RESUMEN
The primary amino acid sequences of the kainate binding proteins from the amphibian and avian central nervous systems are homologous with the functional alpha-amino-3-hydroxyl-5-methyl-isoxazole-4-propionate receptors that have been cloned from rat brain. In this study, we have analysed the anatomical and subcellular distribution of the alpha-amino-3-hydroxyl-5-methyl-isoxazole-4-propionate receptors in the rat hippocampus and cerebellum, using a monoclonal antibody that was raised against a kainate binding protein purified from frog brain. Immunoblots of rat hippocampus and cerebellum, and membranes from COS cells transfected with rat brain alpha-amino-3-hydroxyl-5-methyl-isoxazole-4-propionate receptor cDNAs (GluR1, GluR2, or GluR3) showed a major immunoreactive band migrating at a relative molecular weight of 107,000. In the cerebellum, an additional immunoreactive protein of approximately 128,000 mol. wt was also seen on immunoblots probed with the antibody. The distribution of this protein is apparently restricted to the cerebellum since the 128,000 mol. wt band was not present in other brain areas examined. The identity of the 128,000 mol. wt cerebellar protein is not known. Immunocytochemical analyses of the hippocampus demonstrated that alpha-amino-3-hydroxy-5-methyl-isoxazole-4-propionate receptor subunits are present in the cell bodies and dendrites of pyramidal cells. The granule cells were also immunostained. All of the pyramidal cell subfields were heavily labeled. In the pyramidal cell bodies, a high level of immunoreactivity was observed throughout the cytoplasm. In the cerebellum, the Purkinje cell bodies and dendrites also displayed very high levels of immunoreactivity. In addition to the Purkinje neurons, the Bergmann glia and some Golgi neurons were clearly immunostained. Subcellular fractionation and lesioning experiments using the excitotoxin domoic acid indicated that the alpha-amino-3-hydroxyl-5-methyl-isoxazole-4-propionate receptor subunits were associated with postsynaptic membranes. Direct visualization of the immunoreactivity using electron microscopy confirmed the postsynaptic localization of the staining in the dendritic areas in both the hippocampus and the cerebellum. Thus, unlike the kainate binding proteins, which are found primarily extrasynaptically in the frog and on glial cells in the chicken cerebellum, the GluR1, GluR2, and GluR3 receptor subunits are localized to the postsynaptic membrane in the dendrites of neurons in the rat central nervous system.
Asunto(s)
Anticuerpos Monoclonales , Cerebelo/metabolismo , Hipocampo/metabolismo , Receptores de Neurotransmisores/análisis , Amígdala del Cerebelo/efectos de los fármacos , Amígdala del Cerebelo/fisiología , Animales , Cerebelo/citología , Cromatografía de Afinidad , Electroforesis en Gel de Poliacrilamida , Hipocampo/citología , Hipocampo/efectos de los fármacos , Immunoblotting , Inmunohistoquímica , Ácido Kaínico/análogos & derivados , Masculino , Peso Molecular , Neurotoxinas/toxicidad , Oxadiazoles/metabolismo , Tractos Piramidales/citología , Tractos Piramidales/metabolismo , Ratas , Ratas Wistar , Receptores AMPA , Receptores de Neurotransmisores/aislamiento & purificación , Receptores de Neurotransmisores/metabolismoRESUMEN
Excitatory amino acids (EAA) are major neurotransmitters in the vertebrate central nervous system. EAA receptors have been divided into three major subtypes on the basis of electrophysiological and ligand binding studies: N-methyl-D-aspartate, kainate, and quisqualate receptors. To understand their molecular properties, we undertook a project aimed at isolation and cloning of these receptor subtypes. We purified a kainate binding protein (KBP) from frog brain, in which kainate binding sites are about fortyfold more abundant than in rat brain, using domoic acid affinity chromatography, and made monoclonal and polyclonal antibodies to the purified protein. These antibodies immunoprecipitate the frog KBP but not KBPs from other species. Immunocytochemical analyses show that KBP has a synaptic and extrasynaptic localization in frog optic tectum, with most labeling being extrasynaptic. The cDNA encoding frog brain KBP was isolated by screening a frog brain cDNA library with oligonucleotide probes that were based on the amino acid sequence of the purified protein. The deduced amino acid sequence of the KBP has a hydrophobic profile similar to those of other ligand-gated ion channel subunits, such as the nicotinic acetylcholine receptor, the GABAA receptor, and the glycine receptor. Frog brain KBP is very similar (36% amino acid identity to the carboxyl half) to rat brain kainate receptor, suggesting that these two proteins evolved from a common ancestor. The function of KBP in frog brain remains a major question. Preliminary results showed that Xenopus laevis oocytes injected with KBP RNA did not produce a detectable electrophysiological response when perfused with kainate. These results suggest that additional subunits may be required to form a functional receptor or that KBP is not functionally related to a neurotransmitter receptor.
Asunto(s)
Anuros , Química Encefálica , Clonación Molecular , Receptores de Neurotransmisores , Secuencia de Aminoácidos , Animales , ADN/genética , ADN/aislamiento & purificación , Datos de Secuencia Molecular , Receptores de Ácido Kaínico , Receptores de Neurotransmisores/análisis , Receptores de Neurotransmisores/química , Receptores de Neurotransmisores/genéticaRESUMEN
A frog brain kainic acid receptor (KAR) was studied using monoclonal and polyclonal antibodies against the affinity-purified receptor. Immunocytochemistry was done on sections of the frog CNS, and the distribution of immunostaining was compared with the distribution of high- and low-affinity 3H-kainic acid (3H-KA) binding sites determined with in vitro receptor autoradiography. These studies showed (1) similar distributions of high- and low-affinity 3H-KA binding sites, (2) identical patterns of immunostaining with the polyclonal antibodies and 2 monoclonal antibodies, and (3) an antibody binding distribution which closely matched that of 3H-KA binding, suggesting that the antibodies recognize the primary KAR in frog brain. In the frog brain, an anteroposterior gradient of immunostaining was observed, with the telencephalon intensely and uniformly immunoreactive. Other areas intensely immunoreactive included the cerebellum, the infundibulum, the tectal and posterior commissures, and the laminar nucleus of the torus semicircularis. The optic tectum showed selective staining of the plexiform layers 3 and 5-7. The pattern of staining was punctate and appeared to be associated with nerve fibers, among them dendritic arborizations. Electron microscopic observations showed staining at the cytoplasmic side of postsynaptic membranes. Extra-synaptic staining was observed as patches on the surface of unmyelinated nerve processes.
Asunto(s)
Anticuerpos Monoclonales , Sistema Nervioso Central/metabolismo , Rana pipiens/metabolismo , Receptores de Neurotransmisores/metabolismo , Animales , Sitios de Unión , Sistema Nervioso Central/ultraestructura , Inmunohistoquímica , Microscopía Electrónica , Receptores de Ácido Kaínico , Coloración y Etiquetado , Colículos Superiores/metabolismo , Distribución TisularRESUMEN
Glycine appears to be a major inhibitory neurotransmitter in the cochlear nucleus. In order to determine more precisely the distribution of glycinergic synapses, we have studied the immunocytochemical distribution of the glycine postsynaptic receptor. Two monoclonal antibodies were used, Gly Rec Ab 2, which recognizes the 48kD polypeptide and Gly Rec Ab 7, which primarily recognizes the 93kD subunit of the glycine receptor complex. At the light microscopic level, glycine receptor immunoreactivity was found throughout the ventral cochlear nucleus with a punctuate distribution often found outlining large cell bodies. Indistinguishable patterns of staining were obtained with the two antibodies. Ultrastructural localization was done with Gly Rec Ab 7 because immunoreactivity remained after fixation with glutaraldehyde containing solutions. At the ultrastructural level, immunoreactivity was concentrated at postsynaptic sites on dendrites and cell bodies. In the anteroventral cochlear nucleus, neurons identified as spherical cells contained numerous inmunoreactive synapses on their cell bodies, whereas most immunoreactive synapses on stellate cells were on their proximal dendrites. In the posteroventral cochlear nucleus, neurons identified as octopus cells were immunoreactive on their cell bodies and proximal dendrites. In the granule cell layer, immunoreactivity was found only in the neuropile. Throughout the ventral cochlear nucleus, glycine receptor immunoreactivity was found postsynaptic to terminals containing flattened synaptic vesicles as well as those containing oval/pleomorphic synaptic vesicles.
Asunto(s)
Nervio Coclear/análisis , Receptores de Neurotransmisores/análisis , Rombencéfalo/análisis , Animales , Anticuerpos Monoclonales , Nervio Coclear/ultraestructura , Femenino , Cobayas , Inmunohistoquímica , Microscopía Electrónica , Peso Molecular , Receptores de Glicina , Rombencéfalo/ultraestructura , Sinapsis/análisis , Sinapsis/ultraestructura , Vesículas Sinápticas/ultraestructuraRESUMEN
The immunocytochemical distribution of gamma-aminobutyric acid (GABA) was studied by electron microscopy in the anteroventral cochlear nucleus (AVCN) of the guinea pig using affinity-purified antibodies made against GABA conjugated to bovine serum albumin. Our observations confirm that spherical cells are the predominant cell type in the guinea pig AVCN and receive numerous axosomatic contacts (Schwartz and Gulley, (1978) J. Anat. 153, 489-508). Stellate cells receive few axosomatic contacts. Electron microscopic immunocytochemistry shows that GABA immunoreactivity is present in synaptic terminals in the AVCN. Of the several classes of presynaptic terminals present in the AVCN as characterized by vesicle type (large round; oval/pleomorphic; flat; small round) only those containing oval/pleomorphic vesicles were GABA-immunoreactive. However, GABA immunoreactivity may not be present in all these terminals because some oval/pleomorphic terminals are unlabelled. Immunoreactive terminals are widespread in the AVCN; they are abundant on spherical cell bodies, rarely seen on stellate cell bodies and are also found scattered throughout the neuropile.
Asunto(s)
Nervio Coclear/ultraestructura , Ácido gamma-Aminobutírico/metabolismo , Animales , Cobayas , Microscopía Electrónica , Terminaciones Nerviosas/ultraestructura , Neurotransmisores/fisiología , Receptores de GABA-A/metabolismo , Receptores de Neurotransmisores/ultraestructura , Ácido gamma-Aminobutírico/fisiologíaRESUMEN
Several genetically distinct color phases of mink, which all show an abnormal reduction of pigment in the retinal pigment epithelium and which also show abnormalities of the retinofugal pathways, have been studied. Autoradiographic methods have been used to demonstrate the retino-geniculate pathways, and retrograde degeneration or the retrograde transport of horseradish peroxidase has been used for the geniculo-cortical pathways. The retino-geniculate abnormality is mild in some of the color phases and extremely severe in others, but within any one color phase the variability is relatively low. Although the severity of the abnormality varies between color phases, a rather specific pattern of abnormal geniculate innervation is recognizable for mink in general and this is distinct from that found in Siamese cats. In the abnormal mink the size of geniculate lamina A1 is reduced and there is an abnormal crossed input going to the intermediate sectors of this reduced layer. Layer C1 also receives an abnormal crossed input, but this is more variable than that going to A1 and there appears to be little correspondence, retinotopically, between the normal inputs to layers A1 and C1. In some of the abnormal mink there are interruptions within the cytoarchitectionically definable layer A1, and opposite these gaps reduplications of layer A are commonly seen, as though there is an intrinsic geniculate mechanism for generating the characteristic multilaminar geniculate structure. However, there are also numerous examples of fusions between layers receiving afferents from the same eye, and these demonstrate that the development of geniculate lamination must also be under the influence of the retinal inputs. The geniculo-cortical pathway shows a normal topography in most of the mink. Abnormal geniculo-cortical projections, comparable to the "Boston" pattern of Siamese cats are extremely rare, and their occurrence could not be correlated with the severity of the retino-geniculate abnormality or with the laminar pattern in the lateral geniculate nucleus. We suggest that the development of one or the other pattern of geniculo-cortical projection may depend upon the relative timing of the two mechanisms that produce the geniculate lamination.