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Régulation développementale in vivo de l'expression hypophysaire du gène POMCLavoie, Pierre-Luc January 2006 (has links)
Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.
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Adult neurogenesis and mitochondria play a role in hippocampal plasticity in mouse models of neurodegenerative diseases / Les mitochondries impliquées dans la neurogenèse adulte jouent un rôle dans la plasticité de l’hippocampe dans des modèles murins de maladies neurodégénérativesAndraini Halim, Trinovita 14 November 2017 (has links)
La neurogenèse adulte est cruciale pour certaines fonctions mnésiques dépendantes de l'hippocampe. La mise en évidence d'une altération de la neurogenèse dans le cerveau de souris transgéniques modèles de la maladie d'Alzheimer (MA), en parallèle d'une réduction du contenu mitochondrial de leurs nouveaux neurones ouvre une nouvelle piste de recherche ciblant les mitochondries. Aujourd'hui, l'hypothèse d'un rôle causal des dysfonctionnements mitochondriaux dans l'étiologie des pathologies neurodégénératives est particulièrement pertinente dans la MA. Les mitochondries, " centrales électriques " et régulateurs du métabolisme oxydatif, forment un réseau dynamique qui s'adapte aux différents types et contextes cellulaires, via des événements antagonistes de fusion et de fission de leurs membranes. Les protéines clés ont été identifiées, dont OPA1 qui permet la fusion. Les dysfonctionnements de cette dynamique influent non seulement sur la forme et la distribution des mitochondries dans les neurones, mais affectent aussi leurs principales activités que sont respiration, régulation calcique, production de ROS et apoptose. Dans les neurones, cellules excitables à l'architecture complexe, les dysfonctionnements mitochondriaux ont des conséquences particulièrement cruciales pour la transmission synaptique. Au cours de cette thèse, nous avons étudié parallèlement des souris modèles de la MA, les souris Tg2576 (mutation d'APP) et des souris OPA1+/-, porteuses d'une mutation d'OPA1, modèles de l'Atrophie Optique Dominante. Nous avons observé chez ces deux lignées de souris une altération précoce des performances dans des tests comportementaux mettant en jeu le gyrus denté et les nouveaux neurones (tests de localisation d'objet et de séparation de patron). Nous avons démontré chez les souris Tg2576 et OPA1+/- que ces déficits cognitifs sont associés à des perturbations de la neurogenèse hippocampique adulte.[...] / Adult neurogenesis is crucial for some hippocampus-dependent memory functions. Both the demonstration of an alteration of neurogenesis in the brain of transgenic mouse models of Alzheimer's disease (AD), in parallel with a reduction in the mitochondrial content of their new neurons, open a new research avenue targeting the mitochondria. Today, the hypothesis of a causal role of mitochondrial dysfunctions in the etiology of neurodegenerative pathologies is particularly relevant in AD. Mitochondria, "power plants" and regulators of oxidative metabolism, form a dynamic network that adapts to different cell types and contexts, via antagonistic events of fusion and fission of their membranes. Key proteins have been identified, including OPA1 that allows fusion. Dysfunctions of this dynamics affect not only the shape and distribution of mitochondria in neurons, but also alter their main activities: respiration, calcium regulation, ROS production and apoptosis. In neurons, excitable cells with complex architecture, mitochondrial dysfunctions have particularly crucial consequences for synaptic transmission. In this thesis, we studied in parallel an AD mouse model, the Tg2576 mice (APP mutation) and the OPA1 +/- mice, carrying a mutation of OPA1, a Dominant Optic Atrophy model. In both mouse lines, we observed precocious performance alterations in behavioral tests involving the dentate gyrus and new neurons (object location, pattern separation tests). We demonstrated in Tg2576 and OPA1 +/- mice that these cognitive deficits are associated with disturbances of adult hippocampal neurogenesis. [...]
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Vývoj a funkce endokrinních buněk pankreatu / Development and function of endocrine cells of the pancreasHamplová, Adéla January 2019 (has links)
Diabetes mellitus affects nearly 300 million people in the world. The development of diabetes is caused by dysfunction or by reduction of insulin-producing β-cells that are part of the endocrine pancreas. Therefore, the most critical step for understanding the pathophysiology of diabetes and for restoring lost β cells is the identification of molecular cues that specify the cellular phenotype in the pancreas. This work is based on the hypothesis that the transcription factor NEUROD1 is a key factor for the development of the pancreas and for the maintenance of endocrine tissue function. Neurod1 conditional KO mutants (Neurod1CKO) were generated using the Cre-loxP system by crossing floxed Neurod1 mice with Isl1-Cre line. Immunohistochemical analyses of the pancreas at embryonic day 17.5 and postnatal day 0 showed that the deletion of Neurod1 negatively affected the development, organization of endocrine tissue, and total mass of pancreatic endocrine cells. To better understand molecular changes, quantitative PCR was used to analyse mRNA expression in the developing pancreas at the age of embryonic day 14.5 and postnatal day 1. Genes important for the development and function of the pancreas have been selected for the study of expression changes. These analyses showed changes in expression of genes...
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Funkční role Islet1 ve vývoji pankreatu / Functional role of Islet1 in pancreatic developmentMalfatti, Jessica January 2021 (has links)
1 Abstract Diabetes mellitus is characterized by the dysfunction and reduction of insulin-producing cells, resulting in hyperglycemia, which in long term harms the organism. For future therapy, it is crucial to understand the function of various factors participating in the differentiation and maturation of endocrine pancreatic cells. The aim of this study was to unravel the functional role of ISL1 during the development of the pancreas. ISL1 is expressed in all endocrine cells of the islets of Langerhansbut its function remains unclear, especially during early pancreatogenesis. As the global deletion of this gene is embryonically lethal, we used the tissue specific deletion of Isl1 in Neurod1 possitive cells using the Cre-loxP system. In this work we studied the effect of this deletion on the structure of islets of Langerhans, the formation of endocrine cell types and relative expression of genes during early pancreatic development. A defective achitecture of islets together with postnatal absence of α-cells was found in the Isl1 deletion mutant. Also, the expression of genes important for the specification of α-cell lineage and their subsequent function was decreased. The secondary outcome was the optimalization of a protocol for effective sorting of endocrine cells using fluorescent flow cytometry, which...
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Pancreatic Endocrine Tumourigenesis : Genes of potential importanceJohansson, Térèse A. January 2008 (has links)
<p>Understanding signalling pathways that control pancreatic endocrine tumour (PET) development and proliferation may reveal novel targets for therapeutic intervention. The pathogenesis for sporadic and hereditary PETs, apart from mutations of the <i>MEN1</i> and <i>VHL</i> tumour suppressor genes, is still elusive. The protein product of the <i>MEN1</i> gene, menin, regulates many genes. The aim of this thesis was to identify genes involved in pancreatic endocrine tumourigenesis, with special reference to Notch signalling.</p><p>Messenger RNA and protein expression of NOTCH1, HES1, HEY1, ASCL1, NEUROG3, NEUROD1, DLK1, POU3F4, PDX1, RPL10, DKK1 and TPH1 were studied in human PETs, sporadic and MEN 1, as well as in tumours from heterozygous <i>Men1</i> mice. For comparison, normal and <i>MEN1</i> non-tumourous human and mouse pancreatic specimens were used. Nuclear expression of HES1 was consistently absent in PETs. In mouse tumours this coincided with loss of menin expression, and there was a correlation between <i>Men1</i> expression and several Notch signalling factors. A new phenotype consisting of numerous menin-expressing endocrine cell clusters, smaller than islets, was found in <i>Men1</i> mice. Expression of NEUROG3 and NEUROD1 was predominantly localised to the cytoplasm in PETs and islets from MEN 1 patients and <i>Men1</i> mice, whereas expression was solely nuclear in wt mice. Differences in expression levels of Pou3f4, Rpl10 and Dlk1 between islets of <i>Men1</i> and wt mice were observed.</p><p>In addition, combined RNA interference and microarray expression analysis in the pancreatic endocrine cell line BON1 identified 158 target genes of ASCL1. For two of these, DKK1 (a negative regulator of the WNT/β-catenin signalling pathway) and TPH1, immunohistochemistry was performed on PETs. In concordance with the microarray finding, DKK1 expression showed an inverse relation to ASCL1 expression.</p><p>Altered subcellular localisation of HES1, NEUROD1 and NEUROG3 and down-regulation of DKK1 may contribute to tumourigenesis.</p>
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Pancreatic Endocrine Tumourigenesis : Genes of potential importanceJohansson, Térèse A. January 2008 (has links)
Understanding signalling pathways that control pancreatic endocrine tumour (PET) development and proliferation may reveal novel targets for therapeutic intervention. The pathogenesis for sporadic and hereditary PETs, apart from mutations of the MEN1 and VHL tumour suppressor genes, is still elusive. The protein product of the MEN1 gene, menin, regulates many genes. The aim of this thesis was to identify genes involved in pancreatic endocrine tumourigenesis, with special reference to Notch signalling. Messenger RNA and protein expression of NOTCH1, HES1, HEY1, ASCL1, NEUROG3, NEUROD1, DLK1, POU3F4, PDX1, RPL10, DKK1 and TPH1 were studied in human PETs, sporadic and MEN 1, as well as in tumours from heterozygous Men1 mice. For comparison, normal and MEN1 non-tumourous human and mouse pancreatic specimens were used. Nuclear expression of HES1 was consistently absent in PETs. In mouse tumours this coincided with loss of menin expression, and there was a correlation between Men1 expression and several Notch signalling factors. A new phenotype consisting of numerous menin-expressing endocrine cell clusters, smaller than islets, was found in Men1 mice. Expression of NEUROG3 and NEUROD1 was predominantly localised to the cytoplasm in PETs and islets from MEN 1 patients and Men1 mice, whereas expression was solely nuclear in wt mice. Differences in expression levels of Pou3f4, Rpl10 and Dlk1 between islets of Men1 and wt mice were observed. In addition, combined RNA interference and microarray expression analysis in the pancreatic endocrine cell line BON1 identified 158 target genes of ASCL1. For two of these, DKK1 (a negative regulator of the WNT/β-catenin signalling pathway) and TPH1, immunohistochemistry was performed on PETs. In concordance with the microarray finding, DKK1 expression showed an inverse relation to ASCL1 expression. Altered subcellular localisation of HES1, NEUROD1 and NEUROG3 and down-regulation of DKK1 may contribute to tumourigenesis.
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Proteomic studies on development factors of pig embryonic stem cells into neural cells by RA in vitroChen, Chin-tan 04 August 2005 (has links)
Proteomic techniques were used to analyze the protein expression profile of the early-stage differentiation of pig embryonic stem cells (ES cells). The pig ES cells were induced to develop to neuronal cells by all-trans retinoic acid (ATRA) in vitro by Tainan Livestock Research Institute. The ES cells were cultured with ATRA and collected at time intervals of 0, 1, 2, 4, 8 and 10 days. The cell lysates were analyzed by two-dimensional electrophoresis, and the differentially expressed proteins are identified by MALDI-TOF. Our data shows that the expression profile of pig ES cells is similar to other mammalian models but with some differences. Preliminary pig ES cells 2D database was set up. Six spots each with up or down-regulation in neurogenesis were identified by MS. These proteins may become the good markers of pig ES cells into neural cells by RA. Among those proteins, vimentin, prohibitin and annexin A10 were up-regulated, zinc finger protein 482 (ZNF482), fyn-related kinase (FRK) and annexin A1 were down-regulated during differentiation of pig ES cells to neural cells. Addtionally, we ultilized RT-PCR technique to investigate mRNA expression during neurogenesis, vimentin and prohibitin was up-regulated, anxa1(annexin A1) was slightly down-regulated, neuroD1 and neurogenin 2 were high expression on day 10, beta-catenin was high expression on day 8 to 10.
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Funkční role SOX2 v neurosenzorickém vývoji vnitřního ucha / Functional role of SOX2 in inner ear neurosensory developmentDvořáková, Martina January 2020 (has links)
The main functional cells of the inner ear are neurons and sensory cells that are formed from a common embryonic epithelial neurosensory domain. Discovering genes important for specification and differentiation of sensory cells and neurons in the inner ear is a crucial basis for understanding the pathophysiology of hearing loss. Some of these factors are necessary not only for the inner ear but also for the development of other neurosensory systems such as the visual and olfactory system. The aim of this work was to reveal functions of transcription factor SOX2 in inner ear development by using mouse models with different conditional deletions of Sox2 gene. Sox2 gene was deleted by cre-loxP recombination. In Isl1-cre, Sox2 CKO mutant, reduced number of hair cells differentiated only in some inner ear organs (utricle, saccule and cochlear base) and not in others (cristae and cochlear apex). Early forming inner ear neurons in the vestibular ganglion and neurons innervating the cochlear base developed in these mutants but died by apoptosis due to the lack of neurotrophic support from sensory cells. Late forming neurons in the cochlear apex never formed. In Foxg1-cre, Sox2 CKO mutant, only rudimental ear with no sensory cells was formed. The initial formation of vestibular ganglion with peripheral and...
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Visual cortical circuit dynamics in health and diseaseYu Tang (12441534) 21 April 2022 (has links)
<p>My thesis revolves around neuronal circuit dynamics in health and disease. The first part of the thesis characterized cross-regional synchrony within the visual cortical network following visual perceptual experience in healthy mice. This work for the first time described inter-areal 4-8 Hz superficial layer LFP synchrony across mouse visual cortical regions persisting beyond visual stimulation time window, and revealed that the synchrony was expressed specifically between V1 and the higher-order visual area (HVA) with functional preference matching the entrained spatial frequency (SF) and temporal frequency (TF) content, in mice. The discovery of visual familiarity induced inter-areal 4-8 Hz synchrony extends the previous discovery of the 4-8 Hz oscillation in V1 after visual experience from our lab (Kissinger et al., 2018; Kissinger et al., 2020; Gao et al., 2021), and provided the first pivotal evidence supporting the role of 4-8 Hz oscillation in mediating cross-regional communication. Such 4-8 Hz visual cortical network synchrony has been mostly reported in primate studies in contexts of visual attention and working memory (Liebe et al., 2012; Spyropoulos et al., 2018), while our study extended the visual cortical network synchrony research scope to mouse models and in a new context of visual familiarity. The work is a key step for starting cortical network studies in mice, and for starting predictive coding theory study in the context of oscillations in mouse cortical network in the future. Additionally, unit spiking was more strongly modulated by 4-8 Hz oscillations in V1 and HVAs after visual experience. The visually-locked responsive units in V1 and HVAs exihibted either increased or decreased inter-areal spiking synchrony, while most post-stimulus responsive units in V1 and HVA exhibited higher spiking synchrony. </p>
<p>The other parts of my dissertation looked at V1 activity in disease and following a novel CNS therapy. One project looked at recovery of visually evoked response in mouse V1 after ischemia through NeuroD1 mediated astrocyte-to-neuron conversion, where we characterized the formation of cortical laminated structure from the converted neurons, longitudinal recovery of visually evoked responses of unit populations in V1, and units’ selective responses to orientations. Another project looked at altered visual cortical activity in an Auxilin knockout mouse model, which demonstrated overall reduced visually evoked responses, less selective responses to orientations, impaired visual adaptive responses and mismatch responses, as well as slower visual experience induced oscillations. These projects utilized the high-density silicon probe recording technique to 1) characterize visual cortical function recovery following a therapy, which provided evidence for its high efficacy for recovering physiological functions, and to 2) phenotype visual cortical functional impairments in a mouse disease model, which provided more basic understanding in visual cortical physiology of Auxilin related disease.</p>
<p>In sum, my dissertation work took advantage of the high-density silicon probe recording technique to probe neuronal circuits in health and disease. The discovery of visual experience induced inter-areal 4-8 Hz synchrony paves the way for studying 4-8 Hz activity in relation to stream-dependent visual processing and predictive coding in health and disease.</p>
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