Global ETD Search

1	Étude préclinique d’Immunothérapie des métastases osseuses expérimentales par la fractalkine / Preclinical study of immunotherapy of experimental bone metastases by the fractalkine chemokine Goguet-Surmenian, Émilie 15 December 2014 (has links) Les métastases osseuses représentent un enjeu majeur de santé publique en raison de leur impact négatif sur la qualité de vie des patients mais également en raison de l’absence de traitements curatif. De nouvelles pistes thérapeutiques sont explorées dont l’immunothérapie anti-cancéreuse. En tant que principales responsables du recrutement leucocytaire, les chimiokines représentent des outils potentiels dans cette approche thérapeutique. La chimiokine fractalkine (CX3CL1) est impliquée dans de nombreux mécanismes physiologiques et pathologiques, dont le métabolisme osseux, la réponse immunitaire anti-tumorale mais également l’adressage et le développement tumoral, et ce de manière différentielle selon la forme considérée de cette chimiokine. En effet, CX3CL1 a la particularité d’exister sous deux formes : membranaire atypique (propriétés d’adhésion cellulaire) et soluble, typique des chimiokines (propriétés de chimioattraction). La mise en place d’un modèle syngénique murin de métastases osseuses expérimentales de carcinome pulmonaire nous a permis d’étudier l’effet de la forme soluble de CX3CL1 sur le développement métastatique en site osseux. L’expression ectopique de CX3CL1 soluble dans les cellules tumorales pulmonaires a conduit à une diminution de leur potentiel tumorigénique, une diminution de la résorption osseuse associée à une modification du ratio OPG/RANKL en faveur d’un phénotype ostéoblastique et à une modification du recrutement leucocytaire intratumoral en faveur d’une réponse immunitaire anti-tumorale. Outre l’importance de CX3CL1 dans le remodelage osseux, ce travail souligne le rôle essentiel du microenvironnement immunitaire dans la progression tumorale. Dans ce contexte, la forme soluble de CX3CL1 pourrait représenter un outil prometteur dans l’arsenal thérapeutique des métastases osseuses / Bone metastases represent a major public health issue due to their negative impact on patient’s quality of life as well as the current lack of curative treatment. New therapeutic leads are being investigated, among which is the anti-cancer immunotherapy. As the main molecules responsible for leukocyte recruitment, chemokines appear as potential tools for this therapeutic approach. The chemokine fractalkine (CX3CL1) is implicated in numerous physiological and pathological mechanisms, including bone metabolism, antitumor immune response as well as tumor homing and proliferation, in a differential manner depending on the considered form of CX3CL1. Indeed, the particularity of CX3CL1 is that it can exist under two forms: an atypical membrane-bound form (strong cellular adhesion) and a chemokine typical soluble form (chemoattraction). The development of a mouse syngeneic model of lung cancer experimental bone metastases allowed us to study the effect of the soluble CX3CL1 on metastatic development in a skeletal location. The ectopic expression of soluble CX3CL1 in the lung cancer cells led to a decrease of their tumorigenic potential, a decrease of bone resorption associated with a shift of the OPG/RANKL ratio toward an osteoblastic phenotype and a modification of leukocyte tumor infiltration in favor of an antitumor immune response. In addition to the importance of CX3CL1 in bone remodeling, this study underlines the essential role of the immune microenvironment in bone tumor progression. In this context, the soluble CX3CL1 could represent a promising tool in the therapeutic arsenal of bone metastases. Cancer Immunothérapie Fractalkine Métastases osseuses Cancer Immunotherapy Fractalkine Bone metastases
2	Regulation of Microglia in the Brain by Fractalkine Signaling: Implications for Inflammation-Associated Sickness and Depression Corona, Angela Wynne 25 October 2011 (has links) No description available. Immunology Neurosciences aging neuroinflammation fractalkine fractalkine receptor microglia psychoneuroimmunology
3	Implication de l'axe CX3CL1/CX3CR1 dans la physiopathologie de la réaction aiguë du greffon contre l'hôte en allogreffe de cellules souches hématopoïétiques / Involvement of the CX3CL1 (fractalkine)/CX3CR1 pathway in the pathogenesis of acute graft-versus host disease Davaine, Eolia 27 October 2014 (has links) La physiopathologie de la GVHa implique de nombreux mécanismes aboutissant à ces lésions tissulaires responsables d'une comorbidité majeure en allo-CSH. L'objectif principal de notre étude a été d'identifier des marqueurs précoces de GVHa et d'explorer leurs rôles dans la physiopathologie de ce phénomène. Quarante-deux cytokines ou chémokines, ont été étudiés à J0 dans le sérum de 109 patients allogreffés avec un conditionnement d'intensité réduite. Nous avons complété ce travail par une étude cinétique à différents temps de l'allo-CSH et une étude histologique de biopsies coliques de patients atteints de GVHa. A J0 de l'allo-CSH, seule la mesure de CX3CL1 J0 était significativement plus élevée chez les patients développant par la suite une GVHa en comparaison aux patients indemnes de GVHa (P=0 ,04). Cette observation persistait à J30 et J50 post allo-CSH mais pas à J100 (P=0,02, P=0,03 et P=0,12, respectivement). L'étude des dosages sériques avant le conditionnement (J-30) ne retrouvait pas de différence significative entre ces 2 groupes. L'analyse phénotypique des différents types cellulaires a mis en évidence une augmentation signification de la proportion de lymphocytes CD8+CX3CR1+ chez les patients présentant une GVHa (P=0,01). L'analyse histologique de biopsies coliques (n=12) montrait une nette augmentation de l'expression de CX3CL1 au niveau des cellules épithéliales de la muqueuse intestinale en cas de GVHa ainsi que la présence de cellules mononuclées CX3CR1+ aux contacts de ces cellules épithéliales. Les résultats de cette étude suggèrent fortement l'implication de CX3CL1 et de son récepteur CX3CR1 dans la physiopathologie de la GVHa. / This study investigated the role of cytokines and chemokines in acute graft-versus host disease (aGVHD) incidence and severity in 109 patients who underwent reduced-intensity conditioning allogeneic stem cell transplantation (HSCT). Among the 42 cytokines tested at day 0, only CX3CL1 levels at day 0 was significantly associated with grades II to IV aGVHD development (P=0.04). Increased levels of CX3CL1 at day 30 and day 50 post-HSCT were also significantly associated with aGVHD (P=0.02 and P=0.03, respectively). No such association was found before conditioning regimen or at day 100 post-HSCT. Because the receptor for CX3CL1 is CX3CR1, the number of CX3CR1+ cells was determined by flow cytometry. The CX3CR1+CD8+T cell proportion was significantly higher in patients with aGVHD than those without aGVHD (P=0.01). To investigate the distribution of the CX3CL1/CX3CR1 axis in the anatomic sites of aGVHD, CX3CL1 and CX3CR1 levels were studied using an in situ immunohistochemical analysis on gastro-intestinal biospsies of patients with intestinal aGVHD. CX3CL1 expression was significantly increased in the epithelial cells and mononuclear cells of the lamina propria. CX3CR1+ cells mononuclear cells were identified in close contact with epithelial cells. These findings strongly suggest the implication of the CX3CL1/CX3CR1 axis in the pathogenesis of aGVHD. CX3CL1 Fractalkine CX3CR1 Alloréactivité Fractalkine Fractalkine receptor 612
4	Proteolysis of CX3CL1 Impacts CX3CR1 Signaling and Therapeutic Benefits in a Tauopathy Model Finneran, Dylan John 15 November 2018 (has links) Alzheimer’s disease (AD) is a progressive, neurodegenerative disorder and the most common form of dementia. The hallmark pathologies of AD are extracellular aggregates of amyloid-beta, intracellular aggregates of microtubule associated protein tau and increased neuroinflammation. Current therapeutics offer only symptomatic relief and clinical trials investigating therapeutic benefits of non-steroidal anti-inflammatory drugs have yielded no positive results. Therefore, recent work has focused on immunomodulators, such as CD200 and fractalkine, as potential therapeutic targets for AD. Fractalkine (CX3CL1; FKN) is expressed as a transmembrane protein with an N-terminal chemokine domain followed by a long, mucin-like stalk. FKN can signal as a membrane-bound protein or, upon cleavage, as a soluble ligand (sFKN). Upon binding its receptor, FKN reduces expression of pro-inflammatory genes in activated microglia. Disrupting FKN signaling has been shown to exacerbate neurodegeneration in a number or neurodegenerative diseases. Relevant to this study, there have been conflicting reports on how FKN signaling affects AD pathology and whether a soluble FKN is beneficial or not. Here, we examine the ability of soluble FKN over expression to impact tauopathy and the resulting cognitive deficits in the rTg4510 mouse model of tauopathy, focusing on cognitive improvement after the onset of tau deposition. Furthermore, we explore the functional activity of proteolytic fragments of FKN on activated microglia in vitro to rectify the contradictory findings in the literature. We observed that sFKN over expression can significantly reduce both soluble and insoluble phospho-tau in both a preventative and an early interventional study design. However, in animals with significant pathology and neurodegeneration we did not observe an impact of sFKN over expression on tau pathology. Interestingly, in these late stage animals we did observe an improvement in spatial learning and memory as well as a reduction in hyperactivity. This suggests that earlier intervention would likely be most beneficial in reducing tau pathology but in late stage AD FKN signaling can still have benefits on cognition, likely due to reductions in the inflammatory milieu. Current publications suggest that different proteolytic fragments of FKN may have different functional signaling. Here we demonstrate that the this may be due to differences in receptor binding. sFKN (which includes the mucin-like stalk) exhibited a lower EC50 than the ckFKN (soluble chemokine domain), which leads to reduced functional efficacy of ckFKN at low concentrations. More interestingly, we also observed that high concentrations of FKN, regardless of cleavage variant, is ineffective at reducing pro-inflammatory activation of microglial and may in fact elicit a proinflammatory response. We hypothesize that FKN may signal through an alternative receptor at high concentrations, suggesting an as yet unidentified signaling pathway for FKN. Furthermore, we show that the ckFKN does not rescue pathology in the rTg4510 mouse, as sFKN does. These data may clarify conflicts in the literature and demonstrate that care must be taken with respect to in vitro and in vivo studies using FKN. Alzheimer's disease Fractalkine Microglia Neurodegeneration Neuroinflammation Neurosciences
5	Chemotactic signals released during Burkitt's lymphoma cell death Pasikowska, Marta January 2011 (has links) Tumour-associated macrophages (TAMs) have been shown to play an important role in tumour survival and progression. Thus, high numbers of macrophages in the tumour tissue are often associated with a poor prognosis. Identification of factors responsible for recruiting macrophages to the sites of different types of tumours might help to develop more effective cancer treatment. Burkitt's lymphoma (BL) is characterised by uncontrolled cell proliferation, high rate of spontaneous apoptosis and significant macrophage infiltration. Although BL cells undergo extensive apoptosis, in situ their corpses are cleared very effectively by macrophages infiltrating the tumour. It is now widely believed that dying cells are themselves able to release chemotactic molecules to ensure macrophage chemotaxis and subsequent clearance of their site of death. Previous work carried out in this laboratory identified fractalkine/CX3CL1 (FKN) released from dying BL cells to be an important player in macrophage chemotaxis to BL. Yet, these results have also indicated that FKN may not be the only chemokine involved in this process. Following from those observations, the first part of this work focused on examination of the potential role of monocyte chemoattractant protein-1 (MCP-1) in macrophage recruitment to BL. Despite the initial promising results, careful analysis of the data obtained by various techniques led to the conclusion that MCP-1 is, probably, not expressed by BL cells. Subsequently, effort was concentrated on understanding mechanisms regulating FKN processing during cell death. The studies performed before in this laboratory identified a new form of FKN to be present in apoptotic BL cells and showed that this is the form that is, most likely, responsible for mediating macrophage migration. Here, this apoptosis-related 60 kDa FKN was found to be a likely caspase-3 cleavage product. Moreover, it was demonstrated that FKN and active caspase-3 are released together in apoptotic BL cell-derived microparticles, suggesting that the proteolytic events could take place also extracellularly. In the final results chapter the differences between BL cell lines in the way they process FKN during cell death were revealed and a new cell death-associated 55 kDa FKN was observed. Through several lines of evidence, this new form was identified to be a possible product of calpain-mediated proteolysis. To conclude, this work provides the first evidence for a possible direct participation of the two major cell death executioner proteases – caspases and calpains, in production of ‘find me’ signals for macrophages and thus, ensuring effective clearance of dying cells. These results indicate that FKN cleavage and release might be of key importance during cell death. Moreover, the studies presented here contribute to better understanding of the process of FKN secretion. 616.994
6	CX3CR1/CX3CL1 axis drives the migration and maturation of oligodendroglia in the central nervous system Ford, Catriona Barbara January 2017 (has links) In the central nervous system, the axons of neurons are protected from damage and aided in electrical conductivity by the myelin sheath, a complex of proteins and lipids formed by oligodendrocytes. Loss or damage to the myelin sheath may result in impairment of electrical axonal conduction and eventually to neuronal death. Such demyelination is responsible, at least in part, for the disabling neurodegeneration observed in pathologies such as Multiple Sclerosis (MS) and Spinal Cord Injury. In the regenerative process of remyelination, oligodendrocyte precursor cells (OPCs), the resident glial stem cell population of the adult CNS, migrate toward the injury site, proliferate and differentiate into adult oligodendrocytes which subsequently reform the myelin sheath. Existing research indicates that OPC migration is directed by chemomigratory signals released from the site of injury and that the absence of OPCs is a feature of some MS lesions, suggesting that increased recruitment of OPCs to injury sites might improve remyelination, eventually leading to treatments of patient pathologies. I hypothesized that as yet undiscovered migration cues for OPCs might be released at sites of demyelination, diffuse through the CNS tissue, activate distal OPCs and guide them back to sites of demyelination. In this thesis, I performed bioinformatics analysis of gene expression arrays and identified upregulated cell surface receptors on OPCs activated in a cuprizone model, and upregulated secreted factors in whole lesion sites from an LPC induced MS type injury model and a Spinal Cord Injury model. I then optimised the X-celligence system for the quantification of OPC migration in response to secreted factors identified in my bioinformatics screen. By combination of these techniques with immunofluorescent staining I discovered novel expression of the cell surface receptor CX3CR1 on OPCs, increased expression of the corresponding ligand CX3CL1 in both MS type injury and Spinal Cord Injury, increased directional migration of OPCs in response to low concentrations of CX3CL1, and increased maturation of OPCs into adult oligodendrocytes at high concentrations of CX3CL1. Taken together these results propose a system in which an increasing gradient of CX3CL1 released from the site of injury directs the recruitment, then maturation of OPCs, making CX3CL1 a master regulator of OPC led CNS regeneration.
7	Investigating Microglia-Vascular Interactions in the Developing and Adult Central Nervous System Mondo, Erica 26 August 2020 (has links) Microglia, the resident macrophages of the central nervous system (CNS), are dynamic cells, constantly extending and retracting their processes as they contact and functionally regulate neurons and other glial cells. There is far less known about how microglia interact with the CNS vasculature, particularly under healthy steady-state conditions. Here, I provide the first extensive characterization of juxtavascular microglia in the healthy, postnatal brain and identify a molecular mechanism regulating the timing of these interactions during development. Using the mouse cerebral cortex, I show that microglia are intimately associated with the vasculature in the CNS, directly contacting the basal lamina in vascular sites that are devoid of astrocyte endfeet. I demonstrate a high percentage of microglia are associated with the vasculature during the first week of postnatal development, which is concomitant with a peak in microglial colonization of the cortex and recruitment to synapses. I find that as microglia colonize the cortex, juxtavascular microglia are highly motile along vessels and become largely stationary as the brain matures. 2-photon live imaging in adult mice reveals that these vascular-associated microglia in the mature brain are stable and stationary for several weeks. Further, a decrease in microglia motility along the vasculature is tightly correlated with the expansion of astrocyte endfeet along the vasculature. Finally, I provide evidence that the timing of these microglia-vascular interactions during development is regulated by the microglial fractalkine receptor (CX3CR1). Together, these data support a model by which microglia use the vasculature as a scaffold to migrate and colonize the developing brain and the timing of these associations is modulated by CX3CR1. This migration along the vasculature becomes restricted as astrocyte vascular endfoot territory expands and, upon maturation, vascular-associated microglia become largely stationary. Microglia Blood Vessel Development Fractalkine Receptor Other Neuroscience and Neurobiology
8	The Effects of Matrix Metalloproteinase-9 on CX3CL1 Shedding and Axon Retraction Dobrie, Lauren A 01 January 2019 (has links) Spinal cord injury (SCI) often leads to irreversible damage, and permanent paralysis inferior to the injury is common (Leibinger et al., 2013). Injury to the spinal cord occurs in two phases. In the first phase, components of the spinal cord are subject to mechanical trauma causing direct damage. In the second phase, damage spreads from the area of injury through molecular processes. Several studies have linked M1 "pro-inflammatory" macrophages to exacerbation of damage by inducing dieback of dystrophic axons, but not healthy axons, through direct cellular contact. Several studies have identified the presence of macrophage subtypes at specific time. A literature review was conducted in order to summarize these findings (Busch, Horn, Silver, & Silver, 2009; Evans et al., 2014; Horn, Busch, Hawthorne, van Rooijen, & Silver, 2008; Kigerl et al., 2009; Shechter et al., 2013). Although the full mechanism behind the process of M1 macrophage-mediated dieback of dystrophic axons is unclear, matrix metalloproteinase-9 (MMP-9) produced by these macrophages has been shown to play a role. However, the specific interaction between MMP-9 and neurons is under investigation. The research described explores the relationship between MMP-9 and fractalkine (CX3CL1), a surface protein expressed by CNS neurons. SDS-PAGE and western blot were used to determine whether the presence of MMP-9 increases the cleavage of fractalkine at several time intervals. At a concentration of 300ng/ml, MMP-9 was not found to demonstrate cleavage of fractalkine. MMP-9 fractalkine cx3cl1 neuron macrophage axon Nervous System Neurology
9	Consequences of differential macrophage activation after spinal cord trauma Longbrake, Erin E. 17 May 2007 (has links) No description available. spinal cord injury macrophage microglia CNS inflammation chemokine fractalkine CX3CR1
10	Rôles et caractérisation de la microglie dans le développement du néocortex somatosensoriel de la souris / Roles and caracterisation of microglia in the mouse developing somatosensory neocortex Arnoux, Isabelle 24 April 2014 (has links) Les cellules microgliales, qui sont les macrophages du système nerveux central, ont été principalement étudiées en conditions pathologiques. Néanmoins, l'étude de la microglie aux stades périnataux indique qu'elle influence le développement normal du système nerveux central. Des interactions directes et indirectes entre la microglie et les synapses existent mais les mécanismes par lesquels ces cellules immunitaires ciblent les synapses et modulent leur maturation fonctionnelle durant le développement postnatal sont peu connus. Au cours de mon travail de thèse, je me suis intéressée aux cellules microgliales et à leurs fonctions dans le développement postnatal du cortex somato-sensoriel de la souris. Dans une première étude, nous avons montré qu'au cours de la première semaine post-natale le recrutement des cellules microgliales aux sites synaptiques en maturation met en jeu une voie de signalisation impliquant la chimiokine neuronale fractalkine et de son récepteur microglial CX3CR1. En effet, un défaut d’expression de ce récepteur retarde le recrutement des cellules microgliales aux sites synaptiques et entraine un retard de maturation fonctionnelle des synapses thalamocorticales. Dans une seconde étude, nous avons caractérisé le phénotype des cellules microgliales lors de la maturation fonctionnelle des réseaux synaptiques corticaux. Nous avons montré que les cellules microgliales adoptent un phénotype particulier lorsqu’elles sont recrutées aux synapses en maturation. Ce phénotype diffère de celui exprimé par la microglie adulte en conditions physiologiques et pathologiques et pourrait permettre aux cellules microgliales d’accomplir des fonctions spécifiques nécessaires à la maturation synaptique. Dans une troisième étude, nous avons testé les effets de la minocycline sur le développement cortical. Cette tétracycline est connue pour bloquer l’activation microgliale chez l'adulte. De façon surprenante, nous avons observé que pendant une période critique se situant à la fin de la première semaine post-natale la minocycline induit une importante mort cellulaire qui s'accompagne d'une altération de la distribution des cellules microgliales et déclenche leur activation. L'ensemble de mes données montrent que les cellules microgliales sont très sensibles aux changements de leur environnement, que leur phénotype fonctionnel change en conditions physiologiques en fonction de cet environnement et que des interactions réciproques entre neurones et microglie influencent la maturation fonctionnelle des réseaux synaptiques corticaux lors du développement postnatal. / The microglial cells, which are the resident macrophages of the central nervous system, have been mainly studied in pathological conditions. But, the study of microglia at perinatal stages indicates that they influence the normal development of the central nervous system. Direct and indirect interactions between microglia and synapses exist but mechanisms by which these immune cells target synapses and modulate their functional maturation during post-natal development are still unknown. During my PhD thesis, I was interested in microglial cells and their functions during postnatal development of the mouse somatosensory cortex. In a first study, we showed that during the first postnatal week the recruitment of microglial cells at maturating synaptic sites requires a signaling pathway involving the neuronal chemokine fractalkine and its microglial receptor CX3CR1. Indeed, a deficit in the expression of this receptor delays the recruitment of microglial cells at synaptic sites and leads to a delayed functional maturation of thalamocortical synapses. In a second study, we characterized the phenotype of microglial cells during the functional maturation of cortical synaptic network. We showed that microglial cells adopt a particular phenotype when they are recruited at maturating synapses. This phenotype differs from that expressed by adult microglia in physiological and pathological conditions and may allow microglial cells to accomplish specific functions which are necessary to synaptic maturation. In a third study, we tested the effects of the minocycline on the cortical development. This tetracycline is known to block the microglial activation in adult. Surprisingly, we observed that during a critical period ending at the end of the first post-natal week, minocycline induces an important cellular death which is accompanied by an alteration of microglial cells distribution and which also triggers their activation. Taken together, my data show that microglial cells are highly sensitive to changes in their environment, their functional phenotype evolves in physiological conditions in function of this environment and reciprocal interactions between neurons and microglia influence the functional maturation of cortical synaptic network during the postnatal development. Microglie Synapse thalamocorticale Cortex somatosensoriel Fractalkine CX3CR1 Kv1.3 Microglia Thalamocortical synapses Somatosensory cortex Fractalkine CX3CR1 Kv1.3 573.8

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