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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
151

The tyrosine kinase activity of discoidin domain receptor 1 is essential for the migration of human effector T cells in three-dimensional collagen

Toghi, Mehdi 28 April 2023 (has links)
Titre de l'écran-titre (visionné le 18 avril 2023) / La migration des lymphocytes T à travers la matrice extracellulaire (MEC) du tissu interstitiel est essentielle au développement de la réponse immunitaire adaptative. Pour atteindre les sites inflammatoires, les lymphocytes T doivent traverser la barrière endothéliale, et ce, suivant le mode de migration bidimensionnel (2D) qui implique les intégrines. De plus, ils doivent traverser la MEC du tissu interstitiel, formée majoritairement de collagène, et ce, suivant le mode tridimensionnel (3D). Nous et d'autres avons montré que la migration des lymphocytes Th17 à travers le collagène 3D implique le récepteur à activité tyrosine kinase nommé récepteur de domaine discoïdine 1 (DDR1). Ainsi, leur migration dépend de la voie MAPK/ERK induite par l'activité enzymatique de DDR1. Ici, nous rapportons que les cellules Th1 et Th2 expriment des niveaux comparables de DDR1 à ceux des cellules Th17 et que leur migration à travers le collagène est dépendante de DDR1. Cependant, l'adhésion des cellules auxiliaires (Th) au collagène est indépendante de DDR1, conformément au mouvement amiboïde des cellules T dans les modèles de matrice 3D. Sur un autre plan, il est connu que DDR1 peut induire deux voies de signalisation, la voie canonique dépendante de son activité enzymatique et la voie non canonique indépendante de celle-ci. Nos résultats montrent que l'activité enzymatique de DDR1 est essentielle à la migration des lymphocytes Th. En effet, l'inhibition de son activité enzymatique par le 7rh et par la construction DDR1 kinase-dead ont fortement réduit la migration des cellules Th. De plus, nous avons montré que la voie canonique MAPK/ERK est essentielle à leur migration. En somme, ces résultats fournissent de nouvelles connaissances sur les mécanismes de migration des lymphocytes T. Enfin, l'activité enzymatique de DDR1 pourrait être une cible thérapeutique afin d'inhiber l'infiltration des lymphocytes T dans les sites inflammatoires observés dans les maladies auto-immunes et allergiques. / T cell migration across tissue extracellular matrix (ECM) is a critical step in the development of adaptive immune response. To reach their target sites, T cells have to pass through two main barriers. One is the endothelial barrier and the second one is the interstitial matrix. Passing through the endothelial barrier follows the rules of two-dimensional (2D) mode of migration that has been studied in detail and involves integrin receptors. However, there are less studies regarding T cell migration through the interstitial matrix, which follows the rules of three-dimensional (3D) mode of migration. We and others previously showed that T cell migration across the 3D collagen that is the main component of the interstitial matrix involves the non-integrin collagen tyrosine kinase receptor named discoidin domain receptor 1 (DDR1). Previously, our group has reported that human Th17 cells migrate in 3D collagen via DDR1-mediated activation of the MAPK/ERK pathway. Herein, we report that human Th1 and Th2 effector cells express comparable levels of DDR1 as Th17 cells and also migrate in 3D collagen in a DDR1- dependent manner. DDR1 does not promote adhesion of Th effector cells to collagen consistent with the amoeboid movement of T cells in 3D matrix models. Furthermore, DDR1 could trigger its downstream signaling pathway either with or without using its tyrosine kinase domain, which is called canonical and non canonical signaling pathways, respectively. Therefore, we evaluated if this effect of DDR1 in promoting T cells 3D migration is mediated via DDR1 canonical pathway or non canonical pathway. Our results showed that the DDR1 tyrosine kinase activity was required for T cell migration. Indeed the specific DDR1 kinase inhibitor 7rh and the DDR1 kinase-dead construct strongly reduced the migration in 3D collagen of Th1, Th2 and Th17 cells. Finally, we showed that the DDR1 kinase activity was required for collagen-mediated MAPK/ERK activation, which is essential for T cell migration. Together, these results bring new insights into the mechanisms of T cell migration in 3D collagen and suggest that inhibiting the DDR1 kinase activity might be beneficial to inhibit T cell infiltration into inflammatory tissues in autoimmune and allergic diseases.
152

Silencing Endothelial EphA4 Alters Transcriptional Regulation of Angiogenic Factors to Promote Vessel Recovery Following TBI

McGuire, David Robert 09 July 2020 (has links)
Traumatic brain injury (TBI) can cause a number of deleterious effects to the neurovascular system, including reduced cerebral blood flow (CBF), vascular regression, and ischemia, resulting in cognitive decline. Research into therapeutic targets to restore neurovascular function following injury has identified endothelial EphA4 receptor tyrosine kinase as a major regulator of vascular regrowth. The research outlined herein utilizes an endothelial-specific EphA4 knockout mouse model (KO-EphA4flf/Tie2-Cre) to determine the extent to which this receptor may influence vascular regrowth following TBI. Analysis of the colocalization and proximity of endothelial and mural cell markers (i.e. PECAM-1 and PDGFRβ, respectively) in immunohistochemically-stained brain sections demonstrates that EphA4 silencing does not seem to affect the physical association between, nor total amounts of, endothelial cells and pericytes, between genotypes by 4 days post-injury (dpi). Nevertheless, these measures demonstrate that these cell types may preferentially proliferate and/or expand into peri-lesion tissue in both KO-EphA4flf/Tie2-Cre) and WT-EphA4fl/fl mice. These data further suggest that both genotypes experience homogeneity of PECAM-1 and PDGFRβ expression between regions of the injury cavity. Gene expression analysis using mRNA samples from both genotypes reveals that KO-EphA4flf/Tie2-Cre CCI-injured mice experience increased expression of Vegfa, Flt1, and Fn (Fibronectin) compared to sham-injured condition knockouts. These results demonstrate changes in expression of angiogenic factors in the absence of early differences in patterns of vessel formation, which may underlie improved vascular regrowth, as well as outline a potential mechanism wherein the interplay between these factors and EphA4 silencing may lead to improved cognitive outcomes following TBI. / Master of Science / Every day in the United States, an average of 155 people die due to the consequences of traumatic brain injury (TBI), with many survivors suffering life-long debilitating effects, including deficits in behavior, mobility, and cognitive ability. Because of this, there is a need for researchers to identify therapeutic strategies to stimulate recovery and improve patient outcomes. Recent advancements in the field of vascular biology have identified the regrowth of the blood vessels in the brain following TBI-induced damage as an important step in the recovery process, since the resulting increases in blood flow to damaged tissue will provide oxygen and nutrients necessary to fuel recovery. The work presented in this Masters thesis follows in this vein by examining a protein receptor known as EphA4, which is found on cells within blood vessels and has been implicated in reducing the rate of vessel growth under injury conditions. By blocking the activity of EphA4, we hoped to find increased vascular regrowth following brain injury in mice. During the experiments outlined herein, it was found that there were no statistically significant differences in vessel-associated cell densities between mice with or without EphA4 activity 4 days after injury, but there were differences in the levels of proteins and/or signals associated with vessel growth. Based on these results, we conclude that removing EphA4 activity increases expression of these pro-vessel growth proteins in mouse brains following injury at these early time points, potentially leading to increased vessel growth and improved recovery over subsequent weeks following injury.
153

Voies de signalisation activées par les cristaux d'urate monosodique dans les neutrophiles humains

Popa-Nita, Oana 13 April 2018 (has links)
Les polymorphonucléaires neutrophiles sont les principales cellules effectrices du système immunitaire inné. Les cristaux d'urate monosodique sont l'agent étiologique de l'arthrite goutteuse. L'interaction directe entre les neutrophiles humains et les cristaux d'UMS est essentielle pour le déclenchement de la crise de goutte aiguë. Le principal objectif de ce projet de recherche est d'identifier les voies de signalisation activées par les cristaux d'UMS et de caractériser leurs fonctions dans les réponses des neutrophiles humains.
154

Hypoxia modulates the activity of a series of clinically approved tyrosine kinase inhibitors

Ahmadi, M., Ahmadihosseini, Z., Allison, Simon J., Begum, S., Rockley, K., Sadiq, Maria, Chintamaneni, S., Lokwani, R., Hughes, N., Phillips, Roger M. January 2014 (has links)
No / BACKGROUND AND PURPOSE: Hypoxia in tumours is known to cause resistance to conventional chemotherapeutic drugs. In contrast, little is known about the effects of hypoxia on targeted anti-cancer drugs. This study evaluated the effect of hypoxia on a series of clinically approved tyrosine kinase inhibitors (TKIs). EXPERIMENTAL APPROACH: The effect of hypoxia (0.1% oxygen) on the activity of conventional cytotoxic drugs (5-fluorouracil, doxorubicin and vinblastine), the hypoxia-activated prodrug tirapazamine and 9 TKIs was determined in a panel of cell lines. Where hypoxia had a marked effect on chemosensitivity, Western blot analysis was conducted to determine the effect of hypoxia on target expression and the effect of TKIs on cell signalling response under aerobic and hypoxic conditions. KEY RESULTS: Three patterns of chemosensitivity were observed: resistance under hypoxia, equitoxic activity against hypoxic and aerobic cells, and preferential cytotoxicity to hypoxic cells. Significant hypoxia selectivity (independent of HIF1) was observed in the case of dasatinib and this correlated with the ability of dasatinib to inhibit phosphorylation of Src at tyrosine 530. Sorafenib was significantly less effective under hypoxic conditions but resistance did not correlate with hypoxia-induced changes in Raf/MEK/ERK signalling. CONCLUSIONS AND IMPLICATIONS: Hypoxia influences the activity of TKIs but in contrast to conventional cytotoxic drugs, preferential activity against hypoxic cells can occur. The search for hypoxia-targeted therapies has been long and fruitless and this study suggests that some clinically approved TKIs could preferentially target the hypoxic fraction of some tumour types.
155

New insights on regulation of LMTK2, a membrane kinase integrating pathways central to neurodegeneration.

Rattray, Marcus 05 1900 (has links)
Yes
156

Régulation de la signalisation du récepteur MET par la protéine SOCS1 dans le carcinome hépatocellulaire / Regulation of MET signaling by SOCS1 in hepatocellular carcinoma

Gui, Yirui January 2014 (has links)
Résumé : La répression fréquente du gène encodant pour le « suppressor of cytokine signaling 1 » (SOCS1) dans le carcinome hépatocellulaire (CHC) et la forte susceptibilité des souris déficientes pour SOCS1 à développer des tumeurs hépatiques expérimentales suggèrent que SOCS joue un rôle de suppresseur de tumeur. Cette notion est supportée par les études impliquant la répression de l’expression de SOCS1 via des évènements épigénétiques ou par les microARN dans plusieurs autres types de cancers. Les mécanismes moléculaires sous-jacents au rôle potentiel de suppresseur de tumeur de SOCS1 dans le foie demeurent à ce jour inconnus. Bien que les récepteurs à activité tyrosine kinase (RTK) sont reconnus pour induire l’expression de l’ARNm de SOCS1, le rôle et les mécanismes par lesquels SOCS1 peut réguler la signalisation des RTK sont incertains. Le RTK MET, qui a pour ligand le facteur de croissance des hépatocytes (HGF), régule plusieurs fonctions cellulaires normales. La dérégulation de la signalisation du récepteur MET joue des rôles importants dans la pathogenèse du CHC. Des études ont démontré que l’activation de MET promeut la prolifération, l’invasion et la migration des cellules cancéreuses du foie ainsi que leur dissémination métastatique. La signalisation aberrante de MET est un trait commun de plusieurs autres cancers et serait à l’origine de l’émergence de la résistance à la chimiothérapie. Dans ce projet, j’ai investigué les mécanismes moléculaires par lesquels SOCS1 régule l’activité du récepteur MET. Mes résultats indiquent que le foie des souris Socs1[indice supérieur -/-]Ifng[indice supérieur -/-] se régénère plus rapidement que celui des souris contrôles. Suivant une stimulation au HGF, les hépatocytes issus des souris Socs1[indice supérieur -/-] Ifng[indice supérieur -/-] présentent une augmentation de la signalisation de MET, de la migration et de la prolifération cellulaires. L’expression exogène de SOCS1 dans différentes lignées cellulaires d’hépatocarcinomes humains et murins inhibe la signalisation induite par HGF. De plus, SOCS1 diminue la prolifération, la croissance indépendante de l’anchrage et la migration dans ces lignées de CHC in cellulo et réduit de façon significative leur croissance dans les essais de xénogreffes chez les souris immunodéficientes. Mes résultats suggèrent que l’activation de la signalisation HGF-MET induit la transcription du gène SOCS1, suivi par une interaction physique entre SOCS1 et MET. L’analyse de divers mutants de SOCS1 révèle que cette interaction implique principalement les domaines SH2 et « kinase inhibitory region » (KIR) de SOCS1. L’activité kinasique de MET est requise pour cette interaction puisque l’interaction entre SOCS1 et un mutant kinase-inactif de MET est fortement réduite. SOCS1 est aussi phosphorylé en aval de MET sur quatre résidus tyrosine (Tyr). Quoique ces résidus Tyr représentent théoriquement des sites d’interaction pour des protéines adaptatrices possédant des domaines de liaison aux phospho-Tyr, elles ne semblent pas impliquées dans l’interaction de SOCS1 avec MET. Je démontre également que SOCS1 induit l’ubiquitination de MET via l’élongation de chaînes de polyubiquitine de type K48, conduisant à sa dégradation par le protéasome. Cette modulation négative de MET par SOCS1 dans les cellules CHC survient indépendamment de la voie de dégradation lysosomale de Cbl qui est partagée par plusieurs autres RTK. // Abstract : Frequent repression of the gene coding for the suppressor of cytokine signaling 1 (SOCS1) in hepatocellular carcinoma (HCC) and increased susceptibility of SOCS1 deficient mice to experimental hepatocarcinogenesis suggest a tumor suppressor role for SOCS1. This notion is supported by epigenetic and micro-RNA-mediated blockade of SOCS1 expression in several other cancers. Molecular mechanisms underlying the putative tumor suppressor function of SOCS1 in the liver have not been elucidated yet. Although receptor tyrosine kinases (RTK) can induce SOCS1 mRNA expression, the role and mechanisms of SOCS1 in regulating RTK signaling are not yet clear. c-Met is the RTK for hepatocyte growth factor (HGF) and mediates several normal cellular functions. HGF signaling and MET activation also play important roles in the pathogenesis of HCC. Experimental studies have shown that the activated MET promotes proliferation, invasion and migration of liver cancer cells and enhances metastasis. Aberrant MET signaling is a hallmark of many other cancers and underlies the emergence of chemoresistant clones. In this project, I investigated the molecular mechanisms by which SOCS1 regulates MET RTK activity. My results illustrate that the Socs1[superscript -/-]Ifng[superscript -/-] liver regenerates at a faster rate than the control one. Following HGF stimulation, hepatocytes from Socs1[superscrip -/-]Ifng[superscript -/-] mice display increased MET signaling, cell migration and proliferation. Forced expression of SOCS1 inhibits HGF-induced signaling pathways in different human or murine hepatoma cell lines. Furthermore, SOCS1 also decreases cell proliferation, anchorage-independent growth, and migration of HCC cell lines in cellulo, and results in significant inhibition of their growth as xenografts in immunodeficient mice. My findings show that activation of HGF-MET signaling results in transcriptional activation of SOCS1 gene, followed a physical interaction between SOCS1 and MET. Analysis of various SOCS1 mutants reveals that this interaction is mediated primarily via the SH2 and the kinase inhibitory region (KIR) domain of SOCS1. MET kinase activity is required for this interaction since SOCS1 binding to a kinase-dead MET mutant is dramatically reduced. MET promotes phosphorylation of SOCS1 on four tyrosine (Tyr) residues. Although these Tyr might represent potential binding sites for adaptors containing phospho-Tyr-binding domains, they do not appear to be involved in the interaction of SOCS1 with MET. I also show that SOCS1 induces polyubiquitination of MET via K48-ubiquitin chain elongation leading to its degradation by proteasomes. The SOCS1-mediated downmodulation of MET expression in HCC cells occurs independently of the Cbl-mediated lysosomal degradation pathway shared by many other RTKs. Taken together, my findings show that SOCS1 attenuates HGF-induced cellular functions by targeting the activated MET receptor for proteasomal degradation.
157

Association in vitro de molécules ciblant les inhibiteurs de l’apoptose pour induire spécifiquement la mort des cellules tumorales / In vitro association of anti-apoptotic proteins inhibitors to specifically induce cancer cell death

Airiau, Kelly 15 November 2012 (has links)
L’étude des mécanismes aboutissant à la tumorigénèse a permis de révéler, dans beaucoup de cancers, une amplification ou une mutation de divers oncogènes, avec pour conséquence des capacités de prolifération et de survie accrues pour la cellule tumorale. L’identification des protéines kinases comme étant des éléments centraux de ces processus en ont fait des cibles thérapeutiques prometteuses. Plusieurs inhibiteurs ciblant de façon plus ou moins spécifique les tyrosines kinases oncogéniques ont ainsi été développés. Parmi eux, l’imatinib mesylate (Gleevec®, Novartis) a constitué la première chimiothérapie ciblée. Il correspond aujourd’hui au traitement de première intention contre la LMC. Cependant, malgré sa très grande efficacité, il est apparu que certains mécanismes de résistances pouvaient être mis en place pour diminuer son effet pro-apoptotique. Le travail de cette thèse a consisté à mieux comprendre les mécanismes d’apoptose induits par les inhibiteurs de tyrosine kinases (ITK), et à rechercher quelles voies alternatives de survie devront être bloquées pour leur assurer une meilleure efficacité. Trois modèles ont été utilisés : la leucémie myéloïde chronique (LMC), les leucémies aiguës myéloïdes (LAM) et les glioblastomes (GBM). La LMC a été utilisé comme modèle et la démarche utilisé pour essayer d’augmenter l’efficacité des ITK, a été transposée aux modèles des LAM et des GBM. L’ensemble des résultats obtenus a démontré qu’une meilleure compréhension de la réponse apoptotique et des mécanismes de résistance permettait l’identification de nouvelles cibles thérapeutiques. Nous avons pu observer que, tout en favorisant la diminution des doses de molécules administrées, l’inhibition simultanée de plusieurs cibles apportait plusieurs bénéfices. Elle permet d’augmenter l’action pro-apoptotique des ITK, de contrer certains mécanismes de résistances, d’atteindre la cellule souche cancéreuse résistance et par conséquent de cibler simultanément des populations a plusieurs de stades de différenciation. / Protein kinases have been identified as playing fundamental roles in cancer development, suggesting that they could represent a promising therapeutic target. Several kinase inhibitors have been developed and the most successful of them, by far, is Gleevec® (imatinib, STI57; Novartis), a BCR-ABL inhibitor. It is currently used as the treatment of reference for chronic myeloid leukemia. However, despite a huge efficiency, some resistance mechanisms could be used to decrease its pro-apopototic effect. The global aim of my PhD was to understand the apoptotic mechanisms induced by tyrosine kinase inhibitors (TKI) to identify new potential therapeutic targets. I work on three different tumors: Chronic Myeloid Leukemia (CML), Acute Myeloid Leukemia (AML) and Glioblastomas (GBM). CML has been used as a model and the approach followed to increase TKI efficiency has been transposed to AML and GBM models. Altogether, our results showed that a better understanding of apoptotic response and resistance mechanisms could lead to the identification of new therapeutic targets. We observed that combination therapy brings several benefits. It allows to increase the TKI-induced apoptotic response, to counter some resistance mechanism, to reach the resistant cancer stem cells, and thus, to target simultaneously several populations in the tumour.
158

Modifications post-traductionnelles de la VE-cadhérine : des mécanismes moléculaires aux applications cliniques / VE-cadherin post-translational modifications : from molecular mechanisms to clinical applications : from molecular mechanisms to clinical applications

Sidibe, Adama 14 December 2012 (has links)
La fonction de barrière de l'endothélium vasculaire est affectée par des modifications de la cadhérine des cellules endothéliales (VE-cadhérine) telles que la phosphorylation sur tyrosine dans son domaine cytoplasmique et le clivage de son domaine extracellulaire (sVE). Ce travail s'est articulé en deux parties : 1- Etude de ces modifications dans le contexte de la polyarthrite rhumatoïde (PR), et les mécanismes sous-tendus. Ce travail a permis de montrer que la VE-cadhérine est une cible du TNFα, une cytokine essentielle dans la PR, qui induit de la libération de sVE de façon dépendante de l'activité kinase de Src, suggérant l'implication d'un mécanisme de phosphorylation sur tyrosine dans ce processus. De plus, la VE-cadhérine est aussi la cible des protéases de la matrice extracellulaire telles que MMP-2. L'application de ces données fondamentales à la clinique a permis de montrer que sVE était retrouvée dans le sang de patients PR (n=63) et que son taux était corrélé à l'activité de la maladie. Ainsi, le dosage de sVE est d'intérêt dans la prise en charge des patients. 2-Etude de la phosphorylation de la VE-cadhérine dans un contexte d'angiogenèse hormono-régulée au cours du cycle ovarien chez la souris. Les résultats ont montré que le site Y685 de la VE-cadhérine est phosphorylé dans l'ovaire et l'utérus de souris de façon régulée pendant le cycle, ce qui permet de proposer ce modèle physiologique pour étudier la phosphorylation de la VE-cadhérine in vivo. L'analyse de souris knock-in Y685F de la VE-cadhérine (VE-Y685F) a montré que l'absence du site confère une perméabilité accrue dans l'ovaire et l'utérus mais aussi dans les petits capillaires de la peau. De plus, dans deux modèles d'induction d'arthrite, les souris VE-Y685F ont présenté un taux de sVE plus élevé que les contrôles. Au total, sVE et la phosphorylation de la VE-cadhérine ont un vaste champ d'application dans le traitement de la PR ainsi que pour le développement de nouvelles thérapies pouvant s'étendre à d'autres pathologies vasculaires. / The vascular endothelium barrier function is influenced by vascular endothelial cadherin (VE-cadherin) modifications such as its cytoplasmic tail tyrosine phosphorylation and its ecto-domain cleavage (sVE). The work reported herein was divided into two parts: 1- Study of VE-cadherin modifications and the mechanisms underlying these ones in the rheumatoid arthritis context. This work demonstrated that VE-cadherin is a target of TNFα, a highly important cytokine in rheumatoid arthritis (RA) pathogenesis. We found TNFα to induce sVE shedding in a Src kinase dependent manner, suggesting the involvement of phosphorylation mechanism in this process. In addition, this VE-cadherin cleavage requires matrix metalloproteinase activities such as that of MMP-2. Applying these fundamental data to clinical study showed that sVE was detected in sera of 63 RA patients and its titer was correlated with the disease activity. This finding suggests an obvious interest for assaying sVE in RA therapies. 2- Study of VE-cadherin tyrosine phosphorylation in a context of hormones-regulated angiogenesis during mouse estrous cycle. The results showed VE-cadherin phosphorylation at Y685 that was regulated along mouse estrous cycle allowing to proposing mouse estrous cycle as a physiological model for studying VE-cadherin phosphorylation in vivo. The analysis of VE-cadherin Y685F knock-in mice (VE-Y685F) showed that these mice exhibit a higher vascular permeability in uterus and ovaries and the skin small capillaries compared to wild-type animals. Moreover, VE-Y685F mice presented higher levels of soluble VE-cadherin compared to wild-type counterparts in two induced arthritis model. Altogether, sVE and VE-cadherin phosphorylation present an array of interests for RA therapies as well as developing new therapeutic tools in RA and other vascular diseases.
159

Implication du récepteur à activité tyrosine kinase (RTK) MET sur la balance survie/apoptose et identification de nouvelles mutations de RTKs dans les cancers colorectaux métastatiques / Involvement of the receptor tyrosine kinase (RTK) MET on the survival/apoptosis balance and identification of new RTKs mutations in metastatic colorectal cancers

Duplaquet, Leslie 20 December 2018 (has links)
Les RTKs sont impliqués dans le dialogue au sein des tissus par la régulation de nombreuses réponses cellulaires dont la survie, la prolifération ou la mobilité. Dans les cancers, ces récepteurs sont fréquemment dérégulés notamment par des mutations activatrices. Ainsi, la suractivation des RTKs induit la transformation cellulaire et la tumorigenèse en favorisant par exemple la survie cellulaire. Depuis le début des années 2000, le développement de molécules inhibitrices de l’activité tyrosine kinase (TKI) et d’anticorps bloquant l’interaction ligand/récepteur ont montré que les RTKs représentent des cibles thérapeutiques majeures dans le traitement des cancers.MET est un RTK exprimé par les cellules épithéliales, dont le ligand est l’Hepatocyte Growth Factor/Scatter Factor (HGF/SF). En plus de son rôle pro-survie, MET peut également favoriser l’apoptose en absence de ligand et sous l’effet d’un stress. MET est alors clivé par les caspases et libère dans le cytosol un fragment de 40 kDa nommé p40MET. Ce fragment active la voie intrinsèque de l’apoptose en causant la perméabilisation des mitochondries. Cependant, les mécanismes moléculaires responsables de cette perméabilisation et l’impact physiologique de la fonction pro-apoptotique de MET étaient encore inconnus.Mon travail de thèse a permis de démontrer que le fragment p40MET se localise dans la région des MAMs, constituant l’interface entre le réticulum endoplasmique et les mitochondries, où il favorise un transfert de calcium entre les deux organites. Ce transfert déclenche une surcharge de calcium dans les mitochondries, responsable de leur perméabilisation. De plus, nous avons développé une lignée de souris transgéniques dans lesquelles MET est muté sur l’un des sites caspases. Ces souris sont incapables de produire le fragment p40MET pro-apoptotique. Ce modèle nous a permis de démontrer l'importance du clivage de MET dans l’amplification de l’apoptose in vivo. Ainsi, nos travaux apportent les premières preuves de la fonction de MET en tant que récepteur à dépendance au sein d’un organisme et décrivent un nouveau mécanisme de signalisation pro-apoptotique par la dérégulation des flux calciques.Ces dernières années, la découverte de mutations touchant les RTKs dans les cancers a augmenté de façon exponentielle. Toutefois, pour une grande majorité de mutations, leurs conséquences fonctionnelles sont totalement inconnues. Ainsi, en parallèle de mon principal sujet de thèse nous avons évalué la pertinence biologique et clinique des mutations de RTK identifiées par séquençage haut débit à partir d’échantillons de patients. Le séquençage de tissus sains, de tumeurs colorectales et de métastases hépatiques de 30 patients a permis d'identifier de nombreuses mutations somatiques. Parmi elles, certaines affectent le domaine kinase des récepteurs et sont présentes à la fois dans les tumeurs et les métastases. L’analyse fonctionnelle que j’ai menée sur 7 de ces mutations révèle qu’elles ne provoquent ni la suractivation de la kinase ni la transformation des fibroblastes NIH3T3. Au contraire, deux mutations de RTKs provoquent une inhibition drastique de leur activité kinase. Ces résultats démontrent que ces variants de RTK ne sont pas des cibles appropriées pour l’utilisation de TKI à des fins thérapeutiques et démontre l’intérêt de coupler la recherche de variants à des études fonctionnelles [...] / RTKs are involved in tissue dialogue by regulating many cellular mechanisms such as survival, proliferation or mobility. In cancers, these receptors are frequently deregulated, as a result of various molecular alterations leading to their activation. RTKs overactivation induces cell transformation and tumorigenesis notably by promoting survival. Since the early 2000s, the development of tyrosine kinase inhibitors (TKI) demonstrated that RTKs represent major therapeutic targets in cancer treatment.MET receptor and its ligand the Hepatocyte Growth Factor/Scatter Factor (HGF/SF) are known to promote survival of many epithelial structures during embryogenesis and later during adulthood. Besides pro-survival role of the ligand-activated MET, the receptor is also able to promote apoptosis, which has led to classify it within the dependence receptor family. Indeed, in absence of its ligand and under stress conditions, MET is cleaved by caspases leading to the production of an intracellular fragment of nearly 40 kDa named p40MET able to amplify apoptosis. This fragment activates the intrinsic pathway of apoptosis by causing mitochondrial permeabilization. However, the molecular mechanisms involved in this permeabilization and the physiological impact of the pro-apoptotic function of MET were still unknown.My PhD work has evidenced p40MET localization at the MAM microdomain and characterized a calcium transfer from the endoplasmic reticulum to the mitochondria triggered by p40MET. This calcium transfer triggers a calcium overload in mitochondria leading to their membrane permeabilization and apoptosis. In addition, we engineered a knock-in mouse model expressing mutated MET at the C-terminal caspase site. These mice are unable to produce the pro-apoptotic p40MET fragment. This model allowed us to assess the importance of MET cleavage in physiological apoptosis in vivo. Altogether, our work brings the first evidence for MET function as a dependence receptor in an organism and demonstrates a new signaling mechanism involved in apoptosis amplification by p40MET through calcium flux deregulation. This process may be relevant in the physio-pathology of organs where MET is expressed.In recent years, the discovery of mutations affecting RTKs in cancers has increased exponentially. However, for a large majority of mutations, their functional consequences are totally unknown. Thus, in parallel of my main thesis topic, we evaluated the biological and clinical relevance of RTKs mutations identified by high throughput sequencing from patient samples. Sequencing of healthy tissues, colorectal tumours and liver metastases of 30 patients has identified many somatic mutations. Some of them affect the receptor kinase domain and are present in both tumors and metastases. Functional analysis of 7 of these mutations shows that they do not cause neither kinase overactivation nor transformation of NIH3T3 fibroblasts. On the contrary, two RTK mutations cause drastic inhibition of the corresponding kinase activity. These findings indicate that these RTK variants are not suitable targets for TKI. Therefore, it appears important to set up reliable functional assays to interpret identified variants and classify them as pathogenic or neutral.In conclusion, my work opens up new perspectives on therapeutic strategies targeting RTKs in cancers. First of all, the pro-apoptotic capacities of some RTKs are undoubtedly a brake to tumorigenesis, and their stimulations could reinforce the effectiveness of anti-cancer therapies. On the other hand, we have shown that RTKs mutations in the kinase domain do not necessarily lead to overactivation of the receptor suggesting that they are probably not involved in tumorigenesis and that treatment with TKIs targeting them would be ineffective. This functional information could notably influence the choice of a suitable targeted therapy.
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Mechanism and Therapeutic Potential of Statin-Mediated Inhibition of Tyrosine Kinase Receptors

Zhao, Tong Tong 27 October 2011 (has links)
Receptor tyrosine kinases (RTK) are key regulators of growth, differentiation and survival of epithelial cells and play a significant role in the development and progression of cancers derived from these tissues. In malignant cells, these receptors and their downstream signalling pathways are often deregulated, leading to cell hyper-proliferation, enhanced cell survival and increased metastatic potential. Furthermore, endothelial expressed RTKs regulate tumor angiogenesis allowing for tumor growth and maintenance by promoting their vascularization. Epithelial malignancies such as squamous cell carcinomas (SCC), non-small cell lung (NSCLC) and malignant mesotheliomas have very limited treatment options when presenting as metastatic disease. RTKs, particularly the epidermal growth factor (EGFR) and the vascular endothelial growth factor (VEGFR) receptors, have been shown to play significant roles in the pathogenesis of these tumor types. Statins are potent inhibitors of HMG-CoA reductase, the rate limiting enzyme of the mevalonate pathway, that are widely used as hypercholesterolemia treatments. The mevalonate pathway produces a variety of end products that are critical for many different cellular pathways, thus, targeting this pathway can affect multiple signalling pathways. Our laboratory has previously shown that lovastatin can induce tumor specific apoptosis especially in SCC and that 23% of recurrent SCC patients treated with lovastatin as a single agent showed disease stabilization in our Phase I clinical trial. Subsequently, our lab was able to demonstrate that lovastatin in combination with gefitinib, a potent inhibitor of the EGFR showed co-operative cytotoxicity when combined (Chapter 2). Furthermore, the pro-apoptotic and cytotoxic effects of these agents were found to be synergistic and to be manifested in several types of tumor cell lines including SCC, NSCLC and glioblastoma. I was able to expand upon these important findings and demonstrated that lovastatin, through its ability to disrupt the actin cytoskeleton, inhibited EGFR dimerization and activation (Chapter 3). This novel mechanism targeting this receptor has clinical implications as lovastatin treatment combined with gefitinib showed co-operative inhibitory effects on EGFR activation and downstream signalling. The RTK family of proteins share similar features with respect to activation, internalization and downstream signalling effectors. I further demonstrated that lovastatin can inhibit the VEGFR-2 in endothelial cells and mesotheliomas, where VEGF and its receptor are co-expressed driving their proliferation, and induces synergistic cytotoxicity in mesothelioma cells in combination with VEGFR-2 tyrosine kinase inhibitors (Chapter 4). These findings suggest that statins may augment the effects of a variety of RTK inhibitors in a similar fashion representing a novel combinational therapeutic approach in a wide repertoire of human cancers. More importantly, based on this work, we initiated a Phase I/II study evaluating high dose rosuvastatin and the EGFR inhibitor tarceva in SCC and NSCLC patients at our institute. This clinical evaluation will provide invaluable data that will play a role in developing this novel therapeutic strategy. Together, the work embodied in this thesis provides a model for the regulation of EGFR/VEGFR-2 activation and signalling by targeting the rho family of proteins that demonstrates a novel mechanism that can be exploited to refine current therapeutic paradigms.

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