Nonpyramidal Neurons Research Articles

High‐resolution Scatchard analysis shows D1 receptor binding on pyramidal and nonpyramidal neurons

High‐resolution Scatchard analysis shows D1 receptor binding on pyramidal and nonpyramidal neurons

Model generation and testing to probe neural circuitry in the cingulate cortex of postmortem schizophrenic brain.

In the past decade, there has been increased interest in whether discreet alterations of neural circuitry might play a role in the pathophysiology of schizophrenia. In the absence of a readily identifiable histopathology, a variety of sophisticated neurobiological approaches is being applied to the study of this disorder. In one series of investigations, subtle abnormalities have been detected in the anterior cingulate cortex-layer II (ACCx-II) of schizophrenia patients. One of these studies suggested a reduction of nonpyramidal neurons in schizophrenia patients, and it was postulated that this change could give rise to a relative increase of dopaminergic inputs to the remaining gamma-aminobutyric acid (GABA) cells. Although empiric evidence in support of this hypothesis was obtained, a subsequent post hoc analysis, described in this report, has suggested that this change could have occurred irrespective of whether GABA cells are reduced in number. A shift of cortical dopamine afferents from pyramidal to nonpyramidal neurons in ACCx-II seems to provide a more plausible explanation for such a "miswiring." These findings support critical use of model generation and testing as powerful tools for unraveling the nature of altered neural circuitry in postmortem schizophrenic brain.

Neurochemical organization of the macaque striate cortex: Correlation of cytochrome oxidase with Na +K +ATPase, NADPH-diaphorase, nitric oxide synthase, and N-Methyl- d-aspartate receptor subunit 1

Previously, we found that cytochrome oxidase-rich zones in the supragranular layers of the macaque striate cortex had more asymmetric, glutamate-immunoreactive synapses than the surrounding, cytochrome oxidase-poor regions. A major glutamate receptor family is N-methyl- D-aspartate, which is implicated in the stimulation of nitric oxide synthase and in the production of nitric oxide, a gaseous intra- and inter-cellular messenger. To determine if energy-generating and energy-utilizing enzymes bore any spatial relationship with neurochemicals associated with glutamatergic neurotransmission in the monkey visual cortex, serial cortical sections were processed histochemically for cytochrome oxidase and NADPH-diaphorase, and immunohistochemically for sodium/potassium-ATPase, nitric oxide synthase, and N-methyl- D-aspartate receptor subunit 1 protein, respectively. The general patterns were similar among the five neurochemicals, with layers 4C, 6 and supragranular puffs being labelled, although the intensity of labelling differed among them. Monocular impulse blockade with tetrodotoxin for two to four weeks induced a down-regulation of all five neurochemicals not only in deprived layer 4C ocular dominance columns, but also in deprived rows of puffs. Thus, the regulation of all five neurochemicals in the mature visual cortex is activity-dependent. Combined cytochrome oxidase histochemistry and nitric oxide synthase immunohistochemistry in the same sections revealed that double-labelled cells were primarily medium-sized non-pyramidals in various cortical layers. Likewise, those that were double-labelled by N-methyl- D-aspartate receptor subunit 1 immunohistochemistry and nitric oxide synthase immunogold silver staining in the same sections were of the medium-sized non-pyramidal neurons. At the ultrastructural level, combined cytochrome oxidase cytochemistry and postembedding immnnogold labelling for nitric oxide synthase showed that immunogold particles for nitric oxide synthase were more heavily concentrated in cytochrome oxidase-rich type C cells. These medium-sized non-pyramidal cells were previously found to be gamma aminobutyric acid-immunoreactive and received both gamma aminobutyric acid- and glutamate-immunoreactive axosomatic synapses. Thus, our results are consistent with an enrichment of excitatory synaptic interactions in metabolically active regions of the primate visual cortex that involves glutamate-related neurochemicals, such as N-methyl- D-aspartate receptors and nitric oxide synthase. These interactions impose a higher energy demand under normal conditions and are down-regulated by retinal impulse blockade.

Labeling of pyramidal and nonpyramidal neurons with lectin Vicia villosa during postnatal development of the guinea pig

Labeling of cortical neurons with a lectin, Vicia villosa (VVA), was investigated in guinea pigs aged 1 day old to adult. Lectin histochemistry revealed a perineuronal sheath, which outlined the cell bodies, apical dendrites, and axon initial segments, in distinct populations of pyramidal and nonpyramidal neurons. Their laminar positions were segregated, with the pyramidal neurons confined to layer 5 and the nonpyramidal neurons distributed mainly in layers 3-5. The VVA-labeled substance(s) was detected at the interfaces between neurons and cellular elements present in the perisynaptic region, including glial processes and fine axons. However, it was excluded from synaptic clefts of presynaptic terminals. Double immunohistochemistry revealed that most of the VVA-labeled neurons were also labeled perineuronally with a monoclonal antibody, Cat 301, and vice versa. Dendritic patterns of the VVA-labeled pyramidal neurons were studied further by intracellular injection of Lucifer yellow into fixed slices. Apical dendrites had a considerable thickness before arborizing into a few daughter branches in layer 3 or 4, suggesting a morphological resemblance to intrinsic, bursting pyramidal neurons defined physiologically in vitro. During postnatal development, there was a global spatiotemporal pattern in the onset of VVA labeling of the cortical neurons. The labeling progressed from medial and posterior cortical areas, which are closely related to the hippocampal formation, to more lateral and anterior areas, which are less closely related. The labeling patter thus tends to follow the order of the phylogenetical development of the isocortex.

Labeling of pyramidal and nonpyramidal neurons with lectin Vicia villosa during postnatal development of the guinea pig

Labeling of pyramidal and nonpyramidal neurons with lectin Vicia villosa during postnatal development of the guinea pig

Labeling of pyramidal and nonpyramidal neurons with lectin Vicia villosa during postnatal development of the guinea pig

Labeling of pyramidal and nonpyramidal neurons with lectin Vicia villosa during postnatal development of the guinea pig

Chronic blockade of glutamate-mediated bioelectric activity in long-term organotypic neocortical explants differentially effects pyramidal/non-pyramidal dendritic morphology

Dendritic/axonal growth has been examined in long-term organotypic neocortical explants taken from neonatal rat pups and grown either as isolated slices or as co-cultures. The quantitative light microscopic measurement of dendritic and axonal branching patterns within both types of explants was carried out on Golgi-stained materials. Spontaneous bioelectric activity (SBA) was blocked within both types of explants using a combination of APV and DNQX, NMDA and non-NMDA receptor antagonists, respectively. No extracellularly measurable SBA was observed to occur in the silenced explants in the presence of both antagonists but reappeared following wash-out with control medium. In both control and silenced explants, the overall cellular organization of the slice was maintained throughout the culturing period, with distinguishable pyramidal and non-pyramidal neurons located within the same layers and with the same orientations as observed in situ. The major findings of the present study show the following. (i) Pyramidal neurones chronically exposed to APV/DNQX exhibited no basal dendritic growth in co-cultured explants, while growth of apical dendritic lengths was similar to control values in the absence of SBA. (ii) Pyramidal neurones, nonetheless, exhibited significant terminal segment growth under SBA blockade which was correlated with a concomitant decrease in number of basal dendrites. (iii) Axonal growth in co-cultures was not sustained in silenced pyramidal neurones. (iv) Non-pyramidal neurones showed significant total dendritic and axonal growth in co-cultures following APV/DNQX treatment. (v) Non-pyramidal cells in co-cultures experienced an increase in terminal segment length at 2 weeks which declined in the third week. This increase–decrease was correlated with a decrease–increase in the total number of dendritic segments during the second and third weeks, respectively. (vi) In isolated explants the only departure from control growth curves was a significant increase in terminal segment length which was offset by a similar decrease in number of dendritic segments under APV/DNQX growth conditions. Thus the chronic loss of glutamate-mediated SBA differentially effected pyramidal and non-pyramidal neurones in isolated and co-cultured explants, with pyramidal neurones experiencing the more pronounced effects. We conclude that SBA effects the dynamics of neuritic elongation and branching and that these changes are most dramatically seen in co-cultures which cross-innervate one another, presumably via pyramidal axons. We hypothesize that the activity-dependent changes associated with reduction in pyramidal dendritic and axonal growth may be associated with neurotrophin receptor production/maturation.

The expression pattern of the orphan nuclear receptor RORbeta in the developing and adult rat nervous system suggests a role in the processing of sensory information and in circadian rhythm.

RORbeta is an orphan nuclear receptor related to retinoid and thyroid hormone receptors and is exclusively expressed in the central nervous system (CNS). Here we present an in situ hybridization analysis of the distribution of RORbeta mRNA in the developing and adult rat CNS. The receptor localizes to areas involved in the processing of sensory information. In the cerebral cortex, RORbeta mRNA was exclusively detected in non-pyramidal neurons of layer IV and, less so, layer V. The highest expression was found in primary sensory cortices. In the thalamus highest RORbeta expression was found in the sensory relay nuclei projecting to the respective cortical areas. In contrast, sensory projection neurons in the periphery, for example retinal ganglion cells and neurons of the sensory ganglia showed only little RORbeta expression. RORbeta is also expressed in areas involved in the generation and maintenance of circadian rhythms - the suprachiasmatic nucleus, the pineal gland and the retina. In the latter two tissues, RORbeta mRNA abundance oscillates with circadian rhythmicity peaking during the hours of darkness. RORbeta mRNA could not be detected in striatum, hippocampus, cerebellum, the motor nuclei of the cranial nerves or the ventral part of the spinal cord. During development, RORbeta is expressed in many areas as early as embryonic day (E) 15, anticipating the distribution pattern in the adult. Our data suggest that RORbeta regulates genes whose products play essential roles in the context of sensory input integration as well as in the context of circadian timing system.

Distribution of parvalbumin‐, calretinin‐, and calbindin‐D28k–immunoreactive neurons and fibers in the human entorhinal cortex

Parvalbumin, calretinin, and calbindin-D28k are calcium-binding proteins that are located in largely nonoverlapping neuronal populations in the brain. The authors studied the distribution of parvalbumin-, calretinin-, and calbindin-D28k–immunoreactive (ir) cells, fibers, terminals, and neuropil in the eight subfields of the human entorhinal cortex. The distribution of each of the three calcium-binding proteins largely followed the cytoarchitectonic borders of the eight entorhinal subfields, although the regional and laminar distributions of the three proteins were segregated rather than overlapping. The highest density of parvalbumin-ir neurons and terminals was found in the caudal and lateral subfields of the entorhinal cortex. Calretinin and calbindin-D28k immunoreactivities were high rostromedially, although a large number of calretinin and calbindin-D28k neurons were also found in the caudal subfields. All parvalbumin-ir cells had a morphological appearance of nonpyramidal neurons. Parvalbumin-ir terminals formed basket-like formations around unstained somata and cartridges, suggesting that parvalbumin neurons compose a subpopulation of gamma-aminobutyric acid (GABA)ergic basket cells and chandelier cells, respectively. Although calretinin and calbindin-D28k were also found in numerous nonpyramidal neurons, both were also located in pyramidal-shaped neurons in layers V and VI (calretinin) and in layers II and III (calbindin) of the entorhinal cortex, suggesting that they play roles in projection neurons as well. Moreover, the high density of nonpyramidal neurons containing calcium-binding proteins in layers II and III of the entorhinal cortex suggests that they form an integral component of a network that controls the entorhinal outputs to the hippocampus. Furthermore, the largely nonoverlapping distributions of the parvalbumin-, calretinin-, and calbindin-ir neuronal populations in the entorhinal cortex indicate that each of them may modulate a different subset of topographically organized entorhinal outputs. J. Comp. Neurol. 388:64–88, 1997. © 1997 Wiley-Liss, Inc.

Distribution of parvalbumin-, calretinin-, and calbindin-D28k-immunoreactive neurons and fibers in the human entorhinal cortex

Parvalbumin, calretinin, and calbindin-D28k are calcium-binding proteins that are located in largely nonoverlapping neuronal populations in the brain. The authors studied the distribution of parvalbumin-, calretinin-, and calbindin-D28k-immunoreactive (ir) cells, fibers, terminals, and neuropil in the eight subfields of the human entorhinal cortex. The distribution of each of the three calcium-binding proteins largely followed the cytoarchitectonic borders of the eight entorhinal subfields, although the regional and laminar distributions of the three proteins were segregated rather than overlapping. The highest density of parvalbumin-ir neurons and terminals was found in the caudal and lateral subfields of the entorhinal cortex. Calretinin and calbindin-D28k immunoreactivities were high rostromedially, although a large number of calretinin and calbindin-D28k neurons were also found in the caudal subfields. All parvalbumin-ir cells had a morphological appearance of nonpyramidal neurons. Parvalbumin-ir terminals formed basket-like formations around unstained somata and cartridges, suggesting that parvalbumin neurons compose a subpopulation of gamma-aminobutyric acid (GABA)ergic basket cells and chandelier cells, respectively. Although calretinin and calbindin-D28k were also found in numerous nonpyramidal neurons, both were also located in pyramidal-shaped neurons in layers V and VI (calretinin) and in layers II and III (calbindin) of the entorhinal cortex, suggesting that they play roles in projection neurons as well. Moreover, the high density of nonpyramidal neurons containing calcium-binding proteins in layers II and III of the entorhinal cortex suggests that they form an integral component of a network that controls the entorhinal outputs to the hippocampus. Furthermore, the largely nonoverlapping distributions of the parvalbumin-, calretinin-, and calbindin-ir neuronal populations in the entorhinal cortex indicate that each of them may modulate a different subset of topographically organized entorhinal outputs.

Cytochrome Oxidase, Acetylcholinesterase, and NADPH-Diaphorase Staining in Human Supratemporal and Insular Cortex: Evidence for Multiple Auditory Areas

The pattern of cytochrome oxidase, acetylcholinesterase, and NADPH-diaphorase activity was studied in the supratemporal plane, the posterior part of the superior temporal gyrus, and the insula of normal human brains. Five dark cytochrome oxidase regions were found: (i) on Heschl's gyrus (area TC of von Economo and Koskinas); (ii) on the planum polare (area TC/TG); (iii) posterior to Heschl's gyrus (within area TA); (iv) on the posterior convexity of the superior temporal gyrus (within area TA); and (v) on the posterosuperior insula (area IB). More lightly stained cortex separated these regions (areas IA, TD, and part of TB). The laminar distribution of cytochrome oxidase activity varied in different areas. Acetylcholinesterase-positive fibers predominated in area TC and pyramidal neurons in areas TA and IA and in parts of TB; a mixture of fiber and neuronal staining was found in TC/TG, TD, and IB. NADPH-diaphorase positive profiles included large darkly stained nonpyramidal neurons, mostly in infragranular layers and in subcortical white matter, small faintly stained cells, and a dense array of fibers. The NADPH-diaphorase staining pattern did not vary between areas. The present results suggest that the supratemporal plane, the posterior part of the superior temporal gyrus, and the insula contain at least eight putative cortical areas. Comparison with activation studies by others suggest that, apart from the primary auditory area, six other putative areas may be auditory whereas one putative area, on posterior insula, may be vestibular.

Natural variability in the number of dendritic segments: Model-based inferences about branching during neurite outgrowth

A study was made of the possible basis for naturally occurring variations in the number of segments in individual dendritic trees. Distributions of the number of terminal segments have been studied in dendrites from rat, cat, and frog motoneurons, basal dendrites from rat visual cortex pyramidal and non-pyramidal neurons, in rat cerebellar Purkinje cell dendritic trees, and in human hippocampal dentate granule cells. By means of a mathematical model for dendritic branching, it was shown that the variation in the number of dendritic segments can be accounted for by assuming that new branches during neurite outgrowth are formed randomly at terminal segments. The observed terminal segment number distributions could be closely approximated by additionally assuming that branching probabilities decline with increasing number of terminal segments in growing dendrites. The pyramidal neuron group differed significantly from the other neuron groups in such a way as to suggest that this decline is stronger than in the dendrites of other types of neurons. By using literature data on the mean number of terminal segments in rat cerebellar Purkinje cells, measured at different times during early development, an estimate could be obtained of the time-course of the branching probabilities. The branching probability of a terminal segment was found to be in the order of 0.002 per hour in the first 4 weeks postnatal with a 5-fold transient increase in the second week.

Developmental changes in calpain activity, GluR1 receptors and in the effect of kainic acid treatment in rat brain

The cellular distribution of calpain activation and glutamate receptor 1 (GluR1) subunits of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors and their alterations following kainic acid-induced seizure were evaluated during postnatal development using antibodies specific for spectrin breakdown product and the C-terminus of GluR1 subunits. In the first postnatal week, most brain regions exhibited high levels of calpain activity that progressively decreased during the following weeks. The highest levels of spectrin breakdown product immunoreactivity were observed in the somata and proximal dendrites of hippocampal pyramidal cells, non-pyramidal neurons in stratum oriens, and cortical neurons. In general, during the first two postnatal weeks, kainic acid treatment induced a decrease in spectrin breakdown product immunoreactivity in neuronal cell bodies and an increase in dendritic fields. Obvious elevation in spectrin breakdown product immunoreactivity in selective non-pyramidal cells in stratum oriens started at postnatal day 14, and was further evidenced by postnatal day 21. Likewise, massive calpain activation in subpopulations of neurons in some thalamic nuclei, amygdala, and pyriform cortex was observed after the third postnatal week. GluR1 subunits were highly expressed throughout the forebrain in the first postnatal week, further increased during the second postnatal week, decreased thereafter, and reached adult levels after postnatal day 21. In cortex, intense GluR1 immunostaining was found in the somata and proximal processes of pyramidal and non-pyramidal neurons, with the non-pyramidal neurons in layers IV through VI exhibiting the densest immunolabelling. In the first two postnatal weeks, the somata of hippocampal pyramidal neurons exhibited intense GluR1 immunostaining that became more dendritic in the subsequent developmental period. While hilar cells exhibited a similar developmental pattern as CA regions, the molecular layer of dentate gyrus exhibited weak immunoreactivity from postnatal day 7 to postnatal day 14. The early increase in GluR1 immunoreactivity in hippocampal pyramidal layer following kainic acid treatment occurred throughout the developmental period, while the later decrease in CA regions, amygdala, and pyriform cortex was observed only in postnatal day 21 animals. The combined immunocytochemical studies of spectrin breakdown product localization and GluR1 expression indicate that calpain activation might play an important role in synaptic formation, developmental regulation of synaptic plasticity, and neuronal vulnerability to excitotoxicity during postnatal development. Moreover, calpain-mediated modulation of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors might underlie these processes.

Quantitative Three-Dimensional Analysis of the Catecholaminergic Innervation of Identified Neurons in the Macaque Prefrontal Cortex

The present study provides a complete quantitative three-dimensional analysis of neurons in primate prefrontal cortex targeted by catecholaminergic axons. Individual pyramidal and nonpyramidal cells in fixed slices were filled with Lucifer yellow (LY) and recovered with anti-LY antibody combined with anti-tyrosine hydroxylase (TH) antisera to reveal catecholaminergic axons. The total number of TH contacts and TH apposition density (THAD) was obtained for pyramidal and nonpyramidal cells in different layers. Four TH contacts (two on spines and two on shafts) were selected for correlated electron microscopic examination and serially sectioned; all four were confirmed as membrane appositions. Quantitative analysis revealed 90 TH contacts per pyramidal neuron in layer III, with a density of 0.8 per 100 microm of dendritic length (i.e., averaging one contact per basal dendrite). Remarkably, pyramids of layers III, V, and VI had the same THAD values, with a highly regular distribution of TH terminals on their spiny dendritic trees. In contrast, TH contacts on nonpyramidal neurons in layer III were half as dense and, moreover, were distributed irregularly and showed large variation from cell to cell. Neurons in layers II and superficial III had the highest THAD, as compared with deeper layers (1.4 vs 0.7 per 100 micron of dendritic length for pyramids; 0.53 vs 0.4 for interneurons). The highly organized TH innervation of pyramidal neurons, with at least one contact on virtually every dendrite, indicates that catecholaminergic, presumably dopaminergic, terminals are placed strategically along the entire dendritic tree to modulate most, if not all, of the excitatory input of a neuron. At the same time, the sparsity of contacts per dendrite may explain cortical vulnerability in diseases involving dopamine.

Immunohistochemical and RT-PCR detection of Na +-dependent inorganic phosphate cotransporter (NaP i-2) in rat brain

Expression of a renal Na +-dependent inorganic phosphate (P i) cotransporter (NaP i-2) was studied in rat forebrain with reverse transcription and polymerase chain reaction (RT-PCR) and immunohistochemistry. RT-PCR analysis for total RNA from whole brain and sequencing of the PCR products showed expression of NaP i-2 mRNA in the brain. Immunohistochemical analysis revealed NaP i-2 staining in many nonpyramidal neurons of all six layers throughout neocortical areas and in neurons of proisocortical and periallocortical areas. NaP i-2-immunoreactive neurons were also detectable in the piriform cortex, hippocampal formation, caudate-putamen, amygdaloid nuclei and lateral geniculate nucleus. Furthermore, NaP i-2 staining was shown in ependymal cells and microvascular endothelial cells. The present results suggest that NaP i-2 is synthesized within the brain and involved in maintaining P i homeostasis of certain neurons and/or the entire brain.

Regulation of Dendritic Growth and Remodeling by Rho, Rac, and Cdc42

The acquisition of cell type-specific morphologies is a central feature of neuronal differentiation and has important consequences for nervous system function. To begin to identify the underlying molecular mechanisms, we have explored the role of Rho-related GTPases in the dendritic development of cortical neurons. Expression of dominant negative mutants of Rac or Cdc42, the Rho-inhibitory molecule C3 transferase, or the GTPase-activating protein RhoGAP p190 causes a marked reduction in the number of primary dendrites in nonpyramidal (multipolar) neurons and in the number of basal dendrites in neurons with pyramidal morphologies. Conversely, the expression of constitutively active mutants of Rho, Rac, or Cdc42 leads to an increase in the number of primary and basal dendrites. In cortical cultures, as in vivo, dendritic remodeling leads to an apparent transformation from pyramidal to nonpyramidal morphologies over time. Strikingly, this shift in favor of nonpyramidal morphologies is also inhibited by the expression of dominant negative mutants of Cdc42 and Rac and by RhoGAP p190. These observations indicate that Rho, Rac, and Cdc42 play a central role in dendritic development and suggest that differential activation of Rho-related GTPases may contribute to the generation of morphological diversity in the developing cortex.

Neurofilament and calcium-binding proteins in the human cingulate cortex.

Functional imaging studies of the human brain have suggested the involvement of the cingulate gyrus in a wide variety of affective, cognitive, motor, and sensory functions. These studies highlighted the need for detailed anatomic analyses to delineate its many cortical fields more clearly. In the present study, neurofilament protein, and the calcium-binding proteins parvalbumin, calbindin, and calretinin were used as neurochemical markers to study the differences among areas and subareas in the distributions of particular cell types or neuropil staining patterns. The most rostral parts of the anterior cingulate cortex were marked by a lower density of neurofilament protein-containing neurons, which were virtually restricted to layers V and VI. Immunoreactive layer III neurons, in contrast, were sparse in the anterior cingulate cortex, and reached maximal densities in the posterior cingulate cortex. These neurons were more prevalent in dorsal than in ventral portions of the gyrus. Parvalbumin-immunoreactive neurons generally had the same distribution. Calbindin- and calretinin-immunoreactive nonpyramidal neurons had a more uniform distribution along the gyrus. Calbindin-immunoreactive pyramidal neurons were more abundant anteriorly than posteriorly, and a population of calretinin-immunoreactive pyramidal-like neurons in layer V was found largely in the most anterior and ventral portions of the gyrus. Neuropil labeling with parvalbumin and calbindin was most dense in layer III of the anterior cingulate cortex. In addition, parvalbumin-immunoreactive axonal cartridges were most dense in layer V of area 24a. Calretinin immunoreactivity showed less regional specificity, with the exception of areas 29 and 30. These chemoarchitectonic features may represent cellular reflections of functional specializations in distinct domains of the cingulate cortex.

GABAergic neurons with AMPA GluR1 and GluR2/3 immunoreactivity in the rat striate cortex.

The co-localization of GABA with AMPA receptor subunits GluR1 or GluR2/3 was analysed in the striate cortex of adult rats by post-embedding immunocytochemistry in semithin sections. Adjacent 1 micron semithin sections of four brains were alternately incubated with specific antibodies against GABA and the GluR1 and GluR2/3 subunits. The post-embedding immunocytochemistry showed that 38% of GABAergic neurons contained the GluR1 subunit and 10% contained the GluR2/3 subunits. Previous work has shown GluR1 immunoreactivity in non-pyramidal neurons and GluR2/3 immunoreactivity in pyramidal neurons. However, this study is the first to demonstrate that there are GABAergic neurons co-localized with GluR2/3 AMPA subunits. Additionally, this study provides quantitative estimations of the laminar distribution of GABAergic and non-GABAergic cells containing the AMPA GluR1 and GluR2/3 subunits.

Synaptic Connections of Calretinin-Immunoreactive Neurons in the Human Neocortex

Previous immunocytochemical studies in the cerebral cortex of various species have shown that the calcium-binding protein calretinin (CR) labels specific subpopulations of nonspiny nonpyramidal cells (interneurons). The present study attempts to characterize morphologically and chemically the microcircuitry of CR-immunoreactive (CR-ir) neurons in the human temporal neocortex. Postembedding immunocytochemistry for CR and GABA and combination immunocytochemistry for CR and nonphosphorylated neurofilament protein (NPNFP) or for CR and the calcium-binding proteins parvalbumin (PV) and calbindin (CB) showed CR multiterminal endings frequently innervating the distal apical dendrite or the cell body and proximal dendrites of NPNFP-ir or CB-ir pyramidal cells, respectively. Cell bodies of interneurons immunoreactive for CB or PV were innervated only occasionally by CR multiterminal endings, whereas certain GABA neurons were surrounded by them. Furthermore, CR-ir axon terminals formed either symmetrical (the majority) or asymmetrical synapses with a variety of postsynaptic elements. These results indicate that different subpopulations of CR interneurons exist that are specialized for selective innervation of somatic or dendritic regions of certain pyramidal and nonpyramidal neurons.

Calbindin-D28k immunoreactivity in the rat amygdala

Calbindin-D28k (CB) is a calcium-binding protein whose exact function has yet to be elucidated. Because CB is contained in distinct cell types in the nervous system, it is a valuable marker for distinguishing specific nuclear subdivisions and neuronal populations. In the present study, immunohistochemical methods were used to localize CB in the rat amygdala. A subpopulation of nonpyramidal neurons in all nuclei of the basolateral amygdala (ABL) exhibited intense CB immunoreactivity (CB-ir). CB-positive puncta resembling axon terminals were observed surrounding pyramidal perikarya in the ABL. Pyramidal neurons in caudal and lateral portions of the ABL exhibited moderate CB-ir. Intensely stained nonpyramidal neurons resembling those of the ABL were also seen in the cortical nuclei, periamygdaloid cortex, and nucleus of the lateral olfactory tract; these nuclei also contained variable numbers of moderately stained pyramidal cells. Numerous CB-positive neurons were observed in all subdivisions of the medial nucleus. The posterodorsal subdivision of the medial nucleus exhibited a centrally located island of small CB-negative neurons and three cell-dense clusters of CB-positive neurons. The distribution of CB-ir in the central nuclear complex was very heterogeneous. The intermediate subdivision of the central nuclear complex exhibited the most robust staining, whereas the lateral subdivision contained relatively few CB-positive cells. Dorsal and ventral portions of the lateral capsular subdivision of the central nuclear complex could be readily distinguished on the basis of differing levels of CB-ir. These results indicate that CB is localized in discrete cell types and nuclear subdivisions in the rat amygdala and suggest that CB immunohistochemistry is a useful technique for identifying specific structural components in this brain region.