Temporal-spatial expressions of p27kip1 and its phosphorylation on Serine-10 after acute spinal cord injury in adult rat: Implications for post-traumatic glial proliferation

P27kip1, as a member of Cip/Kip family of cyclin-dependent kinase inhibitors, plays important roles in cell cycle regulation and neurogenesis in the developing central nervous system. Serine-10 is the major phosphorylation site of p27kip1, and post-translational regulation of p27kip1 by different phosphorylation events is critical for its function. To elucidate the expressions and possible functions of p27kip1 and its phosphorylation in central nervous system lesion and repair, we performed an acute spinal cord contusion injury model in adult rats. Our work studied the temporal-spatial expression patterns of p27kip1 and Serine-10 phosphorylated p27kip1 (p-p27s10). Western blot analysis showed p27kip1 level significantly decreased at day 3 after damage, while p-p27s10 was detected at a high-level at the same time reaching the uninjured level. Moreover, immunofluorescence double labeling suggested these changes were striking in microglia and astrocytes, which were largely proliferated. Immunohistochemical analysis revealed subcellular localization changes of p27kip1 and p-p27s10 staining between nucleus and cytoplasm after injury in about 20% of total positive cells including neurons and glial cells. We also investigated the increased interactions of p27kip1 and p-p27s10 with CRM1 3 days after injury by co-immunoprecipitation studies. Taken together, we hypothesized spinal cord injury stimulated mitogenic signals to induce a serine-threonine kinase KIS (kinase interacting stathmin) to phosphorylate p27kip1 on Serine-10, so that p27kip1 could bind to CRM1 and be exported from nuclei for degradation. Such an event facilitated cell cycle progression of glial cells, especially microglia and astrocytes which had a prevalent proliferation.     

Neural repair and glial proliferation: parallels with gliogenesis in insects

There is a growing recognition, stemming from work with both vertebrates and invertebrates, that the capacity for neuronal regeneration is critically dependent on the local microenvironment. That environment is largely created by the non-neuronal elements of the nervous system, the neuroglia. Therefore an understanding of how glial cells respond to injury is crucial to understanding neuronal regeneration. Here we examine the process of repair in a relatively simple nervous system, that of the insect, in which it is possible to define precisely the cellular events of the repair process. This repair is rapid and well organised; it involves the recruitment of blood cells, the division of endogenous glial elements and, possibly, migration from pre-existing glial pools in adjacent ganglia. There are clear parallels between the events of repair and those of normal glial development. It seems likely that the ability of the insect central nervous system to repair resides in the retention of developmental capacities throughout its life and that damage results in the activation of this potential.     

Prospero maintains the mitotic potential of glial precursors enabling them to respond to neurons

During central nervous system development, glial cells need to be in the correct number and location, at the correct time, to enable axon guidance and neuropile formation. Repair of the injured or diseased central nervous system will require the manipulation of glial precursors, so that the number of glial cells is adjusted to that of neurons, enabling axonal tracts to be rebuilt, remyelinated and functional. Unfortunately, the molecular mechanisms controlling glial precursor proliferative potential are unknown. We show here that glial proliferation is regulated by interactions with axons and that the Drosophila gene prospero is required to maintain the mitotic potential of glia. During growth cone guidance, Prospero positively regulates cycE promoting cell proliferation. Neuronal Vein activates the MAPKinase signalling pathway in the glia with highest Prospero levels, coupling axon extension with glial proliferation. Later on, Prospero maintains glial precursors in an undifferentiated state by activating Notch and antagonising the p27/p21 homologue Dacapo. This enables prospero-expressing cells alone to divide further upon elimination of neurons and to adjust glial number to axons during development.     

Base composition, selection, and phylogenetic significance of indels in the recombination activating gene-1 in vertebrates

Background

Echinoderms and chordates belong to the same monophyletic taxon, the Deuterostomia. In spite of significant differences in body plan organization, the two phyla may share more common traits than was thought previously. Of particular interest are the common features in the organization of the central nervous system. The present study employs two polyclonal antisera raised against bovine Reissner's substance (RS), a secretory product produced by glial cells of the subcomissural organ, to study RS-like immunoreactivity in the central nervous system of sea cucumbers.

Results

In the ectoneural division of the nervous system, both antisera recognize the content of secretory vacuoles in the apical cytoplasm of the radial glia-like cells of the neuroepithelium and in the flattened glial cells of the non-neural epineural roof epithelium. The secreted immunopositive material seems to form a thin layer covering the cell apices. There is no accumulation of the immunoreactive material on the apical surface of the hyponeural neuroepithelium or the hyponeural roof epithelium. Besides labelling the supporting cells and flattened glial cells of the epineural roof epithelium, both anti-RS antisera reveal a previously unknown putative glial cell type within the neural parenchyma of the holothurian nervous system.

Conclusion

Our results show that: a) the glial cells of the holothurian tubular nervous system produce a material similar to Reissner's substance known to be synthesized by secretory glial cells in all chordates studied so far; b) the nervous system of sea cucumbers shows a previously unrealized complexity of glial organization. Our findings also provide significant clues for interpretation of the evolution of the nervous system in the Deuterostomia. It is suggested that echinoderms and chordates might have inherited the RS-producing radial glial cell type from the central nervous system of their common ancestor, i.e., the last common ancestor of all the Deuterostomia.     

Glial cells

The nervous system is built from two broad categories of cells, neurones and glial cells. The glial cells outnumber the neurones and the two cell types occupy a comparable amount of space in nervous tissue. The main glial cell types are, in the central nervous system, astrocytes and oligodendrocytes and, in the peripheral nervous system, Schwann cells, enteric glial cells and satellite cells. In the embryo, glial cells form a cellular framework that permits the development of the rest of the nervous system, and regulate neuronal survival and differentiation. The best known function of glia in the adult is the formation of myelin sheaths around axons thus allowing the fast conduction of signalling essential for nervous system function. Glia also maintain appropriate concentrations of ions and neurotransmitters in the neuronal environment. Increasing body of evidence indicates that glial cells are essential regulators of the formation, maintenance and function of synapses, the key functional unit of the nervous system.     

Olfactory ensheathing cells: their role in central nervous system repair

The olfactory system is an unusual tissue in that it can support neurogenesis throughout life; permitting the in-growth and synapse formation of olfactory receptor axons into the central nervous system (CNS) environment of the olfactory bulb. It is thought that this unusual property is in part due to the olfactory glial cells, termed olfactory ensheathing cells (OECs), but also due to neuronal stem cells. These glial cells originate from the olfactory placode and possess many properties in common with the glial cells from the peripheral nervous system (PNS), Schwann cells. Recent data has suggested that olfactory ensheathing cells are a distinct glial cell type and possess properties, which might make them more suitable for transplant-mediated repair of central nervous system injury models. This paper reviews the biological properties of these cells and illustrates their use in central nervous system repair.     

编者按: 神奇的“胶水”细胞

胶质细胞是一类神经系统中区别于神经元的一大类细胞，其数量是神经元的10~50倍。而且在相当长的一段时间胶质细胞也被认为是神经系统中的一种“胶水”，仅起到黏结神经元和填充神经系统的作用。随着近几十年神经科学的发展，神经生物学家们发现，胶质细胞的功能多种多样，并参与记忆、认知、神经发育性和退行性疾病，甚至衰老等高级功能。通过PubMed查询，中国胶质细胞相关论文的十年增长率为270%，远远高于全球平均增长率140%，说明中国在胶质细胞方面的研究势头非常强劲。本期《生物化学与生物物理进展》刊出了围绕胶质细胞的20余篇论文。涵盖胶质细胞的生理功能和病理功能的各个方面。本期的刊行将有利于推动国内胶质细胞科学研究，并为中国脑计划提供参考。     

Development of the peripheral glial cells in Drosophila

In complex organisms the nervous system comprises two cell types: neurons and glial cells. Their correct interplay is of crucial importance during both the development of the nervous system and for later function of the nervous system. In recent years tools have been developed for Drosophila that enable genetic approaches to understanding glial development and differentiation. Focusing on peripheral glial cells we first summarize wild-type development, then introduce some of the relevant genes that have been identified. Despite obvious differences between Drosophila and mammalian glial cells, the molecular machinery that controls terminal differentiation appears well conserved.     

The midline glial cells are required for regionalization of commissural axons in the embryonic CNS of Drosophila

 The ventral nerve cord of arthropods is characterised by the organisation of major axon tracts in a ladder-like pattern. The individual neuromeres are connected by longitudinal connectives whereas the contra-lateral connections are brought about through segmental commissures. In each neuromere of the embryonic central nervous system (CNS) of Drosophila an anterior and a posterior commissure is found. The development of these commissures requires a set of neurone-glia interactions at the midline. Here we show that both the anterior as well as the posterior commissures are subdivided into three axon-containing regions. Electron microscopy of the ventral nerve cord of mutations affecting CNS midline cells indicates that the midline glial cells are required for this subdivision. In addition the midline glial cells appear required for a crossing of commissural growth cones perpendicular to the longitudinal tracts, since in mutants with defective midline glial cells commissural axons frequently cross the midline at aberrant angles. Received: 6 July 1997 / Accepted: 27 August 1997     

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.     

Control of peripheral glial cell proliferation: a comparison of the division rates of enteric glia and Schwann cells and their response to mitogens

The enteric nervous system comprises neurons and a relatively homogeneous population of glial cells, which differ considerably from those found in other parts of the peripheral nervous system and resemble more closely astrocytes from the central nervous system. It provides a simple model system for the study of neuron/glial interactions and glial cell development. In this study the proliferation rates of purified populations of enteric glia and Schwann cells and their response to several mitogens in vitro were compared. Enteric glial cells divided at a much higher rate than Schwann cells in both serum-containing and serum-free media. This difference in their basal proliferation rates was the major difference seen between the two cell types. Both cell populations were stimulated to divide by fibroblast growth factor and glial growth factor but not by epidermal growth factor. Enteric glial cells and Schwann cells proliferated at a greater rate on a basement membrane-like extracellular matrix produced by corneal endothelial cells, laminin, and fibronectin than on poly-L-lysine-coated glass coverslips. The magnitude of stimulation was greater for Schwann cells, presumably due to their lower basal division rates. Like Schwann cells, enteric glial cells were stimulated to divide by two agents which elevate intracellular cAMP, cholera toxin, and dibutyryl cAMP.     

Interleukin 27 induces differentiation of neural C6-precursor cells into astrocytes

Interleukin 6 (IL6)-type cytokines are major regulators of inflammation and thereby contribute to the neuropathology and pathophysiology associated with inflammation of the central nervous system (CNS). Furthermore, astrocyte development which is a key process in the development of the CNS is also controlled by cytokines of the IL6-family. Interleukin 27 (IL27) is a recently identified member of this family and has been implicated in the inhibition of TH₁₇ T-cell-responses. Here we show that IL27 and the HHV8 encoded viral IL6 (vIL6) induce C6 glioma cells to differentiate into an astrocyte-like state. Cytokine stimulation led to STAT-factor phosphorylation and consequently to protein expression of the astrocyte marker glial fibrillary acidic protein (GFAP). These data could be confirmed by GFAP-immunostaining of stimulated cells. Taken together, IL27 and vIL6 can be considered as new astrocyte-inducing cytokines of the brain.     

Structure of the glial cells in the nervous system of parasitic and free-living flatworms

This study is devoted to ultrastructural and immunosytochemical investigation of the nervous system in parasitic and free-living platyhelminthes to learn if glial cells exist in the nervous system of flatworms. We described the ultrastructure of different types of glial cells and the peculiarities of myelinization of gigantic axons; immunoreactivity to the S100b protein is revealed. Comparative analysis of the glia structure of annelids and platods is given; structural, functional, and evolutionary aspects of myelinization of gigantic axons, which are revealed in cestodes, are discussed.     

Gliarin and macrolin,two novel intermediate filament proteins specifically expressed in sets and subsets of glial cells in leech central nervous system

Using monoclonal antibodies, we have identified two novel intermediate filament (IF) proteins, Gliarin and Macrolin, which are specifically expressed in the central nervous system of an invertebrate. The two proteins both contain the coiled‐coil rod domain typical of the superfamily of IF proteins flanked by unique N‐ and C‐terminal domains. Gliarin was found in all glial cells including macro‐ and microglial cells, whereas Macrolin was expressed in only a single pair of giant connective glial cells. The identification of Macrolin and Gliarin together with the characterization of the strictly neuronal IF protein Filarin in leech central nervous system demonstrate that multiple neuron‐ and glial‐specific IFs are not unique to the vertebrate nervous system but are also found in invertebrates. Interestingly, phylogenetic analysis based on maximum parsimony indicated that the presence of neuron‐ and glial cell–specific IFs in coelomate protostomes as well as in vertebrates is not of monophyletic origin, but rather represents convergent evolution and appears to have arisen independently. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 244–253, 1999     

Evolutionarily conserved concepts in glial cell biology

The evolutionary conservation of glial cells has been appreciated since Ramon y Cajal and Del Rio Hortega first described the morphological features of cells in the nervous system. We now appreciate that glial cells have essential roles throughout life in most nervous systems. The field of glial cell biology has grown exponentially in the last ten years. This new wealth of knowledge has been aided by seminal findings in non-mammalian model systems. Ultimately, such concepts help us to understand glia in mammalian nervous systems. Rather than summarizing the field of glial biology, I will first briefly introduce glia in non-mammalian models systems. Then, highlight seminal findings across the glial field that utilized non-mammalian model systems to advance our understanding of the mammalian nervous system. Finally, I will call attention to some recent findings that introduce new questions about glial cell biology that will be investigated for years to come.     

Mechanisms of glial development

Glial cells comprise most of the non-neuronal cells of the brain and peripheral nervous system, and include the myelin-forming oligodendrocytes and Schwann cells, radial glia and astrocytes. Their functions are diverse and include almost every aspect of nervous system function, from the birth and death of cells to the migrations and cell-cell interactions that connect and integrate the working elements of the nervous system. Recent studies have provided exciting insights into the mechanisms that drive the conversion into a glial cell and the developmental signals that guide the behavior of these multifunctional cells. An emerging theme is the so-called glial lineage being more diverse and more plastic than was previously thought. Here, we highlight some recent insights into glial development.     

Schwann Cell Exosomes Mediate Neuron–Glia Communication and Enhance Axonal Regeneration

The functional and structural integrity of the nervous system depends on the coordinated action of neurons and glial cells. Phenomena like synaptic activity, conduction of action potentials, and neuronal growth and regeneration, to name a few, are fine tuned by glial cells. Furthermore, the active role of glial cells in the regulation of neuronal functions is underscored by several conditions in which specific mutation affecting the glia results in axonal dysfunction. We have shown that Schwann cells (SCs), the peripheral nervous system glia, supply axons with ribosomes, and since proteins underlie cellular programs or functions, this dependence of axons from glial cells provides a new and unexplored dimension to our understanding of the nervous system. Recent evidence has now established a new modality of intercellular communication through extracellular vesicles. We have already shown that SC-derived extracellular vesicles known as exosomes enhance axonal regeneration, and increase neuronal survival after pro-degenerative stimuli. Therefore, the biology nervous system will have to be reformulated to include that the phenotype of a nerve cell results from the contribution of two nuclei, with enormous significance for the understanding of the nervous system in health and disease.     

Isolation of radial glial cells by fluorescent-activated cell sorting reveals a neuronal lineage

The developing central nervous system of vertebrates contains an abundant cell type designated radial glial cells. These cells are known as guiding cables for migrating neurons, while their role as precursor cells is less clear. Since radial glial cells express a variety of astroglial characteristics and differentiate as astrocytes after completing their guidance function, they have been considered as part of the glial lineage. Using fluorescence-activated cell sorting, we show here that radial glial cells also are neuronal precursors and only later, after neurogenesis, do they shift towards an exclusive generation of astrocytes. These results thus demonstrate a novel function for radial glial cells, namely their ability to generate two major cell types found in the nervous system, neurons and astrocytes.