Progression des maladies rénales chroniques : Rôle de la voie AKT/mTORC

Canaud, Guillaume

10 October 2012

La maladie rénale chronique (MRC) par ses conséquences organiques et psychologiques représente unenjeu majeur de santé publique. Sa physiopathologie reste mal connue, mais il est établi que toute atteinte rénale,quelle qu'en soit la cause, aboutit à une réduction du nombre de néphrons fonctionnels. Cette réductionnéphronique est responsable de processus adaptatifs complexes des néphrons sains restants pour maintenir unefonction rénale satisfaisante. Si la perte néphronique est suffisamment importante, le parenchyme rénal vas'altérer progressivement aboutissant au remplacement des néphrons sains par un tissu fibreux puis au déclin dela fonction rénale. Les mécanismes moléculaires impliqués, tant dans l'adaptation à la réduction néphronique,que dans la dégradation progressive du parenchyme rénal sont mal connus et les possibilités d'interventionsthérapeutiques limitées.La voie AKT/mTOR est une voie de signalisation intracellulaire ubiquitaire, très conservée, jouant unrôle central dans l'homéostasie cellulaire par sa fonction de régulation de la croissance, de l'apoptose et du cyclecellulaire. L'extraordinaire complexité de son mode de recrutement témoigne du rôle de carrefour de cette voie.Elle intègre des signaux multiples et très variés (facteurs de croissance, acides-aminés, niveau énergétiquecellulaire, disponibilité de l'oxygène) modulant l'anabolisme cellulaire. Notre compréhension du rôle de cettevoie dans la progression de la MRC est encore très limitée et les données sont peu nombreuses et controversées.Mon travail de thèse a consisté à évaluer, en utilisant un modèle expérimental de réduction néphroniquechez la souris, le rôle de la voie AKT/mTORC au cours de la progression des MRC.Nous résultats démontrent que AKT, et plus précisément AKT2, est une molécule essentielle àl'adaptation podocytaire aux contraintes imposées par la réduction néphronique. En appliquant plusieursmodèles de réduction néphronique à des souris génétiquement modifiées, nous avons pu établir la fonctioncruciale de cette isoforme. En effet, l'inactivation d'Akt2, soit systémique soit conditionnelle dans le podocyte,est responsable d'une hyporéactivité de la voie AKT podocytaire, d'un remodelage du cytosquelette, d'uneaugmentation de l'apoptose glomérulaire avec raréfaction podocytaire et de lésions de glomérulosclérose.Transposant nos données à la pathologie humaine, nous avons mis en évidence une activation podocytaired'AKT2 après transplantation rénale chez les patients présentant une altération importante de la fonction rénale.De façon marquante, la survenue d'une protéinurie en réponse à un traitement par sirolimus s'associait à uneperte de cette activation et à une augmentation de l'apoptose glomérulaire.Parallèlement, nous avons évalué le rôle de cette voie chez l'homme au cours d'une MRC trèsparticulière secondaire à la présence d'anticorps antiphospholipides. Cette néphropathie est caractérisée par laprésence de lésions vasculaires sévères prolifératives, hypertrophiques et progressivement obstructivesaboutissant à la destruction du parenchyme rénal. Jusqu'à maintenant, aucun lien formel n'avait été établi entre laprésence de ces anticorps et le développement des lésions vasculaires, et aucune thérapeutique n'était disponible.Nos résultats indiquent que ces anticorps sont directement pathogènes pour l'endothélium induisant l'activationde la voie AKT/mTORC. L'activation de cette voie stimule la prolifération des cellules endothéliales mais aussi ....

Maladie rénale chronique

AKT

MTOR

Podocytes

Cellules endothéliales

Anticorps antiphospholipides

Role fúzního proteinu ETV6-RUNX1 v citlivosti leukemických buněk na L-asparaginázu / The role of ETV6-RUNX1 fusion protein in the sensitivity of leukemic cells to L-asparaginase

Staněk, Petr

January 2018

Translocation t(12;21) with the presence of the fusion gene ETV6-RUNX1 (TEL-AML1) is the most common chromosomal aberration found in acute lymphoblastic leukemia in childhood. The occurrence of the ETV6-RUNX1 is associated with excellent prognosis and high sensitivity to the treatment with the enzyme L-asparaginase (ASNase). Resistance to the drug aggravates the outlook of the patient and increases the risk of treatment failure, therefore, the CLIP working group has been for a long time involved in the identification of the mechanism of action of ASNase and the origin of the resistance to it. This thesis follows previous findings of the group and is devoted to the analysis of the importance of ETV6-RUNX1 and signalization and metabolic changes accompanying shifts in the L-asparaginase resistance. In the first part of the thesis, the knockout clones with stable increased resistance to ASNase have been established thanks to the CRISPR/Cas9 system, which created frameshift in the fusion gene. The accomplishment in this regard and removal of the fusion protein was confirmed on the level of DNA, mRNA a protein expression. The presence of other significant chromosomal aberrations affection the sensitivity to ASNase was ruled out by the means of SNP analysis. In the second part of the project, the signalization...

Inflammation and Altered Signaling in Obstetric Pathologies

Tsai, Ya-Fang

12 August 2021

The purpose of this research project was to elucidate the molecular interactions and detail the signaling pathways in obstetric pathologies. This work first seeks to understand inflammation related complications relevant to obstetrics. Prior research in our lab identified the implications of the receptor of advanced glycation end products (RAGE) during inflammatory response in the placenta. Current work identified the presence of DNA double-strand breaks (DNA-DSBs) in inflammation associated pregnancy complications of preeclampsia (PE) and preterm labor (PTL) and demonstrated the positive role of RAGE in repairing the damage. The confluent relevance of disrupted mitochondrial function and inflammation has been recognized in the etiology of numerous chronic diseases. Our current studies aim to understand the connections between energy metabolism and inflammation in pathologies of pregnancy complications. Previous research conducted in our laboratory has demonstrated the mediation of the Gas6/Axl pathway on the mechanistic target of rapamycin (mTOR), an important metabolic molecule. We observed the negative regulation of Gas6 treatment on the mTOR pathway and its negative effects on trophoblast cell invasion. In the current study looking at the aspect of energy regulation, we identified the activation of placental mTOR in gestational diabetes mellitus (GDM) and its decrease during PE and intrauterine growth restriction (IUGR). We further evaluated the regulation of mTOR on its downstream effector pyruvate kinase M2 (PKM2). We found that inhibition of mTOR decreased PKM2 activation; while PKM2 activation positively regulated trophoblastic invasion and rescued negative effects observed in our second-hand smoke IUGR murine model. Our work has opened a new direction of placental research, especially in pregnancy complications stemming from genomic instability. We also clarified details of mTOR and PKM2 meditated metabolic signaling that are crucial for future investigation on the dynamic metabolic regulation during pregnancy.

RAGE

DNA-DSB

mTOR

PKM2

preeclampsia

preterm labor

intrauterine growth restriction

gestational diabetes mellitus

placenta

pregnancy trophoblast

Life Sciences

Exploring molecular patterns and determinants of melanoma cell susceptibility to natural killer cell cytotoxicity

Cappello, Sabrina

14 June 2021

No description available.

610

Melanoma

Natural killer cells

Immunotherapy

SNAI1

DIABLO

PI3K-AKT-mTOR pathway

NK cell resistance

GOK-MEDIZIN

Biologie (PPN619875151)

Régulation du métabolisme des ARNm par les voies de signalisation MAPK et mTOR

Cargnello, Marie

03 1900

Il est à ce jour bien établi que la régulation de l’expression génique dépend en grande partie des évènements post-transcriptionnels et que la traduction des ARNm tient un rôle de premier plan dans ces processus. Elle est particulièrement importante pour définir le protéome, maintenir l’homéostasie et contrôler la croissance et la prolifération cellulaire. De nombreuses pathologies humaines telles que le cancer découlent de dérèglements de la synthèse protéique. Ceci souligne l’importance d’une meilleure compréhension des mécanismes moléculaires contribuant au contrôle de la traduction des ARNm. Le facteur d’initiation eIF4E est essentiel à la traduction et son activité est régulée par ses partenaires protéiques dont font partie les protéines 4E-BP et 4E-T. Les voies de signalisation PI3K/mTOR et MAPK qui sont fortement impliquées dans l’étiologie du cancer, contrôlent la traduction en modulant l’activité d’eIF4E via l’inhibition des protéines 4E-BP et la localisation de 4E-T. Afin d’améliorer notre compréhension des mécanismes régulant la traduction des ARNm, nous avons utilisé plusieurs approches. Tout d’abord, nous avons caractérisé les mécanismes par lesquels le complexe mTORC1 est activé en réponse aux facteurs de croissance et avons déterminé que la kinase RSK, en aval de la voie Ras/ERK, contrôle directement l’activité de mTORC1 en phosphorylant Raptor, la sous-unité régulatrice du complexe mTORC1. Par ailleurs, nous nous sommes intéressés au rôle joué par mTORC1 dans l’initiation de la traduction. Pour cela, nous avons réalisé un criblage protéomique dans le but d’identifier de nouveaux facteurs sous le contrôle de mTORC1 qui participent activement à la traduction. Ces travaux ont ainsi permis l’identification de la protéine de liaison à l’ARN LARP1 comme effecteur majeur de la traduction des ARNm et de la croissance cellulaire en aval de mTORC1. Finalement, notre étude de l’effet du stress oxydant dans la répression de la traduction nous a permis de montrer que la kinase JNK contrôle la localisation du répresseur 4E-T au sein des P-bodies, qui sont des granules cytoplasmiques concentrant des ARNm non traduits et des facteurs de la dégradation des ARNm. Nos travaux ont donc abouti à la découverte de mécanismes moléculaires cruciaux impliqués dans la régulation de la traduction des ARNm et de la synthèse protéique. Ces derniers étant largement impliqués dans la prolifération cellulaire et la croissance tumorale, nos recherches ouvrent sur un champ d’investigation plus large pour le développement de nouvelles molécules anti-cancéreuses. / It is now well established that gene expression is predominantly regulated by post-transcriptional events and that mRNA translation plays an essential role in this process. Translation of mRNAs is especially important in defining the proteome, maintaining homeostasis and controlling cell growth and cell proliferation. Several human diseases such as cancer are associated with aberrant regulation of protein synthesis highlighting the need to better understand the molecular mechanisms contributing to translational control. The translation initiation factor eIF4E is a key component of the translational machinery whose activity is controlled by its partners, the 4E-BP and 4E-T proteins. The PI3K/mTOR and MAPK signaling pathways, which are strongly implicated in cancer etiology, control mRNA translation by modulating eIF4E activity through the inhibition of the 4E-BPs and the regulation of eIF4E localization by 4E-T. In order to better understand how mRNA translation is regulated we used several approaches. First, we characterized the mechanisms contributing to mTORC1 activation in response to growth factor. We found that the kinase RSK, that lies downstream of the Ras/ERK pathway, directly controls mTORC1 activity by phosphorylating Raptor, the regulatory sub-unit of the complex. This provides evidence of an additional mechanism by which MAPK pathway regulates mTORC1. We next performed a proteomic screen to identify novel mTOR-regulated factors that actively participate in translation. This approach led to the identification of several candidate proteins which included the RNA-binding protein LARP1 that we found to be a major effector of mTORC1-mediated mRNA translation, cell growth and proliferation. Finally we investigated the impact of oxidative stress on translation inhibition and found that the JNK kinase controls 4E-T localization in P-bodies that are cytoplasmic granules containing non-translating mRNAs and proteins from the mRNA decay and silencing machineries. Together this work provides important novel insights into the regulation of mRNA translation and protein synthesis that represent processes strongly connected to tumorigenesis and brings precious information on the mechanisms by which signaling pathways control cell growth and proliferation.

MAPK

Signalisation

Traduction des ARNm

eIF4E

P-Bodies

Signaling pathways

mRNA translation

mTOR

Adipocyte mTORC1 Signaling Separately Regulates Metabolic Homeostasis and Adipose Tissue Mass, Independent of RagGTPase Activity

Lee, Peter L.

05 July 2018

Metabolic disorders are commonly associated with obesity, a condition where excess caloric intake leads to massive adipose tissue (AT) expansion and eventual dysfunction. When adipose tissue loses its ability to store excess energy properly, lipids accumulate in non-adipose tissues such as liver, and muscle. This ectopic lipid deposition is a significant risk factor in the development of a collection of disorders described as metabolic syndrome. While metabolic syndrome is typically linked with obesity, patients who have an inability to develop adipose tissue depots (lipodystrophy) develop similar clinical outcomes. There is evidence that aberrant mTORC1 signaling may occur in both settings, and may be a factor that contributes to adipose dysfunction. I find that adipocyte specific loss of Raptor, a key mTORC1 subunit, leads to progressive lipoatrophy, and associated metabolic dysfunction including AT inflammation, hepatosteatosis, and insulin resistance. Interestingly, inhibition of autophagy, a pathway upregulated during Raptordeletion, prevents lipoatrophy but does not protect from ectopic lipid deposition and AT inflammation. These results suggest that outputs of mTORC1 in adipocytes individually regulate adipocyte storage capacity, and AT health. Furthermore, ablation of the amino acid sensing RagGTPases, thought to be necessary for mTORC1 activity, does not phenocopy Raptor KO, suggesting RagGTPase independent functions of mTORC1 in adipocytes. RagA/B deletion, however, did consistently increase Ucp1 expression in WAT, indicating a possible noncanonical role of the Rags in regulating Ucp1. Overall, these studies advance our understanding of regulation of adipose tissue metabolism, and shed light on previously unstudied nutrient specific signaling pathways in adipocytes.

mTOR

mTORC1

Raptor

Adipose

Adipocytes

Metabolism

Diabetes

Obesity

Lipodystrophy

Metabolic Syndrome

Cell Biology

Cellular and Molecular Physiology

Nutritional and Metabolic Diseases

Circadian Clock as the mechanism of Caloric Restriction in regulating mTOR Signaling and Glucose Homeostasis

Tulsian, Richa

26 November 2018

No description available.

Molecular Biology

Metabolism

gluconeogenesis

glycolysis

calorie restriction

aging

glucose

biological clocks

circadian clocks

mTOR signaling pathway

insulin sensitivity

protein translation

Role fúzního proteinu ETV6-RUNX1 v citlivosti leukemických buněk na L-asparaginázu / The role of ETV6-RUNX1 fusion protein in the sensitivity of leukemic cells to L-asparaginase

Staněk, Petr

January 2018

Translocation t(12;21) with the presence of the fusion gene ETV6-RUNX1 (TEL-AML1) is the most common chromosomal aberration found in acute lymphoblastic leukemia in childhood. The occurrence of the ETV6-RUNX1 is associated with excellent prognosis and high sensitivity to the treatment with the enzyme L-asparaginase (ASNase). Resistance to the drug aggravates the outlook of the patient and increases the risk of treatment failure, therefore, the CLIP working group has been for a long time involved in the identification of the mechanism of action of ASNase and the origin of the resistance to it. This thesis follows previous findings of the group and is devoted to the analysis of the importance of ETV6-RUNX1 and signalization and metabolic changes accompanying shifts in the L-asparaginase resistance. In the first part of the thesis, the knockout clones with stable increased resistance to ASNase have been established thanks to the CRISPR/Cas9 system, which created frameshift in the fusion gene. The accomplishment in this regard and removal of the fusion protein was confirmed on the level of DNA, mRNA a protein expression. The presence of other significant chromosomal aberrations affection the sensitivity to ASNase was ruled out by the means of SNP analysis. In the second part of the project, the signalization...

The Role of Hypoxia on Pyruvate Kinase M2, mammalian Target of Rapamycin, Mitochondrial Function, and Cell Invasion in the Trophoblast

Kimball, Rebecca Lutz

01 March 2016

This thesis will be organized into two chapters discussing the role of hypoxia in the human placenta. The goal of this thesis is to characterize pyruvate kinase M2, mammalian target of rapamycin, mitochondrial function, and cell invasion in hypoxic conditions in the trophoblast. Understanding the mechanisms of placental metabolism can lead to further treatments for placental diseases. Chapter one covers the background of intrauterine growth restriction, hypoxia, placental metabolism, and pyruvate kinase M2 (PKM2). Little is currently understood about the role of the mitochondria in placental diseases. Expression of PKM2, trophoblast cell invasion, and mitochondrial function is shown to be inhibited by hypoxia. PKM2 inhibition decreases trophoblast cell invasion and nuclear expression of PKM2, but increases mitochondrial function. Studying how hypoxia affects the placenta during placental diseases can help clarify the mechanisms by which these diseases occur. Chapter two further characterizes the background of intrauterine growth restriction and hypoxia. It also covers the background of mammalian target of rapamycin. The objective of this chapter was to assess activated mTOR in the trophoblast in hypoxia. Decreased placental and fetal weights, as well as trophoblast cell invasion were observed in hypoxia. A decrease in the activation of mTOR was also found in the hypoxic placenta. This study could provide insight into the physiological relevance of the pathways and could be targeted to help alleviate placental diseases.

placenta

pyruvate kinase M2 (PKM2)

intrauterine growth restriction (IUGR)

metabolism

mammalian target of rapamycin (mTOR)

Cell and Developmental Biology

Physiology

Metabolic Alteration in Growth Hormone Receptor Knock Out (GHRKO) Mice Treatedwith Rapamycin

Bell, Stephen Robert Clyde

10 September 2021

No description available.

Biology

Molecular Biology

Nutrition

Growth Hormone

Rapamycin

Growth Hormone Receptor Knockout Mouse

Insulin

Glucose Homeostasis

mTOR

IGF-1

Diabetes

Adiponectin