Global ETD Search

1	The role of Mcl-1 in the response of human colorectal cancer cells to treatment with dichloroacetate Delaney, Leanne 26 August 2013 (has links) Dichloroacetate (DCA) it a metabolic reprogramming agent that is used to target the unique metabolism of cancer cells, but is not always effective in colorectal cancer cells. In HCT116 cells, DCA was unable to induce apoptosis, but did decrease proliferation when compared to untreated cells. A decrease in full length Mcl-1 protein expression 7 hours following DCA treatment did not correspond with changes in mRNA production or changes in expression of inhibitory binding partners, but may be due to altered proteasomal degradation. Similar reduction in levels of a lower molecular weight Mcl-1 band occurred, which did not result from alternative splicing or from caspase-mediated cleavage. Mcl-1 showed primarily nuclear localization within the cell, and expression changes in full-length Mcl-1 were seen in nuclear lysate but not cytoplasmic lysate after 7 hours of DCA treatment. Changes in nuclear Mcl-1 expression did not correspond with cell cycle arrest or progression. These results suggest that proteasomal degradation of Mcl-1 may be altered following treatment with DCA, and this change may be associated with decreased proliferation, independent of cell cycle arrest. This may indicate a novel role of nuclear Mcl-1 in response of colorectal cancer to DCA exposure. / Final thesis for Leanne Delaney in partial fulfillment of requirements for the degree of Master of Science in Biomedical Sciences / NSERC Colorectal Cancer Cancer Metabolism Mcl-1 Bcl-2 Proteins Apoptosis Cell Cycle Proliferation Dichloroacetate
2	How Do Hexokinases Inhibit Receptor-Mediated Apoptosis? Schöninger, Axel, Wolf, Philipp, Edlich, Frank 13 June 2023 (has links) The regulated cell death apoptosis enables redundant or compromised cells in ontogeny and homeostasis to remove themselves receptor-dependent after extrinsic signaling or after internal stress by BCL-2 proteins on the outer mitochondrial membrane (OMM). Mitochondrial BCL-2 proteins are also often needed for receptor-mediated signaling in apoptosis. Then, the truncated BH3-only protein BID (tBID) blocks retrotranslocation of the pro-apoptotic BCL-2 proteins BAX and BAK from the mitochondria into the cytosol. BAX and BAK in turn permeabilize the OMM. Although the BCL-2 proteins are controlled by a complex regulatory network, a specific mechanism for the inhibition of tBID remained unknown. Curiously, it was suggested that hexokinases, which channel glucose into the metabolism, have an intriguing function in the regulation of apoptosis. Recent analysis of transient hexokinase interactions with BAX revealed its participation in the inhibition of BAX and also BAK by retrotranslocation from mitochondria to the cytosol. In contrast to general apoptosis inhibition by anti-apoptotic BCL-2 proteins, hexokinase I and hexokinase 2 specifically inhibit tBID and thus the mitochondrial apoptosis pathway in response to death receptor signaling. Mitochondrial hexokinase localization and BH3 binding of cytosolic hexokinase domains are prerequisites for protection against receptor-mediated cell death, whereas glucose metabolism is not. This mechanism protects cells from apoptosis induced by cytotoxic T cells. info:eu-repo/classification/ddc/610 ddc:610
3	THE EFFECT OF CHOLESTEROL ON THE STRUCTURE OF MITOCHONDRIAL LIKE LIPID BILAYERS: AN X-RAY STUDY Patel, Amit N. 04 1900 (has links) <p>Apoptosis plays a key role in the regulation and development of healthy multicellular organisms throughout their lifetimes. The mitochondria play a key role in this cellular process, as it contains proapoptotic factors, which once released into the cytosol of the cell, results in the death of the cell. The Bcl-2 family of proteins play a key role in apoptosis, acting as the gateway between life and death of the cell. Proteins such as tBid and Bax act to permeabilize the mitochondrial outer membrane (MOM), releasing the proapoptotic factors into the cell’s cytosol. The interactions between these proteins and the mitochondrial outer membrane have yet to be fully understood. The lipid composition and cholesterol content of the membrane effectively inhibit or promote pore formation by Bax. Specifically, the addition of cholesterol into the membrane inhibits pore formation. This thesis attempts to further understand the effects cholesterol has on the structure of the MOM, and link those changes to the inhibited activity of Bax pore formation. MOM-like lipid bilayers were studied under varying temperatures and with the addition of cholesterol using x-ray reflectivity. Increasing temperatures from 10°C to 30°C resulted in bilayer thinning, as did decreasing cholesterol concentrations below 30%. From 10°C to 20°C, bilayer thickness showed a bell shaped profile, and changed to a linear decrease above about 20°C. This may assist Bax in pore formation, as it has also been observed to cause bilayer thinning. Increasing Cholesterol concentrations up to 30% resulted in little variation in bilayer thickness though hindrance of Bax pore formation is observed at content levels as low as 8%. Thus it is unlikely that bilayer thickening by cholesterol causes the inhibition of Bax pore formation. In addition, cholesterol was observed to increase the electron density of the core of the bilayer at concentration levels above 25%.</p> / Master of Science (MSc) Apoptosis Cholesterol Temperature Mitochondrial Outer Membrane Bcl-2 Proteins Bax Biophysics Biophysics
4	A CHARACTERIZATION OF THE DYNAMIC INTERACTION BETWEEN THE PRO-APOPTOTIC PROTEIN BID AND THE MITOCHONDRIAL OUTER MEMBRANE Shamas-Din, Aisha 10 1900 (has links) <p>Bcl-2 family of proteins regulate apoptosis at the level of the mitochondrial outer membrane (MOM) through both protein-protein and protein-membrane interactions. While the role of the membrane as the “locus of action” has been recognized, the detailed molecular mechanisms and the consequences of the interactions of Bcl-2 family members with the membrane are yet to be fully understood. The findings presented here focus on the dynamic interactions of Bcl-2 proteins, most notably tBid with the MOM, and their functional significance on mitochondrial outer membrane permeabilization. We show that the activation of tBid is a multi-step process that is regulated by MOM lipids and proteins. The rate-limiting step in the activation of tBid is an elaborate conformational change that is facilitated by Mtch2, and is required for the activation and recruitment of Bax to the MOM. Furthermore, we demonstrate that binding of both tBid and Bax to the membrane is reversible and is governed by dynamic equilibria that potentially contribute to the propagation of the permeabilization signal within the cell for the regulation of apoptosis. We report that the transfer of tBid between membranes is accelerated by Bax and restricted by Bcl-XL, whereas the transfer of Bax between membranes is slower than and not influenced by tBid. Finally, by studying the effect of varying lipid composition on Bax-mediated permeabilization, we establish that electrostatic interactions mediate the binding of both tBid and Bim to the membrane. We demonstrate that while Bim does not exhibit any preference for a specific anionic lipid, tBid requires cardiolipin in order to undergo its conformational change at the membrane in the absence of Mtch2. Taken together, our work contributes to the growing understanding of the dynamic interactions and changes in conformation of Bcl-2 proteins at the MOM.</p> / Doctor of Science (PhD) Apoptosis Bcl-2 proteins tBid Bax Fluorescence Spectroscopy Lipids Biochemistry Biophysics Lipids Molecular Biology Biochemistry
5	Characterization of the Activation Mechanism of Bax Kale, Justin January 2017 (has links) Mitochondrial outer membrane permeabilization (MOMP) is regulated by protein-protein and protein-membrane interactions between Bcl-2 family proteins. These interactions are governed by the concentrations and relative binding affinities of the proteins for each other. These affinities are altered by conformation changes of Bcl-2 family proteins resulting from interactions with each other and with membranes. How Bcl-2 proteins transition into and out of the conformations that controls their functions, and ultimately the fate of the cell, is not well understood. Here, kinetic analysis of the pore-forming Bcl-2 family member, Bax, revealed that Bax undergoes a conformational rearrangement through at least one structurally distinct intermediate that is a necessary precursor to pore formation. We discover that four cancer-associated Bax point mutants are trapped in the intermediate state, suggesting that transitions into and out of this intermediate can be modulated independently with consequences for the execution of apoptosis. Furthermore we report that the conformation changes Bax undergoes can be regulated by phosphorylation of Bax on residue S184 by the pro-survival kinase, Akt. Phosphorylation converts Bax into an anti-apoptotic protein that functions in a dominant-negative fashion. Bioinformatics revealed that in human cancers, higher levels of Bax are positively associated with high levels of PI3K/AKT pathway genes representing an added mechanism for cancer cells to evade apoptosis. Additionally we studied the interactions between Bax, the anti-apoptotic protein Bcl-XL, the sensitizer BH3 protein Bad and the BH3 activator protein Bid. We uncover a new mechanism of apoptosis regulation whereby Bad binds to one monomer of a Bcl-XL dimer eliciting an activating conformation change in a tBid bound to the other monomer of the Bcl-XL dimer. This allows Bad to function as a non-competitive inhibitor of Bcl-XL, and represents a novel mechanism that significantly enhances the potency of Bad to elicit apoptosis. / Thesis / Doctor of Philosophy (PhD) / Every day the human body creates billions of cells replacing damaged or unwanted cells. The death of these cells is tightly controlled and can result in disease when misregulated. Cancers arise when there is too little cell death and neurodegenerative diseases, such as Alzheimer’s, arise from too much cell death. Much research, including this thesis, is focused on understanding how cells die because once understood, cell death can be manipulated to treat disease. Cell death ironically occurs at the mitochondria, a cellular organ normally responsible for creating the energy required for the cell to live. When cell death is initiated, the mitochondria get holes poked into them, releasing pro-death factors that irreversibly commit the cell to dying. The work presented here uncovers new information about the regulation of the hole poking process, how it is blocked in breast cancer and how the process may be modulated to treat cancers. Bax Apoptosis Bcl-2 proteins Bcl-XL Biochemistry Biophysics FRET Fluorescence Spectroscopy Cancer AKT
6	Contribution de la forme mitochondriale de Bcl-xL dans le contrôle de la migration cellulaire / Role of mitochondrial Bcl-xL in the control of cell migration Bessou, Margaux 10 July 2017 (has links) Les protéines de la famille Bcl-2 sont les principaux régulateurs de la mort cellulaire par apoptose. Au sein de cette famille, la protéine Bcl-xL appartient au sous-groupe des anti-apoptotiques et contribue à maintenir la survie cellulaire. Cependant, des données récentes suggèrent que les membres de la famille Bcl-2, et en particulier Bcl-xL, ont également d'autres fonctions.Dans le contexte pathologique du cancer du sein, la surexpression du gène Bcl-x n'affecterait pas la taille de la tumeur initiale mais favoriserait plutôt l'invasion ganglionnaire et la formation de métastases. La capacité des tumeurs à former des métastases repose notamment sur le potentiel migratoire et invasif des cellules cancéreuses, et de ce fait nous avons cherché à savoir si Bcl-xL pouvait contrôler ces processus. En lien avec les données cliniques, nous montrons que la perte d'expression de Bcl-xL réduit la capacité migratoire de cellules cancéreuses mammaires. De plus, le contrôle de la migration exercé par Bcl-xL est indépendant de son activité anti-apoptotique. Ainsi, l'inhibition de la poche hydrophobe de Bcl-xL par des composés BH3-mimétiques n'a pas d'effet sur la migration des cellules. Nous avons alors recherché le mécanisme par lequel Bcl-xL agit sur la migration. Nous observons que la fraction mitochondriale de Bcl-xL régule la migration cellulaire, et non la protéine localisée au réticulum endoplasmique. Au niveau de la mitochondrie, nous proposons que Bcl-xL contrôle la migration par l'intermédiaire de son domaine BH4, domaine modulant l'activité du canal mitochondrial VDAC / Proteins of the Bcl-2 family are the main regulators of apoptosis. Among the family, the Bcl-xL protein belongs to the anti-apoptotic subgroup and favors cell survival. However, increasing evidence suggest that Bcl-2 proteins, and in particular Bcl-xL, exert other functions in the cells.In the pathological context of breast cancer, Bcl-x gene overexpression seems to have only little impact on primary tumor growth but instead increases lymph nodes invasion and metastasis. Metastasis formation mainly relies on tumor cells’ ability to migrate and invade surrounding tissues. Therefore, we wondered wether Bcl-xL could control these processes.In line with clinical data, we show that Bcl-xL complete or partial loss of expression reduces cell migration of mammary cancer cell lines. Furthermore, we find that Bcl-xL control of cell migration is independent of its anti-apoptotic activity. Indeed, treatments with BH3-mimetics that bind to and inhibit Bcl-xL hydrophobic pocket have no effect on cell migration. Since Bcl-xL regulation of cell migration seems to be independent of interactions with other Bcl-2 family members, we investigated alternative mechanisms. We observe that mitochondrial Bcl-xL, but not the ER-targeted Bcl-xL, is involved in cell migration. At the mitochondria, we propose that Bcl-xL controls cell migration through its BH4 domain, by modulating the activity of mitochondrial VDAC channel Protéines Bcl-2 Migration Mitochondrie Cancer Calcium Bcl-xL Bcl-2 proteins Migration Mitochondria Cancer Calcium Bcl-xL 571.6
7	Synthèse de nouveaux inhibiteurs de kinases Pim et de modulateurs des protéines de la famille des Bcl-2, anticancéreux potentiels / Synthesis of novel Pim kinase inhibitors and Bcl-2 family protein modulators, potential anticancer agents Saugues, Emmanuelle 21 October 2011 (has links) La formation de cancers est liée à des dérèglements de la progression du cycle cellulaire ou de l’apoptose. L’identification des acteurs cellulaires mis en jeu dans la maladie et l’élucidation des mécanismes responsables de ces dysfonctionnements sont à la base de nouveaux traitements anticancéreux. Ainsi, en vue du développement de thérapies ciblées, les kinases Pim et les protéines anti-apoptotiques de la famille des Bcl-2, surexprimées dans de nombreux types de cancers et associées à des phénomènes de chimiorésistance, constituent des cibles pertinentes. Les kinases Pim (Pim-1,-2 et -3) sont une famille de sérine / thréonine kinases qui jouent un rôle fondamental dans les processus de survie, de prolifération ou de différenciation cellulaire. Bien qu’elles possèdent un substrat commun avec les autres protéines kinases, l’ATP, des différences structurales permettent de les différencier et de les inhiber sélectivement. En tenant compte de ces spécificités, nous nous sommes intéressés à la synthèse de nouveaux inhibiteurs sélectifs des kinases Pim, compétitifs de l’ATP. Parmi les autres agents impliqués dans la formation de tumeurs, les protéines de la famille des Bcl-2, responsables du phénomène d’apoptose ou mort cellulaire programmée, font l’objet d’un domaine d’étude récent. Elles se classent en deux familles selon leur fonction : les protéines pro-apoptotiques et les protéines anti-apoptotiques dont la surexpression est observée dans de nombreux cancers. Nous avons poursuivi l’étude de relations structure-activité initiée au laboratoire à partir de trimères d’alkoxyquinoléines, inhibiteurs micromolaires des protéines anti-apoptotiques Bcl-2 et Bcl-xL, en préparant de nouveaux analogues. / Cancer development is associated with dysfunctions in cell cycle progression or apoptosis. The identification of cellular agents involved in this disease, and the elucidation of mechanisms responsible for these dysfunctions provide the basis for the development of novel anti-cancer drugs.Thus, Pim kinases and Bcl-2 anti-apoptotic proteins which are overexpressed in many malignancies and contribute significantly to chemoresistance are of great interest for the development of targeted cancer therapy. Pim kinases (Pim-1,-2 and -3) belong to a family of serine / threonine kinases which play a key role in cell survival, proliferation and differenciation. Although all protein kinases share ATP as a common substrate, the structure of the ATP-binding pocket of Pim kinases is unique and offers an opportunity for a selective inhibition. Taking account of these specificities, we were interested in the synthesis of novel selective ATP competitive Pim kinase inhibitors. Among the other agents involved in tumorigenesis, Bcl-2 family proteins, which govern apoptosis (or programmed cell death), are subject of a recent interest. These proteins are divided in two classes depending on their function : pro-apoptotic and anti-apoptotic members that are overexpressed in a variety of cancers. In a preliminary work in the laboratory, alkoxyquinoline trimers have demonstrated micromolar inhibition against antiapoptotic proteins Bcl-2 and Bcl-xL. Therefore, we carried on this structure-activity relationship study with the synthesis of novel analogues. Kinases Pim Protéines bcl-2 Isoindole Indazole Quinoléine Couplage de Suzuki Pim kinases Bcl-2 proteins Isoindole Indazole Quinoline Suzuki cross coupling
8	Molecular basis of BCL2L10/Nrh oncogenic activity in breast cancer / Bases Moléculaires de l’activité oncogénique de BCL2L10/Nrh dans le contexte du cancer du sein Nougarede, Adrien 18 October 2016 (has links) L'apoptose, ou « mort cellulaire programmée », joue un rôle clé dans de nombreux processus biologiques. Les protéines de la famille Bcl-2, dont l'expression est souvent altérée dans les cellules tumorales, sont les principaux régulateurs de l'apoptose. Parmi cette famille, la fonction exacte du répresseur apoptotique Nrh, aussi appelé BCL2L10 ou Bcl-B, reste à ce jour mal comprise. Bien que son expression ne soit pas détectable dans la plupart des tissus sains, on retrouve des niveaux élevés de Nrh corrélés à un mauvais pronostique dans les cancers du sein et de la prostate. Nous avons mis au jour un nouveau mécanisme selon lequel Nrz, l'orthologue de Nrh chez le poisson zèbre, interagit avec le domaine de liaison du ligand IP3 du canal calcique IP3R1. Il s'est avéré que la régulation négative des flux calciques par Nrz est critique lors du développement embryonnaire du poisson zèbre. Grâce à ces nouvelles données, nous avons cherché à comprendre la fonction de Nrh chez l'Homme, dans un contexte pathologique. Nous avons montré que Nrh interagit via son domaine BH4 avec le domaine de liaison du ligand du récepteur IP3R1 humain pour réguler l'homéostasie calcique et la mort cellulaire. Cette interaction définit Nrh comme la seule protéine de la famille Bcl-2 à réguler négativement la mort cellulaire exclusivement au niveau du réticulum endoplasmique. Pour aller plus loin, nous avons montré que la dissociation du complexe Nrh/IP3Rs sensibilise des cellules tumorales mammaires à l'action d'agents chimiothérapeutiques. Pour finir, nos résultats apportent une explication moléculaire sur la contribution de Nrh dans la résistance aux thérapies anti-tumorales / Apoptosis, also called “Programmed Cell Death”, plays a key role in many biological processes and pathologies. The B-cell lymphoma 2 (Bcl-2) proteins, whose expression is often altered in tumor cells, are the main regulators of apoptosis.Among this family, the actual physiological function of the human apoptosis inhibitor Nrh, also referred to as BCL2L10 or Bcl-B, remains elusive. Although in most healthy tissues the Nrh protein is nearly undetectable, clinical studies have shown that Nrh expression is correlated with poor prognosis in breast and prostate carcinomas. We have shed light on a novel mechanism by which Nrz, the zebrafish ortholog of Nrh, was found to interact with the Ligand Binding Domain (LBD) of the Inositol-1,4,5-triphosphate receptor (IP3R) type-I Ca2+ channel. Indeed, the regulation of IP3Rs-mediated Ca2+ signaling by Nrz was shown to be critical during zebrafish embryogenesis. We used the knowledge gained with the zebrafish model to investigate Nrh function in cancer. We showed that Nrh interacts with the LBD of IP3Rs via its BH4 (Bcl-2 Homology 4) domain, which is critical to regulate intracellular Ca2+ trafficking and cell death. Actually, this interaction seems to be unique among the Bcl-2 family, and sets Nrh as the only Bcl-2 homolog to negatively regulate apoptosis by acting exclusively at the Endoplasmic Reticulum. Furthermore, we showed that disruption of the Nrh/IP3Rs complex primes Nrh-dependent cells to apoptotic cell death and enhances chemotherapy efficiency in breast cancer cell lines.Lastly our results bring a new insight to the role of Nrh regarding chemotherapy resistance Protéines Bcl-2 Apoptose BCL2L10/Nrh Récepteurs à l’IP3 (IP3R) Calcium Peptides Bcl-2 proteins Apoptosis BCL2L10/Nrh IP3 Receptors (IP3Rs) Calcium Peptides 572
9	Transcription factors and downstream genes modulating TNF-gas + IFN-gcs induced beta cell apoptosis Barthson, Jenny 08 April 2013 (has links) In type 1 diabetes (T1D) a combination of genetic predisposition and environmental factors triggers islet inflammation (insulitis) leading to a selective and gradual destruction of the pancreatic beta cells. Beta cells mainly die through apoptosis, triggered at least in part by pro-inflammatory cytokines such as IL-1β, TNF-α and IFN-γ. Recent findings suggest that the mitochondrial pathway of cell death is involved in this death cascade. Array analysis indicated that TNF-α+IFN-γ induces transcription factors such as NF-ĸB, STAT1, and AP-1 in beta cells. We presently aimed to examine the pathway(s) of apoptosis triggered by TNF-α+IFN-γ in beta cells. <p>TNF-α+IFN-γ induces beta cell apoptosis through the intrinsic pathway of cell death. This involved activation of the BH3 only proteins DP5, PUMA and Bim. Knockdown (KD) of either DP5 or PUMA or both led to a partial protection of INS-1E cells (12-20%), while silencing Bim led to about 60% protection against cytokine-induced apoptosis. Bim is transcriptionally induced by activated STAT1. TNF-α+IFN-γ also induces downregulation of Bcl-XL, an anti-apoptotic Bcl-2 gene which inhibits Bim. Knocking down Bcl-XL alone led to increase in apoptosis, but this was prevented by the parallel KD of Bim.<p>The ultimate goal of our research is to protect beta cells from the autoimmune assault. Previous data revealed that JunB inhibits ER stress and apoptosis in beta cells treated with IL-β+IFN-γ. Here, TNF-α+IFN-γ up-regulated the expression of JunB which was downstream of activated NF-ĸB. JunB KD exacerbated TNF-α+IFN-γ induced beta cell death in primary rat beta cells and INS-1E cells. The gene networks affected by JunB were studied by microarray analysis. JunB regulates 20-25% of the cytokine-modified beta cell genes, including the transcription factor ATF3 and Bcl-XL. ATF3 expression was increased in cytokine-treated human islets and in vitro silencing of JunB led to >60% reduction in ATF3 overexpression. We confirmed direct JunB regulation of the ATF3 promoter by its binding to an ATF/CRE site. Silencing of ATF3 aggravated TNF-α+IFN-γ induced cell death in beta cells and led to the downregulation of Bcl-XL expression in INS-1E cells. Pharmacological upregulation of JunB using forskolin led to upregulation of ATF3 and consistent protection of these cells against cytokine-induced cell death, while genetic overexpression of JunB in mice increased ATF3 expression in the pancreatic islets and reversed the pro-apoptotic effects of cytokines on beta cells (±40 % protection). <p>As a whole, our findings indicate that TNF-α+IFN-γ triggers beta cell apoptosis by the upregulation of the pro-apoptotic protein Bim and downregulation of the Bcl-XL protein. These deleterious effects are at least in part antagonized by JunB via activation of ATF3. <p><p>Dans le diabète de type 1 (DT1), la combinaison de facteurs génétiques de prédisposition et de l'environnement déclenche l'inflammation des îlots de Langerhans (insulite) conduisant à une destruction sélective et progressive des cellules bêta du pancréas. Les cellules bêta meurent principalement d’apoptose, déclenchée au moins en partie par les cytokines pro-inflammatoires sécrétées par les cellules immunitaires comme l’IL-β, le TNF-α l’IFN-γ. De récentes découvertes suggèrent que la voie mitochondriale de la mort cellulaire jouerait un rôle dans la mort de ces cellules. L'analyse de réseaux de gène utilisant les biopuces d’ADN indique que l’association TNF-α+IFN-γ induit l’activation de facteurs de transcription tels que NF-ĸB, STAT1 et AP-1 dans la cellule bêta. Dans ce contexte, nous avons cherché à examiner les voies de l'apoptose déclenchées par le TNF-α+IFN-γ dans la cellule bêta. <p>En présence de TNF-α+IFN-γ les cellules bêta meurent par apoptose via la voie intrinsèque. L’activation des protéines pro-apoptotiques « BH3-seulement » dont DP5, PUMA et Bim étaient en cause de cette apoptose. Le « knockdown »1 (KD), de DP5 ou de PUMA, ou des deux en même temps conduit à une protection partielle des cellules INS-1E (12-20%), tandis que le KD de Bim conduit à environ 60% de protection contre l’apoptose induite par cette combinaison de cytokines. La transcription de Bim est induite par STAT1 activé. Parallèlement à la régulation positive de Bim, TNF-α+IFN-γ conduit à la régulation négative de la protéine Bcl-XL. Bcl-XL est une protèine anti-apoptotique de la famille de protèines Bcl-2 qui en general inhibe Bim. Réduire l’expression de Bcl-XL seul induit une augmention de l'apoptose, alors que le KD de Bim et Bcl-XL en parallèle empêche l'apoptose.<p>Le but ultime de notre recherche est de protéger les cellules bêta des agressions autoimmunitaires. Les données antérieures ont révélé que JunB inhibe le stress du réticulum endoplasmique et l'apoptose dans les cellules bêta traitées avec IL-β+IFN-γ. Nous avons observé que TNF-α+IFN-γ induit l'expression de JunB qui se produit en aval de NF-ĸB activé. Il est important de noter que l’inactivation de JunB par des agents interférants de l’ARN (siRNA) exacerbe la mort des cellules primaires bêta de rat et de cellules INS-1E induite par les cytokines. Les réseaux de gènes touchés par JunB ont été étudiés grâce a l'analyse en microréseaux. JunB règule 20-25% des gènes modifiés par des cytokines dans les cellules bêta, y compris le facteur de transcription ATF3 et Bcl-XL. L’expression d’ATF3 est augmenté dans les îlots humains traités avec les cytokines et la répression in vitro de JunB conduit à une réduction de >60% de l’expression d’ATF3. Nous avons confirmé la régulation d’ATF3 par JunB en montrant que JunB est directement lié au promoteur d’ATF3 via le site ATF/CRE. La diminution d’expression d’ATF3 en presence de TNF-α+IFN-γ a aggravé la mort cellulaire induite dans les cellules bêta et a conduit à la régulation négative de l'expression de Bcl-XL dans les cellules INS-1E. L’augmentation pharmacologique de JunB dans les cellules INS-1E par l’utilisation de forskolin a conduit à la régulation positive en aval d’ATF3 et par conséquente à la protection de cellules bêta vis-a-vis de effets indésirables des cytokines. Dans cette optique, la surexpression génétique de JunB dans le modèle Ubi-JunB de souris transgénique a conduit à une surexpression d’ATF3 dans les îlots pancréatiques et a permir d’inverser les effets pro-apoptotiques de cytokines sur la cellule bêta (protection ± 40%).<p>Globalement, ces résultats indiquent que TNF-α+IFN-γ déclenche l'apoptose des cellules bêta par la régulation positive du gène pro-apoptotique Bim et la régulation négative du gène anti-apoptotique Bcl-XL. Ces effets indésirables sont inhibé en partie par JunB via l’activation de ATF3.<p><p>1Pas d’équivalent en français. Signifie la réduction de l’expression d’un gène via utilisation d’un siRNA (agent interférant de l’ARN).<p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished Disciplines biomédicales diverses Médecine pathologie humaine Transcription factors Islands of Langerhans Pancreatic beta cells Apoptosis Autoimmune diseases Facteurs de transcription Langerhans, Ilots de Langerhans, Cellules bêta des îlots de Apoptose Maladies auto-immunes STAT1 AP1 BCL-2 proteins transcription factors apoptosis beta cell
10	Mechanismen der Inhibierung von Wirtszellapoptose durch <i>Toxoplasma gondii</i> / Inhibition mechanisms of host cell apoptosis by <i>Toxoplasma gondii</i> Hippe, Diana 30 October 2008 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science <i>Toxoplasma gondii</i> Apoptose Caspase Fas/CD95;Bcl-2-Proteine BH3-only Protein <i>Toxoplasma gondii</i> apoptosis caspase Fas/CD95;Bcl-2-proteins BH3-only protein 42.36 WHF 900: Zelltod, Apoptose {Cytologie} MED 337: Parasitologie {Medizin}

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