Global ETD Search

31	RASA1 Function in Vascular Development and Disease Kawasaki, Jun January 2012 (has links) Vascular anomalies include a range of mild to severe defects that can be life-threatening, debilitating, or disfiguring. Mutation in the RASA1 gene was found to underlie capillary malformation-arteriovenous malformation; however, there has been no mechanistic understanding of how the loss of function of RASA1 contributes to this disease. In human endothelial cells, presence of ephrin-B2 dominated over serum stimulation to reduce MAPK and PI3K-mTORC1 pathway activation, only when EphB4 and RASA1 were both present. Indeed, zebrafish model showed that vascular defects in EphB4 knockdown embryos were prevented by EphB4 mRNA only when RASA1 binding sites were present. Moreover, reduced function of either EphB4 or RASA1 gene product can generate comparable defects in blood vessel formation and function. Increased TORC1 activity was observed in the affected caudal tail region, which was rescued by treatment with the small molecule inhibitors of PI3K and/or mTORC1 kinases. To further examine whether endothelial specific activation of TORC1 was responsible for these vascular defects, a transgenic zebrafish line, expressing a gain-of-function mutant RhebS16H under endothelial specific promoter, was generated. Transgene-positive embryos augmented the vascular phenotypes with the low doses of RASA1 or EphB4 morpholino, which showed no phenotypes in their wild-type siblings. These data demonstrate a distinct angiogenic role for EphB4 and RASA1 as vascular suppressors of TORC1 activity. To investigate the translational value of this finding, mouse retinal angiogenesis assay was performed by intravitereally injecting RASA1 siRNA. This resulted in a significant increase in vascular density in the retina. Moreover, immunohistochemistry was performed on resected tissues from patients with RASA1 mutations and RASA1-related vascular malformations. Remarkably, consistent and robust phospho-S6 staining was restricted to endothelial cells in these patient blood vessels. This study provides a molecular rationale for the use of FDA-approved mTORC1 inhibitory drugs in the treatment of RASA1-deficient vascular pathologies. A new therapeutic use of an approved drug reduces the time and cost required for drug development, while providing patients with a targeted treatment. Furthermore, we demonstrate the translational value of the zebrafish model as an alternative vertebrate system for the investigation of endogenous endothelial functions of mTORC1 and its cardiovascular consequences. EphB4 mTORC1 RASA1 cellular biology developmental biology molecular biology vascular anomalies
32	Regulation of exosome secretion and functions by mTORC1 signalling and the microenvironment Perera, Mihindukulasuriya Weliweriyage Sumeth January 2017 (has links) Cancer cells require survival strategies to respond to microenviromental changes and out-compete their neighbours. They activate stress response mechanisms under extreme microenvironmental conditions, some of which are controlled by the amino acid-sensitive kinase complex, mechanistic Target of Rapamycin Complex 1 (mTORC1). Exosomes are secreted nanovesicles made inside intracellular endosomal compartments that mediate a specialised and complex form of intercellular signalling that can reprogramme target cells via the action of multiple active cargos. I investigated whether mTORC1 activity might modulate the type of exosome secreted in response to microenvironmental changes. Here I identify a new form of mTORC1-regulated exosome biogenesis and signalling involving recycling multivesicular endosomes (rMVEs), a previously unrecognised site for exosome biogenesis. Reduced activity of a specific form of glutamine-sensitive mTORC1 in HCT116 colorectal cancer cells results in an âexosome switchâ in which exosomes are preferentially released from these compartments instead of late endosomes. Importantly, RAB11a is found in association with at least a proportion of rMVEs that generate these alternative exosomes and is loaded on to some of their ILVs, providing a RAB signature of compartmental origin. I provide evidence that this exosome switch is conserved in other cancer cell types. My study also presents a proteomics analysis of extracellular vesicle (EV) preparations from normal and mTORC1-inhibited cells. I demonstrate that EV preparations isolated following exosome switching have enhanced pro-angiogenic properties and novel tumour growth-promoting activities. Activation of the receptor tyrosine kinase c-MET and its downstream mitogen-activated protein kinase (MAPK) ERK via phosphorylation is stimulated by these EVs, providing a potential explanation for their growth-promoting effects. Subsequent studies in the lab have demonstrated that several of these pro-tumorigenic activities are mediated by exosomes. I conclude that stress-induced mTORC1 inhibition allows tumour cells to initiate a novel exosome secretion pathway that potentially mediates a cancer cell survival plan that reverses microenvironmental change and supports tumour adaptation. In the future, blocking this response could improve patient outcome following treatment with mTORC1-inhibitory or anti-angiogenic drugs that have currently met with limited success in the clinic.
33	Regulación de la degradación intracelular de proteínas por glucosa Moruno Manchón, José Félix 07 January 2014 (has links) La supervivencia celular frente a los cambios ambientales requiere el mantenimiento de un equilibrio dinámico entre la síntesis y la degradación de proteínas. La degradación de proteínas, además de regular diferentes procesos celulares, tiene como función principal la eliminación de productos que no son útiles para la célula en determinadas situaciones o cuya acumulación puede ser tóxica. Los productos de esta degradación, es decir los aminoácidos, son reutilizados para la síntesis de nuevas moléculas o son metabolizados para la obtención de energía. La alteración de esta proteólisis intracelular puede llevar a la acumulación en el citoplasma de orgánulos defectuosos o de moléculas que se pueden agrupar en agregados insolubles y que pueden así desencadenar diferentes patologías. Aunque se ha avanzado bastante durante los últimos años en los conocimientos sobre la degradación intracelular de proteínas y de sus principales mecanismos, existen bastantes detalles moleculares todavía desconocidos. Por este motivo es necesario aportar nueva información sobre estos procesos que además podría ser relevante para identificar nuevas dianas terapéuticas y desarrollar tratamientos más eficaces para las enfermedades derivadas de alteraciones en los mismos. La degradación de proteínas ocurre por diferentes mecanismos que pueden clasificarse generalmente en dependientes o no de unos orgánulos citoplásmicos, los lisosomas. La macroautofagia (a la que se denomina generalmente con el término más simple de autofagia) y el sistema ubicuitina-proteasomas son, respectivamente, los más importantes de esos dos grupos. Básicamente, el sistema ubicuitina-proteasomas consiste en la poliubicuitinación de proteínas que son después degradadas por los proteasomas. La autofagia en cambio se inicia con el secuestro de porciones del citoplasma en estructuras de doble membrana que se cierran formando los autofagosomas. Posteriormente, los autofagosomas se fusionan con endosomas y con lisosomas dando lugar a los autolisosomas, en los que por la acción de las proteasas o catepsinas lisosomales se degrada el material encerrado. La autofagia está regulada por una amplia variedad de vías de señalización que responden a multitud de factores ambientales. Entre estos últimos, la situación de ayuno de nutrientes es la inductora más potente de la autofagia. Durante la privación de nutrientes como los aminoácidos, la célula sufre un estrés energético que debe tratar de reducir produciendo ATP a partir de nuevas fuentes. Para ello activa la autofagia para degradar los componentes de la célula, como las proteínas, hasta producir sus unidades básicas que después son metabolizadas. Por el contrario, se ha demostrado que cuando se proporcionan aminoácidos a la célula la autofagia es inhibida. Aunque el efecto sobre la autofagia de los aminoácidos ha sido estudiado ampliamente en muchos laboratorios, no estaba tan claro ese efecto en el caso de otro nutriente, la glucosa, ya que cuando planteamos ese estudio los datos eran contradictorios. En este trabajo hemos podido establecer claramente que la glucosa tiene un papel inductor sobre la autofagia empleando técnicas muy variadas que incluyen: la cuantificación por ¿Western-blot¿ de los niveles del marcador de autofagia LC3-II en presencia o en ausencia de inhibidores lisosomales, la cuantificación de la proteína degradada, total y por la vía autofágica, mediante experimentos de pulso y caza, la cuantificación morfométrica de estructuras autofágicas (equivalentes a autofagosomas y autolisosomas) por microscopia electrónica y la cuantificación de la masa lisosomal por fluorescencia. Además, hemos comprobado que la glucosa también induce la ubicuitinación de proteínas y la degradación de estas por los proteasomas. Con estos y otros datos obtenidos durante el desarrollo de esta tesis doctoral, hemos podido concluir que la glucosa induce la autofagia en todos los tipos celulares estudiados y en todas las condiciones ensayadas. Este efecto disminuye o se enmascara cuando están presentes a la vez otros factores que son inhibidores de la autofagia, como los aminoácidos o el suero bovino fetal, lo que podría explicar algunos de los datos contradictorios en la literatura. La glucosa aporta la energía necesaria para el correcto funcionamiento de la autofagia a partir de unos niveles mínimos de ATP. Un descenso en la disponibilidad energética a través de la inhibición de la glucólisis reprime la autofagia inducida por la glucosa. Sin embargo, la estimulación de la autofagia por glucosa no parece depender únicamente de la disponibilidad de ATP, sino que hemos identificado una vía de señalización en la que no interviene AMPK a pesar de responder al descenso de los niveles de ATP y al aumento de los niveles de calcio durante la incubación en un medio carente de glucosa. Esta vía tampoco implica a mTORC1 y en ella sí interviene en cambio la MAPK p38¿, como hemos comprobado con diferentes inhibidores de esta quinasa, con el uso de siRNAs o empleando MEFs p38-/-. Consideramos que estos resultados contribuyen a clarificar más la regulación de la autofagia por nutrientes y, más concretamente, por uno tan relevante como es la glucosa. / Moruno Manchón, JF. (2013). Regulación de la degradación intracelular de proteínas por glucosa [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/34775 / TESIS AMPK Autofagia Autofagosoma Autolisosoma Degradación de proteínas Energía Glucosa LC3 Lisosomas MTORC1 P38 MAPK Proteasoma Proteólisis Ubicuitina
34	Early growth response protein 1 mediates the effect of insulin on leptin transcription in adipocytes Mohtar, Omar 07 October 2019 (has links) All cells and organisms consume energy for survival. A robust system has evolved in vertebrates to serve as an energy reservoir. In particular, specialized cells, adipocytes, are responsible for the dynamic storage of energy by accumulating and releasing fatty acids. Fluctuating energy demands require adipose tissue to adjust in size, however complications can arise in both extremes giving rise to systemic diseases, such as obesity and diabetes mellitus (T2D). In mammals, leptin production in adipocytes is up-regulated by feeding and insulin to provide long-term post-prandial satiety. Although this regulatory connection is central to all physiological effects of leptin, the molecular mechanism remains unknown for leptin production. Here, we show that the transcription factor Egr1 is rapidly but transiently induced by insulin in adipose cells both in vitro and in vivo in a mTORC1-dependent fashion. Induction of Egr1 was immediately followed by an increase in leptin transcription. Chromatin immunoprecipitation and luciferase assays demonstrate that Egr1 directly binds to and activates the leptin promoter. Interestingly, the lipid droplet protein Fat specific protein 27 (FSP27) may work as a co-factor for Egr1 in regulating leptin expression. By using siRNA-mediated knock out of Egr1 along with its over-expression in adipocytes, we demonstrate that Egr1 is both necessary and sufficient for the stimulatory effect of insulin on leptin transcription. Knockout of the mTORC1-regulated translation repressor 4EBP1/2 increases leptin transcription both in vitro and in vivo. Adipose specific doxycycline-inducible constitutively active Rheb transgenic mouse lines contained higher circulating leptin and transcription of leptin following doxycycline treatment and were able to maintain elevated leptin levels following a 16 hour fast. Thus, insulin and nutrients, such as amino acids and glucose, activate leptin expression via the mTORC1-Egr1 regulatory axis. Biochemistry Adipocyte Diabetes Early growth response protein 1 Insulin Leptin MTORC1
35	Effect of Acute Alcohol Ingestion on Resistance Exercise Induced mTORC1 Signaling in Human Muscle Duplanty, Anthony A. 08 1900 (has links) The purpose of this project was to further elucidate the effects post-exercise alcohol ingestion. This project had many novel aspects including using a resistance exercise (RE) only exercise design and the inclusion of women. To our knowledge, we are the first to investigate the effect of post-RE alcohol ingestion in women. In the first chapter of this project, information on the prevalence of alcohol use and the importance of skeletal muscle as a dynamic and metabolic tissue was provided. In chapter two, the effects of post-RE alcohol ingestion in men and women are detailed. The major findings of this study was that although RE elicited similar mTORC1 signaling both in men and in women, alcohol ingestion appeared to only attenuate RE-induced phosphorylation of the mTORC1 signaling pathway in men. The third chapter focused on examining the effects of post-RE alcohol ingestion on acute testosterone bioavailability. The primary findings of this study was that alcohol substantially elevated serum total and free testosterone concentrations during recovery from a bout of resistance exercise. The fourth chapter detailed factors that contribute to bone density in men. The major findings of this study was that young adult male long-distance runners who participated in resistance training at least once per week had greater bone mineral density than their non-resistance trained and non-exercise trained peers. mTORC1 alcohol resistance exercise Isometric exercise. Alcohol -- Physiological effect. Testosterone. Bone -- Density. Muscles.
36	The Functional Role of Hepatic Argonaute (Ago)-2 Slicer Activity in Metformin’s Action and Glucose Metabolism in Obese Mice Salem, Esam 22 October 2020 (has links) No description available. Surgery Argonaute 2 Metformin micro-RNA Slicer activity mTORC1 signaling Nascent protein
37	Identification of interacting partners of mammalian target of rapamycin complex 1 (mTORC1) assembly in human lymphocytes / Identification of interacting partners of mammalian target of rapamycin complex 1 (mTORC1) assembly in human lymphocytes Rahman, Hazir 20 January 2012 (has links) No description available. 570 Biowissenschaften, Biologie Biology (incl. Psychology) T cells mTORC1 signaling proteomics and interactomics rapamycin edc4 mRNA degradation T cells mTORC1 signaling proteomics and interactomics rapamycin edc4 mRNA degradation 42.00 42.13 WF800 WHF000
38	Ciblage thérapeutique d'AMPK dans les leucémies aiguës myéloïdes / AMPK is a therapeutic target in acute meloid leukemias Sujobert, Pierre 20 November 2014 (has links) Les leucémies aiguës myéloïdes (LAM) représentent un groupe d’hémopathies malignes agressives, de pronostic sombre en dépit des traitements intensifs actuellement proposés. Malgré une grande hétérogénéité clinique et moléculaire, les cellules de LAM sont caractérisées par l’activation de voies de signalisation essentielles à leur prolifération et leur survie, comme par exemple celle du complexe mTORC1 (mammalian target of rapamycin complex 1). Cependant, l’utilisation clinique d’inhibiteurs tels que la rapamycine ou des inhibiteurs catalytiques s’est avérée décevante, ce qui suggère qu’il n’y a pas d’addiction oncogénique à mTORC1 dans les LAM. Au cours de ce travail, nous avons démontré que l’activation de mTORC1 est au contraire une condition nécessaire à l’induction de la mort cellulaire en réponse à l’activation d’AMPK (AMP-activated protein kinase), établissant une relation de létalité synthétique entre ces deux voies. Pour cela, nous avons utilisé un nouveau composé activateur spécifique d’AMPK, le GSK621. En invalidant la sous-unité catalytique AMPKα1 par ARN interférence ou par le système CRISPR/Cas9, nous avons démontré que les effets antileucémiques de ce composé sont bien dépendants de l’activation d’AMPK. Nous avons observé que ce composé favorise l’autophagie, et que ce processus est impliqué dans la mort des cellules leucémiques puisque l’inhibition des protéines ATG5 ou ATG7 a un effet protecteur sur les cellules leucémiques. Les effets antileucémiques du composé GSK621 ont été confirmés sur des cellules primaires, ainsi que sur un panel de vingt lignées de LAM, et dans un modèle murin de xénogreffe. De façon intéressante, l’activation d’AMPK pourrait également compromettre la survie des cellules souches leucémiques, comme en atteste l’atténuation du potentiel clonogénique en méthylcellulose de cellules murines transformées par MLL-ENL ou FLT3-ITD. Nous avons observé que le composé GSK 621 n’avait pas de toxicité envers les progéniteurs hématopoïétiques normaux, ouvrant ainsi une fenêtre thérapeutique intéressante. Comme l’activation d’AMPK conduit dans de nombreux modèles cellulaires à l’inhibition de mTORC1, et comme l’activation de mTORC1 est observée dans les cellules de LAM mais pas dans les progéniteurs hématopoïétiques normaux, nous avons proposé l’hypothèse que le niveau d’activation de mTORC1 déterminait les effets de l’activateur d’AMPK. Pour cela, nous avons inhibé mTORC1 dans les cellules leucémiques d’une part, et activé mTORC1 dans les progéniteurs normaux d’autre part. De façon inattendue, mTORC1 échappe au contrôle d’AMPK dans les LAM, et nous avons observé que l’activation de mTORC1 est une condition nécessaire et suffisante pour que le composé GSK621 entraîne la mort des cellules. Le substrat moléculaire de cette létalité synthétique est le facteur de transcription proapoptotique ATF4, dont la transcription est favorisée par mTORC1, et la traduction par AMPK via la phosphorylation d’eIF2A. Ces travaux proposent donc que malgré l’absence d’addiction oncogénique, l’activation de mTORC1 dans les LAM représente une opportunité thérapeutique originale via une relation de létalité synthétique avec l’activation d’AMPK. Ils constituent un rationnel au développement clinique d’activateurs d’AMPK dans les LAM, voire dans d’autres cancers ayant une activation constitutive de mTORC1. / Acute myeloid leukemia (AML) is a heterogeneous disease with poor prognosis despite intensive treatments. Virtually all recurrent molecular alterations in AML functionally converge to cause signal transduction pathway dysregulation that drives cellular proliferation and survival. The mammalian target of rapamycin complex 1 (mTORC1) is a rapamycin-sensitive signaling node defined by the interaction between mTOR and raptor. Constitutive mTORC1 activity is nearly universal in AML. However, pharmacologic inhibition with rapamycin or second-generation mTOR kinase inhibitors has shown limited anti-leukemic activity in both preclinical models as well as in clinical trials, suggesting that addiction to this oncogene is not a recurrent event in AML. Here we report that sustained mTORC1 activity is nonetheless essential for the cytotoxicity induced by pharmacologic activation of AMP-activated protein kinase (AMPK) in AML. Our studies employed a novel AMPK activator called GSK621. Using CRISPR/Cas9 and shRNA-mediated silencing of the AMPKa1 catalytic subunit, we showed that AMPK activity was necessary for the anti-leukemic response induced by this agent. GSK621-induced AMPK activation precipitated autophagy, and blocking autophagy via shRNA-mediated knockdown of ATG5 or ATG7 protected AML cells from cytotoxicity resulting from treatment with GSK621, suggesting that autophagy promotes cell death in the context of active AMPK. GSK621 cytotoxicity was consistently observed across twenty different AML cell lines, primary AML patient samples and AML xenografts in vivo. GSK621-induced AMPK activation also impaired the self-renewal capacity of MLL-ENL- and FLT3-ITD-induced murine leukemias as measured by serial methylcellulose replating assays. Strikingly, GSK621 did not induce cytotoxicity in normal CD34+ hematopoietic progenitor cells. We hypothesized that the differential sensitivity to GSK621 could be due to the difference in amplitude of mTORC1 activation between AML and normal CD34+ cells. In contrast to most reported cellular models in which AMPK inhibits mTORC1, sustained mTORC1 activity was seen following GSK621-induced AMPK activation in AML. Inhibition of mTORC1 either pharmacologically (using rapamycin) or genetically (using shRNAs targeting raptor and mTOR) abrogated AMPK-induced cytotoxicity in AML cells, including primary AML patient samples. The same synthetic lethality could be recapitulated in normal CD34+ progenitors by constitutive activation of mTORC1 using a lentivirally-transduced myrAKT construct. We further observed that the level of ATF4 protein is under a transcriptionnal control by mTORC1 and a translational control by AMPK (through eIF2A), and explains the synthetic lethal relationship between AMPK and mTORC1. Taken together, these data show that the magnitude of mTORC1 activity determines the degree of cytotoxicity triggered by AMPK activation. Our results therefore support AMPK activation as a promising therapeutic strategy in AML and other mTORC1-active malignancies which warrants further investigations in clinical trials. Leucémie aigue myéloïde LAM AMPK MTORC1 Létalité synthétique Autophagie Voie de réponse intégrée au stress ATF4 EIF2A PERK Acute myeloid leukemia AML AMPK MTORC1 Synthetic letality Autophagy Integrated stress response ATF4 EIF2A PERK 616.994 19
39	Etude du rôle de la traduction dans les leucémies aigues myéloïdes : les voies mTORC1, LKB1/AMPK et la sérine-thréonine kinase PIM-2 / Pas de titre traduit Green, Alexa Samantha 11 July 2013 (has links) Les leucémies aigues myéloïdes (LAM) sont des hémopathies malignes de mauvais pronostic dont les thérapies actuelles ne permettent d’obtenir des taux de survie à 5 ans chez les adultes que d’environ 40%. Par conséquent, il est nécessaire d’approfondir nos connaissances concernant les mécanismes d’oncogenèse pour développer de nouvelles approches thérapeutiques. Malgré leur hétérogénéité clinique et biologique, les LAM ont certaines caractéristiques communes comme l’activation de la voie de signalisation mTORCl qui est détectée dans la plupart des échantillons de LAM. MTORCl contrôle la survie, la croissance et la prolifération cellulaire, notamment via le contrôle de la traduction des ARNm et donc de la synthèse protéique. Au cours de ce travail, nous montrons qu’il existe, dans les LAM, une dérégulation de mTORCl qui explique les limites des effets anti-leucémiques observés avec la rapamycine (un inhibiteur allostérique de mTORCl) et qui est médiée en partie par l’activité de la sérine thréonine kinase Pim2, qui contrôle la phosphorylation de la cible de mTORCl, la protéine 4E-BP1. Cependant, cibler directement la traduction produit des effets anti-leucémiques importants, ce que nous avons montré en utilisant une molécule inhibant spécifiquement le complexe d’initiation de la traduction, le 4EGI-l. EIF4E est essentiel à l’initiation de la traduction et nous avons montré sa surexpression au niveau protéique dans la plupart des échantillons de LAM au diagnostic par comparaison à des cellules hématopoïétiques normales CD34+. Bien que son niveau d’expression n’ait pas de valeur pronostique intrinsèque, ce résultat suggère un potentiel important au blocage de la traduction dans la plupart des cas de LAM. Dans la perspective d’inhiber mTORCl, nous avons activé la voie LKBl/AMPK par la metformine, ce qui a induit des effets anti-leucémiques in vitro et in vivo via une modification du métabolisme cellulaire avec en particulier une inhibition de la synthèse de protéines oncogéniques. La metformine n’étant pas un candidat en thérapeutique dans les LAM du fait d’un index thérapeutique trop étroit, de nouvelles molécules modulant la voie LKBl/AMPK sont en cours de développement. Enfin, nous avons étudié le rôle de la sérine thréonine kinase Pim2, qui contrôle la traduction protéique et la survie dans les cellules de LAM Flt3-ITD+. Nous avons de plus montré que la sur-expression de Pim2 constitue un nouveau mécanisme de résistance aux inhibiteurs de Flt3 et représente donc une cible thérapeutique prometteuse dans cette catégorie de LAM. L’étude de la voie mTORCl et de la traduction permet donc d’envisager de multiples perspectives thérapeutiques dans les LAM dont certaines sont déjà en cours de développement clinique. / Acute myeloid leukemia (AML) are hematological malignancies with adverse prognosis in which therapies only gives 40% survival within 5 years in adults. Hence, it is important to increase our knowledge regarding oncogenesis to further develop new therapeutic approaches. Despite their clinical and biological heterogeneity, AML have in common the constitutive activation of mTORC1 signaling which is detected in most AML samples. MTORC1 controls cell survival, growth and proliferation, in particular through control of mRNA translation and protein synthesis. During this work, we show, in AML, that mTORC1 is deregulated which explain the poor effects observed with rapamycin (a mTORC1 allosteric inhibitor) and is partially mediated by the serine/threonine kinase Pim-2 which controls the mTORC1 target 4E-BP1. Nevertheless, directly targeting translation, using a specific translation initiation inhibitor named 4EGI-1, have important anti leukemic effects. EIF4E is described as essential in translation initiation and we show its protein overexpression in most AML samples at diagnosis compared with normal hematopoietic CD34+ cells. Whereas eIF4E level expression has no prognostic impact, this result suggests an important potential for treatment targeting translation initiation in AML. In our purpose of inhibiting mTORC1, we were able to activate LKB1/AMPK signaling pathway with metformin, which induces anti leukemic effects in vitro and in vivo through in particular oncogenic protein translation inhibition. Metformin is not a good AML therapeutic candidate because of a narrow therapeutic index, new compound targeting LKB1/AMPK are in development. Finally, we studied the role of the serine/threonine kinase Pim-2 and show that it controls protein translation and FLT3-ITD+ AML cells survival. Furthermore, we show that Pim-2 overexpression is a new mechanism of Flt3 inhibitors resistance and represent a new promising therapeutic target in this AML subtype. Overall, mTORC1 and protein translation study in AML show multiple therapeutics perspective, some of them are already in clinical development. LAM MTORC1 LKB1/AMPK Metformine Rapamycine SGI-1776 EIF4E Traduction cap-dépendante Pim2 Flt3-ITD AML MTORC1 LKB1/AMPK Metformin Rapamycin SGI-1776 Cap-dependant translation EIF4E Pim2 Flt3-ITD 616.994 19 616.15
40	Characterization of Amino Acid Transporters : Transporters expressed in the central nervous system belonging to the Solute Carrier family SLC38 Hellsten, Sofie Victoria January 2016 (has links) In cells and organelles transporters are responsible for translocation of amino acids, sugars and nucleotides among others. In the central nervous system (CNS), amino acid transporters can function as neurotransmitter transporters and nutrient sensors. The Solute carrier (SLC) superfamily is the largest family of transporters with 395 members divided in 52 families. The system A and system N amino acid transporter family, SLC38, consists of 11 members, SNAT1-11 (SLC38A1-11). The members are expressed in the brain, exclusively in neurons or astrocytes and some in both. Amino acid signaling is mainly regulated via two pathways, the amino acid responsive (AAR) pathway and the mechanistic/mammalian target of rapamycin complex 1 (mTORC1) pathway. These pathways regulate the protein synthesis in opposite directions depending on the amino acid availability. SLC38 members along with other SLCs have been identified to participate in these pathways. In paper I, the regulation of SLC genes after complete amino acid starvation in mouse hypothalamic cells have been studied with microarray and we found that 47 SLC genes were significantly altered at five hours of starvation. Interestingly, we found that Slc38a1 and Slc38a7 were upregulated along with the known starvation responding gene, Slc38a2. A complementary starvation study for the SLC38 genes was performed using primary mouse embryonic cortex cells. We found that Slc38a1, Slc38a2, Slc38a5, Slc38a6 and Slc38a8 were upregulated while Slc38a3, Slc38a7 and Slc38a11 were downregulated. Three members from the SLC38 family, SNAT8 (paper IV), SNAT9 (paper III) and SNAT10 (paper II) have been histologically characterized in mouse brain and all these transporters are exclusively neuronal. SNAT8 and SNAT10 were also functionally characterized and shown to be transporters for alanine and glutamine among others. SNAT8 was shown to mediate sodium dependent transport and was classified to system A. SNAT10 was shown to be a sodium independent bidirectional transporter and displayed characteristics for system A and N. SNAT9 is a lysosomal component of the Ragulator-Rag complex which senses amino acid availability and activates mTORC1. In paper III we also found that Slc38a9 gene expression was upregulated following starvation and downregulated following high-fat diet in mouse brain. Solute carriers amino acid transporter SLC38 family SLC38A8 SNAT8 SLC38A10 SNAT10 SLC38A9 SNAT9 amino acid starvation AAR mTORC1

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