Factors influencing astrocyte growth and development in defined media

A previously described serum-free, defined medium (G2 medium) containing transferrin, selenium, hydrocortisone, biotin, fibroblast growth factor (FGF) and fibronectin developed for the growth of human and rat derived glioma cells was investigated for its ability to support proliferation of astrocytes in primary cultures of neonatal rat cerebrum. These cells were able to grow in G2 medium. Enhanced proliferation and repeated subcultivation were obtained after adding insulin and/or epidermal growth factor (EGF) to the G2 medium at concentrations of 5 μg/ml and 10 ng/ml, respectively. In these modified media (called G4 and G5 medium) astrocytes showed a higher degree of morphological differentiation as compared to serum supplemented medium. Cell type specificity was determined by immunocytochemical staining of glial fibrillary acidic (GFA) protein, which could already be demonstrated 5 days after plating cells. G4 and G5 represent the first serum-free defined media in which astrocytes proliferate and differentiate without preceding or intermediate contact to serum supplemented medium. Modification of the culture substratum by adding hyaluronic acid and chondroitin sulfate A to G4 medium (G2 medium + insulin) enhanced proliferation of astroglial cells by a factor of about 1.5. In the presence of epidermal growth factor no response to the altered culture dish surface was observed and the addition of fibronectin, otherwise a stringent plating requirement, was no longer necessary.

Rapid morphological changes in astrocytes are accompanied by redistribution but not by quantitative changes of cytoskeletal proteins

Astrocytes have the potential to acquire very different morphologies, depending on their regional location in the CNS and on their functional interactions with other cell types. Morphological changes between a flat or a fibroblast-like and a stellate or process-bearing appearance, and vice versa, can occur rapidly, but very little is known as to whether morphological transformations are based on quantitative changes of cytoskeletal proteins in microfilaments, intermediate filaments, and/or microtubules. Using a cell culture of selective type 1 astrocytes, we compared the distribution and protein amounts of a number of cytoskeletal proteins both during primary process growth induced by specific media conditions and after secondary transformations induced by dBcAMP. Our data presented in this report support the idea that astrocytes can undergo dramatic changes in their morphology requiring subcellular redistribution of most cytoskeletal proteins but no quantitative modifications of the amount of the respective proteins. After pharmacological treatment with lysophosphatic acid and genistein we show that astrocytes can acquire intermediate morphologies reminiscent of both fibroblast and stellate-like cells. These experiments demonstrate that the recently described RhoA-mediated signaling cascade between the cell surface and cytoskeletal proteins is only one of several signaling pathways acting on the astrocytic cytoskeleton.

Transient changes in cortical distribution of S100 proteins during reorganization of somatotopy in the primary motor cortex induced by facial nerve transection in adult rats

In adult rats, the primary motor cortex (MI) comprises a somatotopic map of muscle representations. This somatotopy is modified after transection of the facial nerve (N7x). Mapping with cortical stimulation revealed that the underlying cortical reorganization is biphasic. Primary changes cause a transient disinhibition of long cortico-cortical connections in both hemispheres. While the first reaction vanishes within a few hours, short intra-areal connections are disinhibited within MI contralateral to N7x. The resulting co-operation between adjacent parts of MI persists as long as peripheral reinnervation is prevented. Cellular mechanisms underlying this cortical reorganization are largely unknown. Here, we utilized changes in immunoreactivity of S100 proteins (S100-IR) known as a sensitive indicator of astroglial reactions during plastic reactions in the central nervous system. Within 1 h of N7x, zones with enhanced S100-IR appeared in both hemispheres. Between 3. 5 and 18 h, reaction patterns with changing topography were transiently prominent in many cortical areas including parts of MI which surrounded the facial muscle representation fields. After 24 h, the facial muscle representation contralateral to N7x became labelled while S100-IR enhancement disappeared in most of the cortex. S100-IR-enhancement vanished completely during the next day of survival. Data presented suggest that (i) enhancement of S100-IR labels cortical tissue during the functional reorganization that is induced by N7x, (ii) large parts of the cerebral cortex participate in the reorganization, before it is finally focused on the representation field of MI that corresponds with contralateral N7x, and (iii) temporo-spatial patterns of astrocytic reactions apparently play a role in the underlying plasticity reaction.

Facial nerve injury-induced disinhibition in the primary motor cortices of both hemispheres

Unilateral facial nerve transection induces plastic reorganization of the somatotopic order in the primary motor cortex area (MI). This process is biphasic and starts with a transient disinhibition of connections between cortical areas in both hemispheres. Little is known about the underlying mechanisms. Here, cortical excitability has been studied by paired pulse electrical stimulation, applied either within the MI or peripherally to the trigeminal nerve, while the responses were recorded bilaterally in the MI. The ratios between the amplitudes of the second and first evoked potentials (EPs or fEPSPs) were taken as measures of the inhibitory capacity in the MI ipsilateral or contralateral to the nerve injury. A skin wound or unilateral facial nerve exposure immediately caused a transient facilitation, which was followed by a reset to some level of inhibition in the MI on both sides. After facial nerve transection, the first relatively mild reduction of inhibition started shortly (within 10 min) after denervation. This was followed by a second step, involving a stronger decrease in inhibition, 40-45 min later. Previous publications have proved that sensory nerve injury (deafferentation) induces disinhibition in corresponding areas of the sensory cortex. It is now demonstrated that sham operation and, to an even greater extent, unilateral transection of the purely motoric facial nerve (deefferentation), each induce extended disinhibition in the MIs on both sides.

Modulation of the truncated GAD25 by estrogen in the olfactory bulb of adult rats

The aim of our study was to investigate the influence of gonadal steroids on the expression of different GAD isoforms. Here we show that, in addition to the adult GAD forms, the two embryonic splice variants of GAD67 mRNA and the truncated GAD25 are present in the adult rat olfactory bulb, a brain region with high synaptic plasticity, which has preserved some features of the developing brain. By Western blot analysis, we could demonstrate that the expression of the embryonic GAD25 is cyclic in females: its quantity is higher on estrus day. Furthermore, in ovariectomized animals 17-beta-estradiol treatment induced an increase of GAD25 within 3 h, reaching a maximum at 9-12 h. Our data are compatible with the interpretation that the embryonic GAD isoforms may play a role in the neuroplastic changes induced by sexual steroids.

Facial nerve injury produces a latent somatosensory input through recruitment of the motor cortex in the rat

Short-latency effects of unilateral facial nerve transection were studied on neuronal activation evoked in the primary motor cortex (MI) on both sides by vibrissa stimulation in adult rats. In the controls, unilateral trigeminal stimulation evoked activity in the whisker representation of both the contralateral somatosensory cortex (SI) and MI, but never in the ipsilateral MI. Unilateral transection of the facial motoric nerve facilitated evoked responses in the contralateral MI, and induced further neuronal activation (gross potentials and unit activity) in the MI ipsilateral to the stimulation. Since these changes appeared rapidly and could be mimicked by picrotoxin application onto the SI contralateral to the stimulation, they are considered to be based on the disinhibition of preexisting associative and commissural connections, which are unmasked by facial nerve transection.

Activation of the primary motor cortex by somatosensory stimulation in adult rats is mediated mainly by associational connections from the somatosensory cortex

In anaesthetized adult rats, facial nerve injury causes a disinhibition of the interhemispheric connections between homotopic representation fields in the primary motor cortex with a latency of 4 min (Toldi et al., 1996, Neurosci Lett. 203, 179-182). One possible explanation for the induction of such rapid changes is an alteration of the somatosensory input to the motor cortex. To test this hypothesis, unit activity in primary motor cortex was recorded during electrical stimulation of trigeminal afferents in the contralateral whisker-pad. About one-third of all recorded primary motor cortex neurons responded with latencies shorter than in the ventrolateral and posterior nuclei of the thalamus. Responses failed at stimulation frequencies > or = 10 Hz and after elimination or inactivation of the somatosensory cortex. Within primary motor cortex, the activatable neurons displayed a bilaminar distribution and were identified as pyramidal neurons by neurobiotin labelling. The results suggest that trigeminal afferents participate in modulation of the activity of primary motor cortex output neurons via primary somatosensory cortex-to-primary motor cortex associational connections, even under anaesthesia.

Autocellular coupling by gap junctions in cultured astrocytes: a new view on cellular autoregulation during process formation

Neocortical astrocytes make two types of gap junctions, intercellular ones create a functional syncytium, while reflexive gap junctions mediate autocellular coupling and serve unknown functions (Rohlmann and Wolff, 1996). Here, the question is addressed whether solitary astrocytes in vitro express connexin43 (Cx43) and establish gap junctions in the absence of intercellular contacts. In all media conditions tested, immunocytochemistry visualized Cx43-expression and gap junctions irrespective of the presence or absence of intercellular contacts. Reflexive gap junctions were associated with mechanical junctions (adherent spots and fascia adherens) connecting surface membranes and cytoskelal components, respectively. Both were characteristically located along incompletely separated borders between developing processes and/or branches. In addition, Cx43-immunoreactivity was found on some non-junctional membranes: i) intracellular vesicle clusters sited to forming processes and at the basis of filopodia; ii) the surface membrane of filopodial subpopulations usually appearing in bunches. Results suggest changes in the resumptive role of Cx43 in cultivated astrocytes: 1) Cx43 is not confined to intercellular gap junctions, it may even selectively compose reflexive ones; 2) from intracellular stores (vesicle aggregates), Cx43 may be incorporated into the surface membrane of filopodia; 3) by contacting other parts of the same cell surface (or neighboring cells), filopodia and membrane patches carrying Cx43-half channels may be essential in initial steps of gap junction formation; 4) the distribution of reflexive gap junctions is compatible with the hypothesis that autocellular coupling serves reorganization of cytoskeleton during the formation of cell processes and branches; 5) in general, gap junctions may be important for coordinating the cytoskeleton across intercellular contacts and within cells with complex shape.

Distribution of astroglia in glomeruli of the rat main olfactory bulb: exclusion from the sensory subcompartment of neuropil

During an entire lifetime, sensory axons of regenerating olfactory receptor neurons can enter glomeruli in the olfactory bulb and establish synaptic junctions with central neurons. The role played by astrocytes in this unique permissiveness is still unclear. Glomerular astrocytes have been identified by immunocytochemistry for glial fibrillary acidic protein and S100 proteins at the light and electron microscopic levels. The latter labeling included submicroscopic lamellar and filopodial extensions of astroglial processes. Cell bodies and processes accumulate along the border between juxtaglomerular walls and glomerular neuropil. Within glomeruli, a network of astroglial processes encloses mesh-like neuropil zones devoid of astroglia. Electron microscopy confirmed the division into subcompartments of glomerular neuropil: 1) The "sensory-synaptic subcompartment" includes all sensory axon terminals and terminal dendritic branches receiving sensory input, whereas astroglia are excluded; 2) in the "central-synaptic subcompartment," astroglial processes are intermingled with other neuropil components: dendrites of relay cells and interneurons, dendrodendritic synapses, centrifugal (cholinergic and serotonergic) axons, their axodendritic synapses, and blood vessels. Unevenly distributed astroglial processes in this subcompartment are attached to vascular basal laminae, stem dendrites, and subpopulations of dendrodendritic synapses, especially those colocalized with centrifugal projections ("triadic synapses"). Astroglia-free parts of the "central" subcompartment contain segments of dendrites and subpopulations of dendrodendritic synapses. Because of the subdivision of the glomerular neuropil into portions with and without glial components, glia do not completely demarcate the border between the "sensory" and the "central" subcompartments. Interdigitation between the subcompartments varies among glomeruli and even within a single glomerulus. The mesh width of astroglial networks covaries with numerical relations between sensory and dendrodendritic synapses. This distribution pattern of astrocytes suggests that these glial cells monitor brain-derived effects on olfactory glomerular neuropil rather than olfactory input and that astroglial processes are (re-)arranged accordingly.

Beta-galactosidase-labelled relay neurons of homotopic olfactory bulb transplants establish proper afferent and efferent synaptic connections with host neurons

The vertebrate olfactory system has long been an attractive model for studying neuronal regeneration and adaptive plasticity due to the continuous neurogenesis and synaptic remodelling throughout adult life in primary and secondary olfactory centres, its precisely ordered synaptic network and accessibility for manipulation. After homotopic transplantation of fetal olfactory bulbs in bulbectomized neonatal rodents, newly regenerated olfactory neurons form glomeruli within the graft, and the efferent mitral/tufted cells of the transplant innervate the host brain, terminating in higher olfactory centres. However, the synaptic connections of the transplanted relay neurons within the graft and/or host's olfactory centres could not be characterized mainly because of lack of suitable cell-specific markers for these neurons. In this study, we have used olfactory bulbs from transgenic fetuses, in which the majority of the mitral/tufted cells express the bacterial enzyme beta-galactosidase, for homotopic olfactory bulb transplantation following complete unilateral bulbectomy. In the transplants, the cell bodies and terminals of the donor mitral/tufted cells were identified by beta-galactosidase histochemistry and immunocytochemistry at both light and electron microscope levels. We demonstrate that transplanted relay neurons re-establish specific synaptic connections with host neurons of the periphery, source of the primary signal and central nervous system, thereby providing the basis for a functional recovery in the lesioned olfactory system.

Visualization of beta-galactosidase by enzyme and immunohistochemistry in the olfactory bulb of transgenic mice carrying the LacZ transgene

In the olfactory bulb (OB) of a transgenic mouse line that carries the bacterial LacZ gene under the control of the 5'-regulatory region of the GAD67 gene, expression of the beta-galactosidase was confined almost exclusively to the non-GABAergic mitral and tufted cells. By light microscopy, enzyme histochemistry showed strong staining in the cell bodies and faint diffuse staining in the axons and dendrites. With immunohistochemistry for beta-galactosidase the entire cytoplasm, including the axons and dendrites, was strongly stained. By electron microscopy, beta-galactosidase enzyme histochemistry resulted in a submicroscopic reaction product that was diffusely distributed in the cytoplasm of neurons. In addition, large deposits of the reaction product were also seen attached to the cytoplasmic side of the membranes. In contrast, when the intracellular localization of beta-galactosidase was determined by immunohistochemistry, homogeneous cytoplasmic staining was obtained that filled the entire cytoplasm including the terminal dendrites and fine axons. Therefore, synaptic contacts of the beta-galactosidase-positive output neurons with other beta-galactosidase-negative neuronal cells were readily recognized in the OB. As we demonstrated, transgenic mouse lines expressing the LacZ reporter gene in a well-defined neuronal subpopulation can be used to follow beta-galactosidase-positive neurons and to directly identify their synaptic connections.

Non-conventional role of lysosomal acid phosphatase in olfactory receptor axons: co-localization with growth-associated phosphoprotein-43

Olfactory receptor neurons undergo a continuous turnover in adult mammals. It is largely unknown how their axons invade the olfactory bulb and induce synaptic re-organization in glomeruli. Here, the cytochemical localization of lysosomal acid phosphatase has been studied in olfactory bulbs of adult rats and mice. The enzyme has been identified by specific substrate, inhibitors and absence in lysosomal acid phosphatase-knockout mice. Lysosomal acid phosphatase is located in primary and secondary lysosomes, which are unevenly distributed in the olfactory nerve layer and among olfactory glomeruli. In consecutive sections of glomeruli, the intensity of lysosomal acid phosphatase immunoreactivity co-varied with that of growth-associated phosphoprotein. Electron microscopically, differential lysosomal acid phosphatase staining in glomeruli corresponded to different proportions of labelled and unlabelled axons. Quantification revealed that lysosomal acid phosphatase labelling was strongest in non-synaptic profiles of terminal axons, while it was weak in or even missing from most synaptic profiles. Hence, growing olfactory axons apparently carry more lysosomal acid phosphatase than those which have established synaptic contacts. Following olfactory deafferentation both lysosomal acid phosphatase activity and growth-associated phosphoprotein-43 are lost from glomeruli, suggesting that both proteins are expressed in olfactory sensory axons during growth, while lysosomal acid phosphatase is apparently not a marker of anterograde terminal degeneration.

Localization and biochemical characterization of acid phosphatase isoforms in the olfactory system of adult rats

Localization of acid phosphatases was studied with the use of beta-glycerophosphate and p-nitrophenyl phosphate as substrates in the brain with special emphasis on the olfactory system of adult rat at light and electron microscopic level. With the use of beta-glycerophosphate, a selective substrate for the lysosomal acid phosphatase, lead-containing reaction product was found in primary and secondary lysosomes of neurons, glial cells and perivascular macrophages as well as in the cytoplasm of olfactory sensory axons. Incubation with p-nitrophenyl phosphate as substrate additionally revealed a cytoplasmic isoform of acid phosphatase, which could not be inhibited by tartrate or fluoride and was predominantly located in dendrites. Acid phosphatase isoforms were biochemically characterized in samples prepared separately from the olfactory mucosa, olfactory nerve layer, olfactory bulb and its dendrodendritic synaptosomes isolated by subcellular fractionation. In the olfactory mucosa and olfactory nerve layer the lysosomal type (high molecular weight form) was the most prominent acid phosphatase form, whereas the isoform located in dendrites corresponded to the tartrate-resistant extralysosomal, cytosolic type (low molecular weight form). The functional significance of different isoforms of acid phosphatase in the olfactory sensory axons and dendritic elements is discussed.

Rapid astroglial reactions in the motor cortex of adult rats following peripheral facial nerve lesions

We report on changes in the motor cortex of adult rats that rapidly and transiently followed various types of facial nerve lesions. These reactions led to enhanced immunoreactivities of various astroglial markers: S-100 protein (a Ca2+- and Zn2+-binding protein predominantly located in the cytosol of astrocytes), glial fibrillary acidic protein (a cytoskeletal protein) and connexin 43 (the astroglial gap junction protein). Reactions could be visualized 1 h after the facial nerve lesion and disappeared within about 5 days after surgery. Combined lesions of the facial and trigeminal nerves modified the spatial pattern of the astroglial reaction, similar to intramuscular injections of botulinum toxin, which inhibits the release of acetylcholine in motor endplates. Data presented suggest that peripheral interference with muscular functions rapidly induces modifications in the motor cortex.

Changes in glial fibrillary acidic protein immunoreactivity in the rat facial nucleus following various types of nerve lesions

We report about changes on astrocytes in the facial nucleus of the rat following various types of peripheral nerve lesions. Astrocyte-specific glial fibrillary acidic protein (GFAP) was labeled by immunohistochemistry and served as a marker for these changes. Increased GFAP immunoreactivity was found in the facial nucleus on the lesioned side within 2-3 days after axotomy. This change lasted longer (up to 1 year) when axon regeneration was prevented or delayed by placing a metal clip on the proximal nerve stump. Lesion of the trigeminal nerve prior to axotomy reduced the degree of GFAP immunoreactivity. No side differences were observed after botulinum toxin application.

Electron microscopical evidence of synaptic reorganization in the contralateral motor cortex of adult rats following facial nerve lesion

Here we report on the rapid changes in the motor cortex of the rat following peripheral lesioning of a motor nerve. Facial nerve transection increases synaptic reorganization (autophagy, lysosomal degradation of synaptic components) already within 4 h after lesion. These changes occur in the motor cortex of both hemispheres, i.e. on the same and contralateral sides. An increase in the number of presynaptic lysosomes was transient and returned to below normal values within 24 h after facial nerve transection.

Large-scale purification of synaptophysin and quantification with a newly established enzyme-linked immunosorbent assay

Synaptophysin (SYP I), an integral membrane protein, was purified on a large scale (0.55 - 2.7 mg) from isolated small synaptic vesicles (SSV) of porcine cortex. In order to achieve this, a conventional purification procedure which consists of size exlusion chromatography, hydrophobic interaction chromatography and chromatofocusing has been developed. This procedure was compared with purification of SYP I by immunoaffinity chromatography. The elution patterns of both procedures were monitored using sodium dodecylsulfate gel electrophoresis (SDS-PAGE) with subsequent Coomassie blue staining of proteins and simultaneous immunoblotting with SYP I-specific antibody. Contaminating proteins with relative molecular masses (M(r)) very similar to SYP I could be removed during the process of purification, demonstrating that the 38 kDa protein found after Triton X-100 lysis of enriched SSV does not exclusively represent SYP I. A specific antiserum was raised in rabbits using a highly purified preparation of SYP I. This antiserum was used in combination with a monoclonal antibody to establish a specific and sensitive enzyme-linked immunosorbent assay (ELISA) which allowed rapid and reliable quantification of this hydrophobic membrane protein in all purification steps, starting with Triton X-100-lysed brain homogenates. Using this ELISA, the concentration of SYP I in highly purified SSV was determined to be 5.8% of solubilized protein.

Cholinoceptive neurons without acetylcholinesterase activity and enzyme-positive neurons without cholinergic synaptic innervation are present in the main olfactory bulb of adult rat

Light and electron microscopic histochemistry revealed acetylcholinesterase-positive and acetylcholinesterase-negative neurons in the main olfactory bulb of adult rat. Their distribution patterns on various neuron types have been analysed in detail. (1) No acetylcholinesterase staining could be demonstrated in the granule cells which receive a large number of the cholinergic synapses. (2) In contrast, enzyme activity was present in the soma and dendrites in most of the non-cholinergic and non-cholinoceptive relay cells (mitral cells and tufted cells) and in a subset of short-axon interneurons, where cholinergic synapses could not be detected. (3) Within the neuropil of glomeruli, two compartments were present, one of which was free of acetylcholinesterase-positive structures, while many enzyme-positive neuronal elements were seen in the other. (4) Characteristically, cholinergic and non-cholinergic neuronal structures showed triadic arrangements. (5) The axonal release of acetylcholinesterase from cholinergic axons is probable. It is suggested that, in the olfactory bulb, acetylcholinesterase is release by cholinergic afferent axons, and it is the cholinergic synapses that determine which postsynaptic neurons are cholinoceptive rather than the intraneuronal presence of acetylcholinesterase. In the main olfactory bulb, the acetylcholinesterase present in the relay cells therefore appears to have functions other than the hydrolysis of acetylcholine.

The structural localization of galanin, and its function in modulating acetylcholine release in the olfactory bulb of adult rat

The localization of galanin immunoreactivity was analyzed within the olfactory bulb of adult rats. Galanin-positive neurons were differentially distributed among the bulb layers. The density of stained neurons was highest in the glomerular and external plexiform layers. According to morphology, size, location and arrangement, a large proportion of galanin-immunoreactive neurons corresponds to external tufted cells and short-axon neurons in the superficial part of the external plexiform and glomerular layers. A smaller number were middle tufted cells and short-axons neurons while only a few short-axon neurons were labeled in the granule cell layer. Galanin-stained nerve fibers had different structures (thick fibers with or without varicosities, and thin fibers with or without varicosities). Among them were afferent immunoreactive nerve fibers entering the bulb through the olfactory nerve layer, but penetrating superficial layers. Correspondingly, a large number of galanin-positive axons (with or without varicosities) were observed in the olfactory nerve layer. A number of galanin-positive nerve fibers was also present in the glomerular and internal plexiform layers, while these fibers were scarce in the granule cell layer, their density was lowest in the external plexiform layer. These results suggest that galanin-positive axons present in the olfactory bulb originate from at least four different sources. From the periphery axon bundles enter the bulb together with olfactory nerve fibers from the rostral direction and with a fiber bundle from the ventral posterior surface, i.e. at the border between the olfactory tract and the main olfactory bulb along a large blood vessel. Central sources are local interneurons in the olfactory bulb and some extrabulbar brain regions. Double-labeling experiments combining acetylcholinesterase histochemistry with galanin immunocytochemistry did not show any co-localization of acetylcholinesterase and galanin in nerve cell perikarya or nerve fibers. Synthetic porcine galanin (1-29) promoted acetylcholine release in olfactory bulb tissue slices, suggesting that galanin can effectively modulate cholinergic transmission and perhaps other forms of neuronal transmission. It is concluded that galanin may be significantly involved in olfactory processing at cellular and synaptic levels.

Complex synaptic arrangements in the rat suprachiasmatic nucleus: a possible basis for the "Zeitgeber" and non-synaptic synchronization of neuronal activity

A special type of complex synaptic arrangement occurs in the ventro-lateral portion of the rat suprachiasmatic nucleus. These arrangements are polycentric, with about equal numbers of pre- and postsynaptic elements. Because of an incomplete astroglial covering, these synaptic complexes are connected with each other and form a continuous reticulum or sponge-like system throughout the ventro-lateral region of the nucleus. In two partially reconstructed complex synaptic arrangements, boutons from retinal afferents could be seen to make up the majority of presynaptic elements. They form asymmetric and symmetric synaptic appositions with dendritic elements. Non-optic axo-dendritic synapses of unknown origin with asymmetric and symmetric appositions and dendro-dendritic synapses with symmetric appositions are also seen in complex synaptic arrangements. Within complex synaptic arrangements, dendrites often run in bundles, with some dendrites spiralling around others. Membranes of neighbouring dendrites are closely apposed. These interdendritic appositions are possibly ephapses and may, together with intersomatic contacts, mediate non-synaptic synchronization of neuronal activity in the suprachiasmatic nucleus, as described by other authors. The activity of optic and non-optic synapses in complex synaptic arrangements over a 24 h period may also produce an integrated response that influences the circadian rhythm of neuronal activity in this nucleus.

Neuronal plasticity induced by neonatal monocular (and binocular) enucleation

Monocular (ME) and binocular enucleation has become a useful experimental tool for analyzing the mechanisms of neural plasticity. ME when performed during an early postnatal period (up to 15 days after birth) initiates a series of adaptive reactions in the visual (and other sensory) system(s) which tend to compensate for the lost sensory capacity. Extirpation of one eye (usually the right) destroys afferents to both lateral geniculate bodies dorsal nucleus (CGLd) and superior colliculi (CS), being severely impaired by the degeneration of retino-geniculate and collicular synapses. The sprouting of retinogeniculate fibers coming from the remaining eye replaces these synapses in both CGLds. Ipsilateral representation of the remaining eye (usually of minor significance) becomes extended in the left CGLd and consequently in the left visual area, just as in the superior colliculi. A similar but somewhat smaller extension takes place in the contralateral CGLd and visual cortex. The strengthening of commissural connections results in a remarkable extension of callosally connected stripes and patches in both hemispheres. After ME in the critical period, the control over behavior is taken over by the remaining eye. Its power of resolution is improved because of the higher survival of (mainly ipsilaterally projecting) ganglion cells. Therefore, both hemispheres are still available for storing visual information. In ME rats the learning of visual tasks requires both hemispheres, but relearning is still possible after extirpation of the contralateral one. The possible two main mechanisms of adaptive plastic changes are: (i) replacement of degenerated synapses by sprouting collaterals of ingrowing foreign fibers, and (ii) neurons having morphologically intact but inactive synapses establishing connections with afferent fibers other than the usual. The same mechanism is seen operating in cross-modal adaptive reactions as well.

Biphasic reorganization of somatotopy in the primary motor cortex follows facial nerve lesions in adult rats

Effects of facial nerve transection were studied on muscle responses evoked by electrical stimulation in the primary motor cortex (MI) of adult rats. In intact animals, activated muscles varied according to the somatotopic representation map, and responses were restricted to the contralateral side. Unilateral transection of the facial nerve extinguished contralateral vibrissal responses, while ipsilateral vibrissae began to respond within 4 min. This abnormal response (primary change) was transient and gradually disappeared within hours to days. Instead, contralateral movements of forepaw and eye/eyelid muscles could be evoked from increasing portions of the former vibrissal field (secondary change), in which many points became unresponsive. After 4 days, the former vibrissal field had shrunk to a small central part, where ipsilateral vibrissae responsiveness remained. The secondary modification was stable for at least 2 weeks. Since the primary change is rapid, transient and may be mimicked by picrotoxin, it may be based on disinhibition of commissural connections, while the secondary change is longlasting and therefore may include some form of reorganization of associational synapses.

Changes in the phosphorylation of neurofilament proteins in facial motoneurons following various types of nerve lesion

This report defines the conditions for changes in the phosphorylation state of neurofilaments (NF) after facial nerve lesions. In adult control rats, few phosphorylated neurofilament (pNF) epitopes were stained (using SMI 31 antibodies) in a small subpopulation of facial motoneurons. After various types of mechanical lesion (nerve transection with and without attaching a metal clip to the proximal nerve trunk, nerve crush, combined trigeminal and facial nerve lesions) of the right facial nerve, pNF immunoreactivity transiently increased in most cell bodies of facial motoneurons on the operated side. This pNF 'reaction' started within 2 days after the operation and persisted up to 2 weeks but remained longer in those animals in which axonal regeneration had been prevented or delayed by attaching a metal clip to the proximal nerve stump. After botulinum toxin application into facial muscles (i.e. inhibition of synaptic transmission at motoric endplates) there was no increase in the amount of pNF after 4 and 10 days, but it appeared in facial nuclei 4 weeks after injection on both, the treated and the untreated side, i.e. during functional restitution. Selectively transecting the 'vibrissal part' of the trigeminal nerve induced no obvious changes in the pNF immunoreactivity in facial motoneurons, but a combined trigeminal-facial lesion did. Labeling nonphosphorylated epitopes (using SMI 32 antibodies) showed a slight decrease in immunoreactivity in the neuropil of the facial nucleus 15 days after nerve transection and fixing a metal clip on the proximal nerve stump.

Expression of S100 protein in the vestibular nuclei during compensation of unilateral labyrinthectomy symptoms

In adult guinea pigs, unilateral labyrinthine lesions were inflicted by chloroform injections into the middle ear. Immunoreactivity for S100 protein (S100) in the vestibular nuclei was studied during compensation of lesion-induced postural asymmetry symptoms, i.e., nystagmus, asymmetrical head position. 1 h after unilateral labyrinthectomy, increased levels of astroglial S100 immunoreactivity were found in the superior vestibular nucleus and in the medial/lateral vestibular nucleus border region on the side contralateral to the deafferentation. Bilaterally, the astrocytic S100 immunoreaction increased in the lateral vestibular nuclei around Deiters neurons. Maximal expression of S100 was noted 3 h after the lesion. Subsequently, it diminished. Our data reveal that transsynaptically altered neuronal activity induces an astrocytic reaction which provides increased levels of S100 to the local neuropil. Calcium and zinc binding S100 proteins may play a functional role for the neuroplasticity during vestibular compensation.

Identification of the Ulex europaeus agglutinin-I-binding protein as a unique glycoform of the neural cell adhesion molecule in the olfactory sensory axons of adults rats

Histochemical localization of two lectins, Ulex europaeus agglutinin-I (UEA-I) and Tetragonolobus purpureus (TPA), was studied in the olfactory bulb of adult rats. In contrast to TPA, UEA-I detected a fucosylated glycoprotein that is only present in the surface membranes of olfactory sensory cells including the whole course of their neurites up to the final arborization in glomeruli. Immunoblotting revealed that UEA-I binds specifically to a protein of 205 kDa, while TPA stains several other glycoproteins. Affinity chromatography with the use of a UEA-I column identified the 205 kDa protein as a glycoform of neural cell adhesion molecule (N-CAM), specific for the rat olfactory sensory nerves.

S100 protein expression in subpopulations of neurons of rat brain

Available data are conflicting as regards the occurrence of Ca2+ and Zn2+ binding S100 proteins in neurons of mammalian brain. Here the localization and expression of S100 was re-investigated using several different antibodies and in situ hybridization. A map is provided for the distribution of two classes of S100-positive neuron populations in the adult rat CNS. "Persistently S100-positive" neurons had large size, were strongly immunoreactive and were mainly distributed in the nuclei of the lower brainstem and cerebellum. "Variably S100-positive" neurons were preferentially found in the forebrain of rats older than 90 days and were especially numerous in limbic regions. The S100-immunoreactivity in these neurons was moderately intense, occurred with high interindividual variation and appeared related to function as suggested by variations due to anesthesia. The expression of S100 mRNA in neurons was re-investigated at high spatial resolution with non-radioactive in situ hybridization using an oligonucleotide specific for S100 beta-mRNA. Expression of S100 was demonstrated in astrocytes and in those neuron populations which were also strongly S100-immunoreactive. No expression of S100 beta message was seen in weakly immunoreactive neurons, b but this may be due to low sensitivity of the techniques used. The data suggest that the S100 proteins are synthesized in all astrocytes and in distinct subpopulations of neurons in rat brain. These neurons show a characteristic topography and vary in S100 expression probably due to their function and maturation.

Synaptic and non-synaptic cholinergic innervation of the various types of neurons in the main olfactory bulb of adult rat: immunocytochemistry of choline acetyltransferase

The cholinergic neuronal structures and their synaptic connections in the main olfactory bulb of adult rats were analysed by using choline acetyltransferase immunocytochemistry. Within the glomeruli, cholinergic nerve fibers were restricted to strands which subdivided the neuropil into small compartments, the interior of which contained sensory axons but was devoid of cholinergic axons. Small numbers of choline acetyltransferase neurons were detected in all layers. Ultrastructural analysis revealed selective triadic synaptic relationships with different neuron classes in the intraglomerular area and in the external plexiform layer. These triads were made up of (i) a cholinergic axon, (ii) one or several periglomerular or granule cell dendrites, and (iii) usually one relay cell dendrite. In these triads, asymmetric cholinergic synapses were selectively focused on dendrites (gemmules and spines) of periglomerular or granule cells. Within the glomerulus, mitral and tufted cell dendrites were closely apposed to some cholinergic axon varicosities, most abundantly near arborizations of the apical dendrites. However, cholinergic synapses were never seen on any relay cell dendrite. In the external plexiform layer, cholinergic synapses were present on all parts of the superficial short-axon cells. In the internal plexiform layer and the granule cell layer, cholinergic axon varicosities exhibited close apposition or asymmetric synapses with granule cell gemmules. The data suggest that cholinergic projections from the basal forebrain to the main olfactory bulb focus synaptic innervation on interneurons. On relay cells, direct acetylcholine effects may occur, but these must be based on non-synaptic acetylcholine release at the surface of their dendrites.

Expression of protein kinase C family members in the cerebral endothelial cells

The protein kinase C (PKC) family is composed of at least four conventional (alpha, beta I, beta II, and gamma) and several related novel (delta, epsilon, eta, and zeta) isoforms with different distribution and sensitivity to Ca2+ and phorbol esters. The enzyme is known to be present in cerebral endothelial cells. We have investigated the occurrence of seven isoforms (alpha, beta, gamma, delta, epsilon, eta, and zeta) by using reverse transcriptase-polymerase chain reaction in rat brain, in a freshly isolated brain microvessel fraction, in primary cultures of rat brain endothelial cells, in an immortalized rat brain endothelial cell line, and in aortic endothelial cell cultures. Brain tissue contained all seven investigated isoforms. A similar expression pattern was seen in freshly purified microvessels, but the PKC-gamma isoform could not be detected. Primary cultures of endothelial cells expressed PKC-alpha, -beta, -delta, -eta, and -epsilon isoenzymes, whereas the immortalized cell line expressed PKC-alpha, -delta, -epsilon, and -eta. The rat aortic endothelium contained only PKC-alpha and -delta isoforms. The variety of expression patterns of PKC family members in endothelial cells of different type may reflect differences in the functional responsiveness to environmental stimuli. Because PKC has been shown to be involved in the regulation of the blood-brain barrier permeability, the presence of different isoforms may confer a sophisticated intracellular regulatory mechanism to the brain endothelial cells.

Essential functions of synapsins I and II in synaptic vesicle regulation

Synaptic vesicles are coated by synapsins, phosphoproteins that account for 9% of the vesicle protein. To analyse the functions of these proteins, we have studied knockout mice lacking either synapsin I, synapsin II, or both. Mice lacking synapsins are viable and fertile with no gross anatomical abnormalities, but experience seizures with a frequency proportional to the number of mutant alleles. Synapsin-II and double knockouts, but not synapsin-I knockouts, exhibit decreased post-tetanic potentiation and severe synaptic depression upon repetitive stimulation. Intrinsic synaptic-vesicle membrane proteins, but not peripheral membrane proteins or other synaptic proteins, are slightly decreased in individual knockouts and more severely reduced in double knockouts, as is the number of synaptic vesicles. Thus synapsins are not required for neurite outgrowth, synaptogenesis or the basic mechanics of synaptic vesicle traffic, but are essential for accelerating this traffic during repetitive stimulation. The phenotype of the synapsin knockouts could be explained either by deficient recruitment of synaptic vesicles to the active zone, or by impaired maturation of vesicles at the active zone, both of which could lead to a secondary destabilization of synaptic vesicles.

S100 immunoreactivity in a subpopulation of oligodendrocytes and Ranvier's nodes of adult rat brain

The Ca(2+)- and Zn(2+)-binding S-100 proteins (S100) are predominantly localized in astrocytes of adult mammalian brain. In addition, light and electron microscopic immunocytochemistry revealed S100 in a small subpopulation of oligodendrocytes. By nuclear morphology and abundance of rough ER and Golgi fields, these cells resembled actively myelinating oligodendrocytes. S100 immunoreactivity was also found in paranodal loops and outer mesaxons of isolated of myelin sheaths. Data suggests that oligodendroglial content of S100 relates to cell turnover and/or myelin repair in the adult rat brain, and that S100 is present during myelin compaction.

Modifications of S100-protein immunoreactivity in rat brain induced by tissue preparation

Immunocytochemistry using antibodies against various molecular forms of the Ca++ and Zn(++)-binding S100 proteins predominantly labelled astrocytes. However, especially in the neocortex the staining pattern is variable. Methods of tissue preparation have been evaluated with the aim to preserve as much S100 immunoreactivity as possible. Optimal results were obtained after perfusion fixation with 4-5% aldehydes, 0.1 M sodium cacodylate, 0.1% CaCl2, pH 7.3. In such preparations, astrocytes were completely labelled including their lamellar compartments in large parts of the central nervous system. Ca(++)-withdrawal had adverse affects on S100 immunoreactivity. Cryostat sections treated with EDTA-containing solutions before fixation showed that Ca(++)-free S100 can apparently not be fixed to the tissue. Perfusion fixatives containing EDTA resulted in inhomogeneous loss of S100 staining, indicating a differential susceptibility of astrocytic subpopulations. A different type of reduction in S100 immunoreactivity occurred around large neocortical blood vessels. Perivascular defects in immunostaining occasionally appeared even after optimal fixation, but could be regularly provoked by mildly acidic fixation (pH 6.6) or prolonged barbiturate anaesthesia. These defects might be based on S100 release into the cerebrospinal fluid. Presumably under none of the conditions studied can the immunoreactivity of all S100-forms and -fractions be completely preserved in the tissue. However, recommendations are presented for optimizing tissue preparation, to the extent that premortal modifications affecting the stainability of astrocytes may be detected by S100 immunohistochemistry in fixed brain tissue.

Structural dynamics of synapses and synaptic components

Learning and memory formation are apparently based on cascades of molecular and cellular processes with increasing time constants (ms to days and weeks), but even the most long-lasting effects are transient. Memory traces may permanently modify the behavior (activity patterns, gene expression) of neurons and neuronal networks. Therefore the question is raised whether our current view on the stability of synapses under normal conditions is tenable. Evidence is reviewed suggesting that as direct or indirect effects of modifications in bioelectrical activity and chemical trophicity, synapses may be remodeled and removed within days and weeks, and possibly within hours. Accordingly, species-specific connectivity patterns are not restricted to the standard architecture of the CNS, but (morpho-)genetics allow for a considerable number of alternative wiring patterns, which appear under unusual conditions during ontogenesis and in adulthood. Our present knowledge suggests that, rather than the formation of synapses, they are a selective process. Until now there is no direct method of measuring either synaptic reorganization or the average life span of synapses. Specific cases, however, allow to estimate synapse turnover during ontogenesis, at its lowest possible level. Such data suggest that each synapse is on average remodeled or replaced several to many times during normal developmental, e.g. in the cerebral cortex of Marmoset monkeys at the very least 5 to 10 times (corresponding to 250 million synapses eliminated per hour in area 17!). It is discussed how the consequences of synapse turnover could be utilized by learning processes. Conclusions are followed by an outlook.

Distribution of Bergmann glial somata and processes: implications for function

We have used immunocytochemistry for glial fibrillary adidic protein and glutamine synthetase to selectively label Bergmann glia in the adult rat cerebellum. From measurements of radial, tangential and en face sections we provide new data on the distribution and disposition of these glial cells. Specifically, Bergmann glia were found to have a mean areal packing density of 8,269 somata/mm2, their radial processes are packed at a mean density of 39,000/mm2, and their endfeet at the pial surface have a mean density of 19,973/mm2. Each Bergmann glial cell ist "responsible" for the equivalent of a column of cerebellar cortex having a base of 11 microns x 11 microns, a height of 170 microns, and a volume of 20,559 microns3. There are 8.1 Bergmann glia for each Purkinje cell, and each glial cell ensheaths between 2,142 and 6,358 Purkinje cell synapses. We use these data to offer insights on the roles of Bergmann glia during development and in the adult brain.

Chloride is preferentially accumulated in a subpopulation of dendrites and periglomerular cells of the main olfactory bulb in adult rats

GABA is predominantly an inhibitory transmitter. Mediated by GABAA receptors, GABA opens chloride channels, induces a passive flux of chloride ions, which is usually directed from extracellular to intracellular space, and hyperpolarizes postsynaptic neurons. Recent electrophysiological data suggested that GABA may also depolarize neurons and exert excitatory actions. However, it remained unclear whether excitatory GABA effects are based on reversed transmembrane chloride gradient due to modifications in extracellular or intracellular chloride concentrations. Here, the first histochemical evidence is provided for local redistribution of chloride in the CNS of healthy adult rats. Olfactory bulbs were examined using freeze substitution, silver trapping of chloride and intensification techniques at light and electron microscopic level. The chloride content of precipitates was evidenced by electron spectroscopic imaging using a CEM 902 (Zeiss) electron microscope. Chloride concentration was high in a subpopulation of some periglomerular cell bodies and isolated dendritic profiles, while it seemed to be very low in certain parts of the glomerular neuropil including intercellular clefts. Data suggest that reversed chloride gradients can be demonstrated by cytochemical methods, and may be responsible for excitatory GABA effects on selected periglomerular neurons and dendrites in the olfactory glomeruli. Conditions leading to chloride redistribution in the CNS of normal adult rats remain to be determined.

Postnatal development of glial fibrillary acidic protein, vimentin and S100 protein in monkey visual cortex: evidence for a transient reduction of GFAP immunoreactivity

In the cerebral cortex of some species, the gradual appearance of glial fibrillary acidic protein (GFAP) is often interpreted as reflecting the parallel maturation of neuronal connectivity. We studied the postnatal maturation of astrocytes in the primary visual cortex of Callithrix jacchus using antibodies against GFAP, vimentin and S100 protein as immunohistochemical markers. In the cortical grey matter of this species, the overall GFAP-immunoreactivity (IR) as measured by image analysis is high at birth (130% of the adult value), decreases until about 3 months (80%) and increases again towards adult values (100%). Vimentin-IR was high at birth, and declined towards 3 months and later. In contrast, S100-IR augmented postnatally in neuropil, and showed a laminar shift of maximum IR from layer IV to supragranular layers during ontogenesis. The decrease of GFAP-IR is predominantly due to changes in density of GFAP-positive (+) astrocytes within cortical tissue (newborn: 18,600 GFAP+astrocytes/mm3; 1 month: 11,600/mm3; 3 months: 5,700/mm3; adult: 10,200/mm3), while the overall number of astrocytes remained relatively constant as shown by the number of S100-positive astrocytic cell bodies. At times of low GFAP-IR a reduced area density of intermediate filaments was found in astrocytes by electron microscopy. The period of reduced GFAP-expression coincides with the time of prominent synapse remodeling in the visual cortex of marmosets. These data suggest that GFAP-expression may depend on functional conditions rather than time-dependent maturation.

Astrocytes as rapid sensors of peripheral axotomy in the facial nucleus of rats

Facial nerve transection leads to functional and structural reactions in lesioned motor neurones and surrounding glial cells. Data from this study provide evidence that the most rapid reaction described so far consists of an increase in immunoreactivity of connexin-43 (cx-43), the predominant gap junction protein in astrocytes. The ipsilateral facial nucleus is selectively marked as early as 0.75 to 1.5 hours after axotomy, while the unlesioned side as well as the unoperated controls remain faintly stained. Thus, enhanced coupling capacity of astrocytes by gap junctions appears to be a sensitive indicator of modified neuronal-glial interaction in the CNS.

Distinct subsets of neuropeptide Y-negative principal neurons receive basket-like innervation from enkephalinergic and gabaergic axons in the superior cervical ganglion of adult rats

The distributions of axons immunoreactive for [Leu]- or [Met]enkephalin and GABA were studied in the superior cervical ganglion of adult rats. The antigens were visualized separately and in combination with neuropeptide Y by the immunoperoxidase technique, using reaction end-products of different colors. Similarities and differences were found in the light-microscopic innervation patterns of enkephalin- and GABA-immunoreactive nerve fibers. Both fiber systems were heterogeneously distributed within the superior cervical ganglion, forming denser networks in its rostral part than elsewhere in the ganglion. The appearance of labeled nerve fibers differed in the two systems. Enkephalin-immunoreactive axons exhibited dotted profiles due to a strong immunoreaction in the axonal varicosities as compared with that in the intervaricose segments, whereas GABA-positive fibers were evenly labeled in both parts of the axons. The most marked difference between the innervation patterns from enkephalin- and GABA-immunoreactive axons was the presence of bundles of varicose axons in conjunction with the basket-like aggregation of enkephalin-immunoreactive nerve terminals. The possibility that enkephalins and GABA are co-localized in certain axons was excluded in double-labeling studies, silver intensification being used for the first antigen and the nickel-enhanced diaminobenzidine reaction for the second antigen. Different subsets of principal neurons were richly innervated in a basket-like manner by axons immunoreactive for enkephalins and GABA. Additionally, combined staining with antisera against either enkephalin and neuropeptide Y or GABA and neuropeptide Y revealed that both subsets of principal neurons richly innervated either by enkephalin-immunoreactive or by GABA-immunoreactive axons were devoid of neuropeptide Y immunoreactivity. Thus, the enkephalinergic and GABAergic axons have different subpopulations of neuropeptide Y-negative principal neurons as targets in the superior cervical ganglion. These results provide further evidence that sympathetic ganglion cells can be classified on the basis of their receiving input from different sources.

Distribution of GABA-immunoreactive nerve fibers and cells in the cervical and thoracic paravertebral sympathetic trunk of adult rat: evidence for an ascending feed-forward inhibition system

Neurochemical and immunohistochemical evidence suggests that the superior cervical ganglion (SCG) contains all components of a gamma-aminobutyric acid (GABA)ergic transmission system, which includes GABAergic axons of unknown origin. The number of nerve fibers with and without GABA-like immunoreactivity was determined in interganglionic connectives at all cervical and thoracic levels of the paravertebral sympathetic trunk. In addition, the distribution of GABA-immunoreactive (IR) neurons was established within the ganglion chain and compared with the relative frequency of principal neurons richly innervated by GABA-IR axon terminals. The following results were obtained: 1) the total number of nerve fibers in cross sections did not significantly vary between the cervical levels, but it increased steadily from upper to lower thoracic segments; 2) in contrast, the number of GABA-IR fibers decreased from the cervical sympathetic trunk below the SCG (approximately 300 fibers) down to the seventh to tenth thoracic ganglion, below which no such fiber was seen; 3) GABA-IR nerve fibers originate from a subclass of GABA-IR cells; these are small, bipolar neurons with predominantly ascending, unmyelinated axon-like processes; 4) the number of principal neurons richly innervated by GABA-IR nerve fibers decreased from the SCG to the upper thoracic ganglia, and was very small below; and 5) apart from basket-like innervation, GABA-IR axons also formed diffuse networks around GABA-negative principal neurons predominantly in cervical and upper thoracic ganglia. These data suggest that the GABAergic innervation of paravertebral sympathetic ganglia is more complex than previously suspected. What appears as preganglionic afferents from several spinal segments (C8-Th7) innervate GABAergic neurons in the sympathetic trunk which have ascending axons and focus their inhibitory effects on the cervical sympathetic ganglia, predominantly the SCG. These data suggest that GABAergic small interganglionic neurons form a feed-forward inhibition system, which may be driven by multisegmental spinal input in the paravertebral sympathetic ganglion chain.

Pre- and postnatal development of the primary visual cortex of the common marmoset. II. Formation, remodelling, and elimination of synapses as overlapping processes

During ontogenesis changes in the numerical density of synapses are usually assumed to depend essentially on variations in the formation of synapses. Only the final adjustment to adult synapse densities is thought to include the elimination of synapses in some brain regions of certain species. Here, we focus attention on quantitative aspects of synapse elimination throughout development of area 17 of marmoset monkeys (Callithrix jacchus). Mature synapses, various precursor forms, and indicators of lysosomal degradation of synapses were quantitatively analysed by electron microscopy and morphometric methods. A total number of about 135 x 10(9) synapses was calculated for area 17 in each adult hemisphere corresponding to a volume density of 600 x 10(6) synapses/mm3. At 3 months of age, the respective values were 508 x 10(9)/area and 1,159 x 10(6)/mm3, while at birth these values were 69 x 10(9)/area and 328 x 10(6)/mm3. Consequently, at least three out of four synapses are eliminated between 3 months and adulthood. However, the real number of synapses being eliminated during development is probably much larger if the time course of lysosomal degradation is additionally taken into account. The frequency of lysosomes in presynaptic endings is highest before net-elimination of synapses occurs, i.e., between 1 and 3 months. This suggests that lysosomal degradation is not directly responsible for the majority of synapses removed during ontogenesis but apparently represents a second mechanism for synapse remodelling and elimination. Thus, it appears from this study that remodelling and elimination of synapses are quantitatively as important as their formation, and accompany synaptogenesis from its very onset onwards.

Pre- and postnatal development of the primary visual cortex of the common marmoset. I. A changing space for synaptogenesis

The primary visual cortex of Callithrix jacchus occupies a large portion of the occipital neocortex and can be safely delineated from fetal stages onwards. In 20 animals ranging in age from fetal to adult age the morphological development of area 17 was evaluated and compared with the growth of whole brain, skull, and head size. Cortical thickness, surface area, and volume of the area were determined in addition to predominant growth directions. The volume of area 17 approximately doubles between birth (241 mm3) and three months of age (506 mm3). This maximum value marks an overshoot in growth (volume: 180%, surface area: 150%, thickness: 122%), which is followed by a considerable reduction before adult values (100%) are reached. Although these values seem to indicate that the overall reduction in size is fairly isometric, growth and regression are locally anisometric. For example, layers II-IVc contribute disproportionately to the overshoot; thickening is less pronounced than tangential growth and follows a slightly different time course. These data suggest that the developing visual cortex represents a highly dynamic distribution space for the developing synaptic junctions which should be taken into account in studies on synaptogenesis. By comparison it is suggested that this growth dynamic is not restricted to area 17 but also occurs in some other parts of the cerebral cortex. In contrast, most subcortical brain regions apparently do not undergo overshoot growth. Structural changes of the skull compensate the overshoot in cortex growth, so that head size increases steadily.

Perineuronal nets provide a polyanionic, glia-associated form of microenvironment around certain neurons in many parts of the rat brain

The nature and function of previously described perineuronal nets are still obscure. In the present study their polyanionic components were demonstrated in the rat brain using colloidal iron hydroxide (CIH) staining. In subcortical regions, such as the red nucleus, cerebellar, and vestibular nuclei, most neurons were ensheathed by CIH-binding material. In the cerebral cortex perineuronal nets were seen around numerous nonpyramidal neurons. Biotinylated hyaluronectin revealed that hyaluronan occurs in perineuronal nets. Two plant lectins [Wisteria floribunda agglutinin (WFA) and Vicia villosa agglutinin (VVA)] with affinity for N-acetylgalactosamine visualized perineuronal nets similar to those rich in anionic components. Glutamic acid decarboxylase (GAD)-immunoreactive synaptic boutons were shown to occupy numerous meshes of perineuronal VVA-positive nets. Electron microscopically, VVA binding sites were scattered throughout perisynaptic profiles, but accumulated at membranes and in the extracellular space except not in synaptic clefts. To investigate the spatial relationship between glial cell processes and perineuronal nets, two astrocytic markers (S100-protein and glutamine synthetase) were visualized at the light and electron microscopic level. Two methods to detect microglia by the use of Griffonia simplicifolia agglutinin (GSA I-B4) and the monoclonal antibody, OX-42, were also applied. Labelled structures forming perineuronal nets were observed with both astrocytic, but not with microglial, markers. It is concluded that perineuronal nets are composed of a specialized type of glia-associated extracellular matrix rich in polyanionic groups and N-acetylgalactosamine. The net-like appearance is due to perisynaptic arrangement of the astrocytic processes and these extracellular components. Similar to the ensheathment of nodes of Ranvier, perineuronal nets may provide a special ion buffering capacity required around various, perhaps highly active, types of neurons.

Facial nerve lesions lead to increased immunostaining of the astrocytic gap junction protein (connexin 43) in the corresponding facial nucleus of rats

After peripheral transection of the facial nerve, immunostaining of astrocytic gap junction protein changed in the corresponding brainstem nucleus of the rat. Enhanced connexin-43 immunoreactivity was restricted to the ipsilateral facial nucleus and to astrocytes surrounding lesioned motoneurons. This reaction is focally distinct, and marks only a part of the astrocytic network indicating a local plasticity of intercellular coupling. These results suggest that astrocytes work as sensors of signals which either depend on the integrity of neighboring neurons or inform about neuronal disorders.

Calcium/calmodulin-stimulated protein kinase II is present in primary cultures of cerebral endothelial cells

Calcium/calmodulin-stimulated protein kinase II (CaM-PK II), a major kinase in brain, has been established to play an important role in neurotransmitter release and organization of postsynaptic receptors, and it is known to be involved in long-term potentiation and memory. Less is known about the function of this enzyme in nonneural cells. Here we report on the production, presence, and phosphorylation of the alpha-subunit of CaM-PK II in primary cultures of cerebral endothelial cells. These results raise the possibility that alpha-CaM-PK II can act as one of the key enzymes of calcium-mediated intracellular signaling in the cerebral endothelial cells and suggest that alpha-CaM-PK II may participate in such basic cellular processes as permeability in physiological and pathological conditions.

Modulation by GABA of neuroplasticity in the central and peripheral nervous system

Apart from being a prominent (inhibitory) neurotransmitter that is widely distributed in the central and peripheral nervous system, gamma-aminobutyric acid (GABA) has turned out to exert trophic actions. In this manner GABA may modulate the neuroplastic capacity of neurons and neuron-like cells under various conditions in situ and in vitro. In the superior cervical ganglion (SCG) of adult rat, GABA induces the formation of free postsynaptic-like densities on the dendrites of principal neurons and enables implanted foreign (cholinergic) nerves to establish functional synaptic contacts, even while preexisting connections of the preganglionic axons persist. Apart from postsynaptic effects, GABA inhibits acetylcholine release from preganglionic nerve terminals and changes, at least transiently, the neurochemical markers of cholinergic innervation (acetylcholinesterase and nicotinic receptors). In murine neuroblastoma cells in vitro, GABA induces electron microscopic changes, which are similar in principle to those seen in the SCG. Both neuroplastic effects of GABA, in situ and in vitro, could be mimicked by sodium bromide, a hyperpolarizing agent. In addition, evidence is available that GABA via A- and/or B-receptors may exert direct trophic actions. The regulation of both types of trophic actions (direct, receptor-mediated vs. indirect, bioelectric activity dependent) is discussed.

Deep sensibility of the mystacial pad in the rat and its cortical representation

The cortical representation of the rat's mystacial pad was examined with the aid of evoked field potentials and recording of single cell activity. Mechanical bending of the vibrissae activated the well-known area within the somato-sensory cortex. Electrical stimulation of the mystacial pad with inserted needle electrodes, bi- and monopolarly, caused a widespread activation extending practically to the whole exposed cortex, including visual, acoustic and motor areas (MSS potentials). The evoked field potentials were accompanied by well-recordable unit activity, mainly in the upper 1000 microns of the cortical depth. Capsaicin, injected into the mystacial pad on the 8th-10th postnatal day heavily impaired the MSS potentials as recorded at 2 months of age, and only moderately acted on the mechanically evoked potentials. So did also the acutely injected capsaicin. Peak latency of the MSS potentials seemed to be in correlation with the distance from the punctum maximum. The latencies of unit potentials, however, did not show such dependence, they were between 8 and 10 ms. MSS potentials are thought to represent cortical projection mainly of thermo- and nociceptive fibers, which play an important role in the early postnatal life.

Synaptic reorganization in developing and adult nervous systems

Evidence is accumulating that synapse reorganization already starts during development, soon after first synapses appear. Although remodeling continues throughout ontogenesis, there are apparently (critical) periods which are characterized by enhanced synaptic reorganization. In certain parts of the peripheral and central nervous system, synapses may undergo remodeling which leads to changes in their transmission efficiency or complete elimination of the synaptic junctions, even in adulthood. Synaptic reorganization includes progressive and regressive changes on branches of dendritic and/or axonal processes that accompany the formation and elimination of synapses. Three modes of elimination are presently known: Physiological cell death of synaptically connected neurons is involved, especially during certain developmental periods, during hormonally induced metamorphosis and in the olfactory bulb. Synaptic disconnection ("stripping") and lysosomal degradation predominantly of presynaptic elements occur under different conditions. In order to undergo plastic changes, neurons seem to respond to exogenous or intrinsic factors such as lesions (partial deafferentation and axotomy), long-lasting changes in neuronal activity (e.g. drug application and sensory deprivation), hormonal influences (e.g. sexual hormones) or learning conditions.

Termination pattern and fine structural characteristics of GABA- and [Met]enkephalin-containing nerve fibers and synapses in the superior cervical ganglion of adult rat

Morphological features of nerve fibers and synapses containing GABA and [Met]enkephalin were studied at the light and electron microscopic levels in the superior cervical ganglia of rats by pre- and postembedding immunohistochemistry. Both GABA and [Met]enkephalin immunoreactivities were found in varicose nerve fibers, forming diffuse networks which were denser in the rostral than in the caudal part of each ganglion. For both antigens rich and basket-like innervation was observed around some of the principal neurons. The GABA-immunoreactive fibers were evenly stained, while in case of [Met]enkephalin-positive nerve fibers the varicosities showed intensive immunopositivity only. Postembedding immunochemistry revealed that both inhibitory substances were located in axon varicosities which established asymmetric synapses of Gray I type. Fine structural investigation revealed that GABA-like immunoreactivity was confined in the nerve endings to the clear synaptic vesicles of 40 nm diameter, whereas the immunogold particles, indicating the occurrence of [Met]enkephalin, were located over the large dense-cored vesicles of 120 nm diameter. The clear and dense-cored vesicles were, however, mixed in the nerve endings labeled by either neurotransmitter substance. Interestingly, the [Met]enkephalin-immunopositive axon terminals were found, consequently, in synaptic contacts with dendrites containing dense bodies in a row underlying the postsynaptic membrane thickening. Since nerve terminals with GABA-like immunoreactivity established synapses of Gray I type without such subjunctional bodies, one can reasonably assume that, in spite of similarities in termination pattern, there is no co-existence of GABA and enkephalin in the axons in the superior cervical ganglion.

Developmental biology of the common marmoset: proposal for a "postnatal staging"

The published knowledge on neurobiological, psychological, and ethological aspects of development in Callithrix jacchus is still limited. We have collected published and unpublished data from several Callithrix colonies and pooled information on criteria for developmental progress and maturation using a questionnaire sent to numerous experts in the field. The data suggest that developmental stages can be defined not only for the embryonic and fetal but also for the postnatal period. Based on multifactorial definitions, using criteria selected from maturational changes in the motor and visual systems and behavioral features, we propose to subdivide postnatal development of the common marmoset into seven periods ("stages").

GABA-immunoreactive structures in rat kidney

We examined the distribution of gamma-aminobutyric acid-like immunoreactivity (GABA-LI) in the rat kidney by light and electron microscopy. In vibratome sections, GABA-LI was present in both the renal medulla and cortex. The inner stripe of the outer medulla was most heavily and almost homogeneously labeled, whereas GABA-LI in the cortex was mainly confined only to some tubules. GABA-positive structures involved the epithelial cells of the thin and the thick ascending limbs of the loop of Henle, the connecting tubules, and the collecting ducts. In GABA-positive connecting tubules and collecting ducts the immunoreactivity was present in the cytoplasm of about half of the epithelial cells. As revealed by electron microscopy, the labeled cells in the collecting tubules were the light (principal) cells. No GABA-LI occurred in neuronal structures. These findings are consistent with the presence of a non-neuronal GABA system in the rat kidney. Furthermore, the specific distribution of GABA in the tubular epithelium suggests a functional significance of this amino acid in tubular transport processes.