Symposium 8: Regulation of Oligodendrocyte Development. Guidance of oligodendrocyte precursor migration in the developing spinal cord

Oligodendrocyte precursors arise in restricted regions of the developing neuroepithelium due to local signals that include sonic hedgehog. In the spinal cord the founder cells of the oligodendrocyte lineage develop in a specific domain of the ventral ventricular zone. These cells or their progeny subsequently migrate long distances to populate the entire spinal cord and myelinate axons in the peripheral presumptive white matter. The majority of migration in the oligodendrocyte lineage is accomplished by immature precursors, which then stop, proliferate and differentiate in the appropriate location. Several distinct mechanisms appear to regulate this migration. The initial dispersal of cells from the ventral ventricular zone is guided by chemorepellent cues including netrin‐1 present in the ventral ventricular domain. Migratory precursors are arrested in particular locations within the developing spinal cord as the result of the localized expression of the chemokine, CXCL1 by astrocytes. This chemokine, signalling through the CXCR2 receptor combines with PDGF to inhibit cell migration and enhance cell proliferation thereby facilitating the local expansion of the oligodendrocyte lineage and myelination of all relevant axons.     

Acetylcholine estimate in glial cells of the cat spinal cord

Structures containing acetylcholinesterase were found in the motor nuclei of the cervical enlargement of the cat spinal cord by light and electron microscopy in material stained by the Karnovsky-Roots method. The specific response was observed not only in neurons of the motor nuclei, but also in some satellite cells, astrocytic glial cells, and Schwann cells. A positive reaction for acetylcholinesterase was found in some of the satellite cells located close to both cholinergic and noncholinergic neurons. As a result of electron microscopy, an electron-dense deposit of copper ferrocyanide was found on the structures of the nucleolus, on the surface of the inner and outer layers of the nuclear membrane, in the pores of the nuclear membrane, in the perinuclear space, and in the endoplasmic reticulum of the perikaryon of some satellite cells, as well as on the outer and inner surfaces of the cytoplasmic membrane of the Schwann cells.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev, Translated from Neirofiziologiya, Vol. 9, No. 1, pp. 48–51, January–February, 1977.     

Guidance of glial precursor cell migration by secreted cues in the developing optic nerve

Oligodendrocyte precursors are produced in restricted foci of the germinative neuroepithelium in embryo brains and migrate to their sites of function, while astrocytes are produced in a wider area in the neuroepithelium. We investigated the guidance mechanisms of glial precursor (GP) cell migration in the optic nerve. GP cell migration in newborn rat optic nerve was monitored by the UV-thymine-dimer (TD) method. A double labeling study using NG2 and TD revealed that many of these in vivo migrating cells were NG2 positive, while some of them with large TD-positive nuclei were NG2 negative. An in vitro cell migration study using optic nerve with chiasma and/or eyeball tissue revealed that the GP cells migrated under the guidance of repulsive cues secreted from the optic chiasma. We detected the expression of netrin 1 and Sema3a in the optic chiasma, and that of Unc5h1 and neuropilin 1 in the optic nerve. Co-culture experiments of the optic nerve with cell clusters expressing guidance cues revealed that the migrating GP cells in the optic nerve were heterogeneous. Netrin 1 repelled a subtype of NG2-positive and PLP-positive GP cells with small nuclei. Sema3a repelled a subtype of GP cells with large nuclei.     

Expression of vimentin and glial fibrillary acidic protein in human developing spinal cord

Summary Expression of intermediate filament proteins was studied in human developing spinal cord using immunoperoxidase and double-label immunofluorescence methods with monoclonal antibodies to vimentin and glial fibrillary acidic protein (GFAP). Vimentin was found in the processes of radial glial cells in 6-week embryos, while GFAP appeared in vimentin-positive astroglial cells at 8–10 weeks. GFAP and vimentin were present in approximately equal amounts in differentiating astrocytes in 23-week spinal cord. In 30-week fetuses, astrocytes reacted strongly for GFAP, while both the reaction intensity and the number of vimentin-positive cells fluctuated predominantly in the grey matter. No clear-cut transition from vimentin to GFAP was noticed during the development of astrocytes. The majority of ependymal cells in 23-week fetuses contained vimentin but only a few of them reacted for GFAP. The expression of vimentin continued during the whole development of the ependymal layer, in contrast to the reactivity for GFAP which disappeared between the 30th week and term.     

Glutamate-, kainate- and NMDA-evoked membrane currents in identified glial cells in rat spinal cord slice

The effect of L-glutamate, kainate and N-methyl-D-aspartate (NMDA) on membrane currents of astrocytes, oligodendrocytes and their respective precursors was studied in acute spinal cord slices of rats between the ages of postnatal days 5 and 13 using the whole-cell patch-clamp technique. L-glutamate (10(-3) M), kainate (10(-3) M), and NMDA (2x10(-3) M) evoked inward currents in all glial cells. Kainate evoked larger currents in precursors than in astrocytes and oligodendrocytes, while NMDA induced larger currents in astrocytes and oligodendrocytes than in precursors. Kainate-evoked currents were blocked by the AMPA/kainate receptor antagonist CNQX (10(-4) M) and were, with the exception of the precursors, larger in dorsal than in ventral horns, as were NMDA-evoked currents. Currents evoked by NMDA were unaffected by CNQX and, in contrast to those seen in neurones, were not sensitive to Mg2+. In addition, they significantly decreased during development and were present when synaptic transmission was blocked in a Ca2+-free solution. NMDA-evoked currents were not abolished during the block of K+ inward currents in glial cells by Ba2+; thus they are unlikely to be mediated by an increase in extracellular K+ during neuronal activity. We provide evidence that spinal cord glial cells are sensitive to the application of L-glutamate, kainate and transiently, during postnatal development, to NMDA.     

Origin of new glial cells in intact and injured adult spinal cord

Several distinct cell types in the adult central nervous system have been suggested to act as stem or progenitor cells generating new cells under physiological or pathological conditions. We have assessed the origin of new cells in the adult mouse spinal cord by genetic fate mapping. Oligodendrocyte progenitors self-renew, give rise to new mature oligodendrocytes, and constitute the dominating proliferating cell population in the intact adult spinal cord. In contrast, astrocytes and ependymal cells, which are restricted to limited self-duplication in the intact spinal cord, generate the largest number of cells after spinal cord injury. Only ependymal cells generate progeny of multiple fates, and neural stem cell activity in the intact and injured adult spinal cord is confined to this cell population. We provide an integrated view of how several distinct cell types contribute in complementary ways to cell maintenance and the reaction to injury.     

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.     

Engraftment,migration and differentiation of neural stem cells in the rat spinal cord following contusion injury

Background aimsSpinal cord injury is a devastating injury that impacts drastically on the victim's quality of life. Stem cells have been proposed as a therapeutic strategy. Neural stem (NS) cells have been harvested from embryonic mouse forebrain and cultured as adherent cells. These NS cells express markers of neurogenic radial glia.MethodsMouse NS cells expressing green fluorescent protein (GFP) were transplanted into immunosupressed rat spinal cords following moderate contusion injury at T9. Animals were left for 2 and 6 weeks then spinal cords were fixed, cryosectioned and analyzed. Stereologic methods were used to estimate the volume and cellular environment of the lesions. Engraftment, migration and differentiation of NS cells were also examined.ResultsNS cells integrated well into host tissue and appeared to migrate toward the lesion site. They expressed markers of neurons, astrocytes and oligodendrocytes at 2 weeks post-transplantation and markers of neurons and astrocytes at the 6-week time-point. NS cells appeared to have a similar morphologic phenotype to radial glia, in particular at the pial surface.ConclusionsAlthough no functional recovery was observed using the Basso Beattie Bresnahan (BBB) locomotor rating scale, NS cells are a potential cellular therapy for treatment of injured spinal cord. They may be used as delivery vehicles for therapeutic proteins because they show an ability to migrate toward the site of a lesion. They may also be used to replace lost or damaged neurons and oligodendrocytes.     

Alternative pathways of glucose utilization in developing rat spinal cord

The activities of alternative pathways of glucose utilization in the developing rat spinal cord were evaluated from the release of ¹⁴CO₂ and the incorporation of [¹⁴C] into lipids from differentially labelled glucose. Total lipid synthesis had peak activity at 15 days post-partum corresponding to the period of peak myelination in rat spinal cord. The activities of the glycolytic route, tricarboxylic acid cycle and fully activated pentose phosphate pathway were highest up to 20 days post-partum. After this period myelin (which is biochemically relatively inert) will constitute a larger proportion of the mass of the cord and this may contribute to the lower observed rates of the above pathways during later stages of development. Treatment of 20 day old rats with 6-aminonicotinamide resulted in spastic paralysis of the rats and pronounced inhibition of the pentose phosphate pathway indicating that this pathway, although low in activity (less than 4% of total glucose oxidation) has an important role in developing rat spinal cord.     

Calcium-mediated breakdown of glial filaments and neurofilaments in rat optic nerve and spinal cord

Disruptive effects of calcium upon neurofilaments and glial filaments were studied in white matter of rat optic nerve and spinal cord and in rat peripheral nerve. Filament ultrastructure and tissue protein composition were compared following a calcium influx into excised tissues. A calcium influx was induced by freeze-thawing tissues in media containing calcium (5 mM) while control tissues were freeze-thawed in the presence of EGTA (5 mM). Experimental and control tissues were either fixed by immersion in glutaraldehyde and processed for electron microscopic examination or homogenized in a solubilizing buffer and analyzed for protein content by SDS-polyacrylamide gel electrophoresis. Morphological studies showed that calcium influxes led to the loss of neurofilaments and glial filaments and to their replacement by an amorphous granular material. These morphological changes were accompanied by the loss of neurofilament triplet proteins and glial fibrillary acidic (GFA) protein from whole-tissue homogenates. In addition, a calcium-sensitive 58,000-mol-wt protein was identified in rat optic and peripheral nerve. The findings indicate the widespread occurrence of neurofilament proteolysis following calcium influxes into CNS and PNS tissues. The parallel breakdown of glial filaments and loss of GFA protein subunits suggest the presence of additional calcium-activated proteases(s) in astroglial cells.     

Oligodendrocyte precursor cells stop sensory axons regenerating into the spinal cord

1. Download : Download high-res image (286KB)
2. Download : Download full-size image

     

The differentiation of glial cells and glia limitans in organ cultures of chick spinal cord

Summary Differentiation of glial cells and the glia limitans in organ cultures of chick spinal cord explanted at early neural tube stages, alone or with adjacent tissues, was studied by electron microscopy. Oligodendrocytes and astrocytes comparable to those seen in the chicken in vivo were observed, mainly in areas of good neuronal differentiation. A glia limitans with basal lamina, comparable to that in vivo, was found when spinal cord was bordered by normally adjacent tissues. When it was surrounded by vitelline membrane only, a characteristic limiting layer of glial processes, but no basal lamina, was seen. Contact with a filter membrane (Millipore) elicited excessive differentiation of glial filaments and modified cell fine structure; no glia limitans was formed. Supported by Grant 5 RO 1 NB 0637 from the United States Public Health Service.     

Adult neurogenesis in the crayfish brain: Proliferation,migration, and possible origin of precursor cells

The birth of new neurons and their incorporation into functional circuits in the adult brain is a characteristic of many vertebrate and invertebrate organisms, including decapod crustaceans. Precursor cells maintaining life‐long proliferation in the brains of crayfish (Procambarus clarkii, Cherax destructor) and clawed lobsters (Homarus americanus) reside within a specialized niche on the ventral surface of the brain; their daughters migrate to two proliferation zones along a stream formed by processes of the niche precursors. Here they divide again, finally producing interneurons in the olfactory pathway. The present studies in P. clarkii explore (1) differential proliferative activity among the niche precursor cells with growth and aging, (2) morphological characteristics of cells in the niche and migratory streams, and (3) aspects of the cell cycle in this lineage. Morphologically symmetrical divisions of neuronal precursor cells were observed in the niche near where the migratory streams emerge, as well as in the streams and proliferation zones. The nuclei of migrating cells elongate and undergo shape changes consistent with nucleokinetic movement. LIS1, a highly conserved dynein‐binding protein, is expressed in cells in the migratory stream and neurogenic niche, implicating this protein in the translocation of crustacean brain neuronal precursor cells. Symmetrical divisions of the niche precursors and migration of both daughters raised the question of how the niche precursor pool is replenished. We present here preliminary evidence for an association between vascular cells and the niche precursors, which may relate to the life‐long growth and maintenance of the crustacean neurogenic niche. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009