In the cortex inhibition is mediated predominantly by GABAergic interneurons. Although all of these neurons use the same neurotransmitter, studies in the rat frontal cortex have shown that they are molecularly and physiologically diverse. It is not known whether similar subgroups of GABAergic neurons exist in primary visual cortex and how these different inhibitory neurons are inserted into specific cortical circuits. We have used immunostaining with antibodies against gamma aminobutyric acid (GABA), parvalbumin (PV), calretinin (CR), somatostatin (SOM), calbindin (CB) and nitric oxide synthase (NOS) to probe for colocalization of known markers of GABAergic interneurons. The results show that the majority of PV (100%), SOM (89.8%) and CR (93.9%) staining neurons are GABA positive. PV immunoreactive neurons constitute a distinct group that show no overlap with CR, SOM and NOS expressing cells and only a minor overlap (5.3%) with CB. PV immunoreactive cells account for 50.8% of GABAergic neurons. A second group of SOM expressing neurons accounts for 16.9% of GABAergic cells. None of these cells colocalize PV or CR, but 1.7% of SOM neurons stain for NOS and 86.3% show CB immunoreactivity. The third distinct group of CR expressing cells accounts for 17.0% of GABAergic neurons. All of these are PV, CB, SOM and NOS negative. CB expressing neurons represent a heterogeneous group that includes GABAergic and non-GABAergic cells. Our findings indicate that GABAergic neurons in rat area 17 are organized in at least three separate families that can be identified by the expression of PV, CR and SOM. These cells account for 84.9% of GABAergic neurons. These results extend previous observations in rat frontal agranular cortex and suggest that in visual cortex the inhibitory network is composed of similar cell types.
The majority of cortical interneurons use GABA (gamma amino butyric acid) as inhibitory neurotransmitter. GABAergic neurons are morphologically, connectionally, electrically and chemically heterogeneous. In rat cerebral cortex three distinct groups of GABAergic interneurons have been identified by the expression of parvalbumin (PV), calretinin (CR) and somatostatin (SOM). Recent studies in mouse cerebral cortex have revealed a different organization in which the CR and SOM populations are partially overlapping. Because CR and SOM neurons derive from different progenitors located in different embryonic structures, the coexpression of CR + SOM suggests that the chemical differentiation of interneurons is regulated postmitotically. Here, we have taken an important first step towards understanding this process by triple immunostaining mouse visual cortex with a panel of antibodies, which has been used extensively for classifying developing interneurons. We have found at least 13 distinct groups of GABAergic neurons which include PV, CR, SOM, CCK (cholecystokinin), CR + SOM, CR + NPY (neuropeptide Y), CR + VIP (vasointestinal polypeptide), SOM + NPY, SOM + VIP, VIP + ChAT (choline acetyltransferase), CCK + NPY, CR + SOM + NPY and CR + SOM + VIP expressing cells. Triple immunostaining with PV, CR and SOM antibodies during postnatal development further showed that PV is never colocalized with CR and SOM. Importantly, expression of SOM and CR + SOM developed after the percentage of CR cells that do not express SOM has reached the mature level, suggesting that the chemical differentiation of SOM and CR + SOM neurons is a postnatal event, which may be controlled by transcriptional regulation.
Nuclear Ca2؉ plays a critical role in many cellular functions although its mode (s) of regulation is unclear. This study shows that the metabotropic glutamate receptor, mGlu5, mobilizes nuclear Ca 2؉ independent of cytosolic Ca 2؉ regulation. Immunocytochemical, ultrastructural, and subcellular fractionation techniques revealed that the metabotropic glutamate receptor, mGlu5, can be localized to nuclear membranes in heterologous cells as well as midbrain and cortical neurons. Changes in nuclear Ca2ϩ play an integral role in cellular functions such as protein import, apoptosis, and gene transcription (1, 2). Nuclear Ca 2ϩ may be generated from a number of sources including diffusion of cytosolic Ca 2ϩ waves through nuclear pore complexes (2). Because the outer nuclear envelope is continuous with the endoplasmic reticulum, which serves as an internal store of Ca 2ϩ , rises in nuclear Ca 2ϩ may also be attributable to a luminal source (3). Recent studies using high speed imaging of intracellular Ca 2ϩ have shown that waves of Ca 2ϩ can invade the nucleus by emptying intracellular stores (4). Calcium release from internal stores is controlled by various channels including the inositol 1,4,5-trisphosphate (IP 3 ) 1 receptor and ryanodine receptor families (5, 6) both of which are present on nuclear membranes (7,8). Calcium itself is an activator of these channels (1) although nuclear IP 3 can stimulate IP 3 receptors located on the inner nuclear membrane and cADP ribose has been shown to activate nuclear ryanodine receptors (7,8). Luminal Ca 2ϩ is refilled at least in part by the nuclear Ca 2ϩ -ATPase (9, 10) located on the outer nuclear membrane. Thus, although signals originating at the plasma membrane may be transmitted to the nucleus (4), the presence of specific Ca 2ϩ transporters on the nuclear envelope argues for a nuclear Ca 2ϩ regulatory system that may be independent of cytosolic Ca 2ϩ regulation. Many components of G protein signaling pathways are also found in the nucleus or associated with nuclear membranes. These include phospholipase C isozymes (11, 12), nuclear inositol phosphates (12, 13), DAG (13), PKC isozymes (14), adenylate cyclase (15), regulators of G protein signaling (RGS proteins; Refs. 16 and 17) as well as heterotrimeric G proteins themselves (18). These observations raise the possibility that plasma membrane-based signaling components may also serve a similar function at nuclear membranes. Indeed, several recent reports are consistent with the notion that nuclear G protein-coupled receptors directly modulate nuclear signal transduction pathways. For example, angiotensin II receptors were found on hepatocyte nuclear membranes (19), opioid binding sites were described on ventricular myocardial nuclei (20) and endothelin-1 receptors were reported on vascular smooth muscle nuclear membranes (21). Direct evidence of nuclear receptor G protein signaling has also been demonstrated for prostaglandin receptors which, when stimulated, cause rapid Ca 2ϩ influx into the nucleus (22,23). Taken togeth...
In rat visual cortex neurons that are immunoreactive for the calcium-binding protein calretinin (CR+) constitute a distinct family which accounts for 17% of gamma-aminobutyric acid (GABA)-expressing cells. It is not clear, however, (i) whether CR is expressed exclusively in GABAergic neurons and (ii) how CR+ neurons are incorporated into neuronal circuits of rat visual cortex. To address these questions we studied synaptic relationships of CR+ neurons with GABA+ and GABA- elements in the neuropil of rat primary visual cortex (area 17). All CR+ neurons are nonpyramidal cells with smooth or sparsely spiny and often beaded dendrites. Of all CR+ neurons, 56% are located in layers 1 and 2/3. In layer 2/3, most CR+ neurons are bipolar-shaped and have vertically oriented dendrites. Many ascending dendritic branches reach layer 1 where they run parallel to pial surface. CR+ axons are thin, highly branched near the cell body and often send descending collaterals to layers 5 and 6. Double immunofluorescence labeling revealed GABA in 94% of CR+ cell bodies in layer 2/3. Electron microscopic analysis shows that all CR+ axon terminals contain elongated vesicles and form symmetric synapses. Postembedding staining shows that 98% of CR+ terminals are GABA+. GABA-immunoreactivity is also present in somata and thick dendrites of CR+ neurons but many thin dendrites are GABA-. CR+ somata, dendrites and axon terminals are enriched in mitochondria. Somata and thick CR+ dendrites are densely innervated. At least 68% of the targets of CR+ terminals in layer 2/3 are GABA+ and > or = 50% of these are other CR+ neurons. The remainder (32%) of targets of CR+ terminals are thin dendrites of GABA- cells. In contrast, in layers 5 and 6, 60% of CR+ terminals form synapses with GABA- somatic profiles. The preferential interactions of layer 2/3 CR+ neurons with GABAergic neurons, and with CR+ neurons in particular, suggests that these cells play a role in the inhibition of inhibitory neurons of the same layer. Through these interactions CR+ cells may reduce inhibition of pyramidal cells in layers 2/3, 5 and 6 and thus disinhibit a column of neurons.
Differential Expression ofIAChannel Subunits Kv4.2 and Kv4.3 in Mouse Visual Cortical Neurons and Synapses
In cortical neurons, pore-forming ␣-subunits of the Kv4 subfamily underlie the fast transient outward K ϩ current (I A ). Considerable evidence has accumulated demonstrating specific roles for I A channels in the generation of individual action potentials and in the regulation of repetitive firing. Although I A channels are thought to play a role in synaptic processing, little is known about the cell typeand synapse-specific distribution of these channels in cortical circuits. Here, we used immunolabeling with specific antibodies against Kv4.2 and Kv4.3, in combination with GABA immunogold staining, to determine the cellular, subcellular, and synaptic localization of Kv4 channels in the primary visual cortex of mice, in which subsets of pyramidal cells express yellow fluorescent protein. The results show that both Kv4.2 and Kv4.3 are concentrated in layer 1, the bottom of layer 2/3, and in layers 4 and 5/6. In all layers, clusters of Kv4.2 and Kv4.3 immunoreactivity are evident in the membranes of the somata, dendrites, and spines of pyramidal cells and GABAergic interneurons. Electron microscopic analyses revealed that Kv4.2 and Kv4.3 clusters in pyramidal cells and interneurons are excluded from putative excitatory synapses, whereas postsynaptic membranes at GABAergic synapses often contain Kv4.2 and Kv4.3. The presence of Kv4 channels at GABAergic synapses would be expected to weaken inhibition during dendritic depolarization by backpropagating action potentials. The extrasynaptic localization of Kv4 channels near excitatory synapses, in contrast, should stabilize synaptic excitation during dendritic depolarization. Thus, the synapse-specific distribution of Kv4 channels functions to optimize dendritic excitation and the association between presynaptic and postsynaptic activity.
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