Development of mammalian nervous tissue transplanted into the brain and anterior chamber of the eye: problems and prospects

Some theoretical problems arising in connection with nervous tissue grafting in mammals are discussed. The survival of grafts in the brain and anterior eye chamber is provided by a complex of factors, including peculiarities of immunological reaction, blood-brain barrier and certain characteristics of embryonic nervous tissue. Organotypic development of ectopic grafts suggests a significant autonomy of inner genetic programmes in self-organization of brain structures. Development of the graft-host brain nervous connections is, to a great extent, determined by the factors of topographic closeness and the presence of free postsynaptic structures, without prominent specificity of the graft-brain relationships. Complex neurotrophic interactions, mainly provided by the glial cells, are also found between the graft and damaged host brain. A study of electric activity of the grafted neurons has shown a varying degree of dependence of the functional organization of the brain structures on the environmental afferent influences. The grafts can serve as a chronic endogenous source of neurotransmitters and neurohormones, and, possibly, restore interrupted structural connections, thus providing the compensation of some complex brain functions.     

Neuroglia in ageing and disease

The proper operation of the mammalian brain requires dynamic interactions between neurones and glial cells. Various types of glial cells are susceptible to morpho-functional changes in a variety of brain pathological states, including toxicity, neurodevelopmental, neurodegenerative and psychiatric disorders. Morphological modifications include a change in the glial cell size and shape; the latter is evident by changes of the appearance and number of peripheral processes. The most blatant morphological change is associated with the alteration of the sheer number of neuroglia cells in the brain. Functionally, glial cells can undergo various metabolic and biochemical changes, the majority of which reflect upon homeostasis of neurotransmitters, in particular that of glutamate, as well as on defence mechanisms provided by neuroglia. Not only glial cells exhibit changes associated with the pathology of the brain but they also change with brain aging.     

Detection of glial fibrillary acidic protein (GFAP) and vimentin (Vim) by immunoelectron microscopy of the glial cells in the central nervous system of the snail Megalobulimus abbreviatus

When examined under an electron microscope, the central nervous system of Megalobulimus abbreviatus showed two types of glial cells: firstly, protoplasmic glial cells which displayed a nucleus with peripheral heterochromatin, scanty or no intermediate filaments, a developed Golgi complex, rough and smooth endoplasmic reticula, mitochondria and polymorphic lysosomes that indicate phagocytic activity of debris from the extracellular space; and, secondly, fibrous glial cells which showed numerous glial fibrillary acidic protein (GFAP) and vimentin immunoreactive intermediate filament bundles, a discrete Golgi complex, mitochondria, endoplasmic reticulum, lipid droplets and lysosomes. The contacts between the glial cells consisted of desmosomes and puncta adherentia, while those between the glial cells and the basal lamina consisted of hemidesmosomes. Both glial cell types were located in the cortex and medullary regions, however, the protoplasmic glial cells prevailed in the cortical region, while the fibrous glial cells prevailed in the medullar region. As the nervous tissue is avascular, the passage of nutrients and waste products may be facilitated by the glial labyrinthic system which is located in the cortical region. Glial processes adjacent to large and giant neurones formed a trophospongium, which seemed to be involved in a metabolic exchange between these cells. Thus, this evidence suggests that glial cells of M. abbreviatus are involved in structural support, isolation of different ganglionic areas, the formation of a microcirculatory system and an intimate metabolic relationship with neurones.     

The hippocampus and neuro-transplantation

A review of the author's histological and electron-microscopic studies of differentiation of hippocampal transplants with different levels of the graft/host integration. The grafts developing in the anterior eye chamber were the experimental model of complete isolation from the brain. The effects of various factors (age of the donor fetal tissue, host age and strain, degree of the integration with the recipient brain) on the growth and neural organization of grafts were studied. Analysis of fine structure of intraocular and intracortical grafts, as a rule, showed mature highly differentiated neurons and glia and normal density of typical synaptic contacts. However, morphological features suggesting both hyperactivity of some neurons and continuous growth of some neural processes were observed. The expression of nonsynaptic and transport-metabolic interactions between the cells was increased. The observed ultrastructural deviations can be regarded as a compensatory adaptation of the tissue to the deficit of specific afferent signals. It was shown that in the absence of normal cellular targets, axons of the grafted neurons establish functional synaptic contacts with improper neural elements in the host brain.     

Distribution of glial cells in the central nervous system of the pulmonate snail Megalobulimus oblongus identified by means of a glial fibrillary acidic protein marker

The distribution of the glial cells in the pulmonate gastropod Megalobulimus oblongus was studied by means of an immunohistochemical procedure. These cells expressed glial fibrillary acidic protein in their cell bodies as well as in their processes. In all ganglia of the central nervous system, four types of glial cells were identified. The glial lacunar network and the perineuronal glial cells were found in the cortical region of the ganglia, and the perisynaptic and the fibrous glial cells in the neuropilar region. However, in the procerebrum of the cerebral ganglion the glial cells only had a reticular distribution throughout the cellular area. These observations provide morphological evidence of glial cell functions. These cells are probably involved in the support of neurones, the uptake and/or degradation of neurotransmitters, the transfer of metabolic substrates to neurones, as well as the regulation of ionic constituents of extracellular space. As occurs in vertebrates, there is a strong relationship between the different cellular components of the central nervous system of this invertebrate.     

Ultrastructural localization of lectin-binding sites and laminin-like immunoreactivity in glial cells and neurites growing out from explant cultures of the central nervous system of embryonic locusts

Summary Lectins with different sugar specificities and labeled with horseradish peroxidase or gold were used to study, at the electron-microscopic level, surface glycoconjugates of glial cells and neurites growing out from explant cultures of the central nervous system of embryonic locusts. Differential binding to differentiating glial cells and to neurites was demonstrated. Concanavalin A (Con A) and wheat-germ agglutinin (WGA) bound to glial and neurite surfaces with different degrees of labeling. The formation of glial processes and junctional complexes was invariably accompanied by a corresponding increase of Con A- and WGA-receptors. Peanut agglutinin (PNA) failed to bind to glial cells but strongly stained the plasma membrane of neurite junctions. Lotus tetragonolobus a. (LTA) did not bind either to glial cells or to neurites. In addition, staining with an antibody against laminin showed labeling in areas of neurite outgrowth and neurite interactions; this resembled the localization of PNA receptors. These findings provide evidence for the presence of different carbohydrates at the surface of neurites and glial cells of locust. Their predominant localization in glial processes and neurite junctions suggests that these carbohydrates constitute part of a group adhesion glycoproteins that also includes laminin.     

Light and electron microscopical immunocytochemistry of 5'-nucleotidase in rat cerebellum

5'-Nucleotidase in nervous tissue has so far not been localised at the ultrastructural level using immunocytochemical techniques. We have now applied monoclonal antibodies and a polyclonal antiserum raised against this ecto-enzyme and describe the distribution of 5'-nucleotidase antigenicity in rat cerebellum both at the light and electron microscopic levels. Within all cerebellar layers, 5'-nucleotidase immunoreactivity was found on plasma membranes of glial elements, i.e. Bergmann glial cell processes crossing the molecular layer, astrocytic end-feet around blood vessels and glial cell extensions surrounding single Purkinje cells. In the granular layer, 5'-nucleotidase immunoreactivity was present on glial membranes interposed between granule cells. Neuronal cells or processes were devoid of immunoreactivity. The immunocytochemical results were compared with conventional 5'-nucleotidase histochemistry. Both techniques showed the same ecto-localisation of the enzyme and favour the view of 5'-nucleotidase being predominantly situated at glial plasma membranes.     

Aldehyde dehydrogenase activity in the barrier brain structures

The histochemical method was used to study the aldehyde dehydrogenase (EC 1.2.1.3.; ALDH) activity in capillaries and glial structures of different regions in the rat central nervous system (CNS). The occurrence of three metabolic barriers for aldehydes on systemic level in the CNS has been shown. They are: the barrier between blood and the nervous tissue (represented by capillary endothelium and surrounding astrocytes ALDH), that between blood and cerebrospinal fluid (ALDH in ependymocytes of vascular plexus), and that between cerebrospinal fluid and nervous tissue (ALDH of ependymocytes covering brain cavities). On the single microregions level a similar barrier is between interstitial fluid and neurons (ALDH of satellite oligodendrocytes).     

Role of Astrocytes in Pain

Over the last decade, a series of studies has demonstrated that glia in the central nervous system play roles in many aspects of neuronal functioning including pain processing. Peripheral tissue damage or inflammation initiates signals that alter the function of the glial cells (microglia and astrocytes in particular), which in turn release factors that regulate nociceptive neuronal excitability. Like immune cells, these glial cells not only react at sites of central and/or peripheral nervous system damage but also exert their action at remote sites from the focus of injury or disease. As well as extensive evidence of microglial involvement in various pain states, there is also documentation that astrocytes are involved, sometimes seemingly playing a more dominant role than microglia. The interactions between astrocytes, microglia and neurons are now recognized as fundamental mechanisms underlying acute and chronic pain states. This review focuses on recent advances in understanding of the role of astrocytes in pain states.     

Modifications in energy metabolism during the development of chick glial cells and neurons in culture

Developmental changes in lactate dehydrogenase (LDH), enolase, hexokinase (HK), malate dehydrogenase (MDH), and glutamate dehydrogenase (GDH) activities were measured in cultures of pure neurons and glial cells prepared from brains of chick embryos (8 day-old for neurons, 14 day-old for glial cells) as a function of cellular development with time in culture. The modifications observed in culture were compared to those measured in brain extracts during the development of the nervous tissue in the chick embryo and during the post-hatching period. A significant increase of MDH, GDH, LDH, and enolase activities are observed in neurons between 3 and 6 days of culture, whereas simultaneously a decrease of HK values occurs. In the embryonic brain between 11 and 14 days of incubation, which would correspond for the neuronal cultures to day 3 through 6, modifications of MDH, GDH, HK, and enolase levels are similar to those observed in neurons in culture. Only the increase of LDH activity is less pronounced in vivo than in cultivated cells. The evolution of the tested enzymatic activities in the brain of the chick during the period between 7 days before and 10 days after hatching is quite similar to that observed in cultivated glial cells (prepared from 14 day-old embryos) between 6 and 18 days of culture. All tested activities increased in comparable proportions. The modifications of the enzymatic profile indicate that some maturation phenomena affecting energy metabolism of neuronal and glial elements in culture, are quite similar to those occuring in the total nervous tissue. A relationship between the development of the energy metabolism of the brain and differentiation processes affecting neuroblasts and the glial-forming cells is discussed.     

Glial fibrillary acidic protein (GFAP)-like immunoreactivity in the visual system of the crab Ucides cordatus (Crustacea, Decapoda)

Glial fibrillary acidic protein (GFAP) is the main intermediate filament protein used as a marker for the identification of astrocytes in the central nervous system of vertebrates. Analogous filaments have been observed in the glial cells of many mollusks and annelids but not in crustaceans. The present study was carried out to identify by light microscopy immunohistochemistry, immunoelectronmicroscopy and immunoblotting, GFAP-like positive structures in the visual system of the crab Ucides cordatus as additional information to help detect and classify glial cells in crustaceans. Conventional electron microscopy, light microscopy of semithin sections and fluorescence light microscopy were also employed to characterize cells and tissues morphology. Our results indicated the presence of GFAP-like positive cell processes and cell bodies in the retina and adjoining optic lobe. The labeling pattern on the reactive profiles was continuous and very well defined, differing considerably from what has been previously reported in the central nervous system of some mollusks, where a diffuse spotted fluorescence pattern of labeling was observed. We suggest that this glial filament protein may be conserved in the evolution of the invertebrate nervous systems and that it may be used as a label for some types of glial cells in the crab.     

Interaction of thiamine with rat brain synaptosomes

Thiamine has been shown to be bound specifically by a synaptosomal plasmatic membrane and transported inside to the nervous ending. Apparent K[symbol: see text] and Km for processes of binding and transport have been determined as equal 2.34 +/- 0.55 MKM and 3.92 +/- 1.3 MKM, respectively. The thiamine uptake by the isolated nervous endings (synaptosomes) at its physiological concentration is reduced in presence of metabolic inhibitors and partially depends on Mg2+ and Ca2+ ions, that can testify about the interrelation between endogenic thiamine phosphorilation and its transport through the membrane. Thiamine binding with synaptosomes is inhibited by ouabain and neurotoxins such as, latrotoxin and most significantly--with veratridin; tetrodotoxin fail to be efficient practically. In the conditions of synaptic membranes depolarisation their ability to bind thiamine is reduced and output of already uptaken with synaptosomes thiamine is observed.     

Expression of beta-amyloid precursor and Bcl-2 proto-oncogene proteins in rat retinas after intravitreal injection of aminoadipic acid.

In order to investigate the role of glia in relation to factors that affect the expression of beta-amyloid precursor protein (betaAPP) and B cell lymphoma oncogene protein (Bcl-2) in the central nervous tissue, the patterns of expression of betaAPP and Bcl-2 in developing and mature rat retinas were studied immunocytochemically after intravitreal injection of alpha-aminoadipic acid (alpha-AAA), a glutamate analogue and gliotoxin that is known to cause injury of retinal Müller glial cells. In normal developing retinas, betaAPP and Bcl-2 were expressed primarily but transiently in a small number of neurons in the ganglion cell layer during the first postnatal week. Immunoreactivity of betaAPP and Bcl-2 appeared in the endfeet and proximal part of the radial processes of Müller glial cells from the second postnatal week onwards. In rats that received intravitreal injection of alpha-AAA at birth, there was a loss of immunoreactivity to vimentin, and a delayed expressed on betaAPP or Bcl-2 in Muller glial cells until 3-5 weeks post-injection. Immunoreactive neurons were also observed in the inner retina especially in the ganglion cell layer from 5 to 35 days after injection. A significant reduction in numerical density of cells with large somata in the ganglion cell layer was observed in the neonatally injected retinas at P56, which was accompanied by an increased immunostaining in radial processes of Müller glial cells. In contrast, no detectable changes in the expression of betaAPP and Bcl-2 were observed in retina that received alpha-AAA as adults. These results indicate that the gliotoxin alpha-AAA has long lasting effects on the expression of betaAPP and Bcl-2 in Müller glial cells as well as neurons in the developing but not mature retinas. The loss of vimentin and delayed expression of betaAPP and Bcl-2 in developing Müller glial cells suggests that the metabolic integrity of Müller cells was temporarily compromised, which may have adverse effects on developing neurons that are vulnerable or dependent on trophic support from the Müller glial cells.     

Glial cells in the central nervous system of earthworm, Eisenia fetida

Glial elements in the central nervous system of Eisenia fetida were studied at light- and electron microscopic level. Cells were characterized with the aid of toluidine blue, Glial Fibrillary Acidic Protein (GFAP), S100 staining. We identified neurilemmal-, subneurilemmal-, supporting-nutrifying- and myelinsheath forming glial cells. Both neuronal and non-neuronal elements are S100-immunoreactive in the CNS. Among glial cells neurilemmal and subneurilemmal cells are S100-immunopositive. With the antibody against the S100 protein one band is visible at 15 kDa. GFA P-immunopositive supporting-nutrifying glial cells are localized around neurons and they often appear as cells with many vacuoles. GFA P-positive cell bodies of elongated neurilemmal glial cells are also visible. Western blot analysis shows a single 57 kDa GFA P immunoreactive band in the Eisenia sample. At ultrastructural level contacts between neuronal and glial cells are recognizable. Glial cell bodies and their filopodia contain a granular and vesicular system. Close contacts between neuronal cell membranes and glial filopodia create a special environment for material transport. Vesicles budding off glial cell granules move towards the cell membranes, probably emptying their content with kiss and run exocytosis. The secreted compounds in return may help neuronal survival, provide nutrition, and filopodia may also support neuronal terminals.     

Lipid metabolism in myelinating glial cells: lessons from human inherited disorders and mouse models

The integrity of central and peripheral nervous system myelin is affected in numerous lipid metabolism disorders. This vulnerability was so far mostly attributed to the extraordinarily high level of lipid synthesis that is required for the formation of myelin, and to the relative autonomy in lipid synthesis of myelinating glial cells because of blood barriers shielding the nervous system from circulating lipids. Recent insights from analysis of inherited lipid disorders, especially those with prevailing lipid depletion and from mouse models with glia-specific disruption of lipid metabolism, shed new light on this issue. The particular lipid composition of myelin, the transport of lipid-associated myelin proteins, and the necessity for timely assembly of the myelin sheath all contribute to the observed vulnerability of myelin to perturbed lipid metabolism. Furthermore, the uptake of external lipids may also play a role in the formation of myelin membranes. In addition to an improved understanding of basic myelin biology, these data provide a foundation for future therapeutic interventions aiming at preserving glial cell integrity in metabolic disorders.     

Glial cells in synaptic plasticity.

Plasticity of synaptic transmission is believed to be the cellular basis for learning and memory, and depends upon different pre- and post-synaptic neuronal mechanisms. Recently, however, an increasing number of studies have implicated a third element in plasticity; the perisynaptic glial cell. Originally glial cells were thought to be important for metabolic maintenance and support of the nervous system. However, work in the past decade has clearly demonstrated active involvement of glia in stability and overall nervous system function as well as synaptic plasticity. Through specific modulation of glial cell function, a wide variety of roles for glia in synaptic plasticity have been uncovered. Furthermore, interesting circumstantial evidence suggests a glial involvement in multiple other types of plasticity. We will discuss recent advances in neuron-glial interactions that take place during synaptic plasticity and explore different plasticity phenomena in which glial cells may be involved.     

Basic fibroblast growth factor, neurofilament, and glial fibrillary acidic protein immunoreactivities in the myenteric plexus of the rat esophagus and colon

The enteric nervous system consists of a number of interconnected networks of neuronal cell bodies and fibers as well as satellite cells, the enteric glia. Basic fibroblast growth factor (bFGF) is a mitogen for a variety of mesodermal and neuroectodermal-derived cells and its presence has been described in many tissues. The present work employs immunohistochemistry to analyze neurons and glial cells in the esophageal and colic enteric plexus of the Wistar rat for neurofilament (NF) and glial fibrillary acidic proteins (GFAP) immunoreactivity as well as bFGF immunoreactivity in these cells. Rats were processed for immunohistochemistry; the distal esophagus and colon were opened and their myenteric plexuses were processed as whole-mount preparations. The membranes were immunostained for visualization of NF, GFAP, and bFGF. NF immunoreactivity was seen in neuronal cell bodies of esophageal and colic enteric ganglia. GFAP-immunoreactive enteric glial cells and processes were present in the esophageal and colic enteric plexuses surrounding neuronal cell bodies and axons. A dense net of GFAP-immunoreactive processes was seen in the ganglia and connecting strands of the myenteric plexus. bFGF immunoreactivity was observed in the cytoplasm of the majority of the neurons in the enteric ganglia of esophagus and colon. The two-color immunoperoxidase and immunofluorescence methods revealed bFGF immunoreactivity also in the nucleus of GFAP-positive enteric glial cells. The results suggest that immunohistochemical localization of NF and GFAP may be an important tool in the study of the plasticity in the enteric nervous system. The presence of bFGF in neurons and glia of the myenteric plexus of the esophagus and the colon indicates that this neurotrophic factor may exert autocrine and paracrine actions in the enteric nervous system.     

Histochemical demonstration of copper in normal rat brain and spinal cord. Evidence of localization in glial cells

The high sensitivity of the magnesium-dithizonate silver-dithizonate (MDSD) staining procedure makes this method very suitable for the histochemical localization of copper in different regions of the central nervous system of adult rats. In the telencephalon (bulbus olfactorius, nucleus caudatus-putamen, septum pellucidum and area dentata), diencephalon (nucleus habenulae medialis, nuclei of the hypothalamus in the vicinity of the third ventricle, and corpus mamillare), mesencephalon (substantia nigra), cerebellum (mainly in the nodulus), pons (locus coeruleus, nucleus vestibularis), medulla oblongata (nucleus tractus solitarii) and spinal cord, the glial cells exhibit specific copper staining. The glial cells of some circumventricular organs (e.g. the subfornical organ) are also stained using the MDSD method. The significant staining observed in white-matter glial cells (e.g. in the corpus callosum, cerebellum and spinal cord) further indicates the very high sensitivity of this method. In glial cells of the same regions, the presence of copper can likewise be demonstrated using the modified sulphide silver method. On the basis of the present histochemical results, it is suggested that copper may play an important role in the normal physiological functioning of glial cells and also, via glial-neuron interactions, in neuronal processes.     

Mechanism of radiation injury in the ion transport systems of nervous tissue

The biological effect of ionizing radiation (IR) in lethal and sublethal doses on the sodium-potassium transport systems in the fractions, enriched of neuron and glial cells and in cortex slices from rat brain was investigated. It was shown that IR leads to marked disturbances in the activity of Na,K-ATPase both in neuron and in glial cells. Some phasic character of alterations may be noted, which is expressed in different degree for various cellular elements of the brain. Using the surviving brain slices we have shown that IR causes essential phasic changes in potassium ion reaccumulation in different times after exposure. The mechanisms of the disturbance of Na,K-pump function in nervous tissue after irradiation are under discussion.     

Signaling in glial development: differentiation migration and axon guidance.

Glial cells have diverse functions that are necessary for the proper development and function of complex nervous systems. During development, a variety of reciprocal signaling interactions between glia and neurons dictate all parts of nervous system development. Glia may provide attractive, repulsive, or contact-mediated cues to steer neuronal growth cones and ensure that neurons find their appropriate synaptic targets. In fact, both neurons and glia may act as migrational substrates for one another at different times during development. Also, the exchange of trophic signals between glia and neurons is essential for the proper bundling, fasciculation, and ensheathement of axons as well as the differentiation and survival of both cell types. The growing number of links between glial malfunction and human disease has generated great interest in glial biology. Because of its relative simplicity and the many molecular genetic tools available, Drosophila is an excellent model organism for studying glial development. This review will outline the roles of glia and their interactions with neurons in the embryonic nervous system of the fly.