Morphological characteristics of various segments of local connections in the rat somatosensory cortex

Pyramidal, aspinous, sparsely-spinous bipolar and multipolar neurons of the rat sensomotor cerebral cortex, impregnated after Golgi method, have been studied at an electron microscopical level. The ultrastructural characteristics of the pyramidal neurons differs from that of the nonpyramidal cells. Distribution of various synaptic contacts on the cellular surface and cortical postsynaptic targets of the axonal arborizations of the neurons are revealed. On the body of the pyramidal cells only symmetrical synapses exist, on large dendritic trunks symmetrical synapses prevail, on the spines and the terminal dendritic branches assymetrical synapses mainly predominate. Axonal collateralies of the pyramidal cells form asymmetrical synapses on the spines, small and middle dendrites. There are more axo-somatic synapses on the bodies of the nonpyramidal neurons than on the pyramidal cells, among them both symmetrical and asymmetrical types of the synapses occur. On the trunks and small dendrites of the nonpyramidal cells both types of synaptic contacts are revealed. In the distal direction of the dendrites the number of the asymmetrical synapses becomes predominating. Axons of the bipolar cells form asymmetrical synapses on the spines, small and middle dendrites. Axons of the multipolar cells form symmetrical synapses on the dendrites and the dendritic trunks of the nondifferentiated cells. Differences in the distribution character of the synaptic inlets and various postsynaptic targets of the axonal systems in the cells assume various functional role of the identified neurons.     

Catecholaminergic innervation of pyramidal and GABAergic nonpyramidal neurons in the rat hippocampus. Double label immunostaining with antibodies against tyrosine hydroxylase and glutamate decarboxylase

This study describes the catecholaminergic innervation of rat hippocampal neurons at the electron microscopic level by using an antibody against tyrosine hydroxylase (TH) and immunocytochemical techniques. In a first series of experiments, the course and distribution as well as the synaptic contacts of TH-immunoreactive fibers were analyzed with the peroxidase-antiperoxidase (PAP) method. Next, peroxidase immunostaining of TH fibers was combined with glutamate decarboxylase (GAD) immunostaining, using avidinated ferritin as a second electrondense marker. Our results demonstrate that TH-immunostained terminals establish asymmetric synaptic contacts with spines of pyramidal neurons, and symmetric synaptic contacts with cell bodies and dendritic shafts of ferritin-labeled GAD-immunoreactive nonpyramidal cells.     

Glutamatergic components of the retrosplenial granular cortex in the rat

The ultrastructural characteristics, distribution and synaptic relationships of identified, glutamate-enriched thalamocortical axon terminals and cell bodies in the retrosplenial granular cortex of adult rats is described and compared with GABA-containing terminals and cell bodies, using postembedding immunogold immunohistochemistry and transmission electron microscopy in animals with injections of cholera toxin- horseradish peroxidase (CT-HRP) into the anterior thalamic nuclei. Anterogradely labelled terminals, identified by semi-crystalline deposits of HRP reaction product, were approximately 1 μm in diameter, contained round, clear synaptic vesicles, and established asymmetric (Gray type I) synaptic contacts with dendritic spines and small dendrites, some containing HRP reaction product, identifying them as dendrites of corticothalamic projection neurons. The highest densities of immunogold particles following glutamate immunostaining were found over such axon terminals and over similar axon terminals devoid of HRP reaction product. In serial sections immunoreacted for GABA, these axon terminals were unlabelled, whereas other axon terminals, establishing symmetric (Gray type II) synapses were heavily labelled. Cell bodies of putative pyramidal neurons, containing retrograde HRP label, were numerous in layers V–VI; some were also present in layers I–III. Most were overlain by high densities of gold particles in glutamate but not in GABA immunoreacted sections. These findings provide evidence that the terminals of projection neurons make synaptic contact with dendrites and dendritic spines in the ipsilateral retrosplenial granular cortex and that their targets include the dendrites of presumptive glutamatergic corticothalamic projection neurons.     

Catecholaminergic innervation of pyramidal and GABAergic nonpyramidal neurons in the rat hippocampus

Summary This study describes the catecholaminergic innervation of rat hippocampal neurons at the electron microscopic level by using an antibody against tyrosine hydroxylase (TH) and immunocytochemical techniques. In a first series of experiments, the course and distribution as well as the synaptic contacts of TH-immunoreactive fibers were analyzed with the peroxidase-antiperoxidase (PAP) method. Next, peroxidase immunostaining of TH fibers was combined with glutamate decarboxylase (GAD) immunostaining, using avidinated ferritin as a second electrondense marker. Our results demonstrate that TH-immunostained terminals establish asymmetric synaptic contacts with spines of pyramidal neurons, and symmetric synaptic contacts with cell bodies and dendritic shafts of ferritin-labeled GAD-immunoreactive nonpyramidal cells.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthday.     

CCK-immunoreactive terminals form different types of synapses in the rat and monkey hippocampus

Electronmicroscopic immunocytochemical analysis of the types and patterns of synaptic contacts formed by cholecystokinin (CCK)-containing terminals in the CA1 and CA3 region of the rat and monkey hippocampus reveals numerous symmetric synaptic contacts on cell bodies and dendritic shafts of pyramidal cells in both species. In the monkey, however, CCK-immunoreactive terminals also form asymmetric synaptic contacts with dendritic spines, such contacts are absent or very rare in the rat hippocampus. The present finding in primate hippocampus provides evidence that the same neuropeptides can be found in both symmetric and asymmetric contacts and may be added to other evidence challenging the traditional concept that symmetric synapses mediate exclusively inhibitory and asymmetric exclusively excitatory transmission. Furthermore, although our comparative analysis confirms considerable similarities in the distribution of CCK-containing elements in primate and rodent hippocampus it also revealed a potentially important difference in synaptoarchitecture that should be taken into account in extrapolations from one species to the other.     

CCK-immunoreactive terminals form different types of synapses in the rat and monkey hippocampus

Summary Electronmicroscopic immunocytochemical analysis of the types and patterns of synaptic contacts formed by cholecystokinin (CCK)-containing terminals in the CA1 and CA3 region of the rat and monkey hippocampus reveals numerous symmetric synaptic contacts on cell bodies and dendritic shafts of pyramidal cells in both species. In the monkey, however, CCK-immunoreactive terminals also form asymmetric synaptic contacts with dendritic spines, such contacts are absent or very rare in the rat hippocampus. The present finding in primate hippocampus provides evidence that the same neuropeptides can be found in both symmetric and asymmetric contacts and may be added to other evidence challenging the traditional concept that symmetric synapses mediate exclusively inhibitory and asymmetric exclusively excitatory transmission. Furthermore, although our comparative analysis confirms considerable similarities in the distribution of CCK-containing elements in primate and rodent hippocampus it also revealed a potentially important difference in synaptoarchitecture that should be taken into account in extrapolations from one species to the other.Dedicated to Professor Dr. T. H. Schiebler on the occasion of his 65th birthday     

Neuronal composition and interneuronal connection of area 5 in the cat parietal association cortex

Area 5 of the cat cortex was studied by Nissl's method and by Golgi's chromate-silver impregnation method. Its typical six-layered structure with well-developed layers of pyramidal cells was revealed. The characteristic features of area 5 are: predominance of pyramidal cells in layers II–III and the presence of large forms (40×26 µ) among them (in layer III); giant pyramidal neurons (70×23 µ) arranged singly or nidally in layer V; large (diameter 25–30 µ) and giant (diameter 40–45 µ) stellate cells with radial dendrites, arranged singly or in groups in layers V–VI; infrequent efferent fusiform neurons (40×20 µ) in layers V–VI. Stellate cells connecting pyramidal neurons in the same or in different layers were found in layers II–VI. Some stellate cells in layers II–III form long horizontal connections within area 5. Interneuronal connections are effected by axosomatic and axodendritic terminals, the latter being more numerous; Dendrodendritic and axoaxonal synapses are less common.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 11, No. 1, pp. 35–42, January–February, 1979.     

Cholinergic neurons in an association cortex slab chronically isolated from the cat

Small numbers of short- and long-axon cholinergic interneurons were revealed on a slab of association cortex three weeks after (neuronal) isolation from the cat by means of a histochemical acetylcholinesterase reaction. Short-axon neurons are located at layers II–VI and take the form of mainly spindle-shaped medium sized cells with their axons forming synaptic terminals on pyramidal and stellate neurons of the isolated section. Typical positioning of cholinergic terminals on the perikaryon and proximal portions of cholinoceptive neuron dendrites was noted. Pyramidal cholinoceptive cells may be classed as noncholinergic cells, whereas stellate cells may be either cholinergic or noncholinergic. Long-axon cholinergic interneurons of different shapes and sizes are situated at layers I and VI. Neuronal axons located in these layers run within fibers of the first and subcortical layers, establishing intracortical connections beyond the confines of the isolated section.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 21, No. 1, pp. 60–66, January–February, 1989.     

Comparative electron microscopic study of the visual cortex neurons of the cat in postnatal ontogeny

The maturation of layers II-VI of neurons and perineuronal neuropil of the cat visual cortex (field 17) was studied from postnatal day 1 to day 21. The differentiation of large, small (associate) pyramid and stellate neurons was described. During the first postnatal week, the somata of layers II-VI of neurons undergo significant changes, the perikaryal cytoplasm increases in volume. Cell bodies of large pyramidal neurons mature by day 15. During the second postnatal week and almost till day 15, the rough endoplasmic reticulum of small pyramidal and stellate neurons undergoes proliferation; dendritic processes are branching. In stellate neurons the amount of cytoplasmic organelles increases dramatically only after the second postnatal week, and this is presumably induced by the opening of eyes on day 12. The second postnatal week is the period of greatest growth of dendritic, axonal and glial processes in perineural neuropil of layers V-VI. In the perineuronal neuropil of large pyramidal neurons (layers V-VI) there appear symmetric synapses with pyramidal cells, dendritic processes and dendritic spines. This occurs just at the time when kittens first open the eyes. From this time and during postnatal days 15-21, asymmetric synapses appear in the perineuronal neuropil of large pyramidal neurons. In the perineuronal neuropil of small pyramidal and stellate neurons. (layers II-IV), synapses reveal the mature appearance by day 15. After the opening of the eyes and up to postnatal day 21, dendritic growth and spine production occur in the perineuronal neuropil of small pyramidal and stellate neurons.     

Dendritic spines and distributed circuits

Dendritic spines receive most excitatory connections in pyramidal cells and many other principal neurons. But why do neurons use spines, when they could accommodate excitatory contacts directly on their dendritic shafts? One suggestion is that spines serve to connect with passing axons, thus increasing the connectivity of the dendrites. Another hypothesis is that spines are biochemical compartments that enable input-specific synaptic plasticity. A third possibility is that spines have an electrical role, filtering synaptic potentials and electrically isolating inputs from each other. In this review, I argue that, when viewed from the perspective of the circuit function, these three functions dovetail with one another to achieve a single overarching goal: to implement a distributed circuit with widespread connectivity. Spines would endow these circuits with nonsaturating, linear integration and input-specific learning rules, which would enable them to function as neural networks, with emergent encoding and processing of information.     

Expression of nerve growth factor and its receptors in the somatosensory-motor cortex of Macaca nemestrina

The present study was designed to examine the nerve growth factor (NGF) system (ligand and receptor-expressing neurons) in the somatosensory (areas 1, 3a, and 3b) and motor (area 4) cortices of the mature macaque. Light and electron microscope immunohistochemistry was used to assess the distribution and identity of NGF-, p75-, and trk-expressing elements. In each cortical area examined, NGF-positive neuronal somata were distributed through all laminae; most immunolabeled neurons were in layers II, III, and V. Based upon light microscope criteria (e.g., the morphology of proximal dendrites), both pyramidal and stellate neurons expressed NGF. Of the identifiable NGF- immunoreactive cells, 92% were pyramidal neurons and the remainder was stellate neurons. The electron microscope study showed that most (88%) NGF-positive somata formed symmetric synapses, whereas the others formed both symmetric and asymmetric synapses. As the somata of pyramidal neurons form only symmetric synapses and those of inhibitory stellate neurons form both symmetric and asymmetric somatic synapses, the ultrastructural data support the light microscopic analyses. In contrast, neurotrophin receptors, p75 and trk, were expressed chiefly by the cell bodies of layer V pyramidal neurons and the supragranular neuropil. At the ultrastructural level, receptor-positive profiles were post-synaptic elements (e.g., dendritic shafts and spines) and the concentration of immunoreactivity was greatest in the vicinity of post-synaptic densities. Thus, NGF regulatory systems parallel excitatory and inhibitory neurotransmitter systems. Cortex contains the morphological framework by which pyramidal and/or inhibitory stellate neurons can affect the activity of post-synaptic pyramidal neurons via anterograde and autocrine/paracrine NGF systems.     

Neurons and their interconnections in the frontal cortex of monkeys

It was shown by the Golgi and Golgi-Kopsch method that pyramidal cells of layers II–IV in the frontal cortex of the monkeyMacaca rhesus have numeruous, mainly recurrent axon collaterals by means of which they form vertical connections. Pyramidal cells with ascending axons are found. Axons of stellate basket neurons unite pyramidal cells in both horizontal (modules) and vertical (micromodules) directions; depending on the direction of the axon collaterals, two groups of stellate neurons can be distinguished. Groups of 14 to 16 pyramidal cells whose apical dendrites are connected into bundles were found. Axons of pyramidal cells in layers II–IV descend in the composition of the pyramidal tract and give off collaterals which run toward the bodies and dendrites of neighboring pyramidal cells, united into the same group, forming terminal and en passant junctions. Besides bundles, special kinds of "local" cell groups with U-shaped axons are found.A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 15, No. 2, pp. 115–120, March–April, 1983.     

Intrinsic organization of the medial cerebral cortex of the lizard Lacerta pityusensis: A golgi study

The morphology of cells and the organization of axons were studied in Golgi-Colonnier and toluidine blue stained preparations from the medial cerebral cortex of the lizard Lacerta pityusensis. In the medial cortex, six strata were distinguished between the superficial glial membrane and the ependyma. Strata I and II formed the outer plexiform layer, stratum III formed the cellular layer, and strata IV go VI the inner plexiform layer. The outer plexiform layer contained smooth bipolar neurons; their dendrites were oriented anteroposteriorly and their axons were directed towards the posterior zone of the brain. Five neuronal types were observed in the cellular layer. The spinous pyramidal neurons had well-developed apical dendrites and poorly developed basal ones. Their axons entered the inner plexiform layer and gave off collaterals oriented anteroposteriorly. The small, sparsely spinous pyramidal neurons had poorly developed dendrites and their axons entered the inner plexiform layer. The spinous bitufted neurons had well-developed apical and basal dendritic tufts. Their axons gave off collaterals that reached the outer and inner plexiform layers of both the dorsomedial and dorsal cortices. The sparsely spinous horizontal neurons had dendrites restricted to the outer plexiform layer. Their axons entered the inner plexiform layer. The sparsely spinous, multipolar neurons had their soma close to stratum IV and their axons entered the outer plexiform layer. In stratum V of the inner plexiform layer were large, spiny polymorphic neurons; they had dendrites with long spines, and their axons reached the cellular layer. On the basis of these results, we have subdivided the medial cortex into two subregions: the superficial region, which contains the neurons of the cellular layer and their dendritic domains, and the deep region, strata V and VI, which contains the large, spiny polymorphic neurons. The neurons in the medial cortex of these lizards resembles those in the area dentata of mammals. On this basis, the superficial region may be compared to the dentate gyrus and the deep region to the hilar region of the hippocampus of mammals.     

Neuronal organization of field 4 of the motor cortex of the cat brain

By means of the silver nitrate impregnation method after Golgi-Kopsch in kittens and young cats the field 4 in the cerebral motor cortex has been studied. The motor cortex of the field 4 possesses certain heteromorphism. Besides usual stellate and pyramidal neurons, that differ from real ones by some morphological signs: their body is often round, the apical dendrite is much thinner than the corresponding dendrite of a pyramidal neuron, it does not produce oblique branches along the course, never gets into the I layer, the spines arrange less densely. According to the mode of dendrites setting off, the atypical pyramidal neurons can be divided into multipolar and spindle-like with horizontal or vertical branching of the dendrites. According to the spines distribution, the multipolar atypical neurons can be divided into spinous, rare-spinous and aspinous. With respect to various cellular forms and distribution of various types of neurons in layers, every of the areas (gamma, alpha, sfu, fu) possesses specific peculiarities. The greatest variability of the neurons have the field 4 gamma and 4 alpha, where, besides stellate and pyramidal, atypical neurons can be found. The stellate neurons of the field 4 gamma are characterized with a deep arrangement, their number is essentially less, than in other areas of the field 4. In the field 4 alpha they are situated in the layers II-III. Suprafundal and fundal parts of the field do not possess pyramidal atypical neurons and are characterized with presence of large amount of the stellate neurons. In respect to the axonal branching in the suprafundal part of the field 4, 2 types of the stellate cells are distinguished.     

Cholinergic neurons in the hippocampus

Summary We report here on cholinergic neurons in the rat hippocampal formation that were identified by immunocytochemistry employing a monoclonal antibody against choline acetyltransferase (ChAT), the acetylcholine-synthesizing enzyme. In general, ChAT-immunoreactive cells were rare, but were observed in all layers of the hippocampus proper and fascia dentata with a preponderance in zones adjacent to the hippocampal fissure and in the part of CA1 bordering the subiculum. All immunoreactive cells found were non-pyramidal neurons. They were relatively small with round or ovoid perikarya, which gave rise to thin spine-free dendrites. These hippocampal neurons were very similar to ChAT-immunoreactive cells in the neocortex of the same animals but were quite different from cholinergic neurons in the basal forebrain, medial septal nucleus, and neostriatum, which were larger and more intensely immunostained.Electron-microscopic analysis of ChAT-immunoreactive cells in the hippocampus and fascia dentata revealed synaptic contacts, mainly of the asymmetric type, on cell bodies and smooth proximal dendrites. The nuclei of the immunoreactive cells exhibited deep indentations, which are characteristic for non-pyramidal neurons.Our results provide evidence for an intrinsic source of the hippocampal cholinergic innervation in addition to the well-established septo-hippocampal cholinergic projection.Dr. C. Léránth is on leave of absence from the First Department of Anatomy, Semmelweis University Medical School, H-1450 Budapest, Hungary     

On the distribution of axonal terminals containing spheroidal and flattened synaptic vesicles in the hippocampus and dentate gyrus of the rat and cat

Summary A quantitative analysis has been made of the distribution of presynaptic profiles containing round (or spheroidal) and flattened (or ellipsoidal) synaptic vesicles in the apical and basal dendritic zones and in the layer of pyramidal cell somata of fields CA₁ and CA₃ of the hippocampus, and in the molecular and granular layers of the dentate gyrus of the rat and cat.In the apical and basal dendritic zones of fields CA₁ and CA₃ the overwhelming majority of the synapses are of the asymmetrical variety, the axon terminals ending principally upon dendritic spines, and to a lesser extent upon the shafts and secondary or tertiary branches of the dendrites. Between 1 and 8% of the axon terminals in these zones contained flattened vesicles: all of these formed symmetrical contacts upon medium-sized or large dendritic shafts. In the molecular layer of the dentate gyrus a slightly higher percentage of flattened vesicle containing profiles was observed (10%); again these formed symmetrical contacts upon dendritic shafts. In the stratum pyramidale of the hippocampal fields and the stratum granulosum of the dentate gyrus of the rat, flattened vesicle containing synapses are two or three times more numerous than those with spheroidal vesicles. In the cat hippocampus the axosomatic synapses are about equally distributed between those containing round, and those with flattened vesicles.The finding that at the focus of post-synaptic inhibition, at the level of the pyramidal cell somata, the majority of the axon terminals contains flattened synaptic vesicles, whereas in the region of termination of the extrinsic, commissural and long association pathways (all of which are excitatory) virtually all the synapses contain round vesicles, strongly supports the view that endings containing flattened vesicles mediate post-synaptic inhibition in the hippocampal formation.Supported in part by Grant EY-00599 from the National Eye Institute.We should like to thank Mr. Paul Myers and Mr. Milburn W. Rhoades for their technical assistance, and Mrs. Doris Stevenson for secretarial help.     

Morphology of the cat auditory cortex

The ultrastructural features of the primary auditory cortex of the cats and the character of the endings of geniculo-cortical afferent fibers in the early stages of experimental degeneration evoked by destruction of the medial geniculate body were studied. In all layers of the cortex asymmetrical synapses with round synaptic vesicles on dendritic spines and on thin dendritic branches of pyramidal and nonpyramidal neurons are predominant. Symmetrical synapses with flattened or polymorphic vesicles are distributed chiefly on the bodies of the neurons and their large dendrites. Because there are few symmetrical synapses which could be regarded as inhibitory it is postulated that inhibitory influences may also be transmitted through asymmetrical synapses with round vesicles. Other types of contacts between the bodies of neurons, dendrites, and glial processes also were found in the auditory cortex. Degenerating terminals of geniculo-cortical fibers were shown to terminate chiefly in layer IV of the cortex on pyramidal and nonpyramidal neurons. Degeneration was of the dark type in asymmetrical synapses with round vesicles. The results are dicussed in connection with electrophysiological investigations of the auditory cortex.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 5, No. 5, pp. 519–524, September–October, 1973.     

Changes of Dendritic Spine Density and Morphology in the Superficial Layers of the Medial Entorhinal Cortex Induced by Extremely Low-Frequency Magnetic Field Exposure

In the present study, we investigated the effects of chronic exposure (14 and 28 days) to a 0.5 mT 50 Hz extremely low-frequency magnetic field (ELM) on the dendritic spine density and shape in the superficial layers of the medial entorhinal cortex (MEC). We performed Golgi staining to reveal the dendritic spines of the principal neurons in rats. The results showed that ELM exposure induced a decrease in the spine density in the dendrites of stellate neurons and the basal dendrites of pyramidal neurons at both 14 days and 28 days, which was largely due to the loss of the thin and branched spines. The alteration in the density of mushroom and stubby spines post ELM exposure was cell-type specific. For the stellate neurons, ELM exposure slightly increased the density of stubby spines at 28 days, while it did not affect the density of mushroom spines at the same time. In the basal dendrites of pyramidal neurons, we observed a significant decrease in the mushroom spine density only at the later time point post ELM exposure, while the stubby spine density was reduced at 14 days and partially restored at 28 days post ELM exposure. ELM exposure-induced reduction in the spine density in the apical dendrites of pyramidal neurons was only observed at 28 days, reflecting the distinct vulnerability of spines in the apical and basal dendrites. Considering the changes in spine number and shape are involved in synaptic plasticity and the MEC is a part of neural network that is closely related to learning and memory, these findings may be helpful for explaining the ELM exposure-induced impairment in cognitive functions.     

Interneurons of the motor region of the neocortex]

Interneurons of motor area in the brain cortex have been studied in cats and monkeys. The greatest attention has been paid to pyramidal interneurons, among which six cell types have been described according to their axonal composition. Unlike stellate interneurons, all types of pyramidal interneurons possess less developed axonal collaterals. Interneuronal contacts are situated on dendrites or cell bodies of middle and large long-axonal pyramids. Functional role of cortical interneurons seems to be different. Some of them are of inhibitory nature (basket cells and, perhaps, other types of long-axonal stellate neurons), others are exciting elements. The latter include short-axonal stellate neurons and, perhaps, pyramidal interneurons. While comparing the cortex in cats and monkeys, it is evident that the neocortex in monkeys, especially its lower layers, is rich in pyramidal interneurons.     

Clustered dynamics of inhibitory synapses and dendritic spines in the adult neocortex

A key feature of the mammalian brain is its capacity to adapt in response to experience, in part by remodeling of synaptic connections between neurons. Excitatory synapse rearrangements have been monitored in vivo by observation of dendritic spine dynamics, but lack of a vital marker for inhibitory synapses has precluded their observation. Here, we simultaneously monitor in vivo inhibitory synapse and dendritic spine dynamics across the entire dendritic arbor of pyramidal neurons in the adult mammalian cortex using large-volume, high-resolution dual-color two-photon microscopy. We find that inhibitory synapses on dendritic shafts and spines differ in their distribution across the arbor and in their remodeling kinetics during normal and altered sensory experience. Further, we find inhibitory synapse and dendritic spine remodeling to be spatially clustered and that clustering is influenced by sensory input. Our findings provide in vivo evidence for local coordination of inhibitory and excitatory synaptic rearrangements.