Neurons in the cat and monkey cerebral cortex were stained immunocytochemically for glutamic acid decarboxylase (GluDCase; L-glutamate 1-carboxy-lyase, EC 4.1. GluDCase was co-localized with CCK, SRIF, or NPY not only in cell somata, but also in small punctate structures, which are likely to be axon terminals. From the data gained in previous electron microscopic studies, we postulate that neurons displaying GluDCase-and CCK-like immunoreactivity are a class separate from those displaying GluDCase-and SRIF-like immunoreactivity. NPY, however, is co-localized with SRIF immunoreactivity. These results imply that classes of cortical interneuron contain a conventional neurotransmitter (y-aminobutyric acid) and a neuromodulator (one of the peptides).
We have examined the distribution of neurons and terminals that are immunoreactive for glutamic acid decarboxylase (GAD), the synthesizing enzyme for the inhibitory neurotransmitter gamma-aminobutyric acid within the lateral geniculate nucleus of the cat. We estimate that GAD-positive neurons constitute approximately one-fourth of the neurons in all layers of the lateral geniculate nucleus and in the medial interlaminar nucleus (MIN). In addition, almost all of the neurons within the perigeniculate nucleus are GAD-positive. The mean size of GAD-positive cell bodies is significantly smaller than the mean size of unlabeled neurons in all subdivisions of the lateral geniculate nucleus. GAD-positive neurons have thick primary dendrites which are associated with thin lightly immunoreactive processes that give rise to clusters of GAD-positive terminals. Clusters of GAD-positive terminals are prominent in lamina A, A1, magnocellular C, and MIN but are rare in the parvocellular C laminae. Within the A laminae, GAD immunoreactivity is found within vesicle-containing profiles of the synaptic glomerulus lying postsynaptic to optic axon terminals and presynaptic to unlabeled dendritic profiles. GAD-positive neurons in the A laminae are distinguished from other small to medium-sized neurons by their failure to label following injections of HRP into visual cortex and by their lack of cytoplasmic laminated body. These results support the idea that GAD-positive neurons constitute a distinct population of neurons in the lateral geniculate nucleus of the cat; a population which has a number of features in common with previous descriptions of presumed local circuit neurons based on Golgi staining.
Antisera to glutamic acid decarboxylase (GAD) and gamma-aminobutyric acid (GABA) have been used to characterize the morphology and distribution of presumed GABAergic neurons and axon terminals within the macaque striate cortex. Despite some differences in the relative sensitivity of these antisera for detecting cell bodies and terminals, the overall patterns of labeling appear quite similar. GABAergic axon terminals are particularly prominent in zones known to receive the bulk of the projections from the lateral geniculate nucleus; laminae 4C, 4A, and the cytochrome-rich patches of lamina 3. In lamina 4A, GABAergic terminals are distributed in a honeycomb pattern which appears to match closely the spatial pattern of geniculate terminations in this region. Quantitative analysis of axon terminals that contain flat vesicles and form symmetric synaptic contacts (FS terminals) in lamina 4C beta and in lamina 5 suggest that the prominence of GAD and GABA axon terminal labeling in the geniculate recipient zones is due, at least in part, to the presence of larger GABAergic axon terminals in these regions. GABAergic cell bodies and their initial dendritic segments display morphological features characteristic of nonpyramidal neurons and are found in all layers of striate cortex. The density of GAD and GABA immunoreactive neurons is greatest in laminae 2-3A, 4A, and 4C beta. The distribution of GABAergic neurons within lamina 3 does not appear to be correlated with the patchy distribution of cytochrome oxidase in this region; i.e., there is no significant difference in the density of GAD and GABA immunoreactive neurons in cytochrome-rich and cytochrome-poor regions of lamina 3. Counts of labeled and unlabeled neurons indicate that GABA immunoreactive neurons make up at least 15% of the neurons in striate cortex. Layer 1 is distinct from the other cortical layers by virtue of its high percentage (77-81%) of GABAergic neurons. Among the other layers, the proportion of GABAergic neurons varies from roughly 20% in laminae 2-3A to 12% in laminae 5 and 6. Finally, there are conspicuous laminar differences in the size and dendritic arrangement of GAD and GABA immunoreactive neurons. Lamina 4C alpha and lamina 6 are distinguished from the other layers by the presence of populations of large GABAergic neurons, some of which have horizontally spreading dendritic processes. GABAergic neurons within the superficial layers are significantly smaller and the majority appear to have vertically oriented dendritic processes.(ABSTRACT TRUNCATED AT 400 WORDS)
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