Tracing glial cell lineages in the mammalian forebrain.

Astrocytes and oligodendrocytes emerge in late gestational and early post-natal development in the mammalian CNS. The nature, and number, of progenitors for each glial type is a central question. This review will focus upon several unresolved issues relating to glial cell lineages and describe new methods to try to illuminate these issues further: (1) How can developmental patterns by which immature neuroectodermal cells give rise to classes of neurons and glia be understood in the context of lineage? (2) What are the lineage relationships among the various cell classes, how many glial lineages are there in the developing CNS, and how can recent methods of clonal analysis using stable markers be used to clarify lineage patterns? (3) Do patterns of gliogenesis vary in different regions of the CNS? (4) How do patterns of gliogenesis observed in vitro relate to those in vivo?.     

Glia protect fetal midbrain dopamine neurons in culture from L-DOPA toxicity through multiple mechanisms

Summary Mesencephalic glia produce soluble factors that protect dopamine neurons from L-DOPA toxicity. The chemical composition of these soluble factors is unknown. We investigated the protective effect against L-DOPA neurotoxicity in midbrain dopamine neurons of fractions of different molecular size of glia conditioned medium and candidate neuroprotective agents produced by glia including neurotrophic factors and antioxidants. Protective effects were evaluated according to the number of tyrosine hydroxylase immunoreactive cells, high affinity dopamine uptake and levels of quinones. Both fractions of glia conditioned medium, smaller and larger than 10kD, protected against L-DOPA, but the fraction of smaller molecular size, that contains small free radical scanvenger molecules, was more effective than the fraction of larger molecular size, that contains large neurotrophic peptides. Among the neurotrophic factors GDNF and BDNF totally prevented L-DOPA neurotoxicity, while NGF and bFGF were less effective. However, only NGF significantly reduced the elevation of quinones induced by L-DOPA. Ascorbic acid, at the concentration found in glia conditioned medium, provided partial protective effect against L-DOPA toxicity. Glutathione, had neurotrophic effects on untreated midbrain dopamine neurons and prevented the effect of L-DOPA. In conclusion, the protective effect against L-DOPA neurotoxicity by glia conditioned medium is mediated by several compounds including neurotrophic factors and small antioxidants.     

The anticonvulsant sodium valproate specifically induces the expression of a rat glial heat shock protein which is identified as the collagen type IV receptor

A potential mechanism for valproate (VPA)-induced increases in glial cell-substratum adhesivity has been demonstrated. Metabolically labelled glioma (C6) and primary astrocytes showed a statistically significant accumulation of protein when cultured in the presence of therapeutic concentrations of VPA (1 mM). This was mainly accounted for by a 10-fold increase in the production of a single polypeptide of 43 kDa molecular weight. Fractionation studies and metabolic labelling with N-acetyl-D-mannosamine showed this to be a sialoglycoprotein which was plasma membrane-bound. VPA-induction of the polypeptide was apparently specific to glioma and primary astrocytes and was not observed in neuroblastoma (neuro-2a), fibroblasts (3T3), pituicytes (GH3) and epithelial cells (NCTC). The 43 kDa component of glia was demonstrated to be the receptor for type IV collagen by binding metabolically labelled and solubilised cells to Sepharose beads which had been individually coated with laminin, fibronectin and type IV collagen. The protein has also been shown to be a heat shock product as metabolically labelled glioma showed a 10-fold increase in its expression when cultured at 42 degrees C. This heat shock induced expression was transient and was in marked contrast to that seen with VPA where it increased with time and was sustained. The expression of 43 kDa is suggested to arise by VPA and heat shock induced delays in cell cycle progression and this is discussed in relation to teratogenic action.     

A qualitative and quantitative study of the glial cells in normal and athymic mice

A qualitative and quantitative light and electron microscopic analysis of the glial cells in the supraventricular part of the corpus callosum of the neonatal and adult homozygous athymic nude (nu/nu) and normal BALB/c (+/+) mice was carried out to determine the possible contribution of nude gene mutation to glial cell development. Quantitative cell counts using toluidine blue stained serial callosal sections of 0.5 μm thickness showed that the overall glial cell population was significantly reduced in both neonatal and adult athymic mice. The number of glioblasts, astrocytes and microglia of 5-day-old athymic mouse was reduced by 10%, 27%, and 39%, respectively, when compared to the 5-day-old normal mouse. The frequency of necrotic cells in the neonatal athymic mouse increased by 70% when compared with the normal mouse. In the 13-week-old adult athymic mouse, the number of oligodendrocytes, astrocytes, and microglia decreased by 19%, 31%, and 33%, respectively, when compared to normal mouse. There was no significant difference in the area covered by the corpus callosum in 5-day-old and adult nude mice versus the normal ones of corresponding ages. Except for microglia and astrocytes, the ultrastructural features of the other glial cell types in both strains were comparable. Most of the microglial cells of the neonatal normal mouse were round and were selectively marked by Mac-1 monoclonal antibody at their plasma membrane. The immunoreactivity appeared to be more intense in the normal than the athymic mouse, suggesting a down regulation of CR3 receptors and reduced phagocytic activity of this cell type in the athymic mouse. It is proposed that the increased number of necrotic cells in the neonatal athymic mouse may be attributed to the delay in the removal of dead cells normally phagocytosed by microglia. The microglia in both strains of mouse showed comparable lectin staining intensity at the plasma membrane, indicating that their glycoprotein binding receptors to lectin remained unchanged. Some astrocytes in the adult athymic mice showed hypertrophy. The reduced number of glial cells may be the direct result of genetic mutation or consequential to the lack of certain trophic factors arising from the genetic mutation. Thus, the reduction of microglial cells in both neonatal and adult athymic mice may be due to the lack of thymic hormones which, together with lymphokines have been shown to affect the maturation of bone marrow derived cells including monocytes, the putative precursor cells of microglia. The reduction in the number of glioblasts and astrocytes may be attributed to the diminution of T lymphocytes or consequential to the reduction of microglia which are known to secrete interleukin-1 that would influence gliogenesis and produce specific growth factors for promoting astrocyte proliferation. Last, as interaction exists between astrocytes and oligodendrocytes, the products of astrocytes may affect the development of oligodendrocytes and vice vasa. The present findings point to a relation between glial cell development and immune network system. © 1995 Wiley-Liss, Inc.     

Chronic infusion of CDNF prevents 6-OHDA-induced deficits in a rat model of Parkinson's disease

The visual system is widely used as a model in which to study neurotrauma of the central nervous system and to assess the effects of experimental therapies. Adult mammalian retinal ganglion cell axons do not normally regenerate their axons for long distances following injury. Trauma to the visual system, particularly damage to the optic nerve or central visual tracts, causes loss of electrical communication between the retina and visual processing areas in the brain. After optic nerve crush or transection, axons degenerate and retinal ganglion cells (RGCs) are lost over a period of days. To promote and maintain axonal growth and connectivity, strategies must be developed to limit RGC death and provide regenerating axons with permissive substrates and a sustainable growth milieu that will ultimately provide long term visual function. This review explores the role olfactory glia can play in this repair. We describe the isolation of these cells from the olfactory system, transplantation to the brain, gene therapy and the possible benefits that these cells may have over other cellular therapies to initiate repair, in particular the stimulation of axonal regeneration in visual pathways. This article is part of a Special Issue entitled: Understanding olfactory ensheathing glia and their prospect for nervous system repair.     

Cystatin C expression is increased in the hippocampus following photothrombotic stroke in rat

Stroke is a major cause of epilepsy, but the molecular mechanisms underlying post-stroke epileptogenesis are unknown. The expression of cystatin C, a cysteine protease inhibitor, is increased in the hippocampus during status epilepticus (SE)-induced epileptogenesis, and regulates both cell death and birth. To test the hypothesis that increased cystatin C expression represents a common molecular alteration induced by epileptogenic brain insults, we investigated the time course, cellular localization, and association of cystatin C expression with neuronal damage during post-stroke epileptogenesis. Stroke was induced with photothrombosis, which leads to epilepsy in approximately 20-30% of rats. Cystatin C expression was increased in the CA1 area of the hippocampus 4 days after photothrombosis, when the diameter of the lesion was the largest. Double-labeling and confocal analysis indicated that cystatin C was expressed in astrocytes and microglia. Unlike after SE, cystatin C expression did not change in the dentate gyrus. Also, increased cystatin C expression was not associated with neurodegeneration, which was demonstrated as an absence of Fluoro Jade B-positive cells in adjacent sections. The present study provides evidence that cystatin C may be involved in cellular alterations that occur after an epileptogenic insult, not only after SE but also after photothrombotic stroke.     

Cyclic AMP-mediated regulation of the resting membrane potential in myelin-forming oligodendrocytes in the isolated intact rat optic nerve

Myelin formation by oligodendrocytes has been shown to be regulated by cyclic AMP (cAMP) signaling pathways and to depend on the resting membrane potential (RMP). We therefore examined whether cAMP regulates the RMP of myelin-forming oligodendrocytes in isolated intact optic nerves of rats. Oligodendrocytes exhibited a significant developmental shift in the RMP from -37 mV at postnatal day (P)6-8 to -67 mV at P21-30. The regulation of RMP was examined further in myelin-forming oligodendrocytes in nerves aged P15-20. Raising intracellular cAMP with dbcAMP or forskolin induced a significant hyperpolarization in myelin-forming oligodendrocytes by 10-15 mV. Inhibition of cAMP-dependent protein kinase (PKA) with KT5720 depolarized the oligodendroglial RMP -30 mV, which was only partly reversed by dbcAMP. In contrast, inhibition of cAMP specific phosphodiesterase with rolipram had no significant effect on the oligodendroglial RMP or the cAMP-mediated hyperpolarization. Blockade of Kir with 100 microM BaCl(2) depolarized the oligodendrocyte RMP to -25 mV and inhibited the hyperpolarizing action of dbcAMP. The RMP was unaffected by agents that modulated ATP-sensitive potassium channels. The results provide evidence of a predominant role for Kir in setting the oligodendroglial RMP and show that cAMP regulates the oligodendroglial RMP, at least partly by a PKA-mediated pathway, possibly by modulating the activity of Kir.     

An in vitro model of traumatic brain injury utilising two-dimensional stretch of organotypic hippocampal slice cultures

Traumatic brain injury (TBI) is caused by rapid deformation of the brain, resulting in a cascade of pathological events and ultimately neurodegeneration. Understanding how the biomechanics of brain deformation leads to tissue damage remains a considerable challenge. We have developed an in vitro model of TBI utilising organotypic hippocampal slice cultures on deformable silicone membranes, and an injury device, which generates tissue deformation through stretching the silicone substrate. Our injury device controls the biomechanical parameters of the stretch via feedback control, resulting in a reproducible and equi-biaxial deformation stimulus. Organotypic cultures remain well adhered to the membrane during deformation, so that tissue strain is 93 and 86% of the membrane strain in the x- and y-axis, respectively. Cell damage following injury is positively correlated with strain. In conclusion, we have developed a unique in vitro model to study the effects of mechanical stimuli within a complex cellular environment that mimics the in vivo environment. We believe this model could be a powerful tool to study the acute phases of TBI and the induced cell degeneration could provide a good platform for the development of potential therapeutic approaches and may be a useful in vitro alternative to animal models of TBI.     

Astrocytes are involved in long-term facilitation of neuronal excitation in the anterior cingulate cortex of mice with inflammatory pain

Neuronal plasticity in the pain-processing pathway is thought to be a mechanism underlying pain hypersensitivity and negative emotions occurring during a pain state. Recent evidence suggests that the activation of astrocytes in the anterior cingulate cortex (ACC) contributes to the development of negative emotions during pain hypersensitivity after peripheral inflammation. However, it is unknown whether these activated astrocytes contribute to neuronal plasticity in the ACC. In this study, by using optical imaging with voltage- and Ca²⁺-sensitive dyes, we examined the long-term facilitation of neuronal excitation induced by high-frequency conditioning stimulation (HFS) in ACC slices of control mice and mice with peripheral inflammation induced by the injection of complete Freund adjuvant (CFA) to the hind paw. Immunoreactivity of glial fibrillary acidic protein in laminae II–III of the ACC in the CFA-injected mice was higher than in the control mice. Neuronal excitation in ACC slices from the CFA-injected mice was gradually increased by HFS, and the magnitude of this long-term facilitation was greater than in the control mice. The long-term facilitation in the CFA-injected mice was inhibited by the astroglial toxin, the N-methyl-d-aspartate (NMDA) receptor antagonist and NMDA receptor glycine binding site antagonist. The increase of intracellular Ca²⁺ concentration in astrocytes during HFS was higher in the CFA-injected mice than in the control mice and was inhibited by l-α-aminoadipate (l-α-AA). These results suggest that the activation of astrocytes in the ACC plays a crucial role in the development of negative emotions and LTP during pain hypersensitivity after peripheral inflammation.