Inflammatory responses of reactive GLIA

Young, Karen Anne

January 1997

No description available.

572

Reactive gliosis

The effect of protein-energy malnutrition on reactive gliosis following global ischemia

Harmon, Monique Iona

03 December 2007

Protein-energy malnutrition (PEM) has been found in up to 16.3% of acute stroke patients upon admission to hospital. Our laboratory has previously shown that PEM impairs functional outcome in a gerbil model of global ischemia, but the mechanism has not been established. The purpose of the current study was to characterize the marked reactive gliosis apparent in a subset of these animals that could represent an increased inflammatory response. A second objective was to validate a screening protocol for assessing completeness of ischemia in this model. Male Mongolian gerbils, aged 11-12 weeks, were randomized to PEM (2% protein) or control diet (12.5% protein) for 28d. PEM animals lost 12.2% of their initial body weight, and feed intake and serum albumin concentration were 12.3% and 17.8% lower than controls, respectively. At day 28, animals underwent 5 min bilateral common carotid artery occlusion (ischemia) or sham surgery. Activity was monitored using infrared beam interruptions for 20h post-surgery to screen for complete ischemia on the basis of persistent hyperactivity. Brain sections were stained with hematoxylin & eosin, and viable hippocampal CA1 neurons were counted at 10d post-ischemia. Immunohistochemistry for glial-fibrillary acidic protein (GFAP) and ricinus communis agglutinin -120 (RCA-120), markers for astrocytes and microglia, respectively, and the inflammatory cytokine TNF-alpha was performed on brain sections at 6h, 24h, 3d and 10d post-surgery (Ischemic, n=8; Sham, n=3). The activity monitoring procedure for detecting complete ischemia validated against hippocampal CA1 neuronal loss at 10d demonstrated an accuracy of 84.6%. Temporal changes in GFAP and RCA-120 immunoreactivity characteristic of reactive gliosis were demonstrated following ischemia, but this was not exacerbated by PEM. TNF-alpha immunoreactivity following ischemia was also unaltered by PEM. Ischemia significantly reduced surviving CA1 neurons at 10 days post-ischemia (two-way ANOVA; p<0.05), but this was not influenced by PEM. Impaired functional outcome in PEM animals following global ischemia can not be accounted for by increased hippocampal CA1 neuron death or by altered glial response.

protein-energy malnutrion

reactive gliosis

gerbil

The effect of protein-energy malnutrition on reactive gliosis following global ischemia

Harmon, Monique Iona

03 December 2007

Protein-energy malnutrition (PEM) has been found in up to 16.3% of acute stroke patients upon admission to hospital. Our laboratory has previously shown that PEM impairs functional outcome in a gerbil model of global ischemia, but the mechanism has not been established. The purpose of the current study was to characterize the marked reactive gliosis apparent in a subset of these animals that could represent an increased inflammatory response. A second objective was to validate a screening protocol for assessing completeness of ischemia in this model. Male Mongolian gerbils, aged 11-12 weeks, were randomized to PEM (2% protein) or control diet (12.5% protein) for 28d. PEM animals lost 12.2% of their initial body weight, and feed intake and serum albumin concentration were 12.3% and 17.8% lower than controls, respectively. At day 28, animals underwent 5 min bilateral common carotid artery occlusion (ischemia) or sham surgery. Activity was monitored using infrared beam interruptions for 20h post-surgery to screen for complete ischemia on the basis of persistent hyperactivity. Brain sections were stained with hematoxylin & eosin, and viable hippocampal CA1 neurons were counted at 10d post-ischemia. Immunohistochemistry for glial-fibrillary acidic protein (GFAP) and ricinus communis agglutinin -120 (RCA-120), markers for astrocytes and microglia, respectively, and the inflammatory cytokine TNF-alpha was performed on brain sections at 6h, 24h, 3d and 10d post-surgery (Ischemic, n=8; Sham, n=3). The activity monitoring procedure for detecting complete ischemia validated against hippocampal CA1 neuronal loss at 10d demonstrated an accuracy of 84.6%. Temporal changes in GFAP and RCA-120 immunoreactivity characteristic of reactive gliosis were demonstrated following ischemia, but this was not exacerbated by PEM. TNF-alpha immunoreactivity following ischemia was also unaltered by PEM. Ischemia significantly reduced surviving CA1 neurons at 10 days post-ischemia (two-way ANOVA; p<0.05), but this was not influenced by PEM. Impaired functional outcome in PEM animals following global ischemia can not be accounted for by increased hippocampal CA1 neuron death or by altered glial response.

protein-energy malnutrion

reactive gliosis

gerbil

Astrocyte proteoglycans in a model of reactive gliosis

Hoke, Ahmet

January 1994

No description available.

Biology, Neuroscience

Targeting inflammation and neurogenesis in an animal model of small-vessel stroke

Hua, Rui

03 July 2007

Therapeutic strategies of stroke can take two directions: to prevent brain damage from stroke or aid in its repair after a stroke. In this thesis, a rat stroke model, which mimics the human small vessel stroke, was used. Two potential repair strategies were investigated with this model, reduction of inflammatory processes with the aid of minocycline treatment and replacing necrotic neurons with new ones with the aid of neurogenesis of endogenous progenitor cells. <p>The stroke model is induced by disrupting the medium-size pial vessels within a 5mm-circular brain surface of adult Wistar rats. This leads to a cone-shaped cortical lesion. Therefore it mimics the clinical situation of lacunar infarction, the most frequent outcome of small vessel stroke. <p>Minocycline, a second-generation tetracycline, prevented cavitation and facilitated the repopulation of the lesion by reactive astrocytes. However, I could not identify the molecular target as the number of activated microglia, infiltrating leukocytes and CD3+ lymphocytes as well as interleukin-1β expression were not significantly altered. Doublecortin (DCX) is a microtubule-associated protein expressed by migrating neuroblasts and immature neurons. After injury, DCX-positive cells appeared in the neocortex at the base of the lesion. These cells exhibit a morphology resembling differentiated post-migratory neurons with long branched processes. Some of the DCX-positive cells were also immunoreactive for βIII-tubulin, another marker of immature neurons. This might indicate a migratory pathway for developing neuroblasts from the subventricular zone (SVZ) through the corpus callosum to the lesion. SVZ cells were labeled with carboxyfluorescein diacetate, succinimidyl ester (CFSE) stereotaxical injections. Although rostral migratory stream and olfactory bulb were intensely labeled, no CFSE containing cells were found in the cortex underneath the lesion. These results suggest that the DCX-positive cells may not originate from neural precursors from the SVZ, but might be generated from local progenitor cells. In summary, using the PVD II model, which mimics the lacunar stroke, I found that neuroblasts appeared spontaneously near the lesion in the cerebral cortex and were attempting to upregulate neuronal properties. Reducing inflammation with post-stroke minocycline treatment prevented cavitation. I think both findings open up exciting new avenues for treatment of lacunar infarctions.

minocycline

neuroblasts

reactive gliosis

cavitation

focal ischemia

doublecortin

Targeting inflammation and neurogenesis in an animal model of small-vessel stroke

Hua, Rui

03 July 2007

Therapeutic strategies of stroke can take two directions: to prevent brain damage from stroke or aid in its repair after a stroke. In this thesis, a rat stroke model, which mimics the human small vessel stroke, was used. Two potential repair strategies were investigated with this model, reduction of inflammatory processes with the aid of minocycline treatment and replacing necrotic neurons with new ones with the aid of neurogenesis of endogenous progenitor cells. <p>The stroke model is induced by disrupting the medium-size pial vessels within a 5mm-circular brain surface of adult Wistar rats. This leads to a cone-shaped cortical lesion. Therefore it mimics the clinical situation of lacunar infarction, the most frequent outcome of small vessel stroke. <p>Minocycline, a second-generation tetracycline, prevented cavitation and facilitated the repopulation of the lesion by reactive astrocytes. However, I could not identify the molecular target as the number of activated microglia, infiltrating leukocytes and CD3+ lymphocytes as well as interleukin-1β expression were not significantly altered. Doublecortin (DCX) is a microtubule-associated protein expressed by migrating neuroblasts and immature neurons. After injury, DCX-positive cells appeared in the neocortex at the base of the lesion. These cells exhibit a morphology resembling differentiated post-migratory neurons with long branched processes. Some of the DCX-positive cells were also immunoreactive for βIII-tubulin, another marker of immature neurons. This might indicate a migratory pathway for developing neuroblasts from the subventricular zone (SVZ) through the corpus callosum to the lesion. SVZ cells were labeled with carboxyfluorescein diacetate, succinimidyl ester (CFSE) stereotaxical injections. Although rostral migratory stream and olfactory bulb were intensely labeled, no CFSE containing cells were found in the cortex underneath the lesion. These results suggest that the DCX-positive cells may not originate from neural precursors from the SVZ, but might be generated from local progenitor cells. In summary, using the PVD II model, which mimics the lacunar stroke, I found that neuroblasts appeared spontaneously near the lesion in the cerebral cortex and were attempting to upregulate neuronal properties. Reducing inflammation with post-stroke minocycline treatment prevented cavitation. I think both findings open up exciting new avenues for treatment of lacunar infarctions.

minocycline

neuroblasts

reactive gliosis

cavitation

focal ischemia

doublecortin

I. PHOTOAFFINITY CROSSLINKING OF ALZHEIMER'S DISEASE β-AMYLOID FIBRILS II. PROTEOMIC ANALYSIS OF ENDOTHELIN-1 STIMULATED ASTROCYTES

EGNACZYK, GREGORY FRANCIS

08 November 2001

No description available.

beta-amyloid

photoaffinity crosslinking

Alzheimer's Disease

reactive gliosis

proteomics

Etude de la signalisation Hippo/YAP dans les cellules gliales de Müller en conditions physiologiques et pathologiques de dégénérescence rétinienne chez la souris / Study of Hippo/YAP signaling in Müller glial cells under physiological or pathological degenerative conditions in the mouse retina

Hamon, Annaïg

19 December 2017

Les maladies dégénératives de la rétine sont une des causes principales de cécité. Parmi différentes stratégies thérapeutiques actuellement étudiées, notre équipe s’intéresse au potentiel régénératif de la rétine. Une source cellulaire d'intérêt sont les cellules de Müller, principal type de cellules gliales de la rétine, capables de se réactiver en cas de dégénérescence et d’adopter certaines caractéristiques de cellules souches. Elles entrent alors dans un état appelé gliose réactive. Tandis que chez certaines espèces comme le poisson, elles permettent la régénération de la rétine, elles ont des capacités régénératives très limitées et inefficaces chez les mammifères. Une meilleure connaissance des mécanismes moléculaires régissant la gliose réactive des cellules de Müller est donc essentielle si l’on veut identifier des cibles thérapeutiques capables de stimuler le potentiel de régénération de ces cellules. Dans ce contexte, le but de mon projet de thèse a été d’étudier le rôle du co-facteur de transcription YAP dans la réactivation des cellules de Müller. Cette protéine est l’effecteur de la voie de signalisation Hippo, connue pour son implication dans la régulation des cellules souches et la régénération de certains organes.Dans un premier temps, nous avons réalisé une analyse transcriptomique qui a montré que la voie Hippo/YAP est une des principales voies dérégulées dans un modèle de dégénérescence rétinienne chez la souris. Nous avons ensuite montré que la protéine YAP est spécifiquement exprimée dans les cellules de Müller et que son expression et son activité transcriptionnelle sont augmentées au cours de la dégénérescence lorsque les cellules de Müller deviennent réactives. Ces données suggèrent pour la première fois un lien entre YAP et la gliose réactive dans la rétine. Par conséquent, dans un second temps, mon projet de thèse a consisté en l’étude fonctionnelle de YAP dans les cellules de Müller. Dans ce but, nous avons généré par croisements chez la souris un modèle inductible de délétion du gène Yap spécifiquement dans ces cellules. Ce modèle a permis de montrer qu’en absence de Yap en conditions physiologiques, plusieurs gènes spécifiques des cellules de Müller sont dérégulés, suggérant un dysfonctionnement de ces cellules. L’étude phénotypique a permis de révéler que ces dérégulations moléculaires conduisent à un vieillissement prématuré des cellules de Müller et à une baisse de la vision chez les souris âgées. Ces données suggèrent que YAP est requis pour le fonctionnement normal des cellules gliales de Müller. Nous avons ensuite examiné l’impact de la perte de Yap dans les cellules de Müller en conditions de dégénérescence des photorécepteurs. Une analyse transcriptomique a permis de montrer que différents aspects de la réponse moléculaire des cellules de Müller réactives sont affectés. Parmi les processus biologiques dérégulés, nous nous sommes intéressés à la régulation de la prolifération cellulaire. Nous avons montré que YAP est nécessaire à l’augmentation de l’expression de gènes associés à la réentrée dans le cycle cellulaire de la glie de Müller. Par ailleurs, nos résultats suggèrent que des composants de la voie de signalisation EGFR, connue pour son rôle central dans la réactivation des cellules de Müller, sont régulés par YAP.Dans l’ensemble, ces résultats révèlent l’importance de YAP (i) dans le fonctionnement des cellules de Müller en conditions physiologiques pour maintenir l’homéostasie rétinienne, et (ii) dans la régulation des processus de réactivation de ces cellules en conditions dégénératives. De plus, ces données permettent de proposer un modèle selon lequel YAP serait impliqué dans le contrôle de la réentrée des cellules de Müller dans le cycle cellulaire via une interaction avec la voie de signalisation EGFR. Ce travail a donc contribué à approfondir nos connaissances du réseau de signalisation impliqué dans la réactivation des cellules de Müller de la rétine des mammifères. / Retinal dystrophies are one of the main causes of blindness. Among the different therapeutic strategies currently studied, our team is interested in the regenerative potential of endogenous retinal cells. A cellular source of interest are Müller cells, which are the main type of glial cells in the retina. These cells are able to reactivate in case of retinal degeneration and adopt various characteristics of stem cells. They enter a state called reactive gliosis. While in some species such as the fish, they allow the complete regeneration of the retina, they have very limited and ineffective regenerative capacities in mammals. Increasing our knowledge of the complex molecular response of Müller cells to retinal degeneration is thus essential for the development of promising new therapeutic strategies. In this context, the aim of my thesis project was to study the role of the co-transcription factor YAP in Müller cells reactivation. This protein is the main effector of the Hippo signaling pathway which is a crucial player in the field of stem cell biology and regeneration.As a first step, we performed a transcriptomic analysis, which revealed that the Hippo/YAP pathway is one of the main signaling deregulated in a mouse model of photoreceptor degeneration. In particular, we found that YAP is specifically expressed in Müller cells and strongly upregulated upon retinal degeneration, when these cells are reactivated. We thus uncovered for the first time a link between the Hippo/YAP pathway and reactive gliosis in the retina. Consequently, the second part of my thesis project was to undertake a functional study of YAP in Müller cells. For this purpose, we generated, by crossing, a mouse model allowing for Yap conditional knockout specifically in these cells. This model allowed us to show that Yap deletion leads to deregulation of several Müller cell specific genes. A phenotypic analysis revealed that these molecular deregulations lead to premature aging of Müller cells and visual defects in old mice. These results suggest that YAP is required for normal function of Müller glial cells. We then studied the impact of Yap deletion in Müller cells under degenerative conditions. A transcriptomic analysis revealed that various aspects of the molecular response of reactive Müller cells are affected in the absence of Yap. Among the deregulated biological processes, we focussed in particular in the regulation of cell proliferation. We found that YAP is required to trigger cell cycle gene upregulation that occurs in Müller glial cells following photoreceptor cell death. Furthermore, our results suggest that some components of the EGFR signaling pathway, which is known for its central role in the reactivation of Müller cells in pathological conditions, are regulated by YAP in Müller cells.Taken together, these results highlight the importance of YAP (i) in Müller cell function under physiological conditions to maintain retinal homeostasis, and (ii) in the regulation of Müller cell reactivation process under degenerative conditions. Moreover, these data allow us to propose a model in which YAP would be involved in the control of Müller glia cell cycle re-entry through its interaction with the EGFR signaling pathway. Therefore, this work has contributed to increase our knowledge of the signaling network involved in the reactivation of Müller cells in the mammalian retina.

Cellules gliales de Müller

Régénération rétinienne

Voie de signalisation Hippo/YAP

Voie de signalisation EGFR

Gliose réactive

Prolifération cellulaire

Müller glial cells

Retinal regeneration

Hippo/YAP signaling pathway

EGFR signaling pathway

Reactive gliosis

Cell proliferation

BMP Pathway and Reactive Retinal Gliosis

Dharmarajan, Subramanian

06 March 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Reactive gliosis is known to have a beneficial and a degenerative effect following injury to neurons. Although many factors have been implicated in reactive gliosis, their role in regulating this change is still unclear. We investigated the role of bone morphogenetic proteins in reactive gliosis in vivo and in vitro. In vivo, IHC analysis indicated reactive gliosis in the 6 week Ins2Akita mouse and WPK rat retinas. Expression of BMP7 was upregulated in these models, leading to an increase in the phosphorylation of downstream SMAD1. In vitro, treatment of murine retinal astrocyte cells with a strong oxidizing agent such as sodium peroxynitrite regulated RNA levels of various markers, including GFAP, CSPGs, MMPs and TIMPs. BMP7 treatment also regulated RNA levels to a similar extent, suggesting reactive gliosis. Treatment with high glucose DMEM and BMP4, however, did not elicit increase in levels to a similar degree. Increase in SMAD levels and downstream targets of SMAD signaling such as ID1, ID3 and MSX2 was also observed following treatment with sodium peroxynitrite in vitro and in the 6 week Ins2Akita mouse retinas in vivo. These data concur with previously established data which show an increase in BMP7 levels following injury. It also demonstrates a role for BMP7 in gliosis following disease. Further, it suggests SMAD signaling to play a role in initiating reactivity in astrocytes as well as in remodeling the extracellular matrix following injury and in a disease condition.

Astrocytes

reactive gliosis

BMP

retina

Retina

Retina -- Abnormalities

Neuroglia

Neurons -- Physiology

Bone morphogenetic proteins

Astrocytes

RNA -- Research

Cellular signal transduction

Central nervous system -- Regeneration

Retinal ganglion cells

Nervous system -- Pathophysiology

Apoptosis