mTOR Inhibitors and Calcineurin Inhibitors Do Not Affect Adhesion Molecule Expression of Human Macro- and Microvascular Endothelial Cells

Lehle, Karla, Schreml, Stephan, Kunz-Schughart, Leoni A., Rupprecht, Leopold, Birnbaum, Dietrich E., Schmid, Christof, Preuner, Jürgen G.

January 2008

We examined the effect of cyclosporin A, tacrolimus, sirolimus and everolimus on the cell growth, viability, proliferation, expression of cellular adhesion molecules (CAM) and leukocyte (PBMC) binding of human macrovascular (coronary artery, saphenous vein) and microvascular endothelial cells (EC). Tacrolimus did not affect EC integrity, growth or expression of CAM. Exclusively, EC from the coronary arteries showed a reduced cellular growth (about 30%) under cyclosporin A and tacrolimus treatment. In contrast, treatment with mTOR inhibitors reduced EC proliferative activity by about 40%, independently of the EC origin. No induction of apoptosis (caspase-3/7 activity) or cytotoxicity (MTS test) was observed. Long-term treatment with high concentrations of sirolimus and everolimus did not enhance the expression of CAM. Stimulation with tumor necrosis factor significantly increased the expression of CAM, independently of the drugs used. None of the mTOR inhibitors influenced the tumor necrosis factor-induced expression of CAM, whereas adhesion of PBMC increased significantly, as described by other papers. In summary, neither calcineurin inhibitors nor mTOR inhibitors activate human micro- and macrovascular EC. Therefore, the investigated drugs are unlikely to contribute to EC activation during transplant-associated vasculopathy. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/610

ddc:610

Identifikace klíčových regulátorů genové exprese v savčím oocytu a embryu / Identification of key regulators of gene expression in mammalian oocyte and embryo

Jansová, Denisa

January 2017

Mammalian oocyte is a highly differentiated cell which gives rise to an embryo after fertilization. Importantly, fully-grown oocytes become transcriptionally inactive at the end of the growth phase. During following stages of development, i. e. meiotic maturation of the oocyte and early embryonic development, only transcripts previously synthesized and stored are used. The tight correlation between mRNA distribution and subsequent protein localization and function provides a mechanism of spatial and temporal regulation of gene expression used by various cell types. However, not much is known about mRNA localization and translation in the mammalian oocyte and early embryo. The aim of my thesis was to determine the localization of transcripts and components of translational machinery in the mammalian oocyte and embryo and to uncover the mechanisms of spatiotemporal regulation of translation as a prerequisite for correct oocyte and embryo development. We have shown that nuclei of both mouse and human oocytes contain RNA molecules and RNA binding proteins. Following the nuclear envelope breakdown (NEBD), translational hot-spots occur in the area surrounding the nuclear region. We suppose that mRNAs previously retained in the nucleus are released to the cytoplasm during NEBD and their subsequent...

Nouvelles régulations métaboliques exercées par la signalisation LKB1 dans les cellules polarisées : conséquences pour l’ontogénie tissulaire / Novel metabolic regulations exerted by LKB1 signaling in polarized cells : impact on tissue ontogeny

Radu, Anca Gabriela

18 May 2018

Le suppresseur de tumeur et sérine/thréonine kinase LKB1 est un régulateur clé de la polarité cellulaire et du métabolisme énergétique en partie grâce à l'activation de sa kinase substrat AMPK. Cette protéine est un senseur métabolique pour adapter les apports énergétiques aux besoins nutritionnels des cellules confrontées à un stress. Pour cela, AMPK phosphoryle divers substrats qui activent les réactions cataboliques et inhibent les processus anaboliques dont la kinase mTOR.Au cours de ma thèse, via l’utilisation de modèles murins d’inactivation conditionnelle, j'ai découvert que Lkb1 est crucial pour la formation des cellules de crête neurale (CCN). Ces cellules multipotentes, originaires du tube neural, donnent naissance à divers dérivés, comme les cellules des os et cartilage de la face, les cellules pigmentées de la peau et les cellules gliales et neurales des nerfs périphériques et du système nerveux entérique. J'ai démontré que Lkb1 est essentiel pour la formation de la tête des vertébrés et pour la différenciation et le maintien des dérivés des CCN dans le système nerveux périphérique. J'ai également mis en évidence l’acétylation de LKB1 sur la lysine 48 par l'acétyltransférase GCN5 et son rôle dans l'ontogenèse des CCN céphaliques et la formation de la tête. De plus, j'ai découvert que Lkb1 contrôle la différenciation des cellules gliales en réprimant un programme de biosynthèse d’acides aminés couplé à la transamination du pyruvate en alanine, en amont de la voie de signalisation mTOR.Les phénotypes dus à la perte de Lkb1 dans les CCN récapitulent les caractéristiques cliniques de maladies humaines appelées neurocristopathies. L’activation anormale du suppresseur de tumeur p53 est également associée à certaines neurocristopathies et l’ablation de p53 sauve le phénotype pathologique. Ainsi, j'ai montré que Lkb1 dans les cellules gliales contrôle p53 en limitant les dommages à l’ADN. Lkb1 est aussi essentiel pour maintenir l’homéostasie lysosomale et le recyclage des protéines et ainsi empêcher la formation de granules nommés lipofuscine, chargés en protéines et lipides oxydés. De façon intéressante, les voies mTOR et LKB1/AMPK sont activées à la surface des lysosomes de façon dépendante des niveaux d’acides aminés. Des données récentes de la littérature suggèrent que les lysosomes constitueraient une plateforme de signalisation pour contrôler la protéolyse et le devenir cellulaire. Ainsi, nos données proposent que les signalisations Lkb1 et p53 pourraient réguler l'homéostasie lysosomale et en conséquence le vieillissement cellulaire.De façon intéressante, les cellules de Sertoli, des cellules somatiques épithéliales, localisées dans les tubes séminifères des testicules, et qui régissent la maturation des cellules germinales et l'homéostasie testiculaire, partagent des fonctions métaboliques similaires avec les cellules gliales. En effet, ces cellules sécrètent le lactate et l'alanine qui alimentent les mitochondries des cellules voisines (cellules germinales ou neurones respectivement) contrôlant ainsi leur survie et leur maturation. Au cours de ma thèse, nous avons observé que Lkb1 est requis pour l'homéostasie testiculaire et la spermatogenèse en régulant la polarité des cellules de Sertoli et leur métabolisme énergétique par le cycle pyruvate-alanine. Ces résultats suggèrent une conservation des régulations métaboliques par Lkb1 dans divers tissus.Dans leur ensemble, mes travaux de thèse ont apporté une meilleure connaissance des mécanismes sous-jacents des régulations métaboliques lors du devenir cellulaire. Ces résultats fournissent de nouvelles perspectives sur le développement des CCN et élargissent notre compréhension du contrôle métabolique exercé par LKB1. Enfin, mes projets de doctorat ont mis en évidence l'existence d'une communication entre les voie de signalisation Lkb1 et p53 et suggèrent l’importance de cette communication dans les pathologies humaines dues à des défauts des CCN. / The tumor suppressor LKB1 codes for a serine/threonine kinase. It acts as a key regulator of cell polarity and energy metabolism partly through the activation of the AMP-activated protein kinase (AMPK), a sensor that adapts energy supply to the nutrient demands of cells facing situations of metabolic stress. To achieve metabolic adaptations, AMPK phosphorylates numerous substrates which inhibit anabolic processes while activating catabolic reactions. In particular, AMPK inhibits the mammalian target of rapamycin (mTOR).During my PhD, based on genetically engineered mouse models, I uncovered that Lkb1 signaling is essential for neural crest cells (NCC) formation. NCC are multipotent cells that originate from the neural tube and give rise to various derivatives including bones and cartilage of the face, pigmented cells in the skin and glial and neural cells in peripheral nerves and the enteric nervous system. I demonstrated that Lkb1 is essential for vertebrate head formation and for the differentiation and maintenance of NCC-derivatives in the peripheral nervous system. I also emphasized that LKB1 is acetylated on lysine 48 by the acetyltransferase GCN5 and that this acetylation could regulates cranial NCC ontogeny and head formation. Furthermore, I discovered that Lkb1 controls NCC-derived glial differentiation through metabolic regulations involving amino acid biosynthesis coupled to pyruvate-alanine cycling upstream of mTOR signaling.Phenotypes due to Lkb1 loss in NCC recapitulate clinical features of human disorders called neurocristopathies and therefore suggest that aberrant Lkb1 metabolic signaling underlies the etiology of these pathologies. Abnormal activation of the tumor suppressor p53 has been described in some NCC disorders and p53 inactivation in neurocristopathy mouse models rescues the pathological phenotype. By using a NCC line that can be cultivated as progenitors or differentiated in glial cells in vitro, I demonstrated that Lkb1 expression in NCC-derivatives controls p53 activation by limiting oxidative DNA damage and prevents the formation of lysosomes filled with oxidized proteins and lipids called lipofuscin granules. Interestingly, activation of mTOR and LKB1/AMPK pathways is governed by amino acid sensors and takes place at the lysosome surface. Lysosomes have been proposed as a signaling hub controlling proteolysis and aging. Thus Lkb1 and p53 signaling could converge especially through lysosome homeostasis thereby potentially impacting cellular aging.Strikingly, Sertoli cells, that are epithelial somatic cells, located in seminiferous tubules in testes, and which govern germ cells maturation and whole testis homeostasis, share similar metabolic functions with glial cells. For example, they secrete lactate and alanine to fuel mitochondria of neighboring cells (germ cells or neurons respectively) to control their survival and maturation. During my PhD, we highlighted that Lkb1 is essential for testis homeostasis and spermatogenesis by regulating Sertoli cell polarity and, as observed in glial cells, energy metabolism through pyruvate-alanine cycling. These data suggest that this particular Lkb1 metabolic regulation is conserved in tissues with similar function.Taken together, these studies reveal the underlying molecular mechanisms that coordinately regulate energy metabolism and cell fate. They provide new insights into NCC development and expand our understanding of the role of LKB1 as an energy metabolic regulator. Finally, my PhD projects uncover the existence of a crosstalk between Lkb1 and p53 and underline its importance in NCC disorders.

Crêtes neurales

Cellules de Sertoli

Métabolisme énergétique

Neurocristopathies

LKB1. p53. AMPK. mTOR

Polarité

Neural crest

Sertoli cells

Energy metabolism

Neurocristopathies

LKB1. p53. AMPK. mTOR

Polarity

570

ANTIFOLATE MODULATORS OF AMP-ACTIVATED PROTEIN KINASE SIGNALING AS CANCER THERAPEUTICS

Rothbart, Scott

20 September 2010

Since its discovery, it was appreciated that the antifolate pemetrexed had multiple targets within folate metabolism. This laboratory was instrumental in showing that pemetrexed elicited its primary action as a thymidylate synthase inhibitor. Unusual for an antifolate, pemetrexed showed significant clinical activity against malignant pleural mesothelioma and non-small cell lung cancer. Accordingly, the FDA recently issued first-line approvals for pemetrexed in these diseases, leading us to question whether the effects of pemetrexed on other folate-dependent targets could explain this atypical clinical activity of the drug. Studies in this dissertation showed that in addition to thymidylate synthase inhibition, pemetrexed was also an inhibitor of aminoimidazolecarboxamide ribonucleotide formyltransferase (AICART), the second folate- dependent enzyme of de novo purine synthesis. Consequent of AICART inhibition, pemetrexed caused robust activation of a key energy-sensing regulatory enzyme of the PI3K-AKT signal transduction pathway, AMP-activated protein kinase (AMPK). AMPK activation resulted from xx accumulation of the AMP-mimetic, ZMP, behind the AICART block. Constituents of the PI3K- AKT cascade are frequently deregulated in human carcinomas, uncoupling nutrient supply from proliferative capacity. Therefore, interventions that reinstate control over aberrant signaling along this axis, such as AMPK activation, are of significant cancer therapeutic interest. The cellular consequences of AMPK activation in response to pemetrexed were assessed. In particular, effects on the downstream target of PI3K-AKT signaling, the mammalian target of rapamycin complex 1 (mTORC1), were studied. Unlike targeted mTORC1 inhibitors, such as rapamycin and its analogs, pemetrexed-mediated activation of AMPK also signaled to mTOR- independent controlling elements of protein and lipid synthesis, highlighting additional benefits of AMPK activating agents that extend beyond effects on mTOR signaling. We therefore propose that the unusual activity of pemetrexed in mesothelioma and non-small cell lung cancer is due in part to effects on signaling processes downstream of AMPK activation. These findings present a novel approach to AMPK activation secondary to an AICART block, define pemetrexed as a molecularly targeted agent, and ultimately extend the utility of antifolates beyond their traditional function.

folates

antifolates

AMPK

mTOR

pemetrexed

cancer

Medical Pharmacology

Medical Sciences

Medicine and Health Sciences

THERAPEUTIC EFFICACY OF COMBINATION OF MTOR INHIBITORS AND AMPK ACTIVATORS IN NON-SMALL CELL LUNG CANCER.

Corriea, Grinal

01 January 2014

Pemetrexed (PTX), an antifolate drug, has been approved by the US FDA for first line therapy of mesothelioma and non-small cell lung cancer. In addition to its primary site of action on thymidylate synthase (TS), PTX also inhibits the second folate-dependent enzyme of purine biosynthesis aminoimidazolecarboxamide ribonucleotide formyltransferase (AICART). The accumulation of the substrate for AICART, ZMP, in PTX-inhibited cancer cells leads to activation of AMP-activated protein kinase (AMPK) with subsequent inhibition of mammalian target of rapamycin (mTOR) and hypophosphorylation of its downstream targets responsible for protein synthesis and cell proliferation. Inhibitors of mTORC1 like Rapamycin and its analogs (rapalogs) have only partial effects on tumor cells as they do not inhibit mTORC2, which phosphorylates Akt subsequently relieving the inhibition of mTORC1, thus leading to poor cytotoxicity by rapalogs. AMPK exerts control on mTORC1 kinase activity and PTX mediated activation of AMPK leads to its subsequent downregulation and hence, would be expected to have a therapeutic interaction with direct mTOR inhibitors. AZD8055, an ATP-competitive inhibitor of mTOR kinase, potently inhibits both mTORC1 and mTORC2 and therefore, can overcome the feedback mechanism(s) limiting the action of rapalogs to cytostatic effects. To study the effects of AMPK activation and mTOR inhibition pharmacologically, we performed growth suppression assays using pemetrexed, AICAR, RAD001, and AZD8055. The effect of inhibition of mTOR with these drugs was assessed by examining the dephosphorylation of mTORC1 substrates S6K1 and 4E-BP1, as single agents and in combination, at their 50% inhibitory concentrations (IC50) by western blotting. Our data suggested that AMPK activation via PTX mediated AICART inhibition in combination with direct mTOR inhibition by AZD8055 has a synergistic interaction on the proliferation of NSCLC cells in culture. Inhibition of mTOR endogenously by pemetrexed, along with direct pharmacological inhibition of mTOR prevents the feedback circuit which may compromise the therapeutic efficacy of rapamycin analogs. Pemetrexed and AZD8055, as single agents, demonstrated inhibitory activity on phosphorylation events of mTORC1 substrates. This activity was markedly increased by combining both the drugs. Our findings suggest that direct inhibitors of mTOR enhance the effects of activators of AMPK. These effects appear to be mediated via combined effects on mTORC1. Taken together, the combination of catalytic site mTOR inhibitors and pemetrexed is a promising therapeutic strategy and calls for further preclinical and clinical investigations.

mTOR

Non-small cell lung cancer

pemetrexed

AZD8055

AMPK

Medicine and Health Sciences

Inhibition of mTOR Signaling Protects Against Myocardial Reperfusion Injury, Acute Myocardial Infarction

Filippone, Scott M

01 January 2015

Acute myocardial infarction (AMI) is the leading cause of death worldwide. Currently, the best method of treating cardiac ischemia is early reperfusion which, itself, induces myocardial damage. The mTOR complex is a key regulator of cardioprotection against cell stressors. We hypothesized that reperfusion therapy with Rapamycin, a potent mTOR inhibitor, would reduce infarct size in adult mouse hearts. Rapamycin was administered at the onset of reperfusion following 30 min in situ LAD ligation. After 24 hours of reperfusion, myocardial infarct size and apoptosis were significantly reduced in rapamycin-treated mice compared to control. Rapamycin inhibited pro-apoptotic protein Bax and phosphorylation of ribosomal protein S6 (target of mTORC1), while it induced phosphorylation of AKT (target of mTORC2). Rapamycin also induced phosphorylation of ERK, while significantly reduced phosphorylation of p38. Thus, our study shows that reperfusion therapy with Rapamycin provides cardioprotection through induction of the phosphorylation of Akt and ERK.

mTOR

Rapamycin

Cardioprotection

Ischemia

Reperfusion Injury

Circulatory and Respiratory Physiology

Medical Biochemistry

Medical Physiology

Le rôle de la tyrosine phosphatase Shp-1 dans le maintien de l’homéostasie de l’épithélium intestinal

Leblanc, Caroline

January 2015

Shp-1 (Src homology 2 domain-containing phosphatase 1) est une tyrosine phosphatase retrouvée principalement chez les cellules hématopoïétiques, mais également chez les cellules épithéliales. Bien que Shp-1 soit reconnue comme étant un régulateur négatif de plusieurs voies de signalisation intracellulaire chez les cellules hématopoïétiques, son rôle dans les cellules épithéliales a été jusqu’ici très peu étudié. Afin de mieux comprendre son rôle dans les cellules épithéliales intestinales, nous avons généré un modèle murin de délétion conditionnelle de Shp-1 spécifiquement dans l’épithélium intestinal (Shp-1CEI-KO). De manière intéressante, dès l’âge de 6 semaines, les souris expérimentales présentent une intestinalomégalie associée à une légère augmentation de la prolifération cryptale. La taille des cellules épithéliales est également augmentée, suggérant de l’hypertrophie cellulaire chez les souris invalidées pour Shp-1. Parallèlement, la voie de signalisation PI3K/Akt/mTor est activée dans l’épithélium des souris mutantes. Nous avons également noté une production accrue de cellules caliciformes et de leurs précurseures, les cellules intermédiaires, en absence de Shp-1. Par contre, la maturation des cellules de Paneth semble grandement compromise vu la baisse importante d’expression du lysozyme et des RegIIIβ et RegIIIγ, de même que la faible densité de leurs granules de sécrétion. La comparaison du phénotype intestinal des souris Shp-1CEI-KO avec celui des souris PtenCEI-KO suggère que l’hyperactivation de la voie PI3K/Akt/mTor est responsable en partie des altérations phénotypiques observées chez la souris invalidée pour Shp-1. En conclusion, nos résultats montrent que la tyrosine phosphatase Shp-1 est un régulateur important de l’homéostasie de l’épithélium intestinal en contrôlant notamment la croissance cellulaire et la différenciation des cellules de la lignée sécrétrice.

Shp-1

Tyrosine phosphatase

Cellules de Paneth

Cellules intermédiaires

Wnt/β-caténine

PI3K/Akt/mTor

Études des mécanismes d’adaptation du métabolisme énergétique dans le syndrome de Leigh de type canadien français : vers l’identification des cibles thérapeutiques

Mukaneza, Yvette

10 1900

No description available.

LSFC

LRPPRC

COX

mTOR

Rapamycin

AMPK

SIRT1

Palmitate

Rapamycine

A participação da via fosfatidilinositol3-quinase (PI3K)/mTOR no carcinoma epidermoide oral / The participation of the pathway Phosphatidylinositol 3-kinase (PI3K) / mTOR in oral squamous cell carcinoma

Andressa Duarte

15 March 2018

O carcinoma epidermoide oral (CEO) possui alta incidência no Brasil, correspondendo a aproximadamente 95% das neoplasias malignas orais. A biologia molecular do carcinoma de cabeça e pescoço é complexa e se desenvolve a partir da disfunção de várias vias inter-relacionadas. A via das PI3K/mTOR é conhecida por regular várias funções celulares, como a regulação do ciclo celular, migração, angiogênese, morfologia e organização do citoesqueleto. O presente trabalho teve como objetivo avaliar o impacto do bloqueio da via PI3K e mTOR na sobrevida celular, na adesão e na morfologia de células endoteliais, relacionando-o com o processo angiogênico. Em cultura de células, observamos que as inibições farmacológicas de PI3K ou do mTOR diminuem a viabilidade celular do CEO. Houve redução da expressão de PARP, um marcador de apoptose e pS6, uma proteína dowstream na sinalização do mTOR, após o tratamento das células de CEO com os inibidores de mTOR. Além disso, demonstramos que o tratamento com os inibidores de mTOR diminuem a capacidade das células do CEO em formarem clones. Foi observado ainda que o cultivo de célula endoteliais da veia umbilical humana (HUVEC, do inglês Human Umbilical Vein Endothelial Cells) em meio condicionado (MC) proveniente de células de CEO, tratadas com inibidores de mTOR, resultaram em aumento da adesão celular e modificação na morfologia celular. Para investigar a influência dos fatores liberados pelas células tumorais na migração das células HUVECs, foi realizado ensaio de wound healing, em células HUVECs cultivadas em MC. Observamos maior migração das células HUVECs cultivadas em MC quando este era proveniente de células cancerosas tratadas com inibidor de mTOR. Ainda, investigamos a expressão da via VEGF nessa migração por meio do ensaio de ELISA. Observamos que no MC proveniente de células cancerosas tratadas com inibidor de mTOR havia maior presença de VEGF. Nossos dados sugerem que a via da PI3K/mTOR está envolvida na proliferação das células do CEO. Porém, a inibição de mTOR em células cancerosas pode liberar fatores, tais como VEGF, que influenciam na morfologia e migração de células HUVEC. / Oral squamous cell carcinoma (OSCC) has a high incidence in Brazil, corresponding to approximately 95% of oral malignancies. The molecular biology of head and neck carcinoma is complex and develops from the dysfunction of several interrelated pathways. The PI3K/mTOR pathway is known to regulate various cellular functions, such as cell cycle regulation, migration, angiogenesis, cytology, and cytoskeletal organization. The aim of the present study was to evaluate the impact of PI3K and mTOR pathway blockade on cell survival, endothelial cell adhesion and morphology, and to correlate it with the angiogenic process. In cell culture, we observed that pharmacological inhibitions of PI3K or mTOR decrease the OSCC\'s cellular viability. There was a reduction in the expression of PARP, a marker of apoptosis and pS6, a dowstream protein in mTOR signaling, after treatment of OSCC cells with mTOR inhibitors. In addition, we have demonstrated that treatment with mTOR inhibitors decreases the ability of the OSCC cells to form clones. It was further noted that human umbilical vein endothelial cell (HUVEC) culture in conditioned media (CM) from OSCC cells treated with mTOR inhibitors resulted in increased cell adhesion and modification in cell morphology. To investigate the influence of the factors released by the tumor cells in the migration of HUVEC cells, a wound healing assay was performed on HUVEC cells cultured in CM. We observed a greater migration of HUVECs cells cultured in CM when it came from cancer cells treated with mTOR inhibitor. Furthermore, we investigated the role of the VEGF pathway in this migration through the ELISA assay. We observed that in CM from cancer cells treated with mTOR inhibitor there was a greater presence of VEGF. Our data suggest that the PI3K/mTOR pathway is involved in the proliferation of OSCC cells. However, inhibition of mTOR in cancer cells may release factors, such as VEGF, which influence the morphology and migration of HUVEC cells.

AKT

Câncer

Everolimus

mTOR

PI3K

Rapamicina

Torin1

Via de sinalização

Não informado

Regulation of human primordial follicle activation in vitro

Grosbois, Johanne

31 January 2019

Producing competent and fertilizable oocytes from in vitro grown primordial follicles could revolutionize female infertility treatment, particularly using fertility preservation approaches that use cryopreserved ovarian tissue. However, the protracted length of folliculogenesis in humans makes follicular culture complex, and the mechanisms controlling the tightly-regulated activation of primordial follicles remain largely unknown. The delicate balance between follicular recruitment and quiescence might be affected by preservation procedures, such as ovarian fragmentation or in vitro culture, that disrupt crucial pathways, such as the Hippo and PI3K/Akt/mTOR signaling pathways, that are involved in this process. When activated, these pathways induce massive recruitment of primordial follicles and accelerate follicular growth in vitro, with potential negative consequences on future oocyte developmental competence. Therefore, we hypothesized that the inhibition of the PI3K/Akt/mTOR pathway might improve follicular growth by slowing down the activation process.In the first part of this thesis, we explored the potential benefit of inhibiting PI3K/Akt/mTOR signaling on the regulation of in vitro follicular activation and growth, as well as its impact on the Hippo pathway. The effect of everolimus (EVE), a specific mTORC1 inhibitor, was compared to the PI3K/Akt activators recently used to reinitiate the growth of residual follicles in the ovarian tissue of patients with premature ovarian insufficiency. We showed that short-term incubation of ovarian cortex with EVE partially delayed follicular recruitment while supporting follicle survival and steroidogenesis. However, morphological abnormalities were observed in all conditions, suggesting that EVE failed to protect follicles from accelerated in vitro growth-related defects.Our findings also provided evidence that ovarian fragmentation, which disrupts the Hippo pathway, contributes to the triggering of primordial follicle recruitment and early development of quiescent human follicles. Moreover, our data suggested that both PI3K/Akt and Hippo signaling could act synergistically to promote follicular activation and growth.In the second part of the project, we further investigated the integrity of EVE-treated follicles based on their ultrastructural and functional status. Our observations indicate that the integrity of oocyte and granulosa cells, as well as their physical contacts, were preserved in EVE and control conditions, although some in vitro grown follicles sustained cryopreservation- and culture- induced damage. We also found that short exposure to EVE allowed the maintenance of intra-follicular communication while preserving follicular developmental potential. Importantly, results obtained suggested that, at a similar developmental stage, cell coupling and oocyte growth may be improved in EVE-treated follicles.Altogether, these data provide better insight into the regulation of the follicular activation process and emphasize the importance of getting closer to physiological conditions to preserve follicle integrity. They also provide proof-of-concept evidence that reducing the initiation of growth is feasible, and suggest that mTORC1 inhibitors are a potentially useful pharmacological tool to regulate in vitro follicular growth. / La production d'ovocytes compétents et fécondables à partir de follicules primordiaux développés in vitro pourrait révolutionner les traitements liés à l'infertilité féminine, en particulier les approches de préservation de la fertilité à partir du tissu ovarien cryopréservé. Cependant, la longue durée de la folliculogenèse chez l'Homme rend la culture folliculaire complexe, et les mécanismes contrôlant l'activation des follicules primordiaux restent largement inconnus. L’équilibre fragile entre quiescence folliculaire et entrée en croissance pourrait être affecté par la fragmentation ovarienne ou la culture in vitro elle-même, qui perturbent deux voies de signalisation cruciales: les voies Hippo et PI3K/Akt/mTOR, respectivement. Lorsqu'elles sont activées, elles induisent un recrutement massif de follicules primordiaux et accélèrent la croissance folliculaire in vitro, avec des conséquences potentiellement néfastes sur la capacité future des ovocytes à devenir compétents. Par conséquent, nous avons émis l’hypothèse que l’inhibition de la voie PI3K/Akt/mTOR pourrait améliorer la croissance folliculaire via un ralentissement du processus d’activation.Dans la première partie de cette thèse, nous avons exploré le potentiel bénéfice d’une inhibition de la voie PI3K/Akt/mTOR sur la régulation de l'activation et de la croissance folliculaire in vitro, ainsi que son impact sur la voie Hippo. L’effet de l’évérolimus (EVE), un inhibiteur spécifique de mTORC1, a été comparé à ceux d’activateurs de PI3K/Akt, récemment utilisés afin d’initier la croissance des follicules résiduels au sein de tissus ovarien de patientes en insuffisance ovarienne précoce. Nous avons montré que l'exposition à court terme de cortex ovarien à l'EVE retardait partiellement le recrutement folliculaire tout en préservant la survie et la stéroidogenèse des follicules. Toutefois, des anomalies morphologiques ont été observées dans toutes les conditions, ce qui suggère que l’EVE ne préserve pas les follicules de défauts liés à une croissance accélérée.Nos résultats ont également prouvé que la fragmentation ovarienne, en perturbant la voie Hippo, contribue au recrutement et au développement précoce des follicules primordiaux. De plus, les données obtenues suggèrent que les voies PI3K/Akt/mTOR et Hippo pourraient agir de manière synergique pour promouvoir l'activation et la croissance folliculaire.Dans la deuxième partie du projet, nous avons étudié la qualité des follicules traités avec de l’EVE en se basant sur des critères ultrastructural et fonctionnel. Nos observations ont indiqué que l'intégrité des ovocytes et des cellules de la granulosa ainsi que leurs contacts physiques était préservée dans les conditions EVE et contrôle, bien que certains follicules en croissance présentent des signes de dommages induits par la cryopréservation et la culture. Nous avons également constaté qu'une courte exposition à l’EVE permettait de maintenir les communications intra-folliculaires tout en préservant le potentiel de développement des follicules. De façon importante, les résultats obtenus suggèrent qu’à un stade de développement similaire, le couplage cellulaire et la croissance des ovocytes pourraient être améliorés dans les follicules traités à l’EVE.En conclusion, ces données contribuent à une meilleure compréhension de la régulation de l'activation folliculaire in vitro, et soulignent l'importance de mimer les conditions physiologiques pour préserver l'intégrité des follicules. Elles apportent également la preuve qu’un ralentissement de l’initiation de la croissance est réalisable, et suggèrent que l’utilisation d’inhibiteurs de mTORC1 pourrait représenter un outil pharmacologique efficace pour réguler la croissance folliculaire in vitro. / Doctorat en Sciences biomédicales et pharmaceutiques (Médecine) / info:eu-repo/semantics/nonPublished

Sciences biomédicales en général

Croissance et développement [humain]

ovary

fertility preservation

PI3K/Akt/mTOR

Hippo