39 research outputs found

    Structural and functional relationship of Pin1

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    Master'sMASTER OF SCIENC

    Role of the ASPP Family in the Regulation of p53-Mediated Apoptotic Death of Retinal Ganglion Cells after Optic Nerve Injury

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    Le glaucome est la première cause de cécité irréversible à travers le monde. À présent il n’existe aucun remède au glaucome, et les thérapies adoptées sont souvent inadéquates. La perte de vision causée par le glaucome est due à la mort sélective des cellules rétiniennes ganglionnaires, les neurones qui envoient de l’information visuelle de la rétine au cerveau. Le mécanisme principal menant au dommage des cellules rétiniennes ganglionnaires lors du glaucome n’est pas bien compris, mais quelques responsables putatifs ont été proposés tels que l’excitotoxicité, le manque de neurotrophines, la compression mécanique, l’ischémie, les astrocytes réactifs et le stress oxidatif, parmis d’autres. Indépendamment de la cause, il est bien établi que la perte des cellules rétiniennes ganglionnaires lors du glaucome est causée par la mort cellulaire programmée apoptotique. Cependant, les mécanismes moléculaires précis qui déclenchent l’apoptose dans les cellules rétiniennes ganglionnaires adultes sont mal définis. Pour aborder ce point, j’ai avancé l’hypothèse centrale que l’identification de voies de signalisations moléculaires impliquées dans la mort apoptotique des cellules rétiniennes ganglionnaires offrirait des avenues thérapeutiques pour ralentir ou même prévenir la mort de celles-ci lors de neuropathies oculaires telles que le glaucome. Dans la première partie de ma thèse, j’ai caractérisé le rôle de la famille de protéines stimulatrices d’apoptose de p53 (ASPP), protéines régulatrices de la famille p53, dans la mort apoptotique des cellules rétiniennes ganglionnaires. p53 est un facteur de transcription nucléaire impliqué dans des fonctions cellulaires variant de la transcription à l’apoptose. Les membres de la famille ASPP, soit ASPP1, ASPP2 et iASPP, sont des protéines de liaison de p53 qui régulent l’apoptose. Pourtant, le rôle de la famille des ASPP dans la mort des cellules rétiniennes ganglionnaires est inconnu. ASPP1 et ASPP2 étant pro-apoptotiques, l’hypothèse de cette première étude est que la baisse ciblée de ASPP1 et ASPP2 promouvrait la survie des cellules rétiniennes ganglionnaires après une blessure du nerf optique. Nous avons utilisé un modèle expérimental bien caractérisé de mort apoptotique neuronale induite par axotomie du nerf optique chez le rat de type Sprague Dawley. Les résultats de cette étude (Wilson et al. Journal of Neuroscience, 2013) ont démontré que p53 est impliqué dans la mort apoptotique des cellules rétiniennes ganglionnaires, et qu’une baisse ciblée de ASPP1 et ASPP2 par acide ribonucléique d’interference promeut la survie des cellules rétiniennes ganglionnaires. Dans la deuxième partie de ma thèse, j’ai caractérisé le rôle d’iASPP, le membre anti-apoptotique de la famille des ASPP, dans la mort apoptotique des cellules rétiniennes ganglionnaires. L’hypothèse de cette seconde étude est que la surexpression d’iASPP promouvrait la survie des cellules rétiniennes ganglionnaires après axotomie. Mes résultats (Wilson et al. PLoS ONE, 2014) démontrent que le knockdown ciblé de iASPP exacerbe la mort apoptotique des cellules rétiniennes ganglionnaires, et que la surexpression de iASPP par virus adéno-associé promeut la survie des cellules rétiniennes ganglionnaires. En conclusion, les résultats présentés dans cette thèse contribuent à une meilleure compréhension des mécanismes régulateurs sous-jacents la perte de cellules rétiniennes ganglionnaires par apoptose et pourraient fournir des pistes pour la conception de nouvelles stratégies neuroprotectrices pour le traitement de maladies neurodégénératives telles que le glaucome.Glaucoma is the leading cause of irreversible blindness worldwide. At present, there is no cure for glaucoma, and current therapies are often inadequate. Loss of vision in glaucoma results from the death of retinal ganglion cells, the neurons that send visual information from the retina to the brain. The principal mechanism leading to retinal ganglion cell damage during glaucoma is not well understood, however, putative culprits have been proposed including excitotoxicity, neurotrophin deprivation, mechanical compression, ischemia, reactive astrocytes and oxidative stress. It is well established that retinal ganglion cell loss during glaucoma is caused by apoptotic programmed cell death, however, the precise mechanisms that lead to apoptotic death of adult retinal ganglion cells are poorly defined. To address this point, I put forth the central hypothesis that the identification of signaling pathways involved in apoptotic retinal ganglion cell death would offer therapeutic avenues to slow or prevent retinal ganglion cell death during ocular neuropathies such as glaucoma. In the first part of my thesis, I characterised the role of Apoptosis Stimulating Protein of p53 family (ASPP) proteins, which are regulators of p53, in the apoptotic death of retinal ganglion cells. p53 is a nuclear transcription factor implicated in cellular functions ranging from transcription to apoptosis. ASPP family members ASPP1, ASPP2 and iASPP are p53 binding proteins that belong to a family of protein regulators of p53-dependent apoptotic death. However, the role of ASPP family members in retinal ganglion cell death is unknown. As ASPP1 and ASPP2 are pro-apoptotic, the hypothesis of our first study was that the knockdown of ASPP1 and ASPP2 gene expression would lead to retinal ganglion cell survival after an optic nerve lesion. We used a well-characterized experimental model of neuronal apoptosis induced by optic nerve axotomy in Sprague Dawley rats. The results of this study (Wilson et al. Journal of Neuroscience, 2013) demonstrated that p53 is implicated in retinal ganglion cell death, and that targeted knockdown of ASPP1 and ASPP2 by short interference ribonucleic acid promotes retinal ganglion cell survival. The knockdown of ASPP2 correlates with a reduction in the levels of pro-apoptotic p53 regulated targets PUMA and Fas/CD95. In the second part of my thesis, I characterized the role of the anti-apoptotic member of the ASPP family, iASPP, in the apoptotic death of retinal ganglion cells. The hypothesis of this second study is that the overexpression of iASPP would promote retinal ganglion cell survival after axotomy. The data (Wilson et al. PLoS ONE, 2014) demonstrate that the targeted knockdown of iASPP by short interference ribonucleic acid exacerbates retinal ganglion cell death, and that the overexpression of iASPP by adeno-associated virus promotes retinal ganglion cell survival. The overexpression of iASPP correlates with a reduction in protein levels of PUMA and Fas/CD95. In conclusion, the findings presented in this thesis contribute to a better understanding of the pathological mechanisms underlying retinal ganglion cell loss by apoptosis and might provide insights into the design of novel neuroprotective treatments for neurodegenerative diseases such as glaucoma

    Neural Stem Cells

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    Twenty years after the discovery of neural stem cells, the question whether the central nervous system can be considered among regenerative tissues is still open. On one side, deep characterization of neural stem and progenitor cells, their niches, and their progeny in brain neurogenic sites overtly showed that new neurons can be generated in the brain of adult mammals, including humans. On the other side, many problems arise when stem cells encounter the mature brain parenchyma, still hampering the development of efficacious therapeutic approaches with endogenous or exogenously-delivered neural stem cells. This book tries to make the point on these extremely promising, yet unresolved, issues

    Chemicals Facilitating Reprogramming: Targeting the SAM Binding Site to Identify Novel Methyltransferase Inhibitors

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    © 2014 John Wiley & Sons, Ltd. Reprogramming of somatic cells to a pluripotent state has been achieved by viral-mediated transduction of defined transcription factors. In order to achieve the goal of clinical application, it is necessary to overcome a variety of limitations, including poor reprogramming efficiencies and viral integration. One strategy is to identify small-molecule inhibitors that can improve reprogramming efficiency or replace defined transcription factors. Several reports have demonstrated that modulation of chromatin-modifying enzymes can significantly improve reprogramming efficiency. Key enzymes include DNA and histone methyltransferases, which utilize the cofactor S-adenosyl methionine (SAM) to transfer a methyl group. In this chapter, we review our efforts to identify SAM analogues by virtual screening

    Neuroanatomical and gene expression features of the rabbit accessory olfactory system. Implications of pheromone communication in reproductive behaviour and animal physiology

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    Mainly driven by the vomeronasal system (VNS), pheromone communication is involved in many species-specific fundamental innate socio-sexual behaviors such as mating and fighting, which are essential for animal reproduction and survival. Rabbits are a unique model for studying chemocommunication due to the discovery of the rabbit mammary pheromone, but paradoxically there has been a lack of knowledge regarding its VNS pathway. In this work, we aim at filling this gap by approaching the system from an integrative point of view, providing extensive anatomical and genomic data of the rabbit VNS, as well as pheromone-mediated reproductive and behavioural studies. Our results build strong foundation for further translational studies which aim at implementing the use of pheromones to improve animal production and welfare

    Psr1p interacts with SUN/sad1p and EB1/mal3p to establish the bipolar spindle

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    Regular Abstracts - Sunday Poster Presentations: no. 382During mitosis, interpolar microtubules from two spindle pole bodies (SPBs) interdigitate to create an antiparallel microtubule array for accommodating numerous regulatory proteins. Among these proteins, the kinesin-5 cut7p/Eg5 is the key player responsible for sliding apart antiparallel microtubules and thus helps in establishing the bipolar spindle. At the onset of mitosis, two SPBs are adjacent to one another with most microtubules running nearly parallel toward the nuclear envelope, creating an unfavorable microtubule configuration for the kinesin-5 kinesins. Therefore, how the cell organizes the antiparallel microtubule array in the first place at mitotic onset remains enigmatic. Here, we show that a novel protein psrp1p localizes to the SPB and plays a key role in organizing the antiparallel microtubule array. The absence of psr1+ leads to a transient monopolar spindle and massive chromosome loss. Further functional characterization demonstrates that psr1p is recruited to the SPB through interaction with the conserved SUN protein sad1p and that psr1p physically interacts with the conserved microtubule plus tip protein mal3p/EB1. These results suggest a model that psr1p serves as a linking protein between sad1p/SUN and mal3p/EB1 to allow microtubule plus ends to be coupled to the SPBs for organization of an antiparallel microtubule array. Thus, we conclude that psr1p is involved in organizing the antiparallel microtubule array in the first place at mitosis onset by interaction with SUN/sad1p and EB1/mal3p, thereby establishing the bipolar spindle.postprin

    Removal of antagonistic spindle forces can rescue metaphase spindle length and reduce chromosome segregation defects

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    Regular Abstracts - Tuesday Poster Presentations: no. 1925Metaphase describes a phase of mitosis where chromosomes are attached and oriented on the bipolar spindle for subsequent segregation at anaphase. In diverse cell types, the metaphase spindle is maintained at a relatively constant length. Metaphase spindle length is proposed to be regulated by a balance of pushing and pulling forces generated by distinct sets of spindle microtubules and their interactions with motors and microtubule-associated proteins (MAPs). Spindle length appears important for chromosome segregation fidelity, as cells with shorter or longer than normal metaphase spindles, generated through deletion or inhibition of individual mitotic motors or MAPs, showed chromosome segregation defects. To test the force balance model of spindle length control and its effect on chromosome segregation, we applied fast microfluidic temperature-control with live-cell imaging to monitor the effect of switching off different combinations of antagonistic forces in the fission yeast metaphase spindle. We show that spindle midzone proteins kinesin-5 cut7p and microtubule bundler ase1p contribute to outward pushing forces, and spindle kinetochore proteins kinesin-8 klp5/6p and dam1p contribute to inward pulling forces. Removing these proteins individually led to aberrant metaphase spindle length and chromosome segregation defects. Removing these proteins in antagonistic combination rescued the defective spindle length and, in some combinations, also partially rescued chromosome segregation defects. Our results stress the importance of proper chromosome-to-microtubule attachment over spindle length regulation for proper chromosome segregation.postprin

    PRION CHARACTERIZATION USING CELL BASED APPROACHES

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    Prions are the causative agents of a group of lethal, neurodegenerative conditions that include sheep scrapie, bovine spongiform encephalopathy (BSE), and human Creutzfeldt-Jakob disease (CJD). Prions are derived from the conversion of a normal, primarily alpha-helical, cellular prion protein (PrPC), to an infectious, beta sheet-rich conformer (PrPSc). Many unresolved issues surround the process of PrP conversion, and we know very little about cellular responses to these unique pathogens. Our lack of knowledge relates, in part, to the difficulty of infecting cells in vitro with prions. While expression of PrPC is an absolute requirement for prion propagation, I show here that not all cells that express PrPC are capable of propagating PrPSc. The goal of this thesis is to understand the role that host factors play in sustaining prion infection and to develop systems in which the cellular response to prion infection can be assessed. We hypothesize that cellular permissiveness to prion infectivity is co-dependent on unidentified additional cellular factors. To study the role of PrPC expression in susceptibility to prion infectivity, and identify these cofactors in cell culture, we utilized cells which fail to express endogenous PrPC, but become susceptible to prions following stable expression of PrPC. Following transfection of a species specific PrP expression construct and isolation of single cell clones, we assessed PrP expression and susceptibility to prion infectivity by measuring accumulation of protease resistant PrPSc. Differential gene expression studies suggest significant transcriptional differences between susceptible and resistant clones. Using three independent gene expression databases our analyses suggest that the resistant transcriptional profile favors cell division/cycle and chromosomal regulation pathways, while the sensitive transcriptional profile is involved in protein homeostasis and quality control. The results of these studies will not only lead to a greater understanding of PrP cell biology and the mechanisms of prion pathogenesis, but should ultimately lead to sensitive and expedient methods for detecting and characterizing prion infectivity from a wide range of sources

    Using human iPSC-derived neural progenitor cells to increase integrin expression in the CNS

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    Repair of the adult mammalian spinal cord is prohibited by several extrinsic and intrinsic factors. As the CNS matures, growth-promoting proteins such as integrins are developmentally downregulated resulting in a reduced capacity for axonal outgrowth. Integrins are heterodimeric receptors involved in cell-cell and cell-matrix interactions. Specifically, within mature corticospinal tract (CST) axons, integrins are not transported into the axonal compartment. One integrin heterodimer, α9β1, is of particular interest for its ability to promote neurite outgrowth when bound to a component of the injury-induced milieu, tenascin-C. This project aimed to increase integrin expression within the CNS using induced pluripotent stem cell-derived human neural progenitor cells (iPSC-hNPCs). Using immunocytochemistry and western blotting, endogenous integrin expression within iPSC-hNPCs was determined. In addition, overexpression of α9 integrin was achieved using transfection and lentiviral transduction. The capacity of wild type (WT) and α9-hNPCs to extend neurites on tenascin-C was assessed using neurite outgrowth assays. Results revealed increasing α9 integrin expression in hNPCs significantly promoted neurite outgrowth when cultured on tenascin-C. Interestingly, increasing the concentration of human tenascin-C, resulted in increasingly longer neurites from WT hNPCs suggesting hNPCs could actively upregulate integrin expression. Subsequently, WT and α9-hNPCs were transplanted into layer V of the neonatal rat sensorimotor cortex, which projects to the CST. WT and α9-hNPCs survived up to 8 weeks post-transplantation and produced projections along white matter tracts, including areas of the CST. Additionally, hNPCs retained α9-eYFP protein expression in vivo over time and was localised within axonal projections. These results highlight the capabilities of iPSC-hNPCs to promote integrin expression within the rodent CNS presenting one potential avenue to target neuronal replacement following spinal injury. Future research should focus on assessing the regenerative capacity of WT and α9-hNPCs within an injury model concentrating on the ability of these cells to adapt within an injured environment

    Investigating molecular mechanisms of neuronal regeneration: a microarray approach.

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    Injury to the peripheral nervous system (PNS) stimulates a finely regulated regenerative response that generally leads to some recovery of function. In contrast, the response to injury in the adult mammalian central nervous system (CNS) is abortive and adult CNS neurons do not normally regenerate. We used a microarray approach to identify putative regeneration-associated changes in gene expression in the L4 dorsal root ganglion (DRG) in rat models of PNS and CNS injury. Our models included crush injury to both branches of the bifurcating axon of sensory neurons with cell bodies in the DRG (DRGNs). Injury to the peripheral branch at the level of the spinal nerve (SN) results in axonal regeneration and reinnervation. Crush injury of the central branch in the dorsal root (DR) results in active regeneration up to the point of CNS entry at the DR entry zone (DREZ) and subsequent arrest of further growth, while transection injury within the CNS at the level of the dorsal columns (DC) results in abortive and unsuccessful regeneration attempts. These DRGN injury models therefore allowed us to compare the gene expression programmes elicited during active, arrested and abortive regeneration. Following a pilot microarray experiment to optimize experimental parameters and tract tracing and electrophysiological experiments to confirm time points for harvest of DRGs after DR and SN injury, respectively, male Sprague-Dawley rats underwent an L4 SN crush, an L4 DR crush or a bilateral DC transection at the L3/L4 spinal segment boundary. L4 DRGs were collected at 2 weeks (active regeneration) and 6 weeks (arrested regeneration) after DR crush. DRGs were harvested at 6 weeks after SN crush and 2 weeks after DC transection. DRGs harvested from naïve rats served as a control group. Microarray analysis (Affymetrix Rat genome 230 2.0 array) identified several hundred genes showing differential expression (5% FDR) in comparisons of regenerating with non-regenerating conditions. Selected genes were chosen for validation by qRT-PCR. These genes could represent putative regeneration-associated genes and may suggest novel therapeutic interventions to encourage regeneration of the spinal cord following injury. Additionally, we have identified genes upregulated in the DR active regeneration state relative to DR arrested state, which have relevance to root avulsion injury and may provide insight into the mechanisms that prevent regeneration of DR axons through the DREZ to re-enter the spinal cord. We also present evidence that a transcriptional programme consistent with regeneration is mounted within the DRG following DC transection. This lends support to the idea that CNS neurons have intrinsic regenerative capability and that manipulations of the CNS environment may be sufficient to permit regeneration of CNS axons
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