MODULATION OF THE ALPHA-7 NICOTINIC ACETYLCHOLINE RECEPTOR FOLLOWING EXPERIMENTAL RAT BRAIN INJURY IMPROVES CELLULAR AND BEHAVIORAL OUTCOMES

Woodcock, Thomas Matt

01 January 2010

Traumatic brain injury (TBI) is a leading cause of death and long-term disability worldwide, and survivors are often left with cognitive deficits and significant problems with day to day tasks. To date, therapeutic pharmacological treatments of TBI remain elusive despite numerous clinical trials. An improved understanding of the molecular and cellular response to injury may help guide future treatment strategies. One promising marker for brain injury is the translocator protein (TSPO), which is normally expressed at a low level, but is highly expressed following brain damage and is associated with neuroinflammation. The isoquinoline carboxamide PK11195 binds selectively to the TSPO in many species, and has therefore become the most-studied TSPO ligand. To characterize the time-course of TSPO expression in the controlled cortical injury (CCI) model of TBI we subjected Sprague-Dawley rats to CCI and euthanatized them after 30 minutes, 12 hours, 1, 2, 4, or 6 days. Autoradiography with radiolabelled PK11195 was used to assess the time-course of TSPO binding following CCI. Autoradiographs were compared to adjacent tissue slices stained with the microglia/macrophage marker ED-1, with which a moderate positive correlation was discovered. PK11195 autoradiography was used as a tool with which to assess neuroinflammation following CCI and the administration of an α7 nAChR antagonist, methyllycaconitine (MLA). We hypothesized that blocking the calcium permeable α7 nAChR after brain injury would have a neuroprotective effect by attenuating excitotoxicity in the shortterm. Our study revealed clear dose-dependent tissue sparing in rats administered MLA after trauma and a modest improvement in functional outcome. The relatively modest recovery of function with MLA, which could be due to prolonged α7 nAChR blockade or downregulation lead us to explore the potential of α7 nAChR partial agonists in treating TBI. The α7 nAChR partial agonists tropisetron, ondansetron, and DMXB-A produced a moderate attenuation of cognitive deficits, but did not have a neuroprotective effect on tissue sparing. These studies show that following TBI, α7 nAChR modulation can have neuroprotective effects and attenuate cognitive deficits. Whether this modulation is best achieved through partial agonist treatment alone or a combination antagonist/agonist treatment remains to be determined.

Pharmacy and Pharmaceutical Sciences

MICROGLIA ACTIVATION IN A RODENT MODEL OF AN ALCOHOL USE DISORDER: THE IMPORTANCE OF PHENOTYPE, INITIATION, AND DURATION OF ACTIVATION

Marshall, Simon A

01 January 2013

Chronic ethanol exposure results in neuroadaptations that drive the progression of an alcohol use disorder (AUD). One such driving force is alcohol-induced neurodegeneration. Neuroinflammation has been proposed as a mechanism underlying this damage. Although neuroinflammation is a physiological response to damage, overactivation of its pathways can lead to neurodegeneration. A hallmark indicator of neuroinflammation is microglial activation, but microglial activation is a heterogeneous continuum of phenotypes that can promote or inhibit neuroinflammation. Furthermore acute microglial activation is necessary to restore homeostasis, but prolonged activation can exacerbate damage. The diversity of microglia makes both the level and timecourse of activation vital to understanding their role in damage and/or recovery. The current set of experiments examines the effects of ethanol on microglia within the hippocampus and entorhinal cortex in a binge model of alcohol-induced neurodegeneration. In the first set of experiments, the phenotype of microglia activation was assessed using Raivich’s 5-stages of activation that separates pro- and anti-inflammatory forms of microglia. Morphological and functional assessments suggest that ethanol does not elicit classical microglial activation but instead induces partially activated microglia. In the second set of experiments, the earliest signs of microglial activation were determined to understand the initiation of microglial activation. Experiments indicated that activation occurred subsequent to previous evidence of neuronal damage; however, activation was accompanied by a loss of microglia and the discovery of dystrophic microglia. The final set of experiments examined whether alcohol-induced partial activation of microglia would show a differential response with further alcohol exposure. Experiments showed that animals previously exposed to ethanol showed a greater response to a second ethanol insult. Overall, these studies suggest that although alcohol may initially interrupt the normal microglia response, during abstinence from ethanol a partial activation phenotype appears that may contribute to recovery. Once activated, however, data suggest that these microglia are primed and upon subsequent exposure show an increased response. This heterogeneous microglial response with respect to time does not necessarily reflect a neuroinflammatory response that would be neurodegenerative but does imply that chronic ethanol consumption affects the normal neuroimmune system.

microglia activation

alcohol use disorder

neurodegeneration

binge ethanol exposure

neuroinflammation

Neurosciences

Pharmacy and Pharmaceutical Sciences

PET and the Multitracer Concept: An Approach to Neuroimaging Pathology

Engler, Henry

January 2008

<p>Patients suffering from different forms of neurodegenerative diseases, such as: Creutzfeldt Jacob Disease (CJD), Alzheimer disease (AD), mild cognitive impairment (MCI), frontotemporal dementia and Parkinson’s disease (PD) were examined with Positron Emission Tomography (PET) and the combination of different radiotracers: ¹⁵O-water, N-[¹¹C-methyl]-L-deuterodeprenyl (DED), [¹⁸F] 2-fluorodeoxyglucose: (FDG), N-methyl-[¹¹C]2-(4-methylaminophenyl)-6-hydroxybenzothiazole (PIB) and L-[¹¹C]-3,4-dihydroxiphenyl-alanine (DOPA). The radiotracers and the combinations of different radiotracers were selected with the intention to detect, in the brain, patterns of neuronal dysfunction, astrocytosis, axon degeneration or protein aggregation (amyloid), in the brain which are pathognomonic for specific diseases and may contribute to improve clinical differential diagnoses. Examinations in healthy volunteers were performed to allow comparisons with patients. In addition, animal studies were conducted to complement the information. In some cases, the PET findings could be compared with the results of autopsies.</p><p>In contrast to the micropathology, in which only a limited part of a tissue (obtained post-mortem or by biopsy) is inspected, one PET acquisition provides an image of the whole system (e.g.: the brain and the cerebellum). This form of imaging pathology is “<i>in vivo</i>”, where the examination is innocuous for the patient. </p><p>This thesis is an attempt to stimulate the development of new tracers, new tracer combinations and methods that directly or indirectly describe the anatomo-physiopathological changes produced in the brain in neurodegenerative diseases. A better description of different diseases can be obtained, confirming or questioning the clinical diagnoses and widening our understanding of the mechanisms underlying neurodegeneration. Different pathologies can produce similar symptoms and thus causing confusion regarding clinical diagnosis. The used PET combinations improved the accuracy of the diagnoses. The incipient knowledge emerging from a new neuroimaging pathology in combination with other disciplines may open the way to new classifications of dementias and neurodegenerative diseases based on an “<i>in vivo</i>” pathology. </p>

Neurosciences

PET (Positron Emission Tomography)

multitracer

neuroimaging pathology

astrocytes

microglia

neurodegeneration

amyloid

AD

CJD

PD

Neurovetenskap

Immunohistochemical evaluation of antibodies for staining of mouse spinal cord and mouse neuronal cells

Alsén, Per

January 2013

No description available.

NF-L

IB4

GFAP

NeuN

Chat

5-HT

astrocytes

microglia cells

Developmental Programming of Brain and Behavior: A Role for the Innate Immune System of the Placenta and Brain?

Bolton, Jessica Lynn

January 2015

<p>The field of "perinatal programming" has increasingly implicated an adverse early-life environment in the etiology of many chronic health problems and mental disorders. The following dissertation research is based on the hypothesis that the programming of brain and behavior by an altered early-life environment is propagated by inflammatory mechanisms in the placenta and developing brain. Offspring outcomes of two different maternal environmental exposures--air pollution and a "Western diet" (both highly relevant for the modern world)--were assessed in a mouse model in order to identify mechanisms common to developmental programming more generally.</p><p>The first set of experiments characterized the long-term behavioral and metabolic consequences of prenatal air pollution exposure in adult offspring. The male offspring of diesel exhaust particle (DEP)-exposed dams were predisposed to obesity, insulin resistance, and increased anxiety following placement on a high-fat diet (HFD) in adulthood. Furthermore, DEP/HFD male offspring exhibited evidence of macrophage priming, both in microglia and peripheral macrophages. The next experiment examined whether prenatal air pollution exposure could also synergize with a simultaneous "second hit" (i.e., maternal stress) during gestation. The offspring of mothers exposed to both air pollution and stress during gestation were more anxious as adults, but only the male offspring of this group also exhibited impaired cognition, in conjunction with neuroinflammatory changes. A further experiment revealed that prenatal air pollution exposure altered microglial maturation in a TLR4- and sex-dependent manner, consistent with the previous results. However, we found limited evidence of a placental immune response to DEP, potentially due to analysis too late in gestation. </p><p>The second set of experiments characterized the enduring behavioral and metabolic consequences of maternal consumption of a "Western diet" (HFD in combination with BCAA supplementation) prior to and during gestation and lactation. The adult offspring of HFD-fed dams were more anxious in adulthood, despite being placed on a low-fat diet at weaning. Male HFD offspring were also hyperactive, whereas female HFD offspring exhibited more severe metabolic disturbances. Furthermore, there was evidence of microglial priming and peripheral macrophage priming in male HFD offspring, similar to the prenatal air pollution model. The next experiment also found evidence of altered microglial development due to maternal HFD, in conjunction with widespread, sex-specific immune gene regulation in the placenta in response to maternal diet. Moreover, maternal HFD decreased placental serotonin production, and also programmed long-term alterations in serotonergic function in the prefrontal cortex of adult HFD offspring. Taken together, these experiments define sexually dimorphic innate immune mechanisms in the placenta and developing brain that may underlie the long-term metabolic and behavioral consequences of maternal environmental exposures.</p> / Dissertation

Neurosciences

Immunology

Developmental biology

air pollution

cytokines

maternal diet

microglia

perinatal programming

placenta

Neuroimmune and Developmental Mechanisms Regulating Motivational Behaviors for Opioids

Lacagnina, Michael John

January 2016

<p>Opioid drug abuse represents a serious public health concern with few effective therapeutic strategies. A primary goal for researchers modeling substance abuse disorders has been the delineation of the biological and environmental factors that shape an individual’s susceptibility or resistance to the reinforcing properties of abused substances. Early-life environmental conditions are frequently implicated as critical mediators for later-life health outcomes, although the cellular and molecular mechanisms that underlie these effects have historically been challenging to identify. Previous work has shown that a neonatal handling procedure in rats (which promotes enriched maternal care) attenuates morphine conditioning, reduces morphine-induced glial activation in the nucleus accumbens (NAc), and increases microglial expression of the anti-inflammatory cytokine interleukin-10 (IL-10). The experiments described in this dissertation were thus designed to address if inflammatory signaling in the NAc may underlie the effects of early-life experience on later-life opioid drug-taking. The results demonstrate that neonatal handling attenuates intravenous self-administration of the opioid remifentanil in a drug concentration-dependent manner. Transcriptional profiling of the NAc reveals a suppression of pro-inflammatory cytokine and chemokine signaling molecules and an increase in anti-inflammatory IL-10 in handled rats following repeated exposure to remifentanil. To directly test the hypothesis that anti-inflammatory signaling can alter drug-taking behavior, bilateral intracranial injections of plasmid DNA encoding IL-10 (pDNA-IL-10) or control pDNA were delivered into the NAc of naïve rats. pDNA-IL-10 treatment reduces remifentanil self-administration in a drug concentration-dependent manner, similar to the previous observations in handled rats. Additional experiments confirmed that neither handling nor pDNA-IL-10 treatment alters operant responding for food or sucrose rewards. These results help define the conditions under which ventral striatal neuroimmune signaling may influence motivated behaviors for highly reinforcing opioid drugs.</p> / Dissertation

Neurosciences

Behavioral psychology

Physiological psychology

Addiction

Development

Drug abuse

Microglia

Neuroimmune

Opioid

Cannabinoid Modulation of Chemotaxis of Macrophages and Macrophage-like Cells

Raborn, Erinn Shenee

01 January 2007

Exogenous and endogenous cannabinoids have been reported to modulate functional activities of macrophages. It is recognized that macrophages express primarily the CB2 cannabinoid receptor, but recent studies indicate that its expression is differential in relation to activation state with maximal levels occurring when cells are in "responsive" and "primed" states. The functional activities of macrophages when in these states of activation are the most susceptible to the action of cannabinoids, at least in terms of a functional linkage to the CB2. To assess the effect of cannabinoid treatment on macrophage chemotaxis and test the hypothesis that cannabinoids inhibit the chemotactic response of macrophages and microglia to endogenous and exogenous, pathogen-derived stimuli, primary murine peritoneal macrophages and neonatal rat microglia were used. Chemotaxis assays and scanning electron microscopy studies demonstrated that cannabinoids inhibit chemotaxis, a signature activity attributed to "responsive" macrophage-like cells, to the endogenous chemokine RANTES (Regulated upon Activation Normal T-cell Expressed and Secreted) and to Acanthamoeba conditioned medium containing secreted proteases. The partial agonist delta-9-tetrahydrocannabinol (THC), administered in vitro, inhibited the chemotactic response of peritoneal macrophages to the chemokine RANTES and to Acanthamoeba conditioned medium. In vivo treatment with THC also resulted in inhibition of the in vitro chemotactic response of murine peritoneal macrophages to RANTES and amoebic conditioned medium. Pharmacological studies employing cannabinoid receptor agonists and antagonists demonstrated the involvement of CB2 in cannabinoid-mediated inhibition of peritoneal macrophage chemotaxis to RANTES and Acanthamoeba conditioned medium, implying that signaling through cannabinoid receptors may desensitize chemokine receptors. Treatment with cannabinoids had no apparent effect on chemokine receptor mRNA levels, but did enhance CCR5 protein phosphorylation. Macrophage migration to Acanthamoeba conditioned medium may involve activation and signaling through protease activated receptors (PARs), as pathogen-derived proteases have been shown to activate PARs and initiate cellular migration; however, further studies are required to demonstrate PAR activation by amoebic conditioned medium and to assess the effects of cannabinoids on PAR signaling. Acanthamoeba are opportunistic pathogens that cause Granulomatis amoebic encephalitis, an infection of the CNS that is often fatal. THC treatment has been shown to increase mortality to Acanthamoeba infections and is characterized by an absence of granuloma formation. We hypothesize that inhibitory effect of THC on macrophage migration may be a key factor in cannabinoid-mediated immunosuppression. To assess the effect of cannabinoids on microglial migration to Acanthamoeba conditioned medium, chemotaxis assays were performed using primary rat microglia treated with cannabinoids. These studies demonstrated that cannabinoids inhibit microglial chemotaxis to amoebic conditioned medium. Furthermore, the studies demonstrate that cannabinoids, acting through cannabinoid receptors, may cross-talk with a diverse array G-protein coupled receptors so as to modulate responsiveness of macrophage and macrophage-like cells.

chemotaxis

cannabinoids

chemokine receptors

macrophage

microglia

Acanthamoeba conditioned medium

Medicine and Health Sciences

TRIPTOLIDE IS A POTENTIAL THERAPEUTIC AGENT FOR ALZHEIMER’S DISEASE

Allsbrook, Matthew

01 July 2009

Mounting evidence indicates an involvement of inflammation in the pathogenesis of Alzheimer’s disease. While there are other mechanisms involved, it is this role of inflammatory processes that we wish to investigate. Triptolide is the major constituent in the Chinese herb, Tripterygium wilfordii Hook F, and has been used for centuries as part of Chinese herbal medicine. The four ringed structure has close homology to drugs of the steroid class and it has been shown to be beneficial as an anti-inflammatory for rheumatoid arthritis and for treatment of certain cancers. The aim of this study was to evaluate the potential therapeutic effect of Triptolide on the neuropathology and deficits of spatial 6 learning and memory in amyloid precursor protein (APP) and presenilin 1 (PS1) doubletransgenic mice, a well established Alzheimer’s disease (AD) mouse model. After treatment of APP/PS1 mice with Triptolide (40μg/kg, three times weekly,), initiated when the mice were 5 months old, for as little as 8 weeks, significant decrease in β-amyloid (Aβ) deposition and microglia activation was observed. Moreover, Triptolide treatment robustly rescued spatial memory deficits observed in APP/PS1 mice. However, APP processing, tau hyperphosphorylation, and the activities of the two major kinases involved in tau hyperphosphorylation, cyclin dependent kinase 5 (cdk5) and glycogen synthase kinase 3β (GSK3β) were not affected by the Triptolide treatment. Based on the recent finding for the inhibitory effect of Triptolide on Aβ-induced production of pro-inflammatory cytokines from microglia, we propose that Triptolide treatment may have beneficial properties in halting glial activation and help restore an immune system that fights plaque deposition. Although the exact mechanism of action has yet to be deduced, the increase in APP CTFs while having a significant decrease in amyloid plaque deposition suggests that alterations in gamma secretase activity may be a possible answer. Currently, these results support the use of Triptolide as an effective therapeutic to prevent the progression of Alzheimer’s disease.

Alzheimer's Disease

triptolide

APP processing

microglia

Medical Pharmacology

Medical Sciences

Medicine and Health Sciences

Réactivité gliale et transmission glutamatergique/glycinergique spinale dans un modèle de douleur cancéreuse osseuse chez le rat : approches comportementale, immunohistochimique, moléculaire et biochimique / Glial reactivity and spinal glutamatergic/glycinergic transmission in a rat model of bone cancer pain : behavioral, immunohistochemical, molecular and biochemical approaches

Ducourneau, Vincent

25 March 2013

Au vu de la relative inefficacité des traitements actuels de la douleur cancéreuse osseuse (DCO) il est devenu nécessaire aujourd'hui d'identifier de nouvelles cibles (cellulaires et/ou moléculaires) pour développer de nouveaux outils thérapeutiques. Dans ce contexte, ces dernières années, de nombreuses études ont suggéré que les cellules gliales, principalement les astrocytes et la microglie, pourraient contribuer au développement et au maintien de la douleur chronique. D'autre part, dans des modèles d'études précliniques de la DCO, plusieurs auteurs ont récemment constaté une réactivité astrocytaire importante dans les cornes dorsales de la moelle épinière et ont montré que, si on empêche cette réactivité, les symptômes douloureux sont diminués. Cependant, la relation exacte existant entre la réactivité des cellules gliales et les symptômes douloureux en condition de DCO est inconnue. Afin de décrypter cette relation, nous avons dans un premier temps étudié le décours temporel des comportements douloureux et caractérisé l’état de sensibilisation centrale dans un modèle de DCO chez le rat induit par l'injection de cellules de carcinome glandulaire mammaire (MRMT-1) dans le tibia. Nous montrons par des approches radiologiques, comportementales (tests de douleur évoquée et de distribution pondérale dynamique) et immunohistochimiques (immunodétection de la protéine Fos après palpation non douloureuse de la patte) que les animaux cancéreux MRMT développent graduellement une tumeur osseuse (premiers signes au 10ème jour post-inoculation), une allodynie et une hyperalgésie mécaniques (à partir du 10ème jour) et thermiques (à partir du 14ème jour), un inconfort de la patte injectée (à partir du 14ème jour ) et des phénomènes de sensibilisation centrale. Dans un deuxième temps, nous avons recherché des indices structuraux et fonctionnels de réactivité gliale spinale dans notre modèle de DCO. L'objectif était donc de dater l'apparition de la réactivité gliale, et de déterminer la nature des cellules gliales impliquées : microglie et/ou astrocytes. Nous montrons par des approches immunohistochimiques qu’aucun signe morphologique de réactivité astrocytaire ni microgliale n’est observable pendant l’établissement et le maintien de la DCO alors que ces signes existent dans un modèle de douleur neuropathique (ligature de nerfs spinaux). De plus, par des approches moléculaire (qRT-PCR) et biochimique (technique du Bio-Plex) nous montrons que, parmi les 20 marqueurs structuraux et fonctionnels de réactivité gliale testés, seule l’expression de l’aquaporine 4 (un canal à eau spécifique des astrocytes) est significativement augmentée en condition de DCO. Nos résultats suggèrent donc que les astrocytes et les cellules microgliales jouent des rôles différents dans la douleur cancéreuse et dans la douleur neuropathique. Enfin, dans un troisième temps, nous avons cherché à mettre en évidence une implication des astrocytes dans la pathologie DCO au travers d’une caractérisation des transmissions glutamatergique et glycinergique, qui sont toutes deux fortement modulées par l’environnement astrocytaire. Par la quantification de l’expression de l’ARNm (qRT-PCR) et par dosage des taux d’acides aminés (électrophorèse capillaire), nous montrons que les principaux acteurs (transporteurs, récepteurs, agonistes et co-agonistes) de la transmission glutamatergique et glycinergique spinale ne subissent pas d’altération significative en condition de DCO. En conclusion, nous montrons que des symptômes douloureux chroniques peuvent se développer et se maintenir (1) sans signe d’astrogliose et de réactivité microgliale spinale ; et (2) sans altération de l’expression des principaux acteurs de la transmission spinale glutamatergique et glycinergique. Nos résultats invitent donc à revoir le lien très fort qui est fait actuellement entre douleur chronique et astrogliose. / The relative lack of efficiency of current treatments used to relieve bone cancer pain prompts to the identification of new molecular and/or cellular targets for the development of new therapeutic strategies. In that context, a large number of recent studies have suggested the involvement of glial cells, among which astrocytes and microglial cells, in the onset and maintenance of chronic pain symptoms. In few animal models of bone cancer pain, several authors have recently evidenced an increased glial reactivity in spinal cord dorsal horn, and demonstrated that preventing astrocytic reactivity was sufficient to reduce pain symptoms in these models. However, the exact relationship of glial reactivity with bone cancer pain symptoms remains poorly understood. In order to decipher this link, we have first studied the temporal development of pain symptoms, and characterized the degree of central sensitization in a rat model of bone cancer pain induced by the injection of mammary gland carcinoma cells (MRMT-1) in the tibial bone. Using radiologic assessment of tumor development, behavioral measurements to quantify evoked (von Frey hairs) and spontaneous (dynamic weight bearing) pain and immunodetection of Fos after non nociceptive palpation of cancer bearing limb, we demonstrate that animals injected with MRMT-1 cells gradually develop a bone tumor (first detectable 10 days after inoculation), a mechanical allodynia and hyperalgesia (first noticeable at day 10), and later on a thermal allodynia and hyperalgesia (first detectable at day 14) as well as discomfort of the injected limb (day 14) and finally central sensitization phenomenons. Second, we have investigated the presence of structural and functional markers of spinal glial reactivity in our model of bone cancer pain. Our objectives were to date the onset of spinal glial reactivity, for microglial and astrocytic cells. Using immunohistochemical approaches, we show that none of the classical markers of astrocytic and microglial reactivity can be observed during the onset and the persistent phase of bone cancer pain whereas the markerswere easily identified in a neuropathic pain model (spinal nerve ligation). Furthermore, using molecular (qRT-PCR) as well as biochemical (Bio-Plex) approaches, we show that among the 20 structural and functional markers of glial reactivity tested, only aquaporin-4 displays increased mRNA levels in bone cancer pain model. Hence, our results suggest that astrocytes and microglial cells play different roles in bone cancer and neuropathic pain. Finally, we tried to evidence the involvement of astrocytes in bone cancer pain by characterizing glutamatergic and glycinergic synaptic transmission, both of which are heavily modulated by astrocytic environment. By quantifying mRNA levels (qRT-PCR) and measuring the level of inhibitory and excitatory amino acids (capillary electrophoresis), we show that the main actors (transporters, receptors, agonists and co-agonists) of glutamatergic and glycinergic transmissions in the spinal cord do not undergo any significant alteration in bone cancer pain conditions. We conclude that chronic painful symptoms may develop and persist (1) without any sign of astrogliosis or enhanced microglial reactivity in the spinal cord, and (2) without any alteration in the expression/levels of the main actors involved in glutamatergic and glycinergic transmission. These results therefore question the strong link that is frequently made between astrogliosis and chronic pain.

Cancer osseux

Douleur

Astrocyte

Microglie

Bone cancer

Pain

Astrocyte

Microglia

Glutamatergic / glycinergic transmission

Plasticité morphofonctionnelle du système de l’immunité innée cérébrale : modulation par l’inflammation et la nutrition / Morphofunctional plasticity of brain innate immune system : modulation by inflammation and nutrition

Madore, Charlotte

18 December 2013

Le système de l’immunité innée cérébrale (SIIC) est principalement composé des cellules microgliales. En réponse à des stimuli immuns, inflammatoires ou un trauma neurologique, la microglie s’active et produit des facteurs pro et anti-inflammatoires qui d’une part coordonnent la réponse de l’immunité innée cérébrale et d’autre part modulent l’activité neuronale et, in fine, le comportement. Plus récemment, les cellules microgliales se sont révélées jouer un rôle clé dans le développement cérébral. Ainsi, par leurs activités de phagocytose, elles participent à la maturation des réseaux neuronaux. Si l’activation du SIIC permet de défendre le tissu cérébral des agressions, l’activation prolongée des cellules microgliales a aussi des effets délétères. Ainsi, dans le cerveau adulte, la production soutenue de cytokines inflammatoires contribue au développement de pathologies neurodégénératives. Au cours du développement les stimuli inflammatoires, en perturbant l’activité des cellules microgliales conduisent à une dysfonction de circuits neuronaux qui pourrait être impliquée dans des pathologies neuropsychiatriques à composante neurodéveloppementale. La compréhension de la régulation des cellules microgliales et de leur réponse est donc capitale. L’activité microgliale repose sur ses propriétés morphologique, dynamique et sa communication avec les neurones qui impliquent des profils de synthèse de facteurs (cytokines, chemokines, facteurs de croissance, etc..) et de récepteurs particuliers, la polarisation vers un phénotype pro ou anti-inflammatoire et la phagocytose. Peu d’études ont caractérisé l’ensemble des propriétés morphofonctionnelles des cellules microgliales in vivo. Par la combinaison d’approches de FACS, immunohistochimie, microscopie confocale et reconstruction en 3D, microscopie bi-photonique et dosage des facteurs de communication, il est aujourd’hui possible de mieux caractériser ces cellules afin de comprendre leur régulation par l’environnement et l’impact (bénéfique ou délétère) sur les fonctions neuronales. L’objectif général de cette thèse a été d’étudier les propriétés morphofonctionnelles des cellules microgliales in vivo dans deux situations physiopathologiques, une inflammation induite par l’administration périphérique de lipopolysaccharide (LPS) et une déficience alimentaire en acides gras polyinsaturés (AGPI) de type n-3, connus pour leurs propriétés immunomodulatrices. La première étude nous a permis de développer des outils nécessaires à l’étude de la plasticité morphofonctionnelle de la microglie et d’apporter de nouveaux éléments de compréhension de l’impact d’une inflammation périphérique sur l’activité de ces cellules in vivo. Dans la deuxième partie de cette thèse, nous avons montré pour la première fois que le statut alimentaire maternel en AGPI n-3 influence les propriétés morphofonctionnelles des cellules microgliales au cours du développement post-natal ainsi que l’activité des réseaux neuronaux. De façon générale, nos résultats apportent des éléments de compréhension des relations entre plasticité morphologique et fonctionnelle des cellules microgliales in vivo. / The brain innate immune system is mainly composed of microglial cells. Microglia are activated in response to an immune or inflammatory stimuli or a trauma, and then produce pro- and anti-inflammatory factors. These factors drive the innate immune response and can modulate neuronal activity and in fine, learning and memory. Recently, microglia have been shown to play a key role during brain development. Via their phagocytic activity, microglial cells can participate to neuronal networks maturation. Although brain innate immune system defends brain tissue from aggression, chronic activation of microglia can also be deleterious. In the adult brain, chronic production of inflammatory cytokines can contribute to the pathogenesis of neurodegenerative diseases. During development, inflammatory stimuli modifying microglia activity and homeostasis could lead to neuropsychiatric diseases with a neurodevelopmental origin. Understanding how microglia are regulated and how they respond to various stimuli is therefore crucial.Microglia activity is characterized by morphological and dynamic properties of microglia,by its communication with neurons by its polarization into a specific phenotype, and by their phagocytic profile. Few studies have characterized all the morphofunctional properties of microglial cells in vivo. Using a combination of approaches including FACS, immunohistochemistry, confocal microscopy, 3D reconstruction, two-photon microscopy and communication factors assays, it is now possible to better characterize these cells in order to understand their regulation by the environment and the resulting impact (beneficial or deleterious) on neuronal functions. The main goal of this thesis was to study the morphofunctional properties of microglial cells in vivo in two pathophysiological states: a peripheral inflammation induced by a peripheral injection of lipopolysaccharide (LPS) and in an n-3 PUFAs nutritional state. In the first study, we developed tools to investigate microglial morphofunctional plasticity and gained a better understanding of the impact of peripheral inflammation on the activity of these cells in vivo. In the second part of this thesis, we showed for the first time that maternal nutritional status in n-3 PUFAs affect the morphofunctional properties of microglial cells and the establishment of neural circuits during the postnatal development of the pups. Overall, our results provide new insights in the relationship between morphological and functional plasticity of microglial cells in vivo.

Microglie

Inflammation

Nutrition

Modulation

Phénotype

Phagocytose

Microglia

Inflammation

Nutrition

Modulation

Phenotype

Phagocytosis