A Role of CPEB1 in the Modulation of Proliferation and Neuronal Maturation of Rat Primary Neural Progenitor Cells

Cytoplasmic polyadenylation binding protein 1 (CPEB1) is a RNA binding protein, which regulates translation of target mRNAs by regulating polyadenylation status. CPEB1 plays important roles in the regulation of germline cell development by modulating cell cycle progression through the polyadenylation of target mRNAs such as cyclin B1. Similar mechanism is reported in proliferating astrocytes by us, although CPEB1 is involved in the transport of target mRNAs as well as local translation at dendritic spines. In this study, we found the expression of CPEB1 in cultured rat primary neural progenitor cells (NPCs). EGF stimulation of cultured NPCs induced rapid phosphorylation of CPEB1, a hallmark of CPEB1-dependent translational control along with cyclin B1 polyadenylation and translation. EGF-induced activation of ERK1/2 and Aurora A kinase was responsible for CPEB1 phosphorylation. Pharmacological inhibition studies suggested that ERK1/2 is involved in the activation of Aurora A kinase and regulation of CPEB1 phosphorylation in cultured NPCs. Long-term incubation in EGF resulted in the down-regulation of CPEB1 expression, which further increased expression of cyclin B1 and cell cycle progression. When we down-regulated the expression of CPEB1 in NPCs by siRNA transfection, the proliferation of NPCs was increased. Increased NPCs proliferation by down-regulation of CPEB1 resulted in eventual up-regulation of neuronal differentiation with increase in both pre- and post-synaptic proteins. The results from the present study may suggest the importance of translational control in the regulation of neuronal development, an emerging concept in many neurodevelopmental and psychiatric disorders such as autism spectrum disorder.     

Down-regulation of glutamine synthetase enhances migration of rat astrocytes after in vitro injury

Astrocytes undergo reactive transformation in response to physical injury (reactive gliosis) that may impede neural repair. Glutamine synthetase (GS) is highly expressed by astrocytes, and serves a neuroprotective function by converting cytotoxic glutamate and ammonia into glutamine. Glutamine synthetase was down-regulated in reactive astrocytes at the site of mechanical spinal cord injury (SCI) and in cultured astrocytes at the margins of a scratch wound, suggesting that GS may modulate reactive transformation and glial scar development. We evaluated this potential function of GS using siRNA-mediated GS knock-down. Suppression of astrocytic GS by GS siRNA increased cell migration into the scratch wound zone and decreased substrate adhesion as indicated by the number of focal adhesions expressing the adaptor protein paxillin. Migration was enhanced by glutamine and suppressed by glutamate, in contrast to the result expected if enhanced migration was due solely to changes in glutamine and glutamate concomitant with reduced GS activity. The membrane type 1-matrix metalloproteinase (MT1-MMP) was up-regulated in GS siRNA-treated astrocytes, while a broad-spectrum MMP antagonist inhibited migration in both wild type and GS knock-down astrocytes. In addition, GS siRNA inhibited expression of integrin β1, while antibody-mediated inhibition of integrin β1 impaired direction-specific protrusion and motility. Thus, GS may modulate motility and substrate adhesion through transmembrane integrin β1 signaling to the cytoskeleton and by MMT-mediated proteolysis of the extracellular matrix.     

FABP7 expression in normal and stab-injured brain cortex and its role in astrocyte proliferation

Reactive gliosis, in which astrocytes as well as other types of glial cells undergo massive proliferation, is a common hallmark of all brain pathologies. Brain-type fatty acid-binding protein (FABP7) is abundantly expressed in neural stem cells and astrocytes of developing brain, suggesting its role in differentiation and/or proliferation of glial cells through regulation of lipid metabolism and/or signaling. However, the role of FABP7 in proliferation of glial cells during reactive gliosis is unknown. In this study, we examined the expression of FABP7 in mouse cortical stab injury model and also the phenotype of FABP7-KO mice in glial cell proliferation. Western blotting showed that FABP7 expression was increased significantly in the injured cortex compared with the contralateral side. By immunohistochemistry, FABP7 was localized to GFAP(+) astrocytes (21% of FABP7(+) cells) and NG2(+) oligodendrocyte progenitor cells (62%) in the normal cortex. In the injured cortex there was no change in the population of FABP7(+)/NG2(+) cells, while there was a significant increase in FABP7(+)/GFAP(+) cells. In the stab-injured cortex of FABP7-KO mice there was decrease in the total number of reactive astrocytes and in the number of BrdU(+) astrocytes compared with wild-type mice. Primary cultured astrocytes from FABP7-KO mice also showed a significant decrease in proliferation and omega-3 fatty acid incorporation compared with wild-type astrocytes. Overall, these data suggest that FABP7 is involved in the proliferation of astrocytes by controlling cellular fatty acid homeostasis.     

Signaling from P2 nucleotide receptors to protein kinase cascades induced by CNS injury

Gliosis is a hypertrophic and hyperplastic response to many types of central nervous system injury, including trauma, stroke, seizure, as well as neurodegenerative and demyelinating disorders. Reactive astrocytes, a major component of the glial scar, express molecules that can both inhibit and promote axonal regeneration. ATP, which is released upon traumatic injury, hypoxia, and cell death, contributes to the gliotic response by binding to specific cell surface astrocytic P2 nucleotide receptors and evoking characteristic features of gliosis such as increased expression of glial fibrillary acidic protein (GFAP), generation and elongation of astrocytic processes, and cellular proliferation. Here, we review recent studies that demonstrate that (1) metabotropic, P2Y, and ionotropic, P2X, receptors expressed in astrocytes are coupled to protein kinase signaling pathways that regulate cellular proliferation, differentiation, and survival such as ERK and protein kinase B/Akt and (2) these P2 receptor/protein kinase cascades are activated after trauma induced by mechanical strain. We suggest that P2 receptor/protein kinase signaling pathways might provide novel therapeutic targets to regulate the formation of reactive astrocytes and the production of molecules that affect axonal regeneration and neurodegeneration.     

Induction of cyclooxygenase-2 in reactive glial cells by the CD40 pathway: relevance to amyotrophic lateral sclerosis

An inflammatory process in association with reactive gliosis has been suggested to play an important role in the pathogenesis of amyotrophic lateral sclerosis (ALS). One of the key findings is a marked increase in the level of cyclooxygenase-2 (COX-2), a therapeutic target of ALS. We investigated the expression of CD40 in the spinal cord of a transgenic mouse model of ALS (G93A mice), and its relevance to COX-2 upregulation. CD40 was predominantly expressed in neurons in normal spinal cord and upregulated in reactive glial cells in spinal cord injury. In the spinal cord of G93A mice, the expression of CD40 was increased in both reactive microglia and astrocytes, where COX-2 was especially increased. The level of COX-2 was upregulated in microglia and astrocytes by CD40 stimulation in vitro. CD40 stimulation in primary spinal cord cultures caused motor neuron loss that was protected by selective COX-2 inhibitor. These results suggest that CD40, which is upregulated in reactive glial cells in ALS, participates in motor neuron loss via induction of COX-2.     

Reciprocal Modulation Between Microglia and Astrocyte in Reactive Gliosis Following the CNS Injury

Reactive gliosis, also known as glial scar formation, is an inflammatory response characterized by the proliferation of microglia and astrocytes as well as astrocytic hypertrophy following injury in the central nervous system (CNS). The glial scar forms a physical and molecular barrier to isolate the injured area from adjacent normal nervous tissue for re-establishing the integrity of the CNS. It prevents the further spread of cellular damage but represents an obstacle to regrowing axons. In this review, we integrated the current findings to elucidate the tightly reciprocal modulation between activated microglia and astrocytes in reactive gliosis and proposed that modification of cellular response to the injury or cellular reprogramming in the glial scar could lead advances in axon regeneration and functional recovery after the CNS injury.     

Proteomic analysis of the reactive phenotype of astrocytes following endothelin-1 exposure

Reactive gliosis is an invariant feature of the pathology of central nervous system (CNS) injury and a major determinant of neuronal survival and regeneration. To begin to understand the alterations in astrocyte protein expression that drive glial changes that occur following injury, we used an established model system (endothelin-1 stimulation of hypertrophy) and proteomic analysis to define a discrete set of differentially expressed proteins and post-translational modifications that occur as the astrocytes change from a quiescent to a reactive state. This orchestrated set of changes included proteins involved in cytoskeletal reorganization (caldesmon, calponin, alpha B-crystallin, stathmin, collapsing response mediator protein-2), cell adhesion (vinculin, galectin-1), signal transduction (RACK-1) and astrocyte differentiation (glutamine synthetase). Using proteomic analysis to understand what drives astrocyte expression of these functionally divergent molecules may offer insight into the mechanisms by which astrocytes can exhibit both pro-regenerative and anti-regenerative activities following CNS injury.     

A Culture Model of Reactive Astrocytes: Increased Nerve Growth Factor Synthesis and Reexpression of Cytokine Responsiveness

Abstract: Reactive gliosis, which occurs in response to damage to the central nervous system, has been recognized for years but is not yet understood. We describe here a tissue culture model of reactive astrocytes used to characterize their properties. Cultures are prepared 1 week following 6-hydroxydopamine (6-OHDA) lesion of rat substantia nigra and compared with astrocytes cultured from normal adult rats or rats injected with saline only. Astrocytes from the 6-OHDA-lesioned side contained elevated levels of glial fibrillary acidic protein (GFAP) and GFAP mRNA and were intensely immunoreactive for GFAP, vimentin, and two epitopes that in vivo are found only on reactive astrocytes. The basal content of nerve growth factor (NGF) mRNA and NGF in astrocytes from 6-OHDA-lesioned rats was significantly higher relative to control astrocytes. Two inflammatory cytokines, interleukin-1β and interferon-γ, increased synthesis of NGF up to 20-fold in the reactive cells, whereas there was no response in the normal adult astrocytes. Astrocytes from postnatal day 2 rats shared many of the properties of the reactive adult astrocytes. These cultures offer the possibility to characterize the cellular and molecular properties of reactive astrocytes and to determine the factors responsible for activation of astrocytes.     

Induction of cyclooxygenase-2 expression by manganese in cultured astrocytes

Inflammatory and oxidative events are present in neurodegenerative disorders and appear to contribute to initiation and/or progression of the disease. Within the brain, redox-active metals, such as manganese, play an important role as components of proteins essential for neural function. However, increasing evidence implies its participation in neurodegenerative diseases involving immune modulation. Prostaglandins (PGs) are lipid mediators that participate in the regulation of physiological and pathophysiological processes, particularly during brain inflammation. In this study, we investigated whether the immune modulating action of manganese involved regulation of PGE₂ production in cortical astrocytes. Within non-toxic concentrations, manganese caused an elevation in the expression of cyclooxygenase-2 (COX-2) mRNA and protein and increased PGE₂ release. Manganese potentiated COX-2 expression and PGE₂ generation by lipopolysaccharide/interferon-γ-activated astrocytes. The inductive action of manganese was accompanied by generation of oxidative stress, activation of mitogen-activated protein kinases (MAPKs), AKT, and protein kinase C- (PKC-), and increased NF-κB and AP-1 DNA binding activities. The generation of reactive oxygen species (ROS) was critical to manganese-induced changes in astrocytes, including MAPKs, PKC-, NF-κB, AP-1, and COX-2 expression but not AKT. Collectively, these data indicate that manganese might cause changes in neural activity through the modulation of oxidative and inflammatory events in astrocytes.     

Role of Gap Junction Protein Connexin43 in Astrogliosis Induced by Brain Injury

Astrogliosis is a process that involves morphological and biochemical changes associated with astrocyte activation in response to cell damage in the brain. The upregulation of intermediate filament proteins including glial fibrillary acidic protein (GFAP), nestin and vimentin are often used as indicators for astrogliosis. Although connexin43 (Cx43), a channel protein widely expressed in adult astrocytes, exhibits enhanced immunoreactivity in the peri-lesion region, its role in astrogliosis is still unclear. Here, we correlated the temporal and spatial expression of Cx43 to the activation of astrocytes and microglia in response to an acute needle stab wound in vivo. We found large numbers of microglia devoid of Cx43 in the needle wound at 3 days post injury (dpi) while reactive astrocytes expressing Cx43 were present in the peripheral zone surrounding the injury site. A redistribution of Cx43 to the needle site, corresponding to the increased presence of GFAP-positive reactive astrocytes in the region, was only apparent from 6 dpi and sustained until at least 15 dpi. Interestingly, the extent of microglial activation and subsequent astrogliosis in the brain of Cx43 knockout mice was significantly larger than those of wild type, suggesting that Cx43 expression limits the degree of microgliosis. Although Cx43 is not essential for astrogliosis and microglial activation induced by a needle injury, our results demonstrate that Cx43 is a useful marker for injury induced astrogliosis due to its enhanced expression specifically within a small region of the lesion for an extended period. As a channel protein, Cx43 is a potential in vivo diagnostic tool of asymptomatic brain injury.     

Expression of pituitary adenylate cyclase-activating polypeptide (PACAP) and the PACAP-selective receptor in cultured rat astrocytes, human brain tumors, and in response to acute intracranial injury

Pituitary adenylate cyclase-activating polypeptide (PACAP) is a bioactive peptide with diverse activities in the nervous system. In addition to its more classic role as a neurotransmitter, PACAP functions as a neurotrophic factor. PACAP exerts these activities by binding to PACAP-selective (PAC1) or nonselective (VPAC1, VPAC2) receptors (-R). Glial cells also exhibit PACAP binding, which is associated with the increased proliferation of astrocytes. The present report demonstrates a distinct spatiotemporal regulation of PACAP, PAC1-R, VPAC1-R, and VPAC2-R expression in primary cultured rat astrocytes. To determine the role of PACAP and PAC1-R expression on glial proliferation, two in vivo models were examined--human brain tumors of glial origin and the reactive gliosis induced by a penetrating stab wound to the mature rat brain. Relative to normal human brain, PAC1-R expression is significantly upregulated in glioma, particularly oligodendrogliomas. While similar polymerase chain reaction (PCR) analysis does not detect PACAP expression, in situ hybridization studies reveal PACAP expression in a limited number of cells within the tumor. In sharp contrast, neither PACAP nor PAC1-R expression are upregulated consequent to injury. These results suggest a distinct role for PACAP and PAC1-R in glioma development and nervous system response to injury.     

Glial responses to steroids as markers of brain aging.

Glia mediate neuroendocrine and neuroimmune functions that are altered during the process of normal aging. The biological functions of glia are also important in synaptic remodeling and the loss of synaptic connections that occur during aging. These functions are carried out by changes in glia, including changes in shape, interactions with neurons and other glia, and gene expression. The predominant change that occurs in glia during aging is glial activation, which can progress to reactive gliosis in response to neurodegeneration. More markers are needed to distinguish normal and reactive glia. During aging, astrocytes hypertrophy and exhibit signs of metabolic activation, and astrocytic processes surround neurons. Microglia also become activated and subsets of activated microglial increase in number and may enter the phagocytic or reactive stage. Glial markers of brain aging and glial activation include glial fibrillary acidic protein (GFAP) and transforming growth factor (TGF)-beta1, which are increased in astrocytes and microglia, respectively. Steroids regulate the interactions between glia and neurons and glial gene expression, including GFAP and TGF-beta1. Therefore, changes in these parameters during aging may be due to altered steroid regulation. In general, the effects of steroids oppose the effects of aging. Recent data indicate that steroid treatment can decrease the expression of GFAP in the aged brain, yet GFAP is resistant to down-regulation by endogenous glucocorticoids. Cellular and molecular markers of glial activation are being used to determine how changes in neuroendocrine and neuroimmune regulation contribute to repair and functional recovery that may reverse synaptic loss and cognitive impairment during aging.     

14-3-3 expression in denervated hippocampus after entorhinal cortex lesion assessed by culture-derived isotope tags in quantitative proteomics

Activation of astrocytes accompanies many brain pathologies. Reactive astrocytes have a beneficial role in acute neurotrauma but later on might inhibit regeneration. 2D-gel electrophoresis and mass spectrometry were applied to study the proteome difference in denervated hippocampus in wildtype mice and mice lacking intermediate filament proteins glial fibrillary acidic protein (GFAP) and vimentin (GFAP-/-Vim-/-) that show attenuated reactive gliosis and enhanced posttraumatic regeneration. Proteomic data and immunohistochemical analyses showed upregulation of the adapter protein 14-3-3 four days postlesion and suggested that 14-3-3 upregulation after injury is triggered by reactive gliosis. Culture-derived isotope tags (CDIT) and mass spectrometry demonstrated that 14-3-3 epsilon was the major isoform upregulated in denervated hippocampus and that its upregulation was attenuated in GFAP-/-Vim-/- mice and thus most likely connected to reactive gliosis.     

重组反义GFAP逆转录病毒对星形胶质细胞在胶质瘢痕增生中作用的研究

本文研究了脑穿刺损伤后伤灶组织中大胶质细胞的变化、性激素对脑损伤后星形胶质细胞反应的影响,以及反义胶质原纤维酸性蛋白（ＧＦＡＰ）逆转录病毒表达载体对Ａｓｔ形态结构,反应性胶质化及胶质瘢痕形成的作用。结果表明,胶质瘢痕中增生的大胶质细胞主要是Ａｓｔ,ＧＦＡＰ对维持Ａｓｔ的形态结构及功能具有重要作用;少突胶质细胞在胶质瘢痕形成过程中不是反应活跃的细胞成分;性激素对Ａｓｔ的反应性胶质化有一定程度的抑制作     

Upregulation of vascular endothelial growth factor receptors Flt-1 and Flk-1 following acute spinal cord contusion in rats.

To investigate the possible role of vascular endothelial growth factor (VEGF) in the injured spinal cord, we analyzed the distribution and time course of the two tyrosine kinase receptors for VEGF, Flt-1 and Flk-1, in the rat spinal cord following contusion injury using a weight-drop impactor. The semi-quantitative RT-PCR analysis of Flt-1 and Flk-1 in the spinal cord showed slight upregulation of these receptors following spinal cord injury. Although mRNAs for Flt-1 and Flk-1 were constitutively expressed in neurons, vascular endothelial cells, and some astrocytes in laminectomy control rats, their upregulation was induced in association with microglia/macrophages and reactive astrocytes in the vicinity of the lesion within 1 day in rats with a contusion injury and persisted for at least 14 days. The spatiotemporal expression of Flt-1 in the contused spinal cord mirrored that of Flk-1 expression. In the early phase of spinal cord injury, upregulation of Flt-1 and Flk-1 mRNA occurred in microglia/macrophages that infiltrated the lesion. In addition, the expression of both receptors increased progressively in reactive astrocytes within the vicinity of the lesion, predominately in the white matter, and almost all reactive astrocytes coexpressed Flt-1 or Flk-1 and nestin. These results suggest that VEGF may be involved in the inflammatory response and the astroglial reaction to contusion injuries of the spinal cord via specific VEGF receptors.     

The cyclic GMP-protein kinase G pathway regulates cytoskeleton dynamics and motility in astrocytes

We have previously demonstrated that inflammatory compounds that increase nitric oxide (NO) synthase expression have a biphasic effect on the level of the NO messenger cGMP in astrocytes. In this work, we demonstrate that NO-dependent cGMP formation is involved in the morphological change induced by lipopolysaccharide (LPS) in cultured rat cerebellar astroglia. In agreement with this, dibutyryl-cGMP, a permeable cGMP analogue, and atrial natriuretic peptide, a ligand for particulate guanylyl cyclase, are both able to induce process elongation and branching in astrocytes resulting from a rapid, reversible and concentration-dependent redistribution of glial fibrillary acidic protein (GFAP) and actin filaments without significant change in protein levels. These effects are also observed in astrocytes co-cultured with neurons. The cytoskeleton rearrangement induced by cGMP is prevented by the specific protein kinase G inhibitor Rp-8Br-PET-cGMPS and involves downstream inhibition of RhoA GTPase since is not observed in cells transfected with constitutively active RhoA. Furthermore, dibutyryl-cGMP prevents RhoA-membrane association, a step necessary for its interaction with effectors. Stimulation of the cGMP-protein kinase G pathway also leads to increased astrocyte migration in an in vitro scratch-wound assay resulting in accelerated wound closure, as seen in reactive gliosis following brain injury. These results indicate that cGMP-mediated pathways may regulate physio-pathologically relevant responses in astroglial cells.     

Roles of P2 receptors in glial cells: focus on astrocytes

Central nervous system glial cells release and respond to nucleotides under both physiological and pathological conditions, suggesting that these molecules play key roles in both normal brain function and in repair after damage. In particular, ATP released from astrocytes activates P2 receptors on astrocytes and other brain cells, allowing a form of homotypic and heterotypic signalling, which also involves microglia, neurons and oligodendrocytes. Multiple P2X and P2Y receptors are expressed by both astrocytes and microglia; however, these receptors are differentially recruited by nucleotides, depending upon specific pathophysiological conditions, and also mediate the long-term trophic changes of these cells during inflammatory gliosis. In astrocytes, P2-receptor-induced gliosis occurs via activation of the extracellular-regulated kinases (ERK) and protein kinase B/Akt pathways and involves induction of inflammatory and anti-inflammatory genes, cyclins, adhesion and antiapoptotic molecules. While astrocytic P2Y₁ and P2Y_2,4 are primarily involved in short-term calcium-dependent signalling, multiple P2 receptor subtypes seem to cooperate to astrocytic long-term changes. Conversely, in microglia, exposure to inflammatory and immunological stimuli results in differential functional changes of distinct P2 receptors, suggesting highly specific roles in acquisition of the activated phenotype. We believe that nucleotide-induced activation of astrocytes and microglia may originally start as a defence mechanism to protect neurons from cytotoxic and ischaemic insults; dysregulation of this process in chronic inflammatory diseases eventually results in neuronal cell damage and loss. On this basis, full elucidation of the specific roles of P2 receptors in these cells may help exploit the beneficial neuroprotective features of activated glia while attenuating their harmful properties and thus provide the basis for novel neuroprotective strategies that specifically target the purinergic system.     

Phosphorylation of Mitogen- and Stress-Activated Protein Kinase-1 in Astrocytic Inflammation: A Possible Role in Inhibiting Production of Inflammatory Cytokines

Purpose

It is generally accepted that inflammation has a role in the progression of many central nervous system (CNS) diseases, although the mechanisms through which this occurs remain unclear. Among mitogen-activated protein kinase (MAPK) targets, mitogen- and stress-activated protein kinase (MSK1) has been thought to be involved in the pathology of inflammatory gene expression. In this study, the roles of MSK1 activation in neuroinflammation were investigated.

Methods

The bacterial lipopolysaccharide (LPS)-induced brain injury model was performed on Sprague-Dawley rats. The dynamic expression changes and the cellular location of p-MSK1 in the brain cortex were detected by Western blot and immunofluorescence staining. The synthesis of inflammatory cytokines in astrocytes was detected by enzyme-linked immunosorbent assay (ELISA).

Results

Phosphorylated MSK1 (p-MSK1 Thr-581) was induced significantly after intracerebral injection of LPS into the lateral ventricles of the rat brain. Specific upregulation of p-MSK1 in astrocytes was also observed in inflamed cerebral cortex. At 1 day after LPS stimulation, iNOS, TNFα expression, and the astrocyte marker glial fibrillary acidic protein (GFAP) were increased significantly. Also, in vitro studies indicated that the upregulation of p-MSK1 (Thr-581) may be involved in the subsequent astrocyte inflammatory process, following LPS challenge. Using an enzyme-linked immunosorbent assay (ELISA), it was confirmed that treatment with LPS in primary astrocytes stimulated the synthesis of inflammatory cytokines, through MAPKs signaling pathways. In cultured primary astrocytes, both knock-down of total MSK1 by small interfering RNAs (siRNA) or specific mutation of Thr-581 resulted in higher production of certain cytokines, such as TNFα and IL-6.

Conclusions

Collectively, these results suggest that MSK1 phosphorylation is associated with the regulation of LPS-induced brain injury and possibly acts as a negative regulator of inflammation.