Mécanismes moléculaires régulant la pathologie dendritique dans la rétine adulte lésée in vivo

Les dendrites sont essentielles pour la réception et l’intégration des stimuli afférents dans les neurones. De plus en plus d’évidences d’une détérioration dendritique sont associées à une axonopathie dans les maladies neurodégénératives. Le glaucome dont la physiopathologie est caractérisée par une détérioration progressive et irréversible des cellules ganglionnaires de la rétine (CGRs) est la première cause de cécité irréversible dans le monde. Son évolution est associée à un amincissement graduel des axones et à l’atrophie des somas des CGRs. La majorité des études de neuroprotection des neuropathies rétiniennes visent la survie et la protection des somas et des axones. Des études récentes ont démontré des changements dendritiques associés à cette pathologie, toutefois les mécanismes moléculaires les régulant sont méconnus. L’hypothèse principale de ma thèse stipule qu’une lésion axonale entraîne des altérations précoces des structures dendritiques. L’identification de voies de signalisation régulant ces changements permettrait d’élaborer des stratégies de neuroprotection et de rétablir la fonction de ces neurones. Dans la première étude, nous avons examiné l’effet précoce d’une lésion axonale aigüe sur la morphologie dendritique des CGRs in vivo. En utilisant des souris transgéniques exprimant la protéine fluorescente jaune (YFP) soumises à une axotomie, nous avons démontré un rétrécissement de l’arbre dendritique des CGRs et une diminution sélective de l’activité de mTOR avant le début de la mort des CGRs lésées. Aussi nous avons démontré une augmentation de l’expression de la protéine Regulated in development and DNA damage response 2 (REDD2), un régulateur négatif en amont de la protéine mTOR en réponse à la lésion du nerf optique in vivo. Nous avons démontré que la réactivation de mTOR par l’inhibition de l’expression de REDD2 préserve les arbres dendritiques des CGRs adultes. En effet, l’injection de petits ARN d’interférence contre la REDD2 (siREDD2) stimule l’activité de mTOR dans les CGRs lésées et augmente significativement la longueur et la surface dendritique totale. De plus, la rapamycine, un inhibiteur de mTOR, inhibe complètement l’effet du siREDD2 sur la croissance et l’élaboration des dendrites. L’analyse électrophysiologique des CGRs démontre une augmentation de l’excitabilité des CGRs lésées qui est restaurée en présence du siREDD2. Par ailleurs, des données récentes ont mis en évidence l’implication de la neuro-inflammation dans le glaucome, caractérisée par une augmentation de cytokines pro-inflammatoires dont principalement le facteur de nécrose tumorale (TNFα). Ainsi dans la deuxième étude nous avons examiné l’effet du TNF exogène sur la morphologie de l’arbre dendritique des CGRs et commencé l’étude des mécanismes moléculaires sous-jacents à ces changements. Nos résultats démontrent que l’injection de TNF recombinante dans le vitrée induit une rétraction dendritique précoce qui corrèle à une réduction de phospho-S6 suggérant l’implication de mTOR dans ces CGRs lésées. Ainsi, les études présentées dans cette thèse mettent en évidence un nouveau rôle de mTOR dans la stabilité et le maintien des dendrites de neurones rétiniennes adultes. Ces études ont aussi démontré l’effet précoce de stress direct ou indirect, c’est-à-dire l’axotomie et le TNFα respectivement sur la pathologie dendritique et sur leur effet sur la fonction neuronale.Dendrites are major determinants of how retinal neurons integrate and process incoming information. In neurodegenerative disorders, such as glaucoma, dendritic alterations are usually accompanied by axonopathy. However, the mechanisms that regulate these pathological changes are poorly understood. The physiopathology of glaucoma, characterized by a progressive and irreversible degeneration of retinal ganglion cells (RGCs), is the leading cause of irreversible blindness worldwide. This desease is associated with a gradual thining of RGC axons and loss of RGC soma. Most studies on neuroprotection have focused on morphological and quantitative analysis of RGC bodies and axons. Yet, dendrites are critical for neurotransmission between retinal neurons and, as such, play a vital role in the functional properties of the retinal circuit. The main hypotheses of this thesis is that: i) axonal injury induces early dendrite pathology, and ii) the identification of signaling pathways underlying dendritic changes is critical to design neuroprotective strategies and restore neuronal function. In the first study, we investigated the molecular mechanisms involved in the early dendritic changes that occur in RGCs induced by an acute axonal injury (axotomy) in vivo. Using adult transgenic mice carrying the yellow fluorescent protein (YFP) gene subjected to optic nerve axotomy, we demonstrate a marked retraction of RGC dendritic arbors and selective downregulation of the mammalian target of rapamycin (mTOR) activity prior to overt cell death. Axotomy triggered rapid up-regulation of the stress-induced protein Regulated in development and DNA damage response 2 (REDD2), a potent inhibitor of mTOR. Treatment with siRNA against REDD2 stimulated mTOR activity in axotomized RGCs and promoted a significant increase in the length and complexity of injured RGCs compared to retinas treated with control siRNA. Administration of rapamycin completely blocked the effect of siREDD2 on dendritic growth and branching thus confirming that this response occurred via mTOR stimulation. Whole-cell recordings demonstrated that REDD2 depletion leading to mTOR activation in RGCs restored their light response properties. Lastly, we show that REDD2-dependent mTOR activity extended RGC survival following axonal damage. Collectively, these results demonstrate that injury-induced stress leads to REDD2 upregulation, mTOR inhibition and dendrite pathology causing neuronal dysfunction and subsequent cell death. Recent data demonstrate a neuroinflammatory component in glaucoma characterized by upregulation of pro-inflammatory cytokines, most notably tumor necrosis factor α (TNFα) (Tezel, 2013, Soto and Howell, 2014). Therefore, in the second study of my thesis, we investigated the effect of exogenous TNFα on RGC dendritic structure in vivo and initiated the analysis of molecular signals involved in this response. Our results show that injection of recombinant TNFα into the vitreous chamber of YFP mice induced early retraction of the dendritic arbors of RGCs concomitant with a reduction of mTOR activity in these neurons. Taken together, the results shown in this thesis reveal a novel role for mTOR in the stability and maintenance of dendrites in adult retinal neurons. These studies also demonstrate the effect of early direct and indirect stressors, axotomy or TNFα respectively, on the pathology of dendrites and their effect on neuronal function

Rôle des astrocytes dans la décharge rythmique neuronale du noyau sensoriel principal du trijumeau

La communication entre les neurones est fondée sur leur capacité à changer leur patron de décharge pour l’encodage de différents messages. Pour plusieurs fonctions vitales, comme la respiration et la mastication, les neurones doivent pouvoir générer des patrons d’activité répétitifs, et les groupes de neurones responsables de ces décharges rythmiques sont des générateurs de patron central (GPC). En dépit de recherches soutenues, les mécanismes précis qui sous-tendent la rythmogénèse dans les GPCs ne sont pas bien définis. Le plus souvent, la potentielle contribution des astrocytes demeure grandement inexplorée, même si ces cellules sont aujourd’hui connues pour leur implication dans la modulation synaptique neuronale. Pour nos travaux, le noyau sensoriel principal du trijumeau (NVsnpr) a été pris comme modèle à cause de son rôle central dans les mouvements rythmiques de la mastication. Dans ce noyau, des travaux antérieurs ont montré que la décharge en bouffées rythmiques est déclenchée dans les neurones lorsque la concentration de calcium extracellulaire ([Ca2+]e) est artificiellement baissée. Nous fondant sur cette observation, notre première hypothèse a postulé que la baisse de la [Ca2+]e pouvait survenir de façon physiologique en lien avec des stimulations sensorielles pertinentes. Deuxièmement, parce que les astrocytes ont été impliqués dans le tamponnage et l’homéostasie d’ions extracellulaires comme le K+, nous avons postulé que ces cellules pouvaient jouer un rôle équivalent dans le contrôle de la [Ca2+]e. Nos résultats montrent que les astrocytes peuvent réguler la [Ca2+]e et ainsi contrôler la capacité des neurones à changer leur patron de décharge. Premièrement, en stimulant les afférences sensorielles au NVsnpr, nous avons montré que des baisses physiologiques de la [Ca2+]e sont observées en parallèle à l’apparition de bouffées rythmiques neuronales. Deuxièmement, nous avons démontré que les astrocytes répondent aux mêmes stimuli qui induisent l’activité rythmique neuronale, et que leur blocage avec un chélateur de Ca2+ empêche les neurones de générer un patron de décharge en bouffées rythmiques. Cette habilité est rétablie en rajoutant la S100β, une protéine astrocytaire liant le Ca2+, dans le milieu extracellulaire, alors que l’anticorps anti-S100β empêche l’activité rythmique. Ces résultats indiquent que les astrocytes régulent une propriété neuronale fondamentale : la capacité à changer de patron de décharge. Ainsi, les GPCs dépendraient des fonctions intégrées des astrocytes et des neurones. Ces découvertes pourraient avoir des implications transposables à plusieurs autres circuits neuronaux dont la fonction dépend de l’induction d’activité rythmique.Communication between neurons rests on their capacity to change their firing pattern to encode different messages. For several vital functions, such as respiration and mastication, neurons need to generate a repetitive firing pattern, and the groups of neurons responsible for these rhythmic discharges are called central pattern generator (CPG). Despite intense research in this field, the exact mechanisms underlying rhythmogenesis in CPGs are not completely defined. In most instances, the potential contribution of astrocytes is largely unexplored, even though these cells are now well known to be involved in neuronal synaptic modulation. In our work, the trigeminal main sensory nucleus (NVsnpr) was used as a model owing to its central role in the rhythmic movement of mastication. Previous work have shown that rhythmic bursting discharge is triggered in NVsnpr neurons when extracellular calcium concentration ([Ca2+]e) is artificially decreased. Based on this observation, our first hypothesis postulated that the reduction of [Ca2+]e could also happen physiologically in relation to relevant sensory stimulation. Secondly, because astrocytes have been involved in the buffering and the homeostasis of extracellular ions like potassium, we have postulated that these cells could also play a role in the control of [Ca2+]e. The results presented in this thesis show that astrocytes can regulate [Ca2+]e and thus control the ability of neurons to change their firing pattern. First, we showed that stimulation of sensory afferent fibers to the NVsnpr induced neuronal rhythmic bursting and in parallel reduction of [Ca2+]e . Secondly, we have demonstrated that astrocytes respond to the same sensory stimuli that induce neuronal rhythmic activity, and their blockade with a Ca2+ chelator prevents generation of neuronal rhythmic bursting. This ability is restored by adding S100β, an astrocytic Ca2+-binding protein, to the extracellular space, while the application of an anti- S100β antibody prevents generation of rhythmic activity. These results indicate that astrocytes regulate a fundamental neuronal property: that is the capacity to change their firing pattern. Thus, CPG functions result from integrated neuronal and glial activities. These findings may have broad implications for many other neural networks whose functions depend on the generation of rhythmic activity

Ion homeostasis in rhythmogenesis : the interplay between neurons and astroglia

Proper function of all excitable cells depends on ion homeostasis. Nowhere is this more critical than in the brain where the extracellular concentration of some ions determines neurons' firing pattern and ability to encode information. Several neuronal functions depend on the ability of neurons to change their firing pattern to a rhythmic bursting pattern, whereas, in some circuits, rhythmic firing is, on the contrary, associated to pathologies like epilepsy or Parkinson's disease. In this review, we focus on the four main ions known to fluctuate during rhythmic firing: calcium, potassium, sodium, and chloride. We discuss the synergistic interactions between these elements to promote an oscillatory activity. We also review evidence supporting an important role for astrocytes in the homeostasis of each of these ions and describe mechanisms by which astrocytes may regulate neuronal firing by altering their extracellular concentrations. A particular emphasis is put on the mechanisms underlying rhythmogenesis in the circuit forming the central pattern generator (CPG) for mastication and other CPG systems. Finally, we discuss how an impairment in the ability of glial cells to maintain such homeostasis may result in pathologies like epilepsy and Parkinson's disease

Production et effet catabolique du 4-hydroxynonénal dans les tissus articulaires arthrosiques : un nouveau facteur impliqué dans la dégradation du cartilage

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal

Brain-derived neurotrophic factor prevents dendritic retraction of adult mouse retinal ganglion cells

We used cultured adult mouse retinae as a model system to follow and quantify the retraction of dendrites using diolistic labelling of retinal ganglion cells (RGCs) following explantation. Cell death was monitored in parallel by nuclear staining as ‘labelling’ with RGC and apoptotic markers was inconsistent and exceedingly difficult to quantify reliably. Nuclear staining allowed us to delineate a lengthy time window during which dendrite retraction can be monitored in the absence of RGC death. The addition of brain-derived neurotrophic factor (BDNF) produced a marked reduction in dendritic degeneration, even when application was delayed for 3 days after retinal explantation. These results suggest that the delayed addition of trophic factors may be functionally beneficial before the loss of cell bodies in the course of conditions such as glaucoma

Functional Roles of Astrocyte Calcium Elevations: From Synapses to Behavior

Astrocytes are fundamental players in the regulation of synaptic transmission and plasticity. They display unique morphological and phenotypical features that allow to monitor and to dynamically respond to changes. One of the hallmarks of the astrocytic response is the generation of calcium elevations, which further affect downstream cellular processes. Technical advances in the field have allowed to spatially and to temporally quantify and qualify these elevations. However, the impact on brain function remains poorly understood. In this review, we discuss evidences of the functional impact of heterogeneous astrocytic calcium events in several brain regions, and their consequences in synapses, circuits, and behavior.Foundation for Science and Technology (FCT) fellowships (SFRH/BPD/97281/2013 to JO, SFRH/BD/101298/2014 to SG-G, IF/00328/2015 to JO, IF/01079/2014 to LP); Marie Curie Fellowship FP7-PEOPLE- 2010-IEF 273936 and BIAL Foundation Grant 207/14 to JO and 427/14 to LP; Northern Portugal Regional Operational Programme (NORTE 2020), under the Portugal 2020 Partnership Agreement, through the European Regional Development Fund (FEDER; NORTE-01-0145-FEDER-000013); FEDER funds, through the Competitiveness Factors Operational Programme (COMPETE), and National Funds, through the FCT (POCI-01- 0145-FEDER-007038)info:eu-repo/semantics/publishedVersio

An astrocyte-dependent mechanism for neuronal rhythmogenesis

Communication between neurons rests on their capacity to change their firing pattern to encode different messages. For several vital functions, such as respiration and mastication, neurons need to generate a rhythmic firing pattern. Here we show in the rat trigeminal sensori-motor circuit for mastication that this ability depends on regulation of the extracellular Ca2+ concentration ([Ca2+]e) by astrocytes. In this circuit, astrocytes respond to sensory stimuli that induce neuronal rhythmic activity, and their blockade with a Ca2+ chelator prevents neurons from generating a rhythmic bursting pattern. This ability is restored by adding S100b, an astrocytic Ca2+-binding protein, to the extracellular space, while application of an anti-S100b antibody prevents generation of rhythmic activity. These results indicate that astrocytes regulate a fundamental neuronal property: the capacity to change firing pattern. These findings may have broad implications for many other neural networks whose functions depend on the generation of rhythmic activity

Perturbation of adhesion molecule-mediated chondrocyte-matrix interactions by 4-hydroxynonenal binding: implication in osteoarthritis pathogenesis

ABSTRACT: INTRODUCTION: Objectives were to investigate whether interactions between human osteoarthritic chondrocytes and 4-hydroxynonenal (HNE)-modified type II collagen (Col II) affect cell phenotype and functions and to determine the protective role of carnosine (CAR) treatment in preventing these effects. METHODS: Human Col II was treated with HNE at different molar ratios (MR) (1:20 to 1:200; Col II:HNE). Articular chondrocytes were seeded in HNE/Col II adduct-coated plates and incubated for 48 hours. Cell morphology was studied by phase-contrast and confocal microscopy. Adhesion molecules such as intercellular adhesion molecule-1 (ICAM-1) and alpha1beta1 integrin at protein and mRNA levels were quantified by Western blotting, flow cytometry and real-time reverse transcription-polymerase chain reaction. Cell death, caspases activity, prostaglandin E2 (PGE2), metalloproteinase-13 (MMP-13), mitogen-activated protein kinases (MAPKs) and nuclear factor-kappa B (NF-kappaB) were assessed by commercial kits. Col II, cyclooxygenase-2 (COX-2), MAPK, NF-kappaB-p65 levels were analyzed by Western blotting. The formation of alpha1beta1 integrin-focal adhesion kinase (FAK) complex was revealed by immunoprecipitation. RESULTS: Col II modification by HNE at MR approximately 1:20, strongly induced ICAM-1, alpha1beta1 integrin and MMP-13 expression as well as extracellular signal-regulated kinases 1 and 2 (ERK1/2) and NF-kappaB-p65 phosphorylation without impacting cell adhesion and viability or Col II expression. However, Col II modification with HNE at MR approximately 1:200, altered chondrocyte adhesion by evoking cell death and caspase-3 activity. It inhibited alpha1beta1 integrin and Col II expression as well as ERK1/2 and NF-kappaB-p65 phosphorylation, but, in contrast, markedly elicited PGE2 release, COX-2 expression and p38 MAPK phosphorylation. Immunoprecipitation assay revealed the involvement of FAK in cell-matrix interactions through the formation of alpha1beta1 integrin-FAK complex. Moreover, the modification of Col II by HNE at a 1:20 or approximately 1:200 MR affects parameters of the cell shape. All these effects were prevented by CAR, an HNE-trapping drug. CONCLUSIONS: Our novel findings indicate that HNE-binding to Col II results in multiple abnormalities of chondrocyte phenotype and function, suggesting its contribution in osteoarthritis development. CAR was shown to be an efficient HNE-snaring agent capable of counteracting these outcomes

A Neuron-Glial Perspective for Computational Neuroscience

International audienceThere is growing excitement around glial cells, as compelling evidence point to new, previously unimaginable roles for these cells in information processing of the brain, with the potential to affect behavior and higher cognitive functions. Among their many possible functions, glial cells could be involved in practically every aspect of the brain physiology in health and disease. As a result, many investigators in the field welcome the notion of a Neuron-Glial paradigm of brain function, as opposed to Ramon y Cayal's more classical neuronal doctrine which identifies neurons as the prominent, if not the only, cells capable of a signaling role in the brain. The demonstration of a brain-wide Neuron-Glial paradigm however remains elusive and so does the notion of what neuron-glial interactions could be functionally relevant for the brain computational tasks. In this perspective, we present a selection of arguments inspired by available experimental and modeling studies with the aim to provide a biophysical and conceptual platform to computational neuroscience no longer as a mere prerogative of neuronal signaling but rather as the outcome of a complex interaction between neurons and glial cells