Global ETD Search

721	Expression du facteur de transcription SRF chez les chevaux atteints de souffle Guérin-Montpetit, Karine 08 1900 (has links) Il a été démontré que les chevaux atteints du souffle présentent une augmentation de la masse de muscle lisse entourant les voies respiratoires comparativement à des chevaux sains (Herszberg, Ramos-Barbon et al. 2006, Leclere, Lavoie-Lamoureux et al. 2011). L’augmentation de la masse de muscle lisse ainsi observée résulte d’une hyperplasie, et possiblement, d’une hypertrophie des myocytes. Les traitements usuels du souffle ne sont que partiellement efficaces à diminuer cette augmentation. L’objectif de cette étude était d’explorer les mécanismes moléculaires impliqués dans ces changements affectant la cellule musculaire lisse dans la pathologie du souffle chez le cheval. Pour ce faire, nous avons examiné les effets d’une exposition antigénique sur l’expression du «Serum Response Factor» (SRF) dans le muscle lisse bronchique. Le SRF est un facteur de transcription localisé dans le noyau de la cellule musculaire lisse et régulant l’expression génique de celle-ci en favorisant un phénotype prolifératif ou contractile. Les résultats démontrent qu’avant exposition antigénique, les pourcentages de cellules exprimant le SRF sont faibles. Une augmentation significative du pourcentage de myocytes exprimant le SRF survient suite à une stimulation antigénique chez les chevaux atteints de souffle alors qu’aucune augmentation n’est observée chez les chevaux contrôles. Ces résultats suggèrent que le SRF pourrait contribuer au remodelage du muscle lisse péribronchique dans la pathologie du souffle. / Previous studies have shown that heaves-affected horses, when compared to age-matched control horses, have an increased smooth muscle mass surrounding their airways (Herszberg, Ramos-Barbon et al. 2006, Leclere, Lavoie-Lamoureux et al. 2011). Also, it is shown that hyperplasia, and possibly hypertrophy, contribute to this finding. Current therapies are only partially effective at reversing this finding. The goal of this study was to explore the molecular pathways involved in airway smooth muscle remodelling during heaves. We studied the Serum Response Factor (SRF), a nuclear transcriptional factor that controls gene expression in the smooth muscle cell and favour either a proliferative or a contractile phenotype. The results show that before antigenic exposition, the percentage of cells expressing SRF is low. A significant increase in the percentage of SRF-expressing myocytes occurs after antigenic stimulation in heaves-affected horses whereas no increase is observed in control subjects. These results suggest that the transcription factor SRF may contribute to airway smooth muscle remodeling in heaves-affected horses. muscle lisse souffle remodelage des voies respiratoires SRF facteur de transcription smooth muscle heaves airway remodeling transcription factor
722	Exploration du rôle du fragment LG3 sur les cellules souches mésenchymateuses dans le contexte du rejet vasculaire Pilon, Eve-Annie 09 1900 (has links) La vasculopathie du greffon est une pathologie caractérisée par un rétrécissement progressif et oblitérant des vaisseaux sanguins menant à une ischémie et une perte de fonction du greffon. Le rétrécissement vasculaire est dû à une accumulation de matrice extracellulaire (MEC) et de cellules mononuclées positives pour l’actine musculaire lisse alpha (alphaSMA) dont les cellules souches mésenchymateuses, le tout formant une néointima oblitérante. Cette pathologie est la cause principale de la perte des greffons rénaux et cardiaques à long terme. Le rejet vasculaire aigu est un prédicteur de la vasculopathie du greffon. L’équipe du Dr Hébert a démontré que l’apoptose endothéliale, qui joue un rôle important dans le développement du rejet vasculaire, initie la libération de LG3, un fragment du protéoglycan perlécan. Les taux sanguins et urinaires de LG3 sont augmentés chez les receveurs d’allogreffe rénale avec rejet vasculaire et vasculopathie du greffon. Les résultats obtenus en laboratoire durant ma maîtrise ont permis de mieux caractériser l’impact du LG3 sur un type cellulaire important participant à la formation de néointima : les cellules souches mésenchymateuses. Mes travaux ont démontré que le LG3 induit à la fois la migration horizontale des MSC et la transmigration des MSC. Cette migration est dépendante de la voie de signalisation d’ERK1/2, précédemment identifiée comme voie centrale dans la formation de néointima. De plus, nos résultats démontrent que la kinase Src est activée en amont de l’activation de la voie MAPK. La migration horizontale et la transmigration induites par le LG3 sont aussi dépendantes des intégrines alpha2beta1, ainsi que l’activation de la voie MAPK. Dans un modèle de transplantation murin, nous avons également démontré que l’injection sérique de LG3 recombinant favorise l’accumulation de cellules positives pour alphaSMA dans la néointima. En outre, lorsque le receveur est déficient pour l’intégrine alpha2, mais que le greffon est sauvage, la formation de néointima induite par l’injection de LG3 est diminuée dans le greffon suggérant que les cellules du receveur jouent un rôle important dans la formation de la néointima. Enfin, nous avons démontré que l’injection de LG3 augmente aussi le nombre de cellules positives pour la forme phosphorylée d’ERK1/2 (p-ERK1/2) dans la néointima du greffon et que cette accumulation est dépendante de la présence des intégrines 2 1 chez les cellules du receveur.Lorsque le receveur est sauvage, il y a une augmentation du nombre de cellules positives pour p-ERK1/2. L’investigation de ces mécanismes dans le remodelage vasculaire expose de nouvelles opportunités pour inhiber la réponse cellulaire qui mène au remodelage inadapté lors d’un dommage vasculaire chronique et ainsi prolonger la survie du greffon. / Graft vasculopathy is diseases characterized by a progressive and obliterate narrowing of the blood vessels leading to ischemia and loss of graft function. This vascular narrowing is due to an accumulation of extracellular matrix and mononuclear cells positive for alpha smooth muscle actin (alphaSMA) including mesenchymal stem cells, thus forming an occlusive neointima. This condition is the leading cause of long term loss of kidney and heart transplants. Acute vascular rejection is a predictor of graft vasculopathy. Dr. Hébert’s team has demonstrated that endothelial apoptosis, which plays an important role in the development of vascular rejection, initiates the release of LG3, a fragment of the proteoglycan perlecan. Blood and urine levels of LG3 are increased in renal allograft recipients with vascular rejection and graft vasculopathy. The results obtained in the laboratory during my Master have helped to better characterize the impact of LG3 on an important cell type involved in neointima formation: the mesenchymal stem cells. My work has shown that the LG3 induces both the horizontal migration and the transmigration of MSC. This migration is ERK1/2-dependent, previously identified as a key molecule involved in neointima formation. In addition, our results demonstrate that Src kinase is activated by upstream activation of the MAPK pathway. Horizontal migration and transmigration induced by LG3 are also dependent on alpha2beta1 integrins, and the activation of the MAPK pathway. In a murine transplantation model, we also demonstrated that intravenous injection of recombinant LG3 promotes the accumulation of alphaSMA positive cells in the neointima. In addition, when the recipient is deficient for the alpha2 integrin but the graft is wild type, LG3 fails to induce neointima formation in the graft suggesting that recipient cells play an important role in the neointima formation. Finally, we demonstrated that intravenous injection of LG3 also increases the number of positive cells for the phosphorylated form of ERK1/2 (p-ERK1/2) in the neointima. This accumulation is dependent on the presence of alpha2beta1 integrins on recipient cells: when the recipient is wild type, there is an increase in the number of cells positive for p-ERK1/2.The investigation of these mechanisms in vascular remodeling presents new opportunities to inhibit the cellular response that leads to inadequate remodeling during chronic vascular damage and prolong graft survival. LG3 Cellule souche mésenchymateuse Migration Intégration Remodelage vasculaire Néointima Mesenchymal stem cell LG3 Migration Homing Vascular remodeling Neointima
723	High Resolution study of NF-kB - DNA Interactions Lone, Imtiaz Nisar 14 February 2013 (has links) (PDF) In this thesis we have attempted to study four basic aspects of DNA-protein interactions: Affinity, specificity, accessibility and kinetics. With NF-kB as our model transcription factor, we wanted to investigate how a particular dimer recognizes a specific binding sequence? How fast are these interactions? And finally, how does the NF-kB interact with it binding site in the chromatin context? Specificity of NF-kB-DNA interactions has recently come into focus after it was shown that these dimers can bind to the sequences which do not fall into the NF-kB general consensus motif. We studied seven such sequences for their specificity for four NF-kB dimers. Our results show that p50 homodimers are least discriminative and can bind specifically to all these sequences. While as, RelA homodimers were highly discriminative and did not bind to most of these nontraditional sequences. We used two different methods to measure binding affinities: traditional gel mobility shift assay (EMSA) and a novel technique called as UV laser footprinting. Our results show that UV laser footprinting is the better method to determine the binding constants.For studying the dynamics of NF-kB-DNA binding, we combined UV laser footprinting with stopped flow device. This combination, not only give us one base pair resolution but also milli-second time resolution. Using p50 homodimers as a model transcription factor, we showed that the binding of this factor follows a two-step mechanism. First step involves the fast recognition of the sequence and second step follows a slower kinetics most likely for the stabilization of the complex. Our experiments suggest that flanking sequences play a role in the recognition and stabilization process of the complex formation.Finally, we also studied the accessibility of nucleosomes to NF-kB. Our in vitro data sheds light on the in vivo requirements for the alterations in chromatin structure necessary for the productive binding of NF-kB. These include either a removal of H2A-H2B dimers from the nucleosome and/or chromatin remodeler induced relocation of the histone octamer.Our data sheds light on the in vivo requirements for the alterations in chromatin structure necessary for the productive binding of NF-kB. We hypothesize that some factors like PU.1 might be able to target the chromatin remodeling/dimer eviction machinery to particular nucleosomes and lead to productive binding of NF-kB. NF-kB Chromatin Histone H1 UV laser footprinting Specific binding Nucleosome remodeling Dimer eviction
724	Characterization and Modeling of the Remodeling Process that Occurs in Modular Tissue Engineered Constructs Assembled Within Microfluidic Perfusion Chambers Khan, Omar 31 August 2011 (has links) Using a modular approach, a vascularized tissue construct is created by embedding functional cells within submillimeter-sized collagen cylinders (modules) while the outside surfaces are seeded with endothelial cells (EC). The void spaces created by randomly packing modules into a container form EC-lined perfusion channels. Upon implantation, the tissues are remodeled by and integrated into the host and experience, to some degree, immune and inflammatory responses. This work utilized microfluidic techniques to study and model the tissue remodeling in vitro in the absence of the host response. When the construct’s tortuous perfusion channels were reproduced in poly(dimethylsiloxane) microfluidic devices and lined with EC, perfusion at higher flow rates reduced EC activation and maintained the desired quiescent EC phenotype. When applying these results to collagen constructs, higher flow rates were not achievable due to the weak mechanical properties of collagen. To increase the collagen’s mechanical strength, a semi-synthetic collagen/poloxamine-methacrylate hydrogel was examined but due to its heterogeneous surface composition, there was inadequate EC attachment and the material was deemed unsuitable for this application. Proceeding with lower flow rates, tissues assembled within microfluidic perfusion chambers from EC-seeded collagen modules showed that over the course of 24 hours, perfusion did not significantly increase activation but instead increased KLF2 expression, a transcription factor involved in the establishment of EC quiescence, and disrupted VE-cadherin bonds between adjacent EC. However, after 1 week of perfusion, the majority of EC were lost. To ameliorate this loss, mesenchymal stromal cells (MSC) were embedded within the modules in order to take advantage of their anti-apoptotic and immunomodulation effects. The MSC temporarily mitigated the loss of the EC but did not prevent it. They did, however, take on a phenotype similar to smooth muscle cells and migrated towards the EC. Perhaps this indicates that the combination of EC, MSC and perfusion drives the creation and assembly of pseudo vessels. Together, the microfluidic techniques used in this study to assemble and perfuse modular tissues revealed new insights into the remodeling process and exposed critical issues surrounding the adaptation of the EC to the combination of perfusion, remodeling and changing flow fields. tissue engineering microfluidics perfusion endothelial cells mesenchymal stromal cells activation differentiation remodeling model collagen poloxamine activation shear stress disturbed flow vascular modular 0541 0542
725	Characterization and Modeling of the Remodeling Process that Occurs in Modular Tissue Engineered Constructs Assembled Within Microfluidic Perfusion Chambers Khan, Omar 31 August 2011 (has links) Using a modular approach, a vascularized tissue construct is created by embedding functional cells within submillimeter-sized collagen cylinders (modules) while the outside surfaces are seeded with endothelial cells (EC). The void spaces created by randomly packing modules into a container form EC-lined perfusion channels. Upon implantation, the tissues are remodeled by and integrated into the host and experience, to some degree, immune and inflammatory responses. This work utilized microfluidic techniques to study and model the tissue remodeling in vitro in the absence of the host response. When the construct’s tortuous perfusion channels were reproduced in poly(dimethylsiloxane) microfluidic devices and lined with EC, perfusion at higher flow rates reduced EC activation and maintained the desired quiescent EC phenotype. When applying these results to collagen constructs, higher flow rates were not achievable due to the weak mechanical properties of collagen. To increase the collagen’s mechanical strength, a semi-synthetic collagen/poloxamine-methacrylate hydrogel was examined but due to its heterogeneous surface composition, there was inadequate EC attachment and the material was deemed unsuitable for this application. Proceeding with lower flow rates, tissues assembled within microfluidic perfusion chambers from EC-seeded collagen modules showed that over the course of 24 hours, perfusion did not significantly increase activation but instead increased KLF2 expression, a transcription factor involved in the establishment of EC quiescence, and disrupted VE-cadherin bonds between adjacent EC. However, after 1 week of perfusion, the majority of EC were lost. To ameliorate this loss, mesenchymal stromal cells (MSC) were embedded within the modules in order to take advantage of their anti-apoptotic and immunomodulation effects. The MSC temporarily mitigated the loss of the EC but did not prevent it. They did, however, take on a phenotype similar to smooth muscle cells and migrated towards the EC. Perhaps this indicates that the combination of EC, MSC and perfusion drives the creation and assembly of pseudo vessels. Together, the microfluidic techniques used in this study to assemble and perfuse modular tissues revealed new insights into the remodeling process and exposed critical issues surrounding the adaptation of the EC to the combination of perfusion, remodeling and changing flow fields. tissue engineering microfluidics perfusion endothelial cells mesenchymal stromal cells activation differentiation remodeling model collagen poloxamine activation shear stress disturbed flow vascular modular 0541 0542
726	Mécanismes d'action des antioestrogènes totaux Hilmi, Khalid 04 1900 (has links) Le cancer du sein est le cancer qui a la plus forte fréquence au Canada. En 2012, on estime que 23 200 nouveaux cas de cancer du sein seront diagnostiqués. Deux tiers des tumeurs mammaires expriment ou surexpriment le récepteur des oestrogènes α (ERα). De même, les oestrogènes sont importants pour la croissance de ces tumeurs. La présence des récepteurs hormonaux est un critère qui détermine le choix de la thérapie; à cet égard, le ciblage des récepteurs des oestrogènes par les antioestrogènes a pour but d’inactiver ces récepteurs et diminuer leur contribution à la croissance tumorale. Les antioestrogènes sont des inhibiteurs compétitifs de ERα. Tamoxifene est le médicament le plus utilisé pour traiter les tumeurs mammaires ER+ de tous les stades, avant ou après la ménopause. Tamoxifene est antioestrogène partiel ou SERM qui a un profile mixte d’activités agonistes et antagonistes. Fulvestrant ou ICI 182, 780 est un antioestrogène de type total ou SERD dépourvu de toute activité agoniste. Ce composé est utilisé en clinique chez les femmes après la ménopause ayant des tumeurs mammaires avancées. Fulvestrant constitue, donc, une deuxième ligne thérapeutique en cas de rechute après à un traitement par Tamoxifene. Afin de comprendre le potentiel thérapeutique de Fulvestrant, il est primordial d’étudier son impact sur ERα. Actuellement, la polyubiquitination et la dégradation de ERα sont les mécanismes les plus connus pour expliquer l’inactivation de ERα par Fulvestrant. Par ailleurs, en utilisant des modèles cellulaires ER+ et ER-; nous avons montré que les antioestrogènes totaux induisent une insolubilité de ERα indépendamment de leur capacité à induire sa dégradation. L’insolubilité corrèle avec l’association de ERα avec la matrice nucléaire et avec l’inhibition de sa transactivation. L’hélice H12 du domaine de liaison du ligand joue un rôle important dans l’insolubilité et l’inactivation de ERα par les antioestrogènes totaux. Par ailleurs, les antioestrogènes totaux se distinguent par leur capacité à induire la SUMOylation de ERα par SUMO1 et SUMO2/3. La SUMOylation est rapide et précède la dégradation de ERα dans cellules ER+. À l’aide de dérivés de l’antioestrogène total ICI 164, 384, nous avons montré que la chaine latérale des antioestrogènes totaux est à la base de l’induction de la SUMOylation et de l’inactivation de ERα. De plus, la SUMOylation semble être une marque d’inhibition, car la déSUMOylation restaure une activité de ERα en présence des antioestrogènes totaux. L’hélice H12 du LBD et le domaine de liaison à l’ADN sont requis pour l’induction de la SUMOylation. La recherche de protéines impliquées dans l’inactivation et dans la SUMOylation a permis d’identifier le facteur de remodelage de la chromatine ACF dans le même complexe que ERα. De manière similaire à la SUMOylation, le recrutement de ACF est précoce et constitue une propriété spécifique des antioestrogènes totaux. D’autre part, Fulvestrant induit le recrutement de ACF au niveau du promoteur du gène cible des oestrogènes pS2, ce qui suggère une contribution du remodelage de la chromatine dans les mécanismes d’action des antioestrogènes totaux. La surexpression de la DéSUMOylase SENP1 abolit le recrutement de ACF ce qui indique un rôle de la SUMOylation dans le recrutement de ACF. De même, l’hélice H12 du LBD de ERα constitue un lien entre l’inactivation de ERα et le recrutement de ACF. L’insolubilité, la SUMOylation et l'interaction du complexe ACF sont le reflet des mécanismes d’action des antioestrogènes totaux. Ces observations peuvent être utilisées comme des critères fonctionnels pour identifier d’autres composés avec de meilleures propriétés pharmacologiques que Fulvestrant. / Approximately 70% of breast tumors express or overexpress estrogen receptor alpha (ERα) and are treated with antiestrogens (AEs), which act as competitive inhibitors of this receptor. Tamoxifen has been widely used for the treatment of ERα-positive tumors, but intrinsic or acquired resistance can lead to tumor recurrence. Full AEs such as Fulvestrant (ICI182, 780) are currently used to treat postmenopausal women with ERα-positive breast cancers with disease progression following Tamoxifen therapy. Unlike Tamoxifen and other Selective estrogen receptor modulators (SERMs), full AEs (SERDs) are devoid of any agonistic activity. It is currently thought that the capacity of full AEs to induce rapid polyubiquitination and degradation of ERα underlies their complete suppression of ERα signalling. On the one hand, we show a correlation between ICI 182, 780 induced ERα inhibition and its association with the insoluble fraction. This insolubility corresponds to an immobilization within the nuclear matrix and takes place in the absence of an accelerated turn over. The helix 12 in the ligand binding domain is important in the induction of insolubility and inactivation. On the other hand, we identify ERα as a target for Small Ubiquitin-like Modifier (SUMO) posttranslational modification by SUMO1 and SUMO2/3 specifically when liganded with full AEs. Induction of SUMOylation is rapid and precedes receptor degradation in ERα-positive breast cancer cells. On the other hand, the SERMs do not induce SUMOylation. The helix 12 in the ligand binding domain and the DNA binding domain play a role in the induction of SUMOylation in the presence of full AEs. Structure activity relationship experiments with full AE derivatives showed that the induction of SUMOylation is correlated with the degree of inhibition of ERα-mediated transcription. In addition, preventing SUMOylation by overexpression of a SENP1 deSUMOylase abolished the inverse agonist properties of full AEs without increasing activity in the presence of agonists or of Tamoxifen. In our attempt to screen for factors with a possible role in SUMOylation and inactivation, we show that the treatment with SERDs but not SERMs, induces a rapid interaction between ERα and the human ATP-utilizing chromatin assembly and remodeling factor (ACF) in ERα-negative and ERα-positive cell lines. The helix 12 is important since introducing single point mutations in this helix lead to an increased solubility and abrogate ACF recruitment. Using ChIP, we find an increase of ACF1 subunit association with proximal promoter of estrogen target gene pS2 suggesting a possible role of ACF in remodeling in this promoter. ACF recruitment is SUMOylation dependant since the overexpression of DeSUMOylase SENP1 abolishes the interaction between ERα and ACF. Together, induction of insolubility, SUMOylation and ACF recruitment are characteristic properties of full antiestrogens that contribute to their specific activity profile. They can be used to screen for new compounds with an improved therapeutic potential. Cancer du sein Breast cancer Récepteur des oestrogènes estrogen receptor SUMOylation Fulvestrant Remodelage de la chromatine chromatin remodeling antioestrogènes antiestrogens
727	Identification and characterization of novel secreted factors involved in bone remodeling Chim, Shek Man January 2009 (has links) [Truncated abstract] Bone remodeling is an important process to maintain mechanical integrity. It is accomplished by two important steps, bone resorption followed by new bone formation. Osteoclasts and osteoblasts are the principal cells in bone resorption and bone formation, respectively. A multitude of local and systemic factors regulates this process by controlling the cellular activities in bone remodeling compartments (BRC). An imbalance of osteoblastic bone formation and osteoclastic bone destruction will result in the development of skeletal diseases. Recent studies suggested that angiogenesis is closely associated with bone remodeling. The vasculature in bone is important for skeletal development, growth and repair. During endochondral ossification, cartilage is invaded by blood vessels which bring in osteoblast and osteoclast precursor cells, nutrients, growth factors and differentiation factors. During fracture repair, it has been demonstrated that mature osteoclasts produce heparanase which can degrade heparin sulfate proteoglycans, a major component in extracellular matrix (ECM). The process leads to the release of heparin-binding growth factors including vascular endothelial growth factor (VEGF), a potent angiogenic factor which contributes largely to local angiogenesis. In recent studies, endothelial cells have been found to produce bone morphogenetic protein (BMP)-2 and BMP-4 when they are subjected to mechanical stimuli, or a hypoxia environment. Conversely, inhibition of angiogenesis has been shown to prevent fracture healing. In a distraction osteogenesis model, either inhibition of angiogenesis or disruption of the mechanical environment prevents normal osteogenesis and results in fibrous nonunion. .... A total of 42 mice from F1 and F2 generations were genotyped as transgene positive. Preliminary analysis using radiography did not reveal any difference between the gross structures of transgenic and wild type mice. Interestingly, the preliminary histology revealed a decrease in trabecular bone and an increase of lipid space in metaphysis of transgenic mice overexpressing EGFL6. However, further studies will need to be carried out to investigate the role of EGFL6 in angiogenesis and adipogenesis using a transgenic mice model. This will be a prime focus of future work. Collectively, the results presented in this thesis have identified EGFL6, a member of the EGF-like family, as a potential angiogenic factor which may play an important role in bone remodeling. EGFL6 has been found to be expressed highly in calvarial osteoblasts and upregulated during primary murine osteoblast differentiation. EGFL6 has been 8 characterized to be a secreted homomeric complex. More importantly, EGFL6 has been shown to induce angiogenic activity in endothelial cell migration, tube formation and in vivo chick embryo chorioallantoic membrane assay. Furthermore, conditioned medium containing the EGFL6 recombinant protein was shown to induce phosphorylation of ERK in endothelial cells. Inhibition of ERK impaired EGFL6-induced ERK activation and endothelial cell migration. Taken together these studies raise the possibility that EGFL6 has a potential role in angiogenesis, and mediates a paracrine mechanism of cross-talk between vascular endothelial cells and osteoblasts during osteogenesis. An understanding of this process offers the potential to facilitate the development of therapeutic treatments for bone disease. Bone remodeling Neovascularization Epidermal growth factor Bones -- Blood-vessels -- Growth Bone resorption Vascular endothelial growth factors Bones -- Growth Bone remodelling EGF Angiogenesis
728	Passive volume reduction heart surgery using the Acorn cor cap cardiac support device / Bredin, Fredrik, January 2007 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 6 uppsatser.
729	Influência do exercício físico no remodelamento cardíaco, estresse oxidativo e vias de sinalização das MAPK e do NF-κB de ratos espontaneamente hipertensos Pagan, Luana Urbano. January 2018 (has links) Orientador: Katashi Okoshi / Resumo: Introdução: A sobrecarga de pressão causada pela hipertensão arterial sistêmica (HAS) pode gerar mudança na arquitetura do colágeno, favorecer a fibrose, bem como o desbalanço entre a produção de espécies reativas de oxigênio (ERO) e a capacidade antioxidante. Aumento das ERO pode gerar ativação de vias sinalizadoras como a do fator nuclear kappa B (NF-kB) e das proteínas quinases ativadas por mitógenos (MAPK). Alterações dessas vias contribuem para o processo de remodelamento cardíaco causado pela HAS. O exercício físico desempenha importante papel na atenuação dos fatores de risco cardiovascular como a HAS. Dessa forma, o objetivo desse estudo foi avaliar a influência do treinamento físico sobre o remodelamento cardíaco de ratos espontaneamente hipertensos (SHR) na fase que antecede o desenvolvimento de insuficiência cardíaca. Métodos: Foram constituídos quatro grupos experimentais de ratos: normotensos Wistar (W) sedentários (W-SED, n=27); W exercitados (W-EX, n=31); SHR sedentários (SHR-SED, n=27); e SHR exercitados (SHR-EX, n=32). A partir de 13 meses de idade, os animais dos grupos exercitados foram submetidos a protocolo de exercício em esteira, cinco dias por semana, durante quatro meses. A avaliação estrutural e funcional in vivo do coração foi realizada por ecocardiograma. A função miocárdica in vitro foi avaliada em preparações de músculo papilar isolado do ventrículo esquerdo (VE). Amostras de tecido do VE foram obtidas para análises bioquímicas, histológicas e mo... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Introduction: The pressure overload caused by systemic arterial hypertension (SAH) may change the collagen architecture, induce fibrosis, as well as imbalance between the reactive oxygen species (ROS) production and antioxidant capacity. Increased ROS leads to activation of signaling pathways such as nuclear factor kappa B (NF-kB) and mitogen-activated protein kinases (MAPK). Alterations in these pathways contribute to cardiac remodeling process induced by SAH. Physical exercise plays an important role in mitigating cardiovascular risk factors such as hypertension. Therefore, the aim of this study was to evaluate the influence of physical training, started before clinical evidence of heart failure, on cardiac remodeling in spontaneously hypertensive rats (SHR). Methods: Four experimental groups were used: sedentary (W-SED n=27) and trained (W-EX, n=31) normotensive Wistar rats, and sedentary (SHR-SED, n=27) and exercised (SHR-EX, n=32) hypertensive rats. Rats of the exercise groups underwent a protocol of treadmill exercise five days a week, for four months; exercise started at 13 months of age. Echocardiogram was performed to evaluate in vivo cardiac structures and function. In vitro myocardial function was analyzed in left ventricular (LV) papillary muscle preparations. LV tissue samples were obtained for biochemical, histological, and molecular analysis. Total myocardial collagen was assessed by histology and hydroxyproline quantification. Cardiomyocyte size was measured i... (Complete abstract click electronic access below) / Doutor Exercício. Hipertensão. Remodelamento cardíaco Ratos espontaneamente hipertensos Stress oxidativo. Matriz extracelular. MAPK NF-kB Exercício. Arterial hypertension Cardiac remodeling Ratos endogâmicos SHR.
730	Mécanismes physiopathologiques précoces impliqués dans différentes cardiomyopathies induites / Early physiopathological mechanisms involved in different induced cardiomyopathies Chakouri, Nourdine 04 April 2018 (has links) Les stress physiopathologiques cardiaques sont associés dans la plupart des cas à une production d’espèces réactives oxygénées (ROS). Les ROS entrent dans plusieurs mécanismes physiologiques, cependant, des niveaux élevés de production de ROS produisent généralement des changements délétères dans la performance contractile et conduisent à un remodelage cardiaque défavorable. Il est maintenant établit qu’un stress oxydant important entraîne une altération de l'expression et/ou la fonction des protéines sarcomériques contribuant aux dysfonctions contractiles observées dans les diverses pathologies cardiaques. Ce travail de thèse a consisté à étudier l’impact du stress oxydant sur la fonction contractile cardiaque in-vivo, ex-vivo, et in-vitro dans diffèrent modèles de stress physiopathologiques cardiaques. Plus précisément, nous avons étudié le remodelage précoce de la machinerie contractile in-vitro, notamment les modifications post-traductionnelles des protéines sarcomériques dépendantes directement ou indirectement des ROS, mais aussi, la conséquence de ces modifications sur la fonction contractile cardiaque in-vivo et ex-vivo. Pour cela, nous avons généré deux modèles animaux de stress physiopathologiques cardiaques (exercice physique et chimiothérapie) ayants des mécanismes moléculaires différents tout en étant reliés par une perturbation commune : une production importante de ROS. Ainsi, ce travail de thèse s’est intéressé à la compréhension des mécanismes physiopathologiques à l’origine de : i) la dysfonction diastolique résultante d’un exerce physique épuisant, ii) la cardiomyopathie résultante de la prise d’anthracyclines. Dans ces études, nous avons étudié les modifications post-traductionnelles induites par les ROS des protéines sarcomériques (MyBP-C et TnI), ainsi que les conséquences sur la fonction cardiaque in-vivo, ex-vivo, et in-vitro. Ce travail de thèse a permis de montrer l’importance de la voie oxydative dans la régulation/dérégulation de la fonction cardiaque, aussi bien à l’échelle de l’organe qu’à l’échelle de la cellule. Il démontre notamment, que la voie oxydative peut interagir avec la voie adrénergique pour modifier les propriétés contractiles (étude #1). De plus, ce travail a permis de mettre en évidence que la voie oxydative induit des modifications précoces des propriétés contractiles qui sont hétérogènes à travers le ventricule gauche (étude #2). / Cardiac pathophysiological stress is generally associated with reactive oxygen species (ROS) production. ROSs are involved in several physiological mechanisms, however, high levels of ROS production induce deleterious changes in contractile performance and lead to adverse cardiac remodeling. It is now established that significant oxidative stress results in impaired expression and/or function of sarcomeric proteins and contribute to contractile dysfunctions observed in various cardiac pathologies.This work aim to study the oxidative stress impact on cardiac contractile function in-vivo, ex-vivo, and in-vitro, in different models of cardiac pathophysiological stress. Specifically, we studied the in-vitro contractile machinery early remodeling, including post-translational modifications of sarcomeric proteins directly or indirectly related to ROS, and the consequences of these modifications on cardiac contractile function in-vivo and ex-vivo. For this purpose, we used two animal models of cardiac pathophysiological stress (intense physical exercise and chemotherapy) having different molecular mechanisms but connected by an important ROS production.Thus, this thesis work focused on the pathophysiological mechanisms involved in diastolic dysfunction induced by an exhausting physical exercise and the anthracyclines induced cardiomyopathy. In these studies, we investigated ROS-induced post-translational modifications of sarcomeric proteins (MyBP-C and TnI), as well as, the consequences on cardiac function in-vivo, ex-vivo, and in-vitro. This work has shown the oxidative pathway importance in the cardiac function regulation/deregulation. Especially, it demonstrates that the oxidative pathway can interfere with the adrenergic pathway to modify contractile properties (study #1). In addition, this work has shown that the oxidative pathway induces early heterogeneous changes across the left ventricle in contractile properties (study #2). Stress oxydant Cardiomyopathie induite Myofilament Remodelage précoce Protéines sarcomériques Voie adrénergique Oxidative stress Induced cardiomyopathies Myofilament Sarcomeric protein Early remodeling Adrénergic pathaway

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