Global ETD Search

1	Regulation of FOXO transcription factors by gonadotropin-releasing hormone Stavrou, Emmanouil January 2011 (has links) G protein-coupled receptors (GPCRs) are a large family of trans-membrane receptors that transmit signals from extracellular stimuli to target intracellular signal transduction pathways. The gonadotropin-releasing hormone receptor (GnRH-R) is a GPCR which binds the decapeptide GnRH. In the pituitary gonadotrope, GnRH stimulates gonadotropin (LH and FSH) biosynthesis and secretion to regulate reproduction. GnRH and the GnRH-Rs are also present in many extra-pituitary tissues, although their role at these sites remains largely undetermined. GnRH-Rs are known to recruit a diverse array of signalling pathway mediators in different cell-types. These include; Gq/11-PLCβ-IP3/DAG-Ca2+/PKC signalling, monomeric G-proteins and integrins to mediate cell adhesion and migration, the activation of the major members of the mitogen-activated protein kinase (MAPK) super-family (extracellular signal-regulated kinase (ERK), c-Jun N-terminal Kinase (JNK) and p38MAPK), and β-catenin and other mediators of the canonical Wnt signalling pathway. This thesis describes the regulation of Forkhead Box O (FOXO) transcription factors by GnRH. The mammalian FOXO transcription factors, FOXO1, FOXO3a and FOXO4, are emerging as an important family of proteins that modulate the expression of genes involved in cell-cycle regulation, induction of apoptosis, DNA damage repair and response to oxidative stress. In this thesis, emphasis is placed on delineating the novel role of FOXO transcription factors in mediating two important and widely-researched areas of GnRH biology. Firstly, the role of FOXO transcription factors in mediating cell-growth inhibition in response to GnRH treatment is assessed in a heterologous HEK293/GnRH-R expressing cell line. Secondly, the role of transcription factors in regulating luteinising hormone-β (LHβ)-subunit expression is investigated in the LβT2 gonadotrope cell line. Activation of the GnRH-R can inhibit cell proliferation and induce apoptosis in certain tumour-derived cell lines. Several studies have reported that these events can occur as a result of changes in the expression profiles of specific cell-cycle regulatory and apoptotic genes, many of which are FOXO-target genes, including GADD45, FasL, p21Cip1 and p27Kip1. In this thesis, a role for FOXOs in targeting the expression of several of these genes in response to GnRH is assessed, highlighting a specific role for FOXO3a in mediating GADD45 and FasL expression. The signalling mechanisms through which FOXO3a regulates GADD45 expression in response to GnRH is also described. Finally, a stable FOXO3a-knock-down cell line was generated in order to further examine FOXO3a involvement in GnRH-induced cell-growth inhibition. GnRH is an essential regulator of the reproductive process by stimulating the synthesis of LH and FSH in pituitary gonadotropes, thereby regulating gametogenesis and steroidogenesis. Diverse signalling pathways have been reported to regulate LHβ-subunit expression in response to GnRH, including the ERK/JNK/p38MAPK cascades and factors such as Egr1, SF1 and β-catenin. In the second part of this thesis, the role of FOXOs in regulating LHβ-subunit expression in response to GnRH is described. The data presented suggests that GnRH can regulate LHβ-subunit expression through both indirect and direct FOXO3a-mediated mechanisms. Firstly, FOXO3a was found to regulate Egr1 expression to indirectly target LHβ-promoter activity. Secondly, a role for β-catenin as a FOXO3a co-factor to directly regulate LHβ-subunit expression, together with Egr1 and SF1, is also proposed. FOXO3a expression and sub-cellular localisation was assessed and demonstrated in LβT2 cells and in adult human male pituitary sections. The research presented in this thesis adds to the diversity of signalling pathways and mediators that GnRH can target in different cellular backgrounds in order to mediate a variety of cellular processes. The antiproliferative and apoptotic effects of GnRH on tumour-derived cell lines are well-documented, and this research highlights a novel role for FOXO3a in mediating these events. The regulation of gonadotropin synthesis remains an important topic of research, and the novel implication of FOXO3a in mediating LHβ-subunit expression adds further complexity to gonadotrope physiology. 571.74
2	FoxO limits microtubule stability and is itself negatively regulated by microtubule disruption Nechipurenko, Inna 26 June 2012 (has links) No description available. Cellular Biology Neurosciences FoxO Futsch Akt DLK microtubules NMJ
3	FOXO3a Regulates Glycolysis via Transcriptional Control of Tumor Suppressor TSC1 Khatri, Shikha 01 November 2010 (has links) No description available. Molecular Biology FoxO3a, FoxO Tsc1, Tsc2 Glycolysis Metabolism Rapamycin Cancer
4	Bases moleculares da depleção de glutationa sobre a pontencialidade, diferenciação e envelhecimento de células-tronco de pele / Molecular basis of glutathione depletion upon the potenciality, differentiation potential and aging of skin stem cells Forni, Maria Fernanda Pereira de Araújo Demonte 14 March 2013 (has links) A pele está em contínua auto-renovação graças a vários nichos de células-tronco presentes neste tecido. Células progenitoras epidérmicas surgem durante o desenvolvimento embrionário e contribuem para a reposição celular da epiderme durante todo o período de vida dos mamíferos. Neste trabalho, buscou-se analisar o papel da depleção de glutationa durante a estratificação da epiderme embrionária e na manutenção da homeostase no tecido adulto. Encontramos evidências de que este tiol tem um importante papel durante a proliferação da epiderme e formação do folículo capilar. As alterações observadas na ausência de GSH foram relacionados com um padrão diferencial de fosforilação dos fatores de transcrição forkhead-homeobox- tipo-O (FOXO). Em resumo, foi estabelecida uma correlação entre o estado de GSH, a fosforilação de FOXO e o desenvolvimento da epiderme. Para melhor estudar a importância do balanço de GSH, na pele do adulto, e seu papel na manutenção deste tecido, camundongos foram tratados com um inibidor da síntese de GSH e, com N-aceti-lcisteína. Foi observado um aumento da fosforilação de Akt, padrões alterados de fosforilação FOXO e aumento da expressão de genes de genes relacionados à diferenciação. Estes resultados mostram que a via Akt/FOXO desempenha um papel importante na manutenção e diferenciação de células-tronco epidermais. O envelhecimento cronológico leva a alterações morfológicas/funcionais que conduzem à diminuição da auto-renovação, o que ocorre concomitantemente com uma diminuição dos níveis de GSH na pele. Utilizamos, também, animais idosos e avaliamos quais mecanismos eram compartilhados pelo envelhecimento e a depleção deste tiol. Observou-se que uma resposta hiperproliferativa ligada à exaustão de células-tronco pode ser o elo entre a depleção de GSH e o envelhecimento. A influência desse processo também foi investigada no compartimento dérmico, através da análise do impacto da depleção de glutationa sobre a osteogênese de células-tronco mesenquimais murinas. Quando induzidas a se diferenciarem em osso (Alizarin-Red+/Von-Kossa-stain +, aumento dos níveis de mRNA para fosfatase alcalina/osteopontina/osterix), o balanço GSH/GSSG e seu sistema antioxidante correlato é diferencialmente regulado em células-tronco mesenquimais derivadas da derme. Sendo regulado de uma forma redox-dependente através da via de MAPKs. A depleção de GSH leva à diminuição nos níveis de osteogênese em favor da adipogênese, levando ao processo comumente associado ao envelhecimento denominado \"adipogenic switc\". Em conclusão, os dados obtidos permitem propor um papel central para a glutationa na manutenção/comprometimento de células-tronco na pele. / The skin is continuously self-renewing thanks to several stem cell niches. Epidermal progenitor cells arise during embryonic development and contribute to the replenishment of the epidermis during the lifetime of mammals. We set out to analyze the glutathione (GSH) antioxidant system during embryonic epidermis stratification and follicle development and the effect of glutathione withdrawal in this process. We found that glutathione plays an important role during epidermis proliferation and hairshaft formation. The changes observed in the absence of GSH were related to a differential phosphorylation pattern of the forkhead-homeobox-type-O (FOXO) transcription factors. In brief, a correlation between GSH status, FOXO phosphorylation and skin development was established. To further study the importance of GSH in adult skin maintenance and understand the effects of ROS in the Akt/FOXO pathway, we treated cells and mice with an inhibitor of GSH synthesis, and with N-acetyl-cysteine. Increased Akt phosphorylation, altered FOXO phosphorylation patterns and increased gene expression of differentiation-related genes were observed. Our results show that the Akt/FOXO pathway plays an important role in maintenance/differentiation of epidermal stem cells. Chronological ageing leads to morphological/functional changes causing a decline in self-renewal, as well as decreased levels of GSH. We also observed that a cell cycle hyperproliferative response was the link between stem cell exaustion in GSH-depletion and ageing. Dermal mesenchymal stem cells (MSCs), are capable of adipo-chondro- and osteogenesis. Little is known about the impact of ROS in MSC differentiation. We induced murine skin MSCs to differentiate into bone (Alizarin-Red/Von-Kossastain+, increased levels of mRNA for alkalinephosphatase/ osteopontin/osterix). In brief, the balance of GSH/GSSG and related antioxidant system is differentially regulated during this process, found to be regulated in a redox-dependent fashion through the MAPK pathway. When depleted, GSH leads to an adipogenic switch in MSC differentiation. In conclusion, our data leads us to propose a central role for glutathione in the maintenance/commitment of stem cells in skin. Aging Akt/FOXO Akt/FOXO Células-tronco Envelhecimento Expressão gênica Gene expression Glutathione Glutationa MAPK MAPK Pele Skin stem cell
5	Bases moleculares da depleção de glutationa sobre a pontencialidade, diferenciação e envelhecimento de células-tronco de pele / Molecular basis of glutathione depletion upon the potenciality, differentiation potential and aging of skin stem cells Maria Fernanda Pereira de Araújo Demonte Forni 14 March 2013 (has links) A pele está em contínua auto-renovação graças a vários nichos de células-tronco presentes neste tecido. Células progenitoras epidérmicas surgem durante o desenvolvimento embrionário e contribuem para a reposição celular da epiderme durante todo o período de vida dos mamíferos. Neste trabalho, buscou-se analisar o papel da depleção de glutationa durante a estratificação da epiderme embrionária e na manutenção da homeostase no tecido adulto. Encontramos evidências de que este tiol tem um importante papel durante a proliferação da epiderme e formação do folículo capilar. As alterações observadas na ausência de GSH foram relacionados com um padrão diferencial de fosforilação dos fatores de transcrição forkhead-homeobox- tipo-O (FOXO). Em resumo, foi estabelecida uma correlação entre o estado de GSH, a fosforilação de FOXO e o desenvolvimento da epiderme. Para melhor estudar a importância do balanço de GSH, na pele do adulto, e seu papel na manutenção deste tecido, camundongos foram tratados com um inibidor da síntese de GSH e, com N-aceti-lcisteína. Foi observado um aumento da fosforilação de Akt, padrões alterados de fosforilação FOXO e aumento da expressão de genes de genes relacionados à diferenciação. Estes resultados mostram que a via Akt/FOXO desempenha um papel importante na manutenção e diferenciação de células-tronco epidermais. O envelhecimento cronológico leva a alterações morfológicas/funcionais que conduzem à diminuição da auto-renovação, o que ocorre concomitantemente com uma diminuição dos níveis de GSH na pele. Utilizamos, também, animais idosos e avaliamos quais mecanismos eram compartilhados pelo envelhecimento e a depleção deste tiol. Observou-se que uma resposta hiperproliferativa ligada à exaustão de células-tronco pode ser o elo entre a depleção de GSH e o envelhecimento. A influência desse processo também foi investigada no compartimento dérmico, através da análise do impacto da depleção de glutationa sobre a osteogênese de células-tronco mesenquimais murinas. Quando induzidas a se diferenciarem em osso (Alizarin-Red+/Von-Kossa-stain +, aumento dos níveis de mRNA para fosfatase alcalina/osteopontina/osterix), o balanço GSH/GSSG e seu sistema antioxidante correlato é diferencialmente regulado em células-tronco mesenquimais derivadas da derme. Sendo regulado de uma forma redox-dependente através da via de MAPKs. A depleção de GSH leva à diminuição nos níveis de osteogênese em favor da adipogênese, levando ao processo comumente associado ao envelhecimento denominado \"adipogenic switc\". Em conclusão, os dados obtidos permitem propor um papel central para a glutationa na manutenção/comprometimento de células-tronco na pele. / The skin is continuously self-renewing thanks to several stem cell niches. Epidermal progenitor cells arise during embryonic development and contribute to the replenishment of the epidermis during the lifetime of mammals. We set out to analyze the glutathione (GSH) antioxidant system during embryonic epidermis stratification and follicle development and the effect of glutathione withdrawal in this process. We found that glutathione plays an important role during epidermis proliferation and hairshaft formation. The changes observed in the absence of GSH were related to a differential phosphorylation pattern of the forkhead-homeobox-type-O (FOXO) transcription factors. In brief, a correlation between GSH status, FOXO phosphorylation and skin development was established. To further study the importance of GSH in adult skin maintenance and understand the effects of ROS in the Akt/FOXO pathway, we treated cells and mice with an inhibitor of GSH synthesis, and with N-acetyl-cysteine. Increased Akt phosphorylation, altered FOXO phosphorylation patterns and increased gene expression of differentiation-related genes were observed. Our results show that the Akt/FOXO pathway plays an important role in maintenance/differentiation of epidermal stem cells. Chronological ageing leads to morphological/functional changes causing a decline in self-renewal, as well as decreased levels of GSH. We also observed that a cell cycle hyperproliferative response was the link between stem cell exaustion in GSH-depletion and ageing. Dermal mesenchymal stem cells (MSCs), are capable of adipo-chondro- and osteogenesis. Little is known about the impact of ROS in MSC differentiation. We induced murine skin MSCs to differentiate into bone (Alizarin-Red/Von-Kossastain+, increased levels of mRNA for alkalinephosphatase/ osteopontin/osterix). In brief, the balance of GSH/GSSG and related antioxidant system is differentially regulated during this process, found to be regulated in a redox-dependent fashion through the MAPK pathway. When depleted, GSH leads to an adipogenic switch in MSC differentiation. In conclusion, our data leads us to propose a central role for glutathione in the maintenance/commitment of stem cells in skin. Akt/FOXO Células-tronco Envelhecimento Expressão gênica Glutationa MAPK Pele Aging Akt/FOXO Gene expression Glutathione MAPK Skin stem cell
6	Caractérisation de Fam65b, un nouvel effecteur de FoxO1 dans la régulation de la quiescence / Characterization of Fam65b, a new effector of FoxO1 in the regulation of quiescence Froehlich, Jeanne 27 October 2016 (has links) Le comportement et le devenir des lymphocytes T (LT) est conditionné par l’intégration de nombreux signaux solubles et cellulaires. Lorsque les LT ne sont pas stimulés, les facteurs de transcription FoxO orchestrent un réseau moléculaire important participant au maintien de la quiescence et à la capacité migratoire des LT. Longtemps considéré comme un état par défaut, le maintien des LT dans cet état quiescent est hautement régulé par un ensemble de signaux parmi lesquels la signalisation via le récepteur à l’interleukine 7 (IL7) et le récepteur à l’antigène (TCR) activé par des molécules du complexe majeur d’histocompatibilité (CMH) chargées avec des peptides du soi. Etonnamment, ces mêmes signaux sont nécessaires pour induire l’entrée des cellules dans le cycle cellulaire. L’inhibition de la prolifération des LT est donc un mécanisme actif qui peut être levé par des signaux externes. Le mécanisme moléculaire permettant le maintien de cet état quiescent reste très peu décrit. Mon projet de thèse a consisté à étudier les conséquences fonctionnelles de l’expression de Fam65b, une nouvelle cible transcriptionnelle de FoxO, sur la prolifération. Au cours de mon travail, j’ai montré que dans des cellules transformées, ayant donc perdu la capacité de réguler leur prolifération, l’expression forcée de Fam65b perturbe la mise en place du fuseau mitotique, induisant un arrêt en phase G 2 /M et la mort des cellules. Au cours de ce processus, Fam65b agit avec deux partenaires connus pour leur implication dans le cycle cellulaire, l’histone déacétylase 6 (HDAC6) et la protéine d’échafaudage 14-3-3. J’ai également pu établir que, dans les LT primaires humains, Fam65b est un facteur de quiescence. En effet, l’engagement du TCR induit une diminution d’expression de Fam65b et le maintien de son expression bloque la prolifération des LT, suggérant que l’inhibition de son expression est un pré-requis à la prolifération. Inversement, l’inhibition de l’expression de Fam65b dans des LT naïfs diminue leur seuil d’activation. L’ensemble de ces résultats désigne donc Fam65b comme une nouvelle cible pour le contrôle de la prolifération des cellules primaires et transformées. Nous avons également développé au laboratoire un modèle murin invalidé pour Fam65b dans le lignage T afin d’étudier son rôle dans un modèle plus intégré. J’ai pu initier l’analyse du phénotype de ces souris en l’absence de toute stimulation. L’ensemble de ces travaux, en complément de ceux précédemment obtenus au laboratoire, laissent apparaître Fam65b comme un nouvel effecteur de FoxO capable d’interagir avec divers partenaires afin de contrôler conjointement des fonctions cellulaires majeures. / T cell fate is conditioned by the integration of many soluble and cellular signals. When T cells are not stimulated, FoxO transcription factors orchestrate an important molecular network involved in maintaining the quiescent state and migratory ability of the cells. Considered as a "default" state, it is now known that maintenance of T cell quiescence is a process highly regulated by a set of signals including IL7 signaling and sustained contact with MHC molecules presenting self-peptides. Surprisingly, these same signals are required to induce entry of cells into the cell cycle. Inhibition of T cell proliferation is an active mechanism that can be lifted by external signals. The molecular mechanism maintaining this quiescent state is poorly described. My thesis project was studying the functional consequences of Fam65b expression, a new transcriptional target of FoxO, on proliferation. I showed that, in transformed cells, that have lost the ability to regulate their proliferation, forced expression of Fam65b disrupts the establishment of the mitotic spindle, inducing an arrest in G 2 /M phase and cell death. During this process, Fam65b acts with two partners, known to be involved in the cell cycle process, the histone deacetylase HDAC6 and the 14-3-3 protein scaffold. I have also been able to establish that in human primary T cell, Fam65b is a quiescence factor. Indeed, the TCR stimulation induces a reduction of Fam65b expression and maintaining its expression blocks the proliferation of T cells, suggesting that inhibition of Fam65b expression is a prerequisite for proliferation. Conversely, inhibition of Fam65b expression in naive T cells reduces their activation threshold. Altogether these results show that Fam65b is a new target for the control of the proliferation of primary and transformed cells. We have also developed, in the laboratory, a mouse model invalidated for Fam65b in T cell lineage. I initiated the phenotype analysis of these mice in the absence of any stimulation. This work, in addition to the previous results obtained in the laboratory, reveal that Fam65b is a new effector of FoxO factors, able to interact with various partners to jointly control major cellular functions. Prolifération cellulaire Fam65b RhoGTPase HDAC6 Cycle cellulaire et signalisation Voie PI3K/Akt/FoxO Proliferation Fam65b RhoGTPase HDAC6 Cell cycle and signalisation PI3K/Akt/FoxO 571.84
7	Contribuição do estresse oxidativo para a ativação das vias NF-kB, FOXO e MAPK para atrofia muscular associada à insuficiência cardíaca: efeito do treinamento físico aeróbico / Contribution of oxidative stress to NF-kB, FOXO and MAPK signaling pathway activation in atrophy induced by heart failure: role of aerobic exercise training Cunha, Telma Fátima da 20 January 2015 (has links) A musculatura esquelética tem um papel fundamental para a manutenção da homeostase do organismo. A perda de massa muscular está relacionada a prejuízos na qualidade de vida de indivíduos saudáveis, além de piorar o prognóstico de pacientes com doenças sistêmicas, como o câncer, o diabetes e a insuficiência cardíaca. Em quadros mais graves de insuficiência cardíaca, a perda excessiva de massa muscular associada a um reduzido consumo de oxigênio de pico, são considerados como preditores independentes de mortalidade. O aumento do estresse oxidativo tem sido apontado como um dos principais desencadeadores do aumento da degradação de proteínas na atrofia muscular. Na presente tese, investigamos a contribuição do estresse oxidativo para a ativação das vias de sinalização NF-kB, FOXO e MAPK na atrofia muscular desencadeada pela insuficiência cardíaca. Para compreender melhor os mecanismos envolvidos na ativação dessas vias pelo estresse oxidativo, utilizamos a linhagem de células musculares C2C12. Observamos que o tratamento com peróxido de hidrogênio (1,2mM, 12h) induziu um aumento do estresse oxidativo, o qual foi capaz de aumentar a atividade do proteassoma, desencadeando a atrofia dos miotúbulos. Verificamos também um aumento da expressão proteica de alguns componentes dessas vias de sinalização, como p-p38 e NF-kB; apontando para uma ativação diferenciada dessas vias pelo estresse oxidativo. Para verificar se essas vias de sinalização relacionadas ao estresse oxidativo estavam também relacionadas à atrofia desencadeada pela insuficiência cardíaca, avaliamos um modelo experimental de ratos com insuficiência cardíaca induzida pelo infartado do miocárdio. Observamos uma redução da área de secção transversa do músculo plantar, acompanhada de um aumento da inflamação sistêmica, de p38 e das atividades de NF-kB e do proteassoma. Como o treinamento físico aeróbico tem se apresentado como uma estratégia terapêutica não farmacológica eficaz na redução do estresse oxidativo e no restabelecimento da atividade do sistema ubiquitina proteassoma, submetemos os ratos infartados ao treinamento físico aeróbico em esteira rolante. O treinamento físico aeróbico preveniu a perda de massa muscular, reduzindo a inflamação sistêmica e as atividades de NF-kB e do proteassoma. Em conjunto, os resultados apontam para o estresse oxidativo como um fator preponderante para o aumento da degradação de proteínas relacionada à atrofia muscular, seja por indução de inflamação (TNF-α) ou por sua ação direta. Além disso, observamos que as vias de sinalização são ativadas de forma diferenciada nos dois modelos, sugerindo que a degradação de proteínas nos miotúbulos está relacionada ao controle de qualidade de proteínas e, nos ratos infartados, às alterações do metabolismo, servindo como fonte de energia. Já o treinamento físico aeróbico comprovou sua eficácia no restabelecimento da atividade do proteassoma, reduzindo a inflamação e a atividade de NF-kB, prevenindo assim, a perda de massa muscular / About 40% of human body mass consists of skeletal muscles, which are involved in all aspects of movement including breathing, eating, posture, walking and reflexes. Skeletal muscle is also important as a source of heat generation and as a regulator of intermediary metabolism. Loss of skeletal muscle mass and function (skeletal muscle atrophy) leads to several functional impairments, affecting health and quality of life. It occurs in several chronic diseases such as cancer, diabetes and heart failure. In heart failure, atrophy is considered an independent predictor of poor prognosis. Oxidative stress has a crucial role in atrophy, activating different signaling pathways capable of stimulating the ubiquitin proteasome system to degrade proteins. In this study, we investigated the oxidative stress contribution to NF-kB, FOXO and MAPK signaling pathway activation in heart failure-induced atrophy. To better understand the mechanisms involved with oxidative stress and signaling pathways activation in atrophy, we have used C2C12 skeletal muscle cells. We observed that, even in high hydrogen peroxide concentrations, oxidative stress increased proteasome activity, phosphorylated p38 and NF-kB protein expression, causing myotubes atrophy. In an experimental heart failure model of infarcted rats, we evaluated plantaris muscle and verified a reduced cross sectional area, accompanied by increased systemic inflammation, p-38 protein expression and increased both NF-kB and proteasome activities. As aerobic exercise training causes a lot of beneficial effects on skeletal muscle structure and function in chronic diseases, we submitted infarcted rats to 8 weeks of aerobic exercise training on a treadmill. Aerobic exercise training prevented atrophy by reducing inflammation and both NF-kB and proteasome activities. Collectively, our data suggest a differentiated activation by oxidative stress in muscle cells and animal models. In the first case, protein degradation was involved with protein quality control; and, in the other, oxidative stress is a second messenger, stimulating protein degradation to provide substrates to metabolism. Aerobic exercise training re-established proteasome activity by reducing inflammation and NF-kB activity, preventing muscle atrophy Aerobic exercise training Atrofia Atrophy Estresse oxidativo FOXO and MAPK FOXO e MAPK Músculo esquelético NF-kB Oxidative stress Signaling pathways skeletal muscle Treinamento físico aeróbico Vias NF-kB
8	Contribuição do estresse oxidativo para a ativação das vias NF-kB, FOXO e MAPK para atrofia muscular associada à insuficiência cardíaca: efeito do treinamento físico aeróbico / Contribution of oxidative stress to NF-kB, FOXO and MAPK signaling pathway activation in atrophy induced by heart failure: role of aerobic exercise training Telma Fátima da Cunha 20 January 2015 (has links) A musculatura esquelética tem um papel fundamental para a manutenção da homeostase do organismo. A perda de massa muscular está relacionada a prejuízos na qualidade de vida de indivíduos saudáveis, além de piorar o prognóstico de pacientes com doenças sistêmicas, como o câncer, o diabetes e a insuficiência cardíaca. Em quadros mais graves de insuficiência cardíaca, a perda excessiva de massa muscular associada a um reduzido consumo de oxigênio de pico, são considerados como preditores independentes de mortalidade. O aumento do estresse oxidativo tem sido apontado como um dos principais desencadeadores do aumento da degradação de proteínas na atrofia muscular. Na presente tese, investigamos a contribuição do estresse oxidativo para a ativação das vias de sinalização NF-kB, FOXO e MAPK na atrofia muscular desencadeada pela insuficiência cardíaca. Para compreender melhor os mecanismos envolvidos na ativação dessas vias pelo estresse oxidativo, utilizamos a linhagem de células musculares C2C12. Observamos que o tratamento com peróxido de hidrogênio (1,2mM, 12h) induziu um aumento do estresse oxidativo, o qual foi capaz de aumentar a atividade do proteassoma, desencadeando a atrofia dos miotúbulos. Verificamos também um aumento da expressão proteica de alguns componentes dessas vias de sinalização, como p-p38 e NF-kB; apontando para uma ativação diferenciada dessas vias pelo estresse oxidativo. Para verificar se essas vias de sinalização relacionadas ao estresse oxidativo estavam também relacionadas à atrofia desencadeada pela insuficiência cardíaca, avaliamos um modelo experimental de ratos com insuficiência cardíaca induzida pelo infartado do miocárdio. Observamos uma redução da área de secção transversa do músculo plantar, acompanhada de um aumento da inflamação sistêmica, de p38 e das atividades de NF-kB e do proteassoma. Como o treinamento físico aeróbico tem se apresentado como uma estratégia terapêutica não farmacológica eficaz na redução do estresse oxidativo e no restabelecimento da atividade do sistema ubiquitina proteassoma, submetemos os ratos infartados ao treinamento físico aeróbico em esteira rolante. O treinamento físico aeróbico preveniu a perda de massa muscular, reduzindo a inflamação sistêmica e as atividades de NF-kB e do proteassoma. Em conjunto, os resultados apontam para o estresse oxidativo como um fator preponderante para o aumento da degradação de proteínas relacionada à atrofia muscular, seja por indução de inflamação (TNF-α) ou por sua ação direta. Além disso, observamos que as vias de sinalização são ativadas de forma diferenciada nos dois modelos, sugerindo que a degradação de proteínas nos miotúbulos está relacionada ao controle de qualidade de proteínas e, nos ratos infartados, às alterações do metabolismo, servindo como fonte de energia. Já o treinamento físico aeróbico comprovou sua eficácia no restabelecimento da atividade do proteassoma, reduzindo a inflamação e a atividade de NF-kB, prevenindo assim, a perda de massa muscular / About 40% of human body mass consists of skeletal muscles, which are involved in all aspects of movement including breathing, eating, posture, walking and reflexes. Skeletal muscle is also important as a source of heat generation and as a regulator of intermediary metabolism. Loss of skeletal muscle mass and function (skeletal muscle atrophy) leads to several functional impairments, affecting health and quality of life. It occurs in several chronic diseases such as cancer, diabetes and heart failure. In heart failure, atrophy is considered an independent predictor of poor prognosis. Oxidative stress has a crucial role in atrophy, activating different signaling pathways capable of stimulating the ubiquitin proteasome system to degrade proteins. In this study, we investigated the oxidative stress contribution to NF-kB, FOXO and MAPK signaling pathway activation in heart failure-induced atrophy. To better understand the mechanisms involved with oxidative stress and signaling pathways activation in atrophy, we have used C2C12 skeletal muscle cells. We observed that, even in high hydrogen peroxide concentrations, oxidative stress increased proteasome activity, phosphorylated p38 and NF-kB protein expression, causing myotubes atrophy. In an experimental heart failure model of infarcted rats, we evaluated plantaris muscle and verified a reduced cross sectional area, accompanied by increased systemic inflammation, p-38 protein expression and increased both NF-kB and proteasome activities. As aerobic exercise training causes a lot of beneficial effects on skeletal muscle structure and function in chronic diseases, we submitted infarcted rats to 8 weeks of aerobic exercise training on a treadmill. Aerobic exercise training prevented atrophy by reducing inflammation and both NF-kB and proteasome activities. Collectively, our data suggest a differentiated activation by oxidative stress in muscle cells and animal models. In the first case, protein degradation was involved with protein quality control; and, in the other, oxidative stress is a second messenger, stimulating protein degradation to provide substrates to metabolism. Aerobic exercise training re-established proteasome activity by reducing inflammation and NF-kB activity, preventing muscle atrophy Atrofia Estresse oxidativo FOXO e MAPK Músculo esquelético Treinamento físico aeróbico Vias NF-kB Aerobic exercise training Atrophy FOXO and MAPK NF-kB Oxidative stress Signaling pathways skeletal muscle
9	Nuclear Translocation of FoxO3a Transcription Factor During Prelamin A Induced Cell Cycle Arrest in 3T3 Cells. Keasler, Jessica B. 05 May 2012 (has links) As the so-called “Mothership of the Human Genome,” the cell nucleus must keep all vital genetic information safe, but accessible, inside a strong protective envelope. The inner membrane of the nuclear envelope is lined by tough but adaptable proteins called lamins. While lamins polymerize into fibrous structures that hold up the “walls” of the nucleus, they also serve as an internal scaffold for the complex machinery involved in DNA replication and gene expression. It is in this later role that we have been looking for clues to premature and possibly to normal aging. One type of lamins, Lamin A is made through an unusual pathway involving a lipid dependent cleavage of a larger precursor called prelamin A. The functional significance of this processing pathway is that prelamin A cannot assemble and is inhibitory of proper lamina formation. Pathological cases of immature lamin A accumulation include Hutchinson-Gilford progeria syndrome (HGPS) or Progeria characterized by premature aging and Restrictive Dermopathy (RD), a lethal prenatal disease. We have previously shown that accumulation of prelamin A leads to cell cycle arrest and drastic changes in expression of genes involved in cell cycle control, among those, several members of the FoxO family of transcription factors. The goal of this study was to determine the mechanisms by which accumulation of uncleavable prelamin A activates FoxO-mediated cell cycle arrest. Cells expressing an uncleavable form of Lamin A in an inducible manner were used to determine subcellular distribution of FoxO3a upon accumulation of prelamin A. This was done by indirect immunofluorescence and Western blotting. The proliferation rate of these cells and controls expressing wild type Lamin A was also determined by measuring the incorporation of BrdU into DNA. During these experiments, it was hypothesized and observed that overexpression of prelamin A leads to redistribution of FoxO3a from the cytoplasm of the cell to the nucleoplasm. Expression of FoxO3a target genes was accordingly increased, leading to a decrease in cell proliferation. The information obtained from this study could not only be of interest in broadening our knowledge of the mechanisms of quiescence and aging in general, but also could inform the discussion of the use of several therapeutics for the treatment of Progeria and other diseases that result from the accumulation of prelamin A. Progeria Lamin A Cell Cycle Prelamin A FoxO p27 Quiescence Senescence Chemistry Physical Sciences and Mathematics
10	Contrôle génétique de l'établissement et de la plasticité de la pigmentation abdominale chez Drosophila melanogaster / Genetic control of the establishment and the plasticity of abdominal pigmentation in Drosophila melanogaster Silva de Castro, Sandra 29 November 2018 (has links) La plasticité phénotypique est la capacité d’un génotype donné à produire différents phénotypes en réponse à différents environnements tels que la température, la nutrition ou encore la présence de prédateurs. Ce phénomène permet aux individus de s’adapter à des environnements fluctuants. Il peut également faciliter l’évolution en élargissant la gamme de phénotypes produits par un génotype. Comme modèle de plasticité phénotypique, nous étudions la pigmentation abdominale chez les femelles Drosophila melanogaster. En effet, ce caractère est sensible à la température : les femelles drosophiles sont plus pigmentées lorsqu’elles se développent à basse température, particulièrement dans les segments abdominaux postérieurs. Les études précédentes du laboratoire ont montré que le gène tan (t), codant une enzyme de pigmentation, est beaucoup plus fortement exprimé à 18°C qu'à 29°C. Par ailleurs, ce gène joue un rôle essentiel dans la plasticité phénotypique de la pigmentation abdominale des femelles Drosophila melanogaster. Au cours de ma thèse, je me suis intéressée à la caractérisation du réseau de gènes impliqué dans la régulation de l’expression de t dans l’épiderme abdominal des femelles Drosophila melanogaster. J'ai également cherché à identifier, dans ce réseau, les acteurs pouvant médier l'effet de la température sur l'expression de t. A l'aide d'une approche gène candidat, j'ai montré que les facteurs de transcription Bric-à-Brac (Bab) et Abdominal-B (Abd-B) intervenaient dans la plasticité phénotypique de la pigmentation abdominale en régulant notamment t. De plus, j'ai réalisé un crible génétique ciblant 573 gènes codant des facteurs de transcription et des régulateurs de la chromatine afin d'identifier de nouveaux régulateurs de t. A l'issue de ce crible, j'ai obtenu une liste de 27 gènes impliqués dans cette régulation. J'ai ensuite commencé la caractérisation fonctionnelle de deux de ces candidats : forkhead box subgroup O (foxo) codant un facteur de transcription impliqué dans la voie de réponse à l'insuline et little imaginal discs (lid) codant une histone déméthylase. / Phenotypic plasticity is the ability of a given genotype to produce different phenotypes in response to different environmental factors such as temperature, nutrition or presence of predators. This phenomenon allows the adaptation of individuals to their fluctuating environments. It can also facilitate evolution, as it broadens the range of phenotypes produced by a given genotype. As a model of phenotypic plasticity, we study the abdominal pigmentation in Drosophila melanogaster females. Indeed, this trait is temperature-sensitive: drosophila females are darker when they develop at lower temperatures particularly in the posterior segments. In the laboratory, it has been previously shown, that tan (t), a gene encoding a pigmentation enzyme, is more expressed at 18°C than at 29°C. Moreover, this gene plays an essential role in the phenotypic plasticity of abdominal pigmentation in Drosophila melanogaster females. During my thesis, I aimed to characterize the gene regulatory network involved in t regulation in the abdominal epidermis of Drosophila melanogaster females. I also tried to identify, in this network, the actors mediating the effect of temperature on t expression. Using a candidate gene approach, I showed that the transcription factors Bric-à-brac (Bab) and Abdominal-B (Abd-B) are involved in the phenotypic plasticity of abdominal pigmentation by regulating t. Furthermore, I performed a genetic screen targeting 573 genes encoding transcription factors and chromatin regulators to identify new regulators of t. At the end of this screen, I obtained a list of 27 genes involved in this regulation. I then started the functional characterization of two of these candidates: forkhead box subgroup O (foxo) encoding a transcription factor involved in the insulin response pathway and little imaginal discs (lid) encoding a histone demethylase. Drosophile Plasticité phénotypique Pigmentation abdominale Tan Bab Foxo Lid Drosophila Phenotypic plasticity Abdominal pigmentation 571.85

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