Global ETD Search

1	CONSEQUENCE OF MMP-9 DEFICIENCY ON INTRAOCULAR PRESSURE REGULATION AND RETINAL GANGLION CELL SURVIVAL Siwakoti, Anuja January 2014 (has links) Matrix metalloproteinases (MMPs) are known to be the mediators of extracellular matrix remodeling. Increased levels of matrix metalloproteinases, particularly MMP-9, have been found in the aqueous humor of patients with glaucoma. However the exact role of MMP-9 in glaucomatous changes is not understood. Previous results from the West-Mays’ lab indicated that MMP-9 deficient (knockout - KO) mice exhibit elevated IOP, in the absence of distinct morphological changes in the anterior chamber. In the current thesis, I investigated whether the elevated IOP in MMP-9KO mice leads to RGC death. Wild type and KO littermates at different age groups: 2-3 months, 3-4 months, 6-8 and 9-12 months were studied. IOP was measured using TonoLab rebound tonometer. My results demonstrated that IOP was significantly increased in MMP-9KO mice compared to control littermates at all ages examined. To investigate if the elevated IOP was due to a difference in central corneal thickness (CCT), CCT measurements were made between WT and KO mice using ultrasound pachymeter. There was no difference in CCT demonstrating that the elevated IOP observed in MMP-9KO mice was not related to changes in corneal thickness. To determine whether the elevated IOP led to RGC death, the animals were sacrificed, eyes were enucleated and retinas (n=4) from both WT and KO animals were dissected and stained with Brn-3a antibody. Additional eyes were harvested from both WT and KO mice for histological and immunofluorescence studies. I found no observable difference in Brn3a+ RGC count between MMP9-WT and KO mice. Furthermore, no difference in retinal morphology, glial reactivity and laminin expression between WT and KO mice was observed. In the future it will be important to investigate whether elevated IOP in the MMP-9KO mice leads to optic nerve axonal loss and further investigate the possibility that the MMP-9KO retina is neuroprotected. / Thesis / Master of Science (MSc)
2	The role of signaling via the receptor tyrosine phosphatase PTPmu in retinal development and axon guidance Ensslen, Sonya Emily Lesya 05 April 2004 (has links) No description available. PTP¿¿¿¿ neurite RGC growth cone retina PKC¿¿¿¿ nasal
3	The Receptor Protein Tyrosine Phosphatase-mu Signaling Pathway Differentially Regulates E-cadherin, N-cadherin and R-cadherin-Mediated Axon Outgrowth Oblander, Samantha Anne 21 July 2009 (has links) No description available. E-CADHERIN Neurite Neurite Outgrowth PTP¿¿¿¿ OUTGROWTH R-CADHERIN-MEDIATED RGC
4	Electrophysiological Properties of a Quail Neuroretina Cell Line (QNR/D): Effects of Growth Hormone? Andres, Alexis D Unknown Date No description available. Growth Hormone Ion Channels Retina Retinal Ganglion Cell QNR/D RGC-5 Calcium Channels Potassium Channels
5	The Effects Of Early Postnatal Ethanol Intoxication On Retina Ganglion Cell Morphology And The Development Of Retino-geniculate Projections In Mice Dursun, Ilknur 01 February 2010 (has links) (PDF) Experimental and clinical data have documented the adverse effects of perinatal ethanol intoxication on peripheral organs and the central nervous system. There is little known, however, about potential damaging effects of perinatal ethanol on the developing visual system. The purpose of this study was to examine the effects of neonatal ethanol intoxication on RGC morphology, estimate the total number of neurons in RGC layer and dorsolateral geniculate nucleus (dLGN), and on the eye-specific fiber segregation in the dLGN), in YFP and C57BL/6 mice pups. Ethanol (3 g/kg/day) was administered by intragastric intubation throughout postnatal days (PD) 3-20 or 3-10. Intubation control (IC) and untreated control (C) groups were included. Blood alcohol concentration (BAC) was measured in separate groups of pups on PD3, PD10, and PD20 at 4 different time points, 1, 1.5, 2 and 3 h after the second intubation. Numbers neurons in the RGCs and dLGN were quantified on PD10, PD20 using unbiased stereological procedures. The RGC images were taken using a confocal microscope and images were traced using Neurolucida software. On PD9, intraocular injections of cholera toxin- QP Nervous System 361-430
6	Le rôle des récepteurs aux cannabinoïdes CB1 et CB2 dans le guidage axonal Argaw, Anteneh 12 1900 (has links) Au cours du développement, les axones des cellules ganglionnaires de la rétine (CGRs) voyagent sur de longues distances pour établir des connexions avec leurs cellules cibles. La navigation des cônes de croissance est guidée par différentes molécules chimiotropiques présentes dans leur environnement. Les endocannabinoïdes (eCB) sont d’importants neuromodulateurs qui régulent de manière rétrograde la fonction de nombreuses synapses du cerveau. Ils agissent principalement par le biais de leurs récepteurs liés à une protéine Gi/o CB1 (CB1R) et CB2 (CB2R). La présence des eCBs durant le stade fœtal et la période postnatale suggère leur implication dans des événements régulant le développement du système nerveux. Cette thèse confirme l’expression des récepteurs aux cannabinoïdes CB1 et CB2 ainsi que l’enzyme dégradant les eCBs lors du développement embryonnaire et perinatal des CGRs et de la voie rétinothalamique in vivo. La manipulation pharmacologique de l’activité de CB1R et CB2R réorganise la morphologie du cône de croissance des CGRs et des neurones corticaux in vitro. De plus, la stimulation locale avec un agoniste de CB1R ou de CB2R modifie le comportement du cône de croissance entraînant sa répulsion. CB1R et CB2R modulent par le biais de la voie de signalisation AMPc/PKA, la mobilisation de DCC à la membrane plasmique. Par ailleurs, les résultats de cette recherche démontrent également l’implication de CB1R et CB2R dans la ségrégation des projections ipsi- et controlatérales et le développement de la voie rétinothalamique. / Following differentiation, retinal ganglion cell (RGC) axons, tipped at their distal end by the growth cone (GC), navigate through relatively long distances in a highly directed manner in order to establish functional synapses with thalamic and superior colliculus (SC) neurons. This is achieved with the help of extracellular guidance molecules which steer RGC axon growth by regulating GC morphology by means of attractive and/or repulsive mechanisms. In the adult brain, endocannabinoids (eCBs) exert an important neuromodulatory function by acting as retrograde messengers to regulate the function of many synapses. Endocannabinoids act mainly via their Gi/o protein coupled receptors CB1 (CB1R) and CB2 (CB2R). Due to their presence at the fetal and early postnatal periods, it has been proposed that eCBs and their receptors might be involved in several developmental events, such as cell proliferation and migration, axon guidance and synaptogenesis. We observed that during early postnatal development, components of the eCB system are expressed along the visual pathway (the optic chiasm, the lateral geniculate nucleus and the SC). To assess the implication of the eCB system, in vitro, embryonic retinal explant and primary neuron cultures were treated with pharmacological agonists and inverse agonists of CB1R and CB2R. These experiments demonstrated that these cannabinoid receptors modify the GC’s morphology. Most importantly, CB1R and CB2R act through the cAMP/PKA pathway to modulate the presence of DCC at the plasma membrane. In vivo, CB1R and CB2R play a major role and the absence of either one of them induces a decrease in eye-specific segregation of retinal projections. These results show an implication of CB1R and CB2R during RGC growth and retinothalamic development. Cône de croissance guidage axonal récepteurs aux cannabinoïdes CGR DCC PKA AMPc Growth cone axon guidance cannabinoid receptors RGC DCC PKA cAMP
7	Le rôle des récepteurs aux cannabinoïdes CB1 et CB2 dans le guidage axonal Argaw, Anteneh 12 1900 (has links) Au cours du développement, les axones des cellules ganglionnaires de la rétine (CGRs) voyagent sur de longues distances pour établir des connexions avec leurs cellules cibles. La navigation des cônes de croissance est guidée par différentes molécules chimiotropiques présentes dans leur environnement. Les endocannabinoïdes (eCB) sont d’importants neuromodulateurs qui régulent de manière rétrograde la fonction de nombreuses synapses du cerveau. Ils agissent principalement par le biais de leurs récepteurs liés à une protéine Gi/o CB1 (CB1R) et CB2 (CB2R). La présence des eCBs durant le stade fœtal et la période postnatale suggère leur implication dans des événements régulant le développement du système nerveux. Cette thèse confirme l’expression des récepteurs aux cannabinoïdes CB1 et CB2 ainsi que l’enzyme dégradant les eCBs lors du développement embryonnaire et perinatal des CGRs et de la voie rétinothalamique in vivo. La manipulation pharmacologique de l’activité de CB1R et CB2R réorganise la morphologie du cône de croissance des CGRs et des neurones corticaux in vitro. De plus, la stimulation locale avec un agoniste de CB1R ou de CB2R modifie le comportement du cône de croissance entraînant sa répulsion. CB1R et CB2R modulent par le biais de la voie de signalisation AMPc/PKA, la mobilisation de DCC à la membrane plasmique. Par ailleurs, les résultats de cette recherche démontrent également l’implication de CB1R et CB2R dans la ségrégation des projections ipsi- et controlatérales et le développement de la voie rétinothalamique. / Following differentiation, retinal ganglion cell (RGC) axons, tipped at their distal end by the growth cone (GC), navigate through relatively long distances in a highly directed manner in order to establish functional synapses with thalamic and superior colliculus (SC) neurons. This is achieved with the help of extracellular guidance molecules which steer RGC axon growth by regulating GC morphology by means of attractive and/or repulsive mechanisms. In the adult brain, endocannabinoids (eCBs) exert an important neuromodulatory function by acting as retrograde messengers to regulate the function of many synapses. Endocannabinoids act mainly via their Gi/o protein coupled receptors CB1 (CB1R) and CB2 (CB2R). Due to their presence at the fetal and early postnatal periods, it has been proposed that eCBs and their receptors might be involved in several developmental events, such as cell proliferation and migration, axon guidance and synaptogenesis. We observed that during early postnatal development, components of the eCB system are expressed along the visual pathway (the optic chiasm, the lateral geniculate nucleus and the SC). To assess the implication of the eCB system, in vitro, embryonic retinal explant and primary neuron cultures were treated with pharmacological agonists and inverse agonists of CB1R and CB2R. These experiments demonstrated that these cannabinoid receptors modify the GC’s morphology. Most importantly, CB1R and CB2R act through the cAMP/PKA pathway to modulate the presence of DCC at the plasma membrane. In vivo, CB1R and CB2R play a major role and the absence of either one of them induces a decrease in eye-specific segregation of retinal projections. These results show an implication of CB1R and CB2R during RGC growth and retinothalamic development. Cône de croissance guidage axonal récepteurs aux cannabinoïdes CGR DCC PKA AMPc Growth cone axon guidance cannabinoid receptors RGC DCC PKA cAMP
8	ANALYSES OF THE DEVELOPMENT AND FUNCTION OF STEM CELL DERIVED CELLS IN NEURODEGENERATIVE DISEASES.pdf Sailee Sham Lavekar (14152875) 03 February 2023 (has links) <p>Human pluripotent stem cells (hPSCs) are an attractive tool for the study of different neurodegenerative diseases due to their potential to form any cell type of the body. Due to their versatility and self-renewal capacity, they have different applications such as disease modeling, high throughput drug screening and transplantation. Different animal models have helped answer broader questions related to the physiological functioning of various pathways and the phenotypic effects of a particular neurodegenerative disease. However, due to the lack of success recapitulating some targets identified from animal models into successful clinical trials, there is a need for a direct translational disease model. Since their advent, hPSCs have helped understand various disease effectors and underlying mechanisms using genetic engineering techniques, omics studies and reductionist approaches for the recognition of candidate molecules or pathways required to answer questions related to neurodevelopment, neurodegeneration and neuroregeneration. Due to the simplified approach that iPSC models can provide, some <em>in vitro</em> approaches are being developed using microphysiological systems (MPS) that could answer complex physiological questions. MPS encompass all the different <em>in vitro</em> systems that could help better mimic certain physiological systems that tend to not be mimicked by <em>in vivo</em> models. In this dissertation, efforts have been directed to disease model as well as to understand the intrinsic as well as extrinsic cues using two different MPS. First, we have used hPSCs with Alzheimer’s disease (AD)-related mutations to differentiate into retinal organoids and identify AD related phenotypes for future studies to identify retinal AD biomarkers. Using 5 month old retinal organoids from AD cell lines as well as controls, we could identify retinal AD phenotypes such as an increase in Aβ42:Aβ40 ratio along with increase in pTau:Tau. Nanostring analyses also helped in identification of potential target genes that are modulated in retinal AD that were related to synaptic dysfunction. Thus, using retinal organoids for the identification of retinal AD phenotypes could help delve deeper into the identification of future potential biomarkers in the retina of AD patients, with the potential to serve as a means for early identification and intervention for patients. The next MPS we used to serve to explore non-cell autonomous effects associated with glaucoma to explore the neurovascular unit. Previous studies have demonstrated the degeneration of RGCs in glaucoma due to a point mutation OPTN(E50K) that leads to the degeneration of RGCs both at morphological and functional levels. Thus, using the previous studies as a basis, we wanted to further unravel the impact of this mutation using the different cell types of the neurovascular unit such as endothelial cells, astrocytes and RGCs. Interestingly, we observed the barrier properties being impacted by the mutation present in both RGCs and astrocytes demonstrated through TEER, permeability and transcellular transport changes. We also identified a potential factor TGFβ2 that was observed to be overproduced by the OPTN E50K astrocytes to demonstrate similar effects with the exogenous addition of TGFβ2 on the barrier. Furthermore, the inhibition of TGFβ2 helped rescue some of the barrier dysfunction phenotypes. Thus, TGFβ2 inhibition can be used as a potential candidate that can be used to further study its impact in <em>in vivo</em> models and how that can be used in translational applications. Thus, MPS systems have a lot of applications that can help answer different physiologically relevant questions that are hard to approach using <em>in vivo</em> models and the further development of these systems to accentuate the aspects of neural development and how it goes awry in different neurodegenerative diseases. </p> Neurosciences not elsewhere classified Vision science RETINAL ORGANOIDS retinal ganglion cell (RGC) astrocyte biology Endothelial Cells blood brain barrier dysfunction glaucoma neurodegenerative diseases Alzheimer's disease stem cells

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