Global ETD Search

401	Dissection moléculaire de l’interaction de la DNA topoisomérase I avec la matrice extracellulaire et les fibroblastes Beauchemin, Karine 06 1900 (has links) La sclérose systémique est une maladie autoimmune dont l’une des complications majeures est la fibrose. La DNA topoisomérase I (topo) est l’un des principaux autoantigènes associés à cette maladie. Toutefois, aucun lien n’a encore pu être établi entre la présence des anti-topo et le développement de la fibrose. Les travaux antérieurs du laboratoire d’accueil ont montré une interaction directe de la topo avec la surface des fibroblastes et la matrice extracellulaire. Nous avons voulu caractériser ces interactions du point de vue moléculaire. La topo a donc été exprimée sous forme de 5 fragments, déterminés à partir de ses principaux domaines structuraux et de ses épitopes majeurs, chez E. coli. Les fragments purifiés ont été analysés pour leur interaction avec l’héparine, représentant les héparane sulfates de la surface des fibroblastes, et avec des protéines purifiées de la matrice extracellulaire. Nous avons montré que le fragment topo-N est le principal responsable de l’interaction avec l’héparine, ce qui suggère donc l’implication potentielle de ce domaine dans l’interaction de la topo avec la surface des fibroblastes. Le fragment topo-DIDII est responsable de l’interaction avec la plupart des protéines de la matrice extracellulaire étudiées, alors que le fragment topo-H15 n’interagit qu’avec la vitronectine. Aucune interaction des fragments topo-DIII et topo-C n’a été décelée. Ces résultats pourront maintenant servir à mieux comprendre le rôle potentiel de la topo et des autoanticorps circulants anti-topo dans la fibrose présente chez les personnes atteintes de sclérose systémique en contribuant à l’identification de la cible de la topo sur les fibroblastes. / Systemic sclerosis is an autoimmune disease in which one of the major complications is fibrosis. DNA topoisomerase I (topo) is a major autoantigen associated with this disease. However, no link has yet been established between the presence of anti-topo and the development of fibrosis. Previous work of the host laboratory showed a direct interaction of the topo with the surface of fibroblasts and extracellular matrix. We wanted to characterize these interactions at the molecular level. Topo was expressed in 5 fragments, determined from its main structural domains and its major epitopes, in E. coli. The purified fragments were analyzed for their interaction with heparin, representing heparan sulfates on the surface of fibroblasts, and with purified proteins of the extracellular matrix. We have shown that the topo-N fragment is responsible for interaction with heparin, suggesting hence, potential involvement of this domain in the interaction of topo with the surface of fibroblasts. The topo-DIDII fragment is responsible for the interaction with most proteins of the extracellular matrix studied, whereas the topo-H15 fragment only binds to vitronectin. No interaction of fragments topo-DIII and topo-C was found. These results can now be used to better understand the potential role of topo and circulating anti-topo autoantibodies in the fibrosis present in patients with systemic sclerosis in helping to identify the target of topo on fibroblasts. Sclérose systémique Systemic sclerosis ADN topoisomérase I DNA topoisomerase I Fibroblaste Fibroblast Matrice extracellulaire Extracellular matrix Autoanticorps Autoantibodies
402	Lipid Modified Polymers for Transfection of Human CRL Fibroblasts, and for siRNA Mediated MDR Reversal in Melanoma Cancer Therapy Abbasi Dezfouli, Meysam Unknown Date No description available. Plasmid DNA Polymer Transfection Fibroblast P-glycoprotein Melanoma Cancer Multidrug Resistance siRNA Non Viral Gene Delivery In Vivo Gene Delivery Chemotherapy Doxorubicin Paclitaxel SCID Mice Tumor
403	Regulation of collagen type I production by ionizing radiation and transforming growth factor-β1 in primary human skin fibroblasts derived from early stage breast cancer patients in relation to acute radiation-induced toxicity Wang, Ying Wang Unknown Date No description available. Collagen type I Fibroblast Radiation Breast Cancer Transforming growth factor Radiation Therapy Vascular endothelial growth factor Matrix metalloproteinase Tissue inhibitor of metalloproteinase Cathepsin K
404	Contribution de l’hypoxie et du facteur hif1a à la guérison cutanée chez le cheval Deschene, Karine 08 1900 (has links) Le cheval est souvent victime de plaies traumatiques, dont la guérison est fréquemment problématique, et ce, principalement quand la plaie survient sur le membre. Il est courant de voir chez le cheval le développement d’un tissu de granulation exubérant ou « bouton de chair », qui mène à une cicatrisation excessive due à la surproduction de tissu fibreux. Ce tissu cicatriciel, non épithélialisé, est caractérisé par une occlusion au niveau de la microcirculation due à l’hypertrophie des cellules endothéliales, qui laisse supposer la présence d’hypoxie tissulaire. Une hypoxie relative a effectivement été mesurée par spectroscopie dans le proche infrarouge au niveau des plaies appendiculaires prédisposées au développement de tissu de granulation exubérant, par rapport aux plaies corporelles. De plus, une étude thermographique a révélé un patron spatial similaire de la perfusion. Au niveau moléculaire, la littérature rapporte que le facteur de transcription «hypoxia inducible factor» (HIF) est à l’origine de plusieurs changements dans les niveaux d’expression de divers gènes régulés par l’hypoxie. L’objectif du présent projet de recherche était de définir la contribution de l’hypoxie à la guérison cutanée chez le cheval. Le premier volet (in vivo) du projet visait à mesurer l’expression protéique temporelle du HIF1A dans des échantillons tissulaires en provenance de plaies cutanées guérissant normalement et d’autres développant une cicatrisation excessive, selon divers sites anatomiques (tronc, membre). Les résultats obtenus suggèrent que la mesure de HIF1A, dans les échantillons pluricellulaires de cette étude, reflète l’épithélialisation de la plaie plutôt que les niveaux d’oxygène tissulaire. En effet, le HIF1A semble réguler l’homéostasie et la prolifération des kératinocytes. Le second volet (in vitro), consistait en la mise en culture de fibroblastes dermiques équins provenant du tronc ou du membre, en condition de normoxie ou d’hypoxie (à 1% d’O2 ou à l’aide d’un mimétique, le CoCl2) afin d’en étudier le comportement (capacités de prolifération et de synthèse protéique). Les résultats obtenus soutiennent une contribution de l’hypoxie à la cicatrisation extensive chez le cheval puisque l’hypoxie favorise la prolifération des fibroblastes en plus d’encourager la synthèse de collagène de type 1 et de diminuer la synthèse de la métalloprotéinase de type 2. Les changements observés semblent dépendre de facteurs extrinsèques (environnementaux) car les fibroblastes dermiques se comportent de façon similaire indépendamment de la provenance anatomique. En somme, les deux volets de l’étude ont permis d’élucider une part des mécanismes sous-jacents à la formation du tissu de granulation exubérant lors de guérison cutanée chez le cheval. La poursuite des recherches dans ce domaine mènera à une meilleure compréhension de la pathologie et ainsi, permettra de développer des méthodes de traitement spécifiques à la condition. / The horse is often victim of traumatic wounds for which healing can be problematic, mainly when the wound occurs on the limb. The development of exuberant granulation tissue, also known clinically as “proud flesh”, leads to extensive scarring characterized by overproduction of fibrous tissue and the absence of an epithelial cover. This scar tissue suffers from occlusion of the microcirculation within the residual granulation tissue, due to endothelial cell hypertrophy, suggesting tissue hypoxia. The presence of relative hypoxia in limb wounds of horses was recently confirmed using near infrared spectroscopy. Additionally, thermography showed decreased perfusion in limb wounds. Abundant literature incriminates "hypoxia inducible factor” (HIF) in the regulation of expression of a number of genes in response to hypoxia. The overall objective of this research project was to define the contribution of hypoxia to problematic wound healing in horses. The first phase of the project (in vivo) aimed to measure the temporal expression of HIF1A protein in tissue samples taken from skin wounds healing normally and others developing exuberant granulation tissue and subsequent extensive scarring, according to various anatomical sites (trunk, limb). Results suggest that the expression of HIF1A within the pluricellular tissue samples of this study reflects wound epithelialization rather than tissue oxygen levels. Indeed, HIF1A appears to regulate the homeostasis and proliferation of skin keratinocytes. The second phase of the project (in vitro) consisted in the culture of equine dermal fibroblasts from the body or the limb, under conditions of normoxia or hypoxia (1% O2 or using a mimetic, CoCl2) in an effort to study their behavior (proliferation and protein synthesis). Results corroborate the contribution of hypoxia to over-scarring in the horse since hypoxia promotes both the proliferation of dermal fibroblasts and the synthesis of collagen type 1 while decreasing the synthesis of matrix metalloproteinase 2. Extrinsic factors (environmental) appear to govern the behavior of equine dermal fibroblasts since these cells behave similarly regardless of their anatomic origin (body or limb). In summary, the two phases of the study contributed to the elucidation of a portion of the mechanisms underlying the development of exuberant granulation tissue during wound healing in horses. Further research in this area will provide a better understanding of the pathology and thus aid in the design and development of targeted therapies. Cheval Guérison tissulaire Hypoxie HIF1A Fibroblaste Kératinocyte Matrice extracellulaire Horse Wound healing Hypoxia HIF1A Fibroblast Keratinocyte Extracellular matrix
405	Apoptosis and caspase-3 activity in isolated fetal rat lung cells, human A549 cells and rat periodontal ligament fibroblasts following exposure to cigarette smoke extract Ahmed, Asra 26 March 2012 (has links) Exposure cigarette smoke (CS) during prenatal life is the leading cause of preventable premature death. In this study, we explored the hypothesis that in vitro exposure of fetal lung cells to cigarette smoke extract (CSE) may result in the alteration of apoptosis through activation of caspase-3. Alongside we compared the responses of fetal lung cells with A549 cells and rat periodontal ligament (PDL) fibroblasts exposed to CSE in a dose dependent manner. Caspase-3 activity and inhibition was measured using a fluorometric assay. Cell viability in smoke exposed cells was measured using MTT formazan assay. Caspase-3 expression and cellular localization was detected by western blot analysis and immunofluorescence. Our results indicate that caspase-3 activity was significantly (p < 0.05) elevated and cell viability was significantly inhibited in fetal rat lung cells exposed to 10% or 15 % (v/v) CSE. No significant differences were observed in the caspase-3 activity or cellular viability in A549 cells and rat PDL fibroblasts exposed to 5%, 10% or 15% (v/v) CSE. Activation of caspase-3 in fetal lung connective tissue and alveolar epithelial cells may be one of the reasons for the developmental pulmonary toxicity induced by CSE. Lung development Cigarette smoke extract Caspase-3 Apoptosis Maternal smoking Type II alveolar epithelial cells Fetal lung fibroblasts Periodontal ligament fibroblast
406	Exploiting and exploring the interactions between microRNA-122 and Hepatitis C virus 2014 September 1900 (has links) Hepatitis C virus (HCV) is a single-stranded plus-sense RNA virus that is transmitted by blood-to-blood contact, and infects the human liver. HCV has a unique dependence on the liver-specific microRNA miR-122, where miR-122 binds the 5´ un-translated region of the viral RNA at two tandem sites and increases viral RNA abundance. The mechanisms of augmentation are not yet fully understood, but the interaction is known to stabilize the viral RNA, increase translation from the viral internal ribosomal entry site (IRES), and result in increased viral yield. In an attempt to create a small animal model for HCV, we added miR-122 to mouse cell lines previously thought non-permissive to HCV, which rendered these cells permissive to the virus, additionally showing that miR-122 is one of the major determinants of HCV hepatotropism. We found that some wild-type and knockout mouse cell lines – NCoA6 and PKR knockout embryonic fibroblasts – could be rendered permissive to transient HCV sub-genomic, but not full-length, RNA replication upon addition of miR-122, and that other wild-type and knockout cell lines cannot be rendered permissive to HCV replication by addition of miR-122. These knockout cell lines demonstrated varying permissiveness phenotypes between passages and isolates and eventually completely lost permissiveness, and we were unable to achieve sub-genomic RNA replication in PKR knockout primary hepatocytes. Knockdown of NCoA6 and PKR in Huh7.5 cells did not substantially impact sub-genomic replication, leading us to conclude that there are additional factors within the cell lines that affect their permissiveness for HCV replication such as epigenetic regulation during passage or transformation and immortalization. We also added miR-122 to Hep3B cells, a human hepatoma cell line lacking expression of miR-122 and previously thought to be non-permissive to HCV replication. Added miR-122 rendered the cells as highly permissive to HCV replication as the Huh7-derived cell lines commonly used to study the virus. In these cells, we were also able to observe miR-122-independent replication of sub-genomic HCV RNA. This was verified by use of a miR-122 antagonist that had no impact on the putative miR-122-independent replication, and by mutating the miR-122 binding sites to make them dependent on a single nucleotide-substituted microRNA. This replication in the absence of miR-122 was not detected in full-length HCV RNA, but was detectable using a bi-cistronic full-length genomic replicon, suggesting that the addition of a second IRES in sub-genomic and full-genomic replicons altered replication dynamics enough to allow detectable RNA replication without miR-122 binding. Because miR-122 has been implicated in protecting the viral RNA from destabilization and degradation by Xrn1, the main cytoplasmic 5´ to 3´ RNA exonuclease, we employed our miR-122-independent system to test this miR-122-mediated protection. We verified that miR-122 functions to protect the viral RNA from Xrn1, but this was insufficient to account for the overall impact of miR-122 on replication, meaning that miR-122 has further functions in the virus’ life cycle. We showed that the effect of miR-122 on translation is due to stabilization of the RNA by protecting it from Xrn1, through binding at both sites. We further evaluated the role of each miR-122 binding site (S1 and S2) in the virus life cycle, and found that binding at each site contributes equally to increasing viral RNA replication, while binding at both sites exerts a co-operative effect. Finally, we determined that binding of miR-122 at site S2 is more important for protection from Xrn1, suggesting that miR-122 binding at S1 is more important for the additional functions of miR-122 in enhancing HCV RNA accumulation. Altogether, we have shown that miR-122 is partially responsible for the hepatotropic nature of Hepatitis C virus, and that supplementation with this microRNA can render non-permissive cells permissive to viral replication. We have also identified and confirmed replication of both sub-genomic and full-length HCV RNA in the absence of miR-122. Finally, we have characterized the impact of the host RNA exonuclease Xrn1 on the HCV life cycle, and determined the roles of each miR-122 binding site in shielding the viral RNA from this host restriction factor. Hepatitis C virus HCV microRNA miR-122 Hep3B murine embryonic fibroblast MEF virus-host interactions animal model model system Xrn1 virus replication
407	Apoptosis and caspase-3 activity in isolated fetal rat lung cells, human A549 cells and rat periodontal ligament fibroblasts following exposure to cigarette smoke extract Ahmed, Asra 26 March 2012 (has links) Exposure cigarette smoke (CS) during prenatal life is the leading cause of preventable premature death. In this study, we explored the hypothesis that in vitro exposure of fetal lung cells to cigarette smoke extract (CSE) may result in the alteration of apoptosis through activation of caspase-3. Alongside we compared the responses of fetal lung cells with A549 cells and rat periodontal ligament (PDL) fibroblasts exposed to CSE in a dose dependent manner. Caspase-3 activity and inhibition was measured using a fluorometric assay. Cell viability in smoke exposed cells was measured using MTT formazan assay. Caspase-3 expression and cellular localization was detected by western blot analysis and immunofluorescence. Our results indicate that caspase-3 activity was significantly (p < 0.05) elevated and cell viability was significantly inhibited in fetal rat lung cells exposed to 10% or 15 % (v/v) CSE. No significant differences were observed in the caspase-3 activity or cellular viability in A549 cells and rat PDL fibroblasts exposed to 5%, 10% or 15% (v/v) CSE. Activation of caspase-3 in fetal lung connective tissue and alveolar epithelial cells may be one of the reasons for the developmental pulmonary toxicity induced by CSE. Lung development Cigarette smoke extract Caspase-3 Apoptosis Maternal smoking Type II alveolar epithelial cells Fetal lung fibroblasts Periodontal ligament fibroblast
408	In Vitro and In Vivo Studies with Measles Virus and its Interaction with the Mouse Innate Immune System Ha, Michael Neul 21 August 2012 (has links) Measles is one of the most contagious diseases known to mankind. Despite the availability of a safe and effective vaccine, approximately 164,000 measles-related deaths were recorded in 2008. The inherent restricted host tropism of MV means that the development of authentic rodent models will be a valuable research tool in testing new vaccines and antivirals. In addition to the receptor requirement, mouse innate immunity has been shown to inhibit MV growth. In this thesis, the contributions of several key components of the mouse innate immune system on the inhibition of MV replication were examined. The transcription factor interferon regulatory factor 3 (IRF3), which normally plays a key role in mediating innate immune signaling, contributed relatively little in inhibiting MV replication both in vitro and in vivo. In contrast, the JAK/STAT pathway and the double-stranded RNA inducible protein kinase, PKR, played more important roles in controlling virus replication. The resurgence of measles in areas where the virus was once thought to be eradicated makes the development of anti-MV treatments essential. Concurrent to the development of an animal model to better study its pathogenesis, we wanted to look at the effect of MV inhibitors on its replication. The MV fusion inhibitor, carbobenzoxy-D-phenylalanine-L-phenylalanine-glycine (ZfFG), was developed in the past to study fusion; however, its mechanism of action has not yet been elucidated. To examine this, spontaneous ZfFG-resistant mutants were generated and characterized. Mutations were found in the HRB region of the fusion (F) protein, and when these were modeled using published paramyxovirus F crystal structures, data suggested that ZfFG targeted a small pocket present between the head and stalk regions of its pre-fusion conformation. An authentic mouse model of measles developed from findings in this study may allow for in vivo efficacy testing of ZfFG in the future. molecular biology virology paramyxovirus measles innate immunity mouse models transgenic mouse fusion fusion inhibitor FIP IRF3 microbiology ZfFG plasmacytoid dendritic cell mouse embryonic fibroblast receptor 0720
409	In Vitro and In Vivo Studies with Measles Virus and its Interaction with the Mouse Innate Immune System Ha, Michael Neul 21 August 2012 (has links) Measles is one of the most contagious diseases known to mankind. Despite the availability of a safe and effective vaccine, approximately 164,000 measles-related deaths were recorded in 2008. The inherent restricted host tropism of MV means that the development of authentic rodent models will be a valuable research tool in testing new vaccines and antivirals. In addition to the receptor requirement, mouse innate immunity has been shown to inhibit MV growth. In this thesis, the contributions of several key components of the mouse innate immune system on the inhibition of MV replication were examined. The transcription factor interferon regulatory factor 3 (IRF3), which normally plays a key role in mediating innate immune signaling, contributed relatively little in inhibiting MV replication both in vitro and in vivo. In contrast, the JAK/STAT pathway and the double-stranded RNA inducible protein kinase, PKR, played more important roles in controlling virus replication. The resurgence of measles in areas where the virus was once thought to be eradicated makes the development of anti-MV treatments essential. Concurrent to the development of an animal model to better study its pathogenesis, we wanted to look at the effect of MV inhibitors on its replication. The MV fusion inhibitor, carbobenzoxy-D-phenylalanine-L-phenylalanine-glycine (ZfFG), was developed in the past to study fusion; however, its mechanism of action has not yet been elucidated. To examine this, spontaneous ZfFG-resistant mutants were generated and characterized. Mutations were found in the HRB region of the fusion (F) protein, and when these were modeled using published paramyxovirus F crystal structures, data suggested that ZfFG targeted a small pocket present between the head and stalk regions of its pre-fusion conformation. An authentic mouse model of measles developed from findings in this study may allow for in vivo efficacy testing of ZfFG in the future. molecular biology virology paramyxovirus measles innate immunity mouse models transgenic mouse fusion fusion inhibitor FIP IRF3 microbiology ZfFG plasmacytoid dendritic cell mouse embryonic fibroblast receptor 0720
410	Lipid Modified Polymers for Transfection of Human CRL Fibroblasts, and for siRNA Mediated MDR Reversal in Melanoma Cancer Therapy Abbasi Dezfouli, Meysam 11 1900 (has links) Gene delivery for therapeutic purposes is quickly emerging as the best potential treatment option for inherited genetic diseases and cancer. Viral gene carriers have been the choice for this purpose due to their high efficiency, but harmful immunogenic and oncogenic host reactions have limited their in vivo use. Cationic polymers provide a safe alternative to viral carriers as they can be engineered to reduce immunogenic and toxic responses and serve therapeutic purposes in the body. Due to their strong positive charge, they are able to compact the negatively charged nucleotides to small nano-sized particles appropriate for cellular uptake. Additionally, they efficiently encapsulate the highly sensitive nucleotides, and protect them against degradation by the nucleases present at the physiological milieu. In this thesis work, I have used a novel approach for gene delivery by combining the critical properties of a cationic polymer (i.e., nucleotide condensing ability) with that of a fatty acid (i.e., lipid membrane compatibility). The resulting lipid modified polymer increased delivery of our gene of interest into target cells and resulted in increased siRNA delivery for cancer gene therapy. / Biomedical Sciences Plasmid DNA Polymer Transfection Fibroblast P-glycoprotein Melanoma Cancer Multidrug Resistance siRNA Non Viral Gene Delivery In Vivo Gene Delivery Chemotherapy Doxorubicin Paclitaxel SCID Mice Tumor

Search results