Layer-specific production of nitric oxide during cortical circuit formation in postnatal mouse brain

In the developing cerebral cortex, neuronal nitric oxide synthase (nNOS) is expressed abundantly, but temporarily. During the early postnatal stage, cortical neurons located in the multi-layered structure of the cortical plate start forming well-organized cortical circuits, but little is known about the molecular machinery for layer-specific circuit formation. To address the involvement of nitric oxide (NO), we utilized a new NO indicator (DAR-4M) and developed a protocol for the real-time imaging of NO produced in fresh cortical slices upon N-methyl-D-aspartic acid stimulation. At postnatal day 0 (P0), NO production was restricted to the deep layers (layers V and VI) of the somatosensory cortex where transient synapses are formed. At P10, the production of NO was expanded to layer IV where large numbers of thalamocortical axons form synapses. The pattern of NO production could correspond to active sites for synaptic formation. This study is the first clear demonstration of NO production in the postnatal mouse neocortex. The findings presented may reflect a function of NO in relation to the layer-specific development of neural circuits in the neocortex.     

Dual role of substance P/GABA axons in cortical neurotransmission: synaptic triads on pyramidal cell spines and basket-like innervation of layer II-III calbindin interneurons in primate prefrontal cortex

In spite of accumulating evidence on the potent neuromodulatory, neuroprotective, trophic and memory-enhancing effects of the neuropeptide substance P (SP) in the cerebral cortex, the excitatory or inhibitory nature of the cortical SP innervation remains unclear and the postsynaptic targets of SP fibers are not defined. To obtain further insight into these issues, we have examined SP-containing axons and their postsynaptic targets in the prefrontal cortex of adult monkeys with single- and double label immunocytochemistry combined with light and correlated electron microscopy. SP fibers in the primate prefrontal cortex, unlike those in the rat cortex, preferentially innervate cortical layers I, II and upper layer III. Our results demonstrate for the first time that all SP-immunoreactive boutons in all cortical layers contain GABA. Of the entire sample of SP boutons, 53% synapse on dendritic shafts, 39% on dendritic spines and 8% on cell bodies. Another new finding is that synapse-forming SP boutons, in addition to their known innervation of pyramidal cells, form pericellular baskets around interneurons in layers II and upper III, a subpopulation of which contains calbindin D28k. Finally, the study also revealed that SP boutons frequently participate in 'synaptic triads' with spines which receive another (asymmetric, putatively excitatory amino acid-utilizing) synapse. Our findings indicate that SP/GABA axons in the primate prefrontal cortex modulate excitatory amino acid- mediated neurotransmission and control feed-forward disinhibitory GABAergic circuits in supragranular cortical layers.      

Synaptogenesis in monkey somatosensory cortex.

The time course and rate of synaptogenesis were studied in the somatosensory cortex (Brodmann's areas 1 and 3b) of 27 rhesus monkeys ranging in age from embryonic day 41 to 20 years. Two to four vertical probes, each consisting of a series of overlapping electron micrographs and extending from the pial surface to the interface of the cortex with the white matter, were made from sections cut across the postcentral gyrus in the region of the upper limb representation. We found that the density of synapses per unit volume of cortex as well as per unit volume of neuropil increases steadily throughout the late fetal ages and early infancy. A density of 70/100 microns 3 of neuropil was reached by the second postnatal month; thereafter, between 1 and 3 years a slightly lower density of 50-60/100 microns 3 was maintained. At around puberty, the decrease in concentration of synapses appears to be accelerated. Thus, the average synaptic density of a group of 10 adult animals composed of monkeys over 4 years of age was 30-40 synapses per 100 microns 3 of neuropil. This value is significantly lower than that of the group of 11 infant and juvenile animals below 4 years of age. Since synaptic density per unit volume of neuropil is not affected by changes in other parameters of cortical growth, these numbers reflect an actual overproduction of synapses in infancy followed by their elimination during adolescence. The decline in the number of synapses is due primarily to elimination of asymmetrical junctions located on dendritic spines while symmetrical synapses on dendritic shafts and cell bodies remained relatively constant during postnatal life. The course of synapse formation recorded in the present study coincides with the course of overproduction and elimination of neurotransmitter receptors (Lidow et al., 1991) and the developmental schedule of synaptogenesis in other neocortical areas (Rakic et al., 1986). The timing of synaptogenesis and synaptic elimination in the postcentral gyrus may account for the maturation and plasticity of various aspects of somatosensory function during post-natal life.     

Spaceflight induces changes in the synaptic circuitry of the postnatal developing neocortex

The establishment of the adult pattern of neocortical circuitry depends on various intrinsic and extrinsic factors, whose modification during development can lead to alterations in cortical organization and function. We report the effect of 16 days of spaceflight [Neurolab mission; from postnatal day 14 (P14) to P30] on the neocortical representation of the hindlimb synaptic circuitry in rats. As a result, we show, for the first time, that development in microgravity leads to changes in the number and morphology of cortical synapses in a laminar-specific manner. In the layers II/III and Va, the synaptic cross-sectional lengths were significantly larger in flight animals than in ground control animals. Flight animals also showed significantly lower synaptic densities in layers II/III, IV and Va. The greatest difference was found in layer II/III, where there was a difference of 344 million synapses per mm(3) (15.6% decrease). Furthermore, after a 4 month period of re-adaptation to terrestrial gravity, some changes disappeared (i.e. the alterations were transient), while conversely, some new differences also appeared. For example, significant differences in synaptic density in layers II/III and Va after re-adaptation were no longer observed, whereas in layer IV the density of synapses increased notably in flight animals (a difference of 185 million synapses per mm(3) or 13.4%). In addition, all the changes observed only affected asymmetrical synapses, which are known to be excitatory. These results indicates that terrestrial gravity is a necessary environmental parameter for normal cortical synaptogenesis. These findings are fundamental in planning future long-term spaceflights.     

RORβ induces barrel-like neuronal clusters in the developing neocortex

Neurons in layer IV of the rodent whisker somatosensory cortex are tangentially organized in periodic clusters called barrels, each of which is innervated by thalamocortical axons transmitting sensory information from a single principal whisker, together forming a somatotopic map of the whisker pad. Proper thalamocortical innervation is critical for barrel formation during development, but the molecular mechanisms controlling layer IV neuron clustering are unknown. Here, we investigate the role in this mapping of the nuclear orphan receptor RORβ, which is expressed in neurons in layer IV during corticogenesis. We find that RORβ protein expression specifically increases in the whisker barrel cortex during barrel formation and that in vivo overexpression of RORβ is sufficient to induce periodic barrel-like clustering of cortical neurons. Remarkably, this clustering can be induced as early as E18, prior to innervation by thalamocortical afferents and whisker derived-input. At later developmental stages, these ectopic neuronal clusters are specifically innervated by thalamocortical axons, demonstrated by anterograde labeling from the thalamus and by expression of thalamocortical-specific synaptic markers. Together, these data indicate that RORβ expression levels control cytoarchitectural patterning of neocortical neurons during development, a critical process for the topographical mapping of whisker input onto the cortical surface.     

Activity-dependent regulation of synapse and dendritic spine morphology in developing barrel cortex requires phospholipase C-beta1 signalling

The phospholipase C-beta1 (PLC-beta1) signalling pathway, activated via metabotropic glutamate receptors (mGluRs), is implicated in activity-dependent development of the cerebral cortex, as both PLC-beta1 and mGluR5 knockout mice exhibit disrupted barrel formation in somatosensory cortex. To characterize the effects of this signalling system on development of synaptic circuitry in barrel cortex, we have examined neuronal ultrastructure, synapse formation and dendritic spine morphology in PLC-beta1 knockout mice. Qualitative ultrastructure of neurons and synapse density in layers 2-4 of barrel cortex were unchanged in PLC-beta1 knockout mice during development [postnatal day (P) 5] and in mature cortex (P19-21). We found a decrease in the proportion of synapses with symmetric morphology at P5 that was gone by P19-21, indicating a transient imbalance in excitatory and inhibitory circuitry. We also investigated dendritic spines by back-labelling layer 5 pyramidal neurons with carbocyanine. We observed normal dendritic spine densities on apical dendrites as they passed through layer 4 of barrel cortex, but spine morphology was altered in PLC-beta1 knockout mice at P9. These observations indicate that the PLC-beta1 signalling pathway plays a role in the development of normal cortical circuitry. Interrupting this regulation leads to changes in synapse and dendritic spine morphology, possibly altering post-synaptic integration of signal.     

Cell type-specific three-dimensional structure of thalamocortical circuits in a column of rat vibrissal cortex

Soma location, dendrite morphology, and synaptic innervation may represent key determinants of functional responses of individual neurons, such as sensory-evoked spiking. Here, we reconstruct the 3D circuits formed by thalamocortical afferents from the lemniscal pathway and excitatory neurons of an anatomically defined cortical column in rat vibrissal cortex. We objectively classify 9 cortical cell types and estimate the number and distribution of their somata, dendrites, and thalamocortical synapses. Somata and dendrites of most cell types intermingle, while thalamocortical connectivity depends strongly upon the cell type and the 3D soma location of the postsynaptic neuron. Correlating dendrite morphology and thalamocortical connectivity to functional responses revealed that the lemniscal afferents can account for some of the cell type- and location-specific subthreshold and spiking responses after passive whisker touch (e.g., in layer 4, but not for other cell types, e.g., in layer 5). Our data provides a quantitative 3D prediction of the cell type-specific lemniscal synaptic wiring diagram and elucidates structure-function relationships of this physiologically relevant pathway at single-cell resolution.     

Paternal deprivation alters region- and age-specific interneuron expression patterns in the biparental rodent, Octodon degus

The impact of paternal care on the postnatal development of inhibitory neuronal subpopulations in prefrontal and limbic brain regions was studied in the rodent Octodon degus. Comparing offspring from biparental families with animals raised by a single mother revealed region-specific deprivation-induced changes in the density of PARV- and CaBP-D28k expressing cells. Some deprivation-induced changes were only seen at P21: elevated CaBP-D28k-positive neurons in the orbitofrontal cortex, CA1, CA3, and dentate gyrus (DG) and elevated PARV-positive neurons in the lateral orbitofrontal, prelimbic/infralimbic (PL/IL), DG and CA1, nucleus accumbens, and amygdala. Some deprivation-induced changes were obvious in both age groups: increased CaBP-D28k-positive neurons in the nucleus accumbens shell and increased PARV-positive neurons in the ventral orbitofrontal. Some deprivation-induced changes were only seen in adulthood: increased CaBP-D28k-positive neurons in the amygdala and decreased PARV-positive neurons in the PL/IL and in CA3. In CA1, PARV-positive neurons were increased at P21 and decreased in adulthood. The functional significance of the deprivation-induced changes in PARV-positive neurons, which are involved in gamma oscillations and thereby affect information processing and which appear to be key players for critical period plasticity in sensory cortex development, as well as the behavioral implications remain to be further elucidated.     

Differential Expression of Acetylcholinesterase in the Developing Barrel Cortex of Three Rodent Species

Acetylcholinesterase (AChE) is transiently expressed in severalimmature axon systems. Its presence in developing thalamocorticalafferents has led to the use of enzyme histochemistry to visualizethis axon system in rats. Because of the spatiotemporal distributionof the enzyme in the rat neocortex. it has been suggested thatAChE plays a role in the establishment of thalamocortical connectivity. We show here that AChE is distributed in a pattern that is markedlydifferent in SI cortex of rats as compared to that of mice andhamsters. In rat pups, AChE-rich patches are distributed ina vibrissa-related array in the SI cortex soon after birth,whereas regions of cortex that lie between individual patches,and between rows of patches, are impoverished in the enzyme.In contrast. sections through flattened cortices from PND3 andolder mice and hamsters reveal lightly stained, AChE-positivespots in the center of barrel cores, while barrel walls remaindevoid of AChE; septae that divide individual barrels are denselyenzyme positive. Differences in laminar localization of theenzyme for all three species are also visible. In the thalamus of postnatal rats, both the ventral posteriormedial (VPM) and ventral posterior lateral (VPL) nuclei expressAChE, correlating with the presence of enzyme-containing patchesthroughout the barrelfield cortex. In the other two rodents,however, the enzyme is present in VPL but not in VPM, despitethe fact that in these species the cortical barrels associatedwith both thalamic nuclei have very little of the enzyme. Thus,the relationship between the distribution of AChE in nucleiof the thalamic ventrobasal complex and the presence of AChEin the terminals of their cortical axons in the barrelfieldis not consistent across different rodent species. Our results call for caution in the use of AChE histochemistryas a universal marker for immature thalamocortical axons, andchallenge the generality of currently hypothesized roles forthis transiently expressed enzyme during the development ofthe rodent thalamocortical projection.     

A Unique Mosaic in the Visual Cortex of the Reeler Mutant Mouse

Numerous studies have revealed abnormal cytoarchi-tectonicsin the reeler mouse brain. In the present study, acetylcholinesterase(AChE) histochemistry has revealed a distinctive mosaic withinthe occipital cortex of the reeler mouse. The mosaic does notappear until after the second postnatal week, perhaps in associationwith eye opening. AChE staining in the visual cortex of normallittermates does not exhibit a mosaic pattern, but rather, ispresent within bands or laminae. The AChE mosaic in reeler persistsinto adulthood. Immunocyto-chemical staining of the tenascinglycoprotein, an astrocyte-derived extracellular matrix moleculethat is concentrated in boundaries around emerging functionalpatterns in the CNS, reveals a boundary-mosaic pattern in thefirst postnatal week. Dil axonal tracing in normal versus reelermice indicates that the thalamocortical projections may alsobe associated with the AChE mosaic. The observation that a mosaicis unique to the occipital cortex of reeler mice suggests thatit may evolve through abnormal cell and molecular interactionsin the mutant cortex that normally lead to the development offunctional visual representations.     

Hearing loss alters the subcellular distribution of presynaptic GAD and postsynaptic GABAA receptors in the auditory cortex

We have shown previously that auditory experience regulates the maturation of excitatory synapses in the auditory cortex (ACx). In this study, we used electron microscopic immunocytochemistry to determine whether the heightened excitability of the ACx following neonatal sensorineural hearing loss (SNHL) also involves pre- or postsynaptic alterations of GABAergic synapses. SNHL was induced in gerbils just prior to the onset of hearing (postnatal day 10). At P17, the gamma-aminobutyri acid type A (GABA(A)) receptor's beta2/3-subunit (GABA(A)beta2/3) clusters residing at plasma membranes in layers 2/3 of ACx was reduced significantly in size (P < 0.05) and number (P < 0.005), whereas the overall number of immunoreactive puncta (intracellular + plasmalemmal) remained unchanged. The reduction of GABA(A)beta2/3 was observed along perikaryal plasma membranes of excitatory neurons but not of GABAergic interneurons. This cell-specific change can contribute to the enhanced excitability of SNHL ACx. Presynaptically, GABAergic axon terminals were significantly larger but less numerous and contained 47% greater density of glutamic acid decarboxylase immunoreactivity (P < 0.05). This suggests that GABA synthesis may be upregulated by a retrograde signal arising from lowered levels of postsynaptic GABA(A)R. Thus, both, the pre- and postsynaptic sides of inhibitory synapses that form upon pyramidal neurons of the ACx are regulated by neonatal auditory experience.     

Connectivity of GABAergic calretinin-immunoreactive neurons in rat primary visual cortex.

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.     

Postnatal development of tyrosine hydroxylase- and dopamine transporter- immunoreactive axons in monkey rostral entorhinal cortex

Dopamine afferents from the mesencephalon appear to play a critical role in the normal development and cognitive functions of multiple areas of the primate cerebral cortex. In some regions, such as the prefrontal and motor cortices, dopamine innervation changes substantially during postnatal development. However, little is known about the postnatal maturation of dopamine afferents to the primate rostral entorhinal cortex, a periallocortical region that receives a dense dopamine innervation in adults. In this study, we used immunocytochemical techniques and antibodies against tyrosine hydroxylase and the dopamine transporter to examine the postnatal development of dopamine axons in the rostral subdivision of macaque monkey entorhinal cortex. Within animals, the axons labeled with each antibody did not differ in overall density or laminar distribution. Across development, the density of dopamine axons in layers I and VI did not change appreciably. In contrast, the density of labeled axons in layer III significantly increased by a factor of three between birth and 5-7 months of age. The timing of this change differs substantially from that observed in prefrontal cortex, where peak dopamine innervation occurs between 2 and 3 years of age. These findings, in concert with other data, suggest that developmental changes in the dopamine innervation of cortical regions may parallel the functional maturation of those areas.      

Development of inhibitory timescales in auditory cortex

The time course of inhibition plays an important role in cortical sensitivity, tuning, and temporal response properties. We investigated the development of L2/3 inhibitory circuitry between fast-spiking (FS) interneurons and pyramidal cells (PCs) in auditory thalamocortical slices from mice between postnatal day 10 (P10) and P29. We found that the maturation of the intrinsic and synaptic properties of both FS cells and their connected PCs influence the timescales of inhibition. FS cell firing rates increased with age owing to decreased membrane time constants, shorter afterhyperpolarizations, and narrower action potentials. Between FS-PC pairs, excitatory postsynaptic potentials (EPSPs) and inhibitory postsynaptic potentials (IPSPs) changed with age. The latencies, rise, and peak times of the IPSPs, as well as the decay constants of both EPSPs and IPSPs decreased between P10 and P29. In addition, decreases in short-term depression at excitatory PC-FS synapses resulted in more sustained synaptic responses during repetitive stimulation. Finally, we show that during early development, the temporal properties that influence the recruitment of inhibition lag those of excitation. Taken together, our results suggest that the changes in the timescales of inhibitory recruitment coincide with the development of the tuning and temporal response properties of auditory cortical networks.     

Synaptic distinction of laminar-specific prefrontal-temporal pathways in primates

Prefrontal pathways exert diverse effects in widespread cortical areas, issuing projections both to the middle layers and to layer I, which are anatomically and functionally distinct. Here we addressed the still unanswered question of whether cortical pathways that terminate in different layers are distinct at the synaptic level. We addressed this issue using as a model system the robust and functionally significant pathways from prefrontal areas 10 and 32 to superior temporal areas in rhesus monkeys. Boutons from prefrontal axons synapsing in the middle layers of superior temporal cortex were significantly larger than boutons synapsing in layer I. Most synapses were on spines in both layers, which are found on dendrites of excitatory neurons. The less prevalent synapses on smooth dendrites, characteristic of inhibitory interneurons, were more common in the middle cortical layers than in layer I. Bouton volume was linearly related to vesicular and mitochondrial content in both layers, though a subset of small boutons, found mostly in layer I, contained no mitochondria. The systematic laminar-specific presynaptic differences in stable cortical synapses in adult primates were independent of their origin in the functionally distinct prefrontal areas 10 and 32, or their destination in architectonically distinct superior temporal areas. This synaptic distinction suggests differences in efficacy of synaptic transmission and metabolic demands in laminar-specific pathways that may be selectively recruited in behavior.     

Increasing Interaction of amygdalar afferents with GABAergic interneurons between birth and adulthood

Previous work in animal models has shown that projections from the basolateral amygdala (BLA) progressively infiltrate the medial prefrontal cortex (mPFC) from birth to adulthood, with the most dramatic sprouting occurring during the postweanling period. GABAergic (gamma-aminobutyric acidergic) interneurons in the human homolog of the rat mPFC have been implicated in the pathophysiology of schizophrenia, an illness with an onset that is delayed until late adolescence. Here we investigated the interaction of BLA fibers with mPFC GABAergic interneurons from postnatal day 6 (P6) to P120 using anterograde tracing and immunocytochemistry. We found a 3-fold increase in axosomatic and an 8-fold increase in axo-dendritic contacts in both layers II and V of the mPFC. Ultrastructural analysis using a colloidal gold immunolocalization demonstrated that the greatest proportion of BLA appositions were with GABA-negative spines (30.8%) and GABA-positive dendritic shafts (35.5%). Although GABA-negative interactions demonstrated well-defined axo-spinous synapses, membrane specializations could not be identified with confidence in GABA-positive elements. Our findings suggest that GABAergic interneurons are major targets for BLA fibers projecting to the mPFC. The establishment of this circuitry, largely during adolescence, may contribute to the integration of emotional responses with attentional and other cognitive processes mediated within this region during corticolimbic development.     

Disruption of layer 4 development alters laminar processing in ferret somatosensory cortex

Treatment with the anti-mitotic agent methylazoxymethanol (MAM) on embryonic day 33 (E33) in ferrets changes features of somatosensory cortex. These include dramatic reduction of cells in layer 4, and altered distributions of thalamocortical afferent terminations and GABA(A) receptors. To determine the effect of the relative absence of layer 4 on processing of sensory stimuli we used current source-density profiles to assess laminar activity patterns. Nearly synchronous activation occurs across all layers in treated animals, which contrasts with the normal cortical activation pattern of initial sinks in layer 4. This change after MAM treatment is consistent with the absence of layer 4 cells and widespread termination of thalamocortical afferents. Using periodic stimulation at 'flutter' frequency, layer 4 neurons in normal somatosensory cortex fire reproducibly to the stimulus rate; the capacity for entrainment is best for layer 4 and weaker in the extragranular layers. The capacity to encode periodic sensory stimuli is disrupted in MAM-treated somatosensory cortex; after an initial response to the onset of periodic stimuli, neurons in all cortical layers show weak entrainment. Neural responses to sensory drive in E33 MAM-treated cortex are also embedded in levels of neural activity substantially above those in normal somatosensory cortex. Sustained stimulation additionally reveals different capacities in each layer for improved signal-to-noise ratios, with layer 4 neurons in normal animals exhibiting the most improved signaling over time. We conclude that normal thalamic terminations, an intact layer 4 and subsequent intracortical processing are integral to proper encoding of stimulus features.     

Fast-spike interneurons and feedforward inhibition in awake sensory neocortex

'Fast-spike' interneurons of layer 4 mediate thalamocortical feedforward inhibition and can, with some confidence, be identified using extracellular methods. In somatosensory barrel cortex of awake rabbits, these 'suspected inhibitory interneurons' (SINs) have distinct receptive field properties: they respond to vibrissa displacement with very high sensitivity and temporal fidelity. However, they lack the directional specificity that is clearly seen in most of their ventrobasal thalamocortical afferents. Several lines of evidence show that layer-4 SINs receive a potent and highly convergent and divergent functional input from topographically aligned thalamocortical neurons. Whereas the unselective pooling of convergent thalamocortical inputs onto SINs generates sensitive and broadly tuned inhibitory receptive fields, the potent divergence of single thalamocortical neurons onto many SINs generates sharply synchronous (+/-1 ms) activity (because of coincident EPSPs). Synchronous discharge of these interneurons following thalamocortical impulses will generate a synchronous feedforward release of GABA within the barrel. Thalamocortical impulses will, therefore, generate only a brief 'window of excitability' during which spikes can occur in the post-synaptic targets of fast-spike interneurons. This fast, synchronous, highly sensitive and broadly tuned feed-forward inhibitory network is well suited to suppress spike generation in spiny neurons following all but the most optimal feedforward excitatory inputs.     

Differential distribution of group I metabotropic glutamate receptors during rat cortical development

Neurons in the rat cerebral cortex are enriched in group I metabotropic glutamate receptor (mGluR) subtypes and respond to their activation during development. To understand better the mechanisms by which mGluR1 and mGluR5 mediate these effects, the goal of this study was to elucidate the expression pattern and to determine the cellular and the precise subcellular localization of these two receptor subtypes in the rat neocortex and hippocampus during late prenatal and postnatal development. At the light microscopic level, mGluR1alpha and mGluR5 were first detected in the cerebral cortex with different expression levels at embryonic day E18. Thus, mGluR5 had a moderate expression, whereas mGluR1alpha was detected as a diffuse and weak labeling. mGluR5 was localized in some Cajal- Retzius cells as well as in other cell types, such as pioneer neurons of the marginal zone. During postnatal development, the distribution of the receptors dramatically changed. From P0 to around P10, mGluR1alpha was localized in identified, transient Cajal-Retzius cells of neocortex and hippocampus, until these cells disappear. In addition, a population of interneurons localized the receptor from the second/third postnatal week. In contrast, mGluR5 was localized mainly in pyramidal cells and in some interneurons, with a neuropilar staining throughout the cerebral cortex. At the electron microscopic level, the immunoreactivity for both group I mGluR subtypes was expressed postsynaptically. Using immunogold methods, mGluR1alpha and mGluR5 immunoreactivities were found throughout postnatal development at the edge of postsynaptic specialization of asymmetrical synapses. These results show that the two group I mGluRs have a differential expression pattern in neocortex and hippocampus that may suggest roles for the receptors in the early processing of cortical information and in the control of cortical developmental events.