamma-aminobutyrate (GABA)-transaminase immunoreactivity in the superior cervical ganglion and in the coeliac-superior mesenteric ganglion complex of the rat was studied by an indirect immunofluorescence method and by immunoelectron microscopy, with specific antisera raised in rabbits against the corresponding enzymes. In light microscopy, several glutamate decarboxylase- or GABA-transaminase-immunoreactive principal nerve cells were detected in the superior cervical ganglion and coeliac-superior mesenteric ganglion complex. In addition, numerous small cells in both the superior cervical ganglion and coeliac-superior mesenteric ganglion complex showed intense immunoreactivity to glutamate decarboxylase or GABA-transaminase. The small cells were 10-20 micron in diameter and resembled in size and morphology the small intensely fluorescent cells. In consecutive sections, the small glutamate decarboxylase-immunoreactive cell clusters also showed immunoreactivity to tyrosine hydroxylase, suggesting that these cells contain the enzymes for both GABA and catecholamine synthesis. In the superior cervical ganglion and in the coeliac-superior mesenteric ganglion complex, GABA-transaminase immunoreactivity was also localized in fibre-like processes around and between the principal nerve cells, in nerve trunks traversing the ganglia, and around or in close contact with ganglionic blood vessels. Furthermore, GABA-transaminase immunoreactivity was observed in fibre-like structures close to the capsule of the ganglia. Division of the preganglionic nerve trunk of the superior cervical ganglion caused no detectable change in GABA-transaminase immunoreactivity in the ganglion. In immunoelectron microscopy of the superior cervical ganglion, GABA-transaminase immunoreactivity was localized in nerve fibres in association with neurotubules. A large number of GABA-transaminase labelled principal nerve cells were detected, containing immunoreactivity evenly distributed in their cytoplasm. GABA-transaminase immunoreactivity was also observed in satellite cells and their processes in the superior cervical ganglion. The present immunocytochemical results provide evidence that the rat sympathetic ganglia contain an intrinsic neuronal system showing histochemical markers for GABA synthesis and inactivation, but its functional role in the modulation of ganglionic neurotransmission remains to be established.

Biochemical and morphological studies on GABA neurons in reaggregate culture

Dissociated cells from the 14-day fetal mouse corpus striatum (CS), rostral mesencephalic tegmentum (RMT) and tectum were reaggregated in rotation-mediated cultures in the following combinations: CS alone, RMT-CS, RMT-tectum, and tectum alone. Reaggregates were cultured for 1-4 weeks. An even distribution of gamma-aminobutyric acid (GABA)-positive cells was observed in all the reaggregate combinations that were cultured for 1 and 2 weeks. With increasing time in culture, cellular staining was decreased while positive fiber staining increased. CS and RMT-CS co-cultures increased their capacity to take up [3H]GABA with time in culture. All reaggregates reached a maximum uptake/accumulation capacity of 30-40 pmol/mg protein/30 min, by 4 weeks in vitro. There were no significant differences between the various co-aggregate combinations in the accumulation capacity. [3H]GABA accumulation in the reaggregates was largely blocked by the putative neuronal GABA uptake inhibitor, diaminobutyric acid, and was inhibited to a much lesser degree by the putative glial uptake inhibitor beta-alanine. All reaggregates released [3H]GABA to 70 mM potassium depolarization, in a calcium-dependent manner. One-three week CS reaggregates released more [3H]GABA in response to the potassium-induced depolarization than RMT-CS co-cultures. Since nigral dopamine neurons within the RMT proliferate processes and actively release dopamine only when co-cultured with CS target cells, it is suggested that these dopamine neurons might chronically inhibit striatal GABA neurons in the RMT-CS co-cultures, thereby depressing stimulated release of [3H]GABA.

Studies of neurotransmitter chemistry of central nervous system neurons in primary tissue culture

Primary tissue culture methods have been applied to various areas of the central nervous system, including cerebral cortex, spinal cord, cerebellum, hippocampus, hypothalamus, striatum, mesencephalon, lower brain stem and retina. Experimental studies in vitro involving central neurotransmission are discussed here. Information gleaned from such studies impacts on neurotransmitter identification, neuronal development, patterns of receptor distribution, peptidergic transmission, transmitter metabolism, synaptogenesis and the regulation of synaptic development.

Glutamate decarboxylase-immunoreactive structures in the rat neostriatum: a correlated light and electron microscopic study including a combination of Golgi impregnation with immunocytochemistry

An antibody to glutamate decarboxylase has been used in a light and electron microscopic study of the neostriatum of rats that had received intracerebral injections of colchicine. In the light microscope, neuronal perikarya and small punctate structures that displayed immunoreactivity were found. The perikarya could be divided into two classes based on their sizes: small-to-medium-sized and large. Proximal dendrites, axon initial segments, and axon collaterals were occasionally stained. When the nuclei of the neurons were visible, they possessed indentations. The immunoreactive punctate structures were spread evenly throughout the neostriatum but occasionally were associated with immunoreactive and nonimmunoreactive perikarya. When the same sections were examined in the electron microscope, the small-to-medium-sized immunoreactive perikarya were found to be similar in morphology and synaptic input to a class of Golgi-impregnated neuron that has been previously shown to accumulate locally administered, radiolabelled gamma-aminobutyric acid. Neurons with the ultrastructural characteristics of typical striatonigral neurons did not display immunoreactivity. As neurons in this pathway probably contain gamma-aminobutyric acid, it is possible that our procedure or our antibody does not stain all gamma-aminobutyric-acid-containing structures in the neostriatum. A total of 404 immunoreactive punctate structures were examined by correlated light and electron microscopy or by electron microscopy alone. They were identified as immunoreactive axonal boutons and each of them, when examined in serial sections, displayed typical synaptic specialisations. Membrane specialisations were always of the symmetrical type. At least five distinct targets of the immunoreactive terminals were identified: neurons that were themselves immunoreactive for glutamate decarboxylase; the immunoreactive terminals made synaptic contact with all parts of the neurons examined, i.e., perikarya, proximal dendrites, and axon initial segments. Neurons identified by Golgi impregnation of the same sections as medium-sized and densely spiny; the immunoreactive terminals made contact predominantly with the perikarya and dendritic shafts. Large neurons found only in the ventral caudate-putamen, whose somata and dendrites were ensheathed in immunoreactive terminals. Medium-sized nonimmunoreactive perikarya that possessed nuclear indentations. Large nonimmunoreactive perikarya that had the typical structural features of striatal cholinergic neurons.(ABSTRACT TRUNCATED AT 250 WORDS)

The section-Golgi-impregnation procedure--3. Combination of Golgi-impregnation with enzyme histochemistry and electron microscopy to characterize acetylcholinesterase-containing neurons in the rat neostriatum

Three morphologically distinct types of neuron that contain acetylcholinesterase have been distinguished by Golgi-impregnation of sections of the rat neostriatum that had been incubated to reveal acetylcholinesterase activity. The neuron that stained most intensely for acetylcholinesterase was a large cell, with smooth or sparsely spiny dendrites; the axon of one these neurons was partially impregnated by the Golgi stain and had local axon collaterals (type 1). Another acetylcholinesterase-containing neuron had a small to medium-size cell body with long sparsely spiny dendrites emerging from opposite poles (type 2). The third type of neuron that contained acetylcholinesterase was medium to large size and had many primary, sparsely spiny dendrites that branched frequently (type 3). Examination of the same Golgi-impregnated, acetylcholinesterase-stained neurons that had been studied in the light microscope by electron microscopy allowed us to distinguish several other differences between the three types of neuron. Whereas all three types had acetylcholinesterase reaction product in the endoplasmic reticulum and along the nuclear envelope, only neurons of type 1 displayed reaction product in the Golgi apparatus. All three types of neuron received synaptic input, mainly along their dendrites. It is concluded that the combination of Golgi-impregnation with histochemical procedures that demonstrate endogenous enzyme activity can be applied to reveal the morphological characteristics, synaptic input and local synaptic output of neurons with specific biochemical properties.

An immunohistochemical study on the location of GABAergic neurons in rat septum

Antisera against L-glutamate decarboxylase (GAD), the synthesizing enzyme of gamma-aminobutyric acid (GABA) were used to locate GABAergic neurons and nerve terminals in the septal complex of the rat by using the peroxidase-antiperoxidase method. Varying densities of immunoreactive terminals were observed in saline-treated rats but nerve cell bodies were only demonstrated after interventricular or intraseptal injections of colchicine. Small and medium-sized GAD-positive neurons were found in lateral septal nuclei, the largest number of these cells being in the pars dorsalis, and in the bed nucleus of the stria terminalis. Several GAD-immunoreactive neurons were located in the medial septal nucleus and the nucleus of the diagonal band of Broca (DB), where the cells were larger in the ventral than dorsal parts of the region. In the medial septal nucleus and in DB the GAD-positive cell bodies were distributed similarly to cholinergic neurons. Large GAD-positive neurons were also found in the septofimbrial nucleus. Intense immunoreactivity in nerve terminals was observed in the lateral septal nucleus, around the island of Calleja magna, between the DB and nucleus accumbens, and in the septofimbrial and triangular septal nuclei. In contrast, the medial septal nucleus, the DB, and the bed nucleus of the stria terminalis only showed weak to moderate immunoreactivity. These results provide direct morphological evidence for the presence of neurons capable of synthesizing GABA in septal nuclei. We suggest that there are two different GABAergic neuronal systems operating in the septum: a population of small cells in the lateral septal nucleus and a group of large cells in the medial septum and DB.

A type of aspiny neuron in the rat neostriatum accumulates [3H]gamma-aminobutyric acid: combination of Golgi-staining, autoradiography, and electron microscopy

Light microscopic autoradiography was used to identify cells in the neostriatum that became labelled after the local injection of [3H]gamma-aminobutyrate (GABA). The GABA-accumulating cells comprised up to 15% of the total population of neurons. Thirty-seven of these cells were examined in the electron microscope and it was found that they all had similar cytological characteristics, i.e., prominent nuclear indentations, a moderate volume of cytoplasm, rich in organelles, and sparse synaptic input to the perikaryon. Nine of the cells that had accumulated GABA were also impregnated following Golgi staining. These Golgi-impregnated neurons were of medium size and all had dendrites that were aspiny, often varicose, and that occasionally followed a recurving path. After gold toning, the Golgi-impregnated, GABA-accumulating neurons were examined in the electron microscope and were found to receive boutons forming symmetrical or asymmetrical synaptic contacts on their somata and dendrites; the symmetrical synapses were most common on the cell body and proximal dendrites, while the distal dendrites mainly received boutons forming asymmetrical contacts. We conclude that one type of GABAergic neuron in the neostriatum is a type of medium-sized aspiny neuron and that this neuron is likely to receive synaptic input both from neurons within the striatum and from neurons in distant brain regions. We suggest that this neuron is a local circuit neuron in the neostriatum since its morphological features are quite distinct from those of identified projecting neurons.