Global ETD Search

1	Identification et vectorisation de combinaisons de traitements pour la thérapie des tumeurs pulmonaires résistantes aux inhibiteurs de tyrosine kinase de l'EGFR / Identification and vectorization of combination of drugs for the treatment of lung tumors resistant to EGFR tyrosine kinase inhibitors Jeannot, Victor 01 October 2015 (has links) Responsable d'environ 30000 décès/an en France, le cancer du poumon est un problème de santé publique majeur. Un des enjeux actuels est d'adapter le traitement du cancer du poumon pour proposer des thérapeutiques ciblées plus efficaces et moins agressives. Les inhibiteurs de l'activité tyrosine kinase du récepteur de l'EGF (EGFR-TKI, gefitinib et erlotinib) constituent un réel progrès pour le traitement des cancers du poumon. Cependant, des mécanismes de résistance ont été décrits et des traitements combinés de thérapies ciblées avec des EGFR-TKI pourraient permettre de surmonter les résistances dans les cancers du poumon.Dans ce contexte, nous avons étudié les mécanismes impliqués dans la résistance à ces traitements. Nous montrons que l'activation de la voie de signalisation PI3K/AKT joue un rôle majeur dans la résistance aux EGFR-TKI, en inhibant l'apoptose par des mécanismes dépendant de l'acétylation. Les histones déacétylases (HDACs) et les sirtuines interviennent dans ces mécanismes de résistance, en modulant l'activation de la voie PI3K/AKT et l'apoptose. Ainsi l'utilisation d'inhibiteurs des HDACs (HDACi) et des sirtuines permettent de restaurer la sensibilité aux EGFR-TKI. Ces résultats confirment l'intérêt thérapeutique de l'association EGFR-TKI/HDACi et montrent le potentiel thérapeutique d'associer des inhibiteurs de l'EGFR et de la voie PI3K/AKT pour contourner la résistance aux EGFR-TKI.Les molécules thérapeutiques doivent atteindre spécifiquement le site tumoral, nécessitant parfois de les protéger contre leur dégradation, de réduire leurs effets indésirables, et de contrôler leur libération dans le temps et l'espace, à l'aide de transporteurs. Ainsi dans la deuxième partie de cette thèse, nous avons évalué les capacités de ciblage des tumeurs pulmonaires de nanoparticules à base de copolymère amphiphile, contenant une partie polysaccharidique hydrophile (le hyaluronane) et une partie polypeptidique hydrophobe (le poly(γ‐benzyl L‐glutamate, PBLG). Nos travaux mettent en évidence la capacité de ciblage tumoral de ces nanoparticules injectées par voie intraveineuse, ouvrant ainsi de nouvelles perspectives thérapeutiques. Notre objectif est de charger les combinaisons de traitements EGFR-TKI/HDACi que nous avons identifiées dans ces vecteurs, afin de traiter les tumeurs pulmonaires résistantes aux EGFR-TKI. / Responsible of 30000 deaths each year in France, lung cancer is a major public health problem. One of the current challenges is to adapt the treatment of lung cancer to offer more effective and less aggressive targeted therapies. EGFR tyrosine kinase inhibitors (EGFR-TKI, gefitinib and erlotinib) represent a real progress in lung cancer therapy. However resistance mechanisms have been described and combination of targeted therapy with EGFR-TKI could overcome resistance in lung cancer.In this context, we studied mechanisms involved in resistance to EGFR-TKI. We show that PI3K/AKT activation is a major pathway leading to EGFR-TKI resistance leading to apoptosis inhibition through acetylation-dependent mechanisms. Histone deacetylase (HADCs) and sirtuin are involved in these mechanisms and modulate PI3K/AKT activation and apoptosis. The use of HDACs inhibitors (HDACi) and sirtuins inhibitors thus restores the sensitivity to EGFR-TKI. Altogether these results confirm the therapeutic effect of the EGFR-TKI/HDACi combination and show the therapeutic potential of the association of EGFR and PI3K/AKT inhibitors to overcome EGFR-TKI resistance.Therapeutic molecules must specifically reach the tumor site, sometimes requiring to protect them against degradation, to reduce their side effects, and to control their release in time and space, using transporters. In the second part of this thesis, we have thus evaluated the lung tumors targeting capabilities of amphiphilic copolymer-based nanoparticles, containing an hydrophilic polysaccharidic block (hyaluronan) and an hydrophobic polypeptidic block (the poly(γ‐benzyl L‐glutamate PBLG). Our work highlights the tumor targeting capability of these nanoparticles injected intravenously, offering new lung cancer therapy perspectives. Our aim is to load the drugs combination (EGFR-TKI/HDACi) in these vectors, to treat the lung tumors resistant to EGFR-TKI. Cancer du poumon Imagerie Vectorisation innovante Egfr-Tki Résistance Lung cancer Imaging Vectorization Egfr-Tki Resistance 570
2	Signalisation nucléaire de l'IGF-1R et résistance aux thérapies anti-EGFR dans les cancers du poumon / Nuclear IGF-1R signaling and resistance to EGFR-targeted therapies in lung cancer Guérard, Marie 21 September 2016 (has links) Responsable de 1,6 million de décès par an dans le monde, le cancer du poumon constitue aujourd’hui la première cause de mortalité par cancer. Les cancers bronchiques non-à-petites cellules représentent 85% des cancers du poumon et ont un pronostic vital très mauvais. Les EGFR-TKI (inhibiteurs de l’activité tyrosine kinase de l’EGFR, gefitinib) constituent un réel progrès thérapeutique pour le traitement des cancers du poumon. Cependant, ces traitements ne sont efficaces que dans un petit sous-groupe de patients. Un des enjeux actuels est donc d’identifier les mécanismes de résistance primaire mis en jeu par les tumeurs.Les récepteurs à activité tyrosine kinase (RTK) activent des voies de signalisation intracellulaires depuis la membrane plasmique. Ces dernières années, une translocation nucléaire des RTK a également été mise en évidence. Ces travaux récents suggèrent que la signalisation nucléaire des RTK pourrait contribuer à la résistance des tumeurs en réponse aux thérapies anti-cancéreuses.Dans l’équipe, il a été montré que l’activation de l’IGF-1R est associée à la progression tumorale des adénocarcinomes pulmonaires et que le gefitinib induit une accumulation nucléaire de l’IGF-1R dans un modèle d’adénocarcinome mucineux. Sur la base de ces résultats, nous avons émis l’hypothèse que l’IGF-1R nucléaire pourrait jouer un rôle dans la résistance aux EGFR-TKI des adénocarcinomes pulmonaires mucineux.Nos résultats indiquent que plus de 70% des adénocarcinomes pulmonaires présentent un marquage nucléaire de l’IGF-1R. A l’aide de différents modèles cellulaires résistants aux EGFR-TKI, nous montrons que le gefitinib induit l’accumulation nucléaire de l’IGF-1R dans les adénocarcinomes pulmonaires mucineux. Cette translocation nucléaire implique l’endocytose clathrines-dépendante de l’IGF-1R et la formation d’un complexe entre l’IGF-1R, l’importine β1 et la pro-amphiréguline. La neutralisation de l’amphiréguline prévient le transport nucléaire de l’IGF-1R et resensibilise les cellules à l’apoptose induite par le gefitinib in vitro et in vivo. L’ensemble de ces résultats identifient le trafic intracellulaire de l’IGF-1R comme un nouveau composant de la réponse aux EGFR-TKI et suggèrent que la signalisation nucléaire IGF-1R/Areg contribue à la progression des adénocarcinomes mucineux sous EGFR-TKI. / Responsible of 1.6 million deaths each year worldwide, lung cancer is today the leading cause of cancer mortality in the world. Non-small-cell lung cancers account for about 85% of lung cancer and have a very bad prognosis (5-year survival rate inferior to 10%). EGFR-TKI (EGFR tyrosine kinase inhibitors, gefitinib) are a real medical advance for lung cancers treatment. However, these treatments are efficient in a small subgroup of patients. So, one of the current issues is to identify primary resistance mechanisms involved in tumors.Tyrosine kinase receptors (RTK) activate intracellular signaling pathways from the plasma membrane. These last years, a nuclear translocation of the RTK was shown. Recent works suggest that RTK nuclear signaling could contribute to tumors resistance in response to anti-cancerous therapies.In our team, it was shown that activation of IGF-1R signaling is associated with lung adenocarcinoma progression and that gefitinib induces IGF-1R nuclear accumulation in a mucinous adenocarcinoma cell line. On the basis of these results, we hypothesize that nuclear IGF-1R could play a role in the resistance of mucinous lung adenocarcinoma to EGFR-TKI.Our results indicate that more than 70% lung adenocarcinoma tumors present a positive IGF-1R nuclear staining. Thanks to EGFR-TKI-resistant cell lines, we show that gefitinib induces the nuclear accumulation of IGF-1R in mucinous adenocarcinoma. This nuclear translocation involves clathrin-mediated endocytosis and a complex between IGF-1R, importin β1 and pro-amphiregulin. Amphiregulin silencing prevents IGF-1R nuclear translocation in response to gefitinib and restores gefitinib-induced apoptosis in vitro and in vivo. Our whole results identify that IGF-1R intracellular trafficking is a new component of response to EGFR-TKI and strongly suggest that a nuclear IGF-1R/amphiregulin signaling contributes to mucinous lung adenocarcinoma progression in response to EGFR-TKI. IGF-1R nucléaire Amphiréguline Cancer du poumon Résistance Egfr-Tki Nuclear IGF-1R Amphiregulin Lung cancer Resistance Egfr-Tki 610
3	EGFR in Early Non-small Cell Lung Cancer: Tyrosine Kinase Inhibition in a Neoadjuvant Trial Lara-Guerra, Humberto 10 January 2012 (has links) EGFR TKIs are standard therapy for advanced NSCLC. In order to define their role in early disease, we implemented a phase II trial of neoadjuvant gefitinib in clinical stage I NSCLC. Tumour shrinkage was seen in 43% of patients, with 11% achieving RECIST partial response (PR). Analysis of molecular markers showed EGFR TKD mutations in 17% of cases, being the only associated with PR. For the first time we defined the histopathological response of NSCLC to these agents, characterized by reduction in tumour cellularity and proliferative index as well as presence of non-mucinous BAC histology. Clinical PR tumours also presented large areas of stromal fibrosis with presence of focal residual tumour. In a characterization of intracellular signalling response, EGFR dephosphorylation in the residues Y1068 and Y1173 was not concordant and only the former was significantly reduced. pAkt Ser473/Akt and Thr308/Akt ratios were significantly reduced but observed among both, clinical responders and resistant patients. Interestingly, reduction in pEGFR Y1068 was significantly associated with increase in tumour cellularity (p=0.047), Ki-67 index (p=0.018) and tumour growth (p=0.019) with a residual perinuclear localization been detected, suggesting a novel mechanism of resistance involving receptor internalization. Finally, we determined that the EGFR protein remains stable up to one hour of post resection ischemia but two to three tumour samples are necessary for an adequate tumour representation. Furthermore, EGFR cytoplasmic compartment presented the best association with clinical response in our cohort. Taking all together, we were able to generate the first clinical trial exploring the use of an EGFR TKI in early NSCLC, characterizing for the first time the histopathological and signalling responses to these agents with an evidence of a potential novel mechanism of resistance. Finally, we observed that multiple samples collection for an adequate tumour representation, and assessment of the cytoplasmic compartment, are warrant. lung cancer NSCLC neoadjuvant EGFR EGFR TKI response histopathological response molecular response Intratumoural heterogeneity ischemia 0992
4	EGFR in Early Non-small Cell Lung Cancer: Tyrosine Kinase Inhibition in a Neoadjuvant Trial Lara-Guerra, Humberto 10 January 2012 (has links) EGFR TKIs are standard therapy for advanced NSCLC. In order to define their role in early disease, we implemented a phase II trial of neoadjuvant gefitinib in clinical stage I NSCLC. Tumour shrinkage was seen in 43% of patients, with 11% achieving RECIST partial response (PR). Analysis of molecular markers showed EGFR TKD mutations in 17% of cases, being the only associated with PR. For the first time we defined the histopathological response of NSCLC to these agents, characterized by reduction in tumour cellularity and proliferative index as well as presence of non-mucinous BAC histology. Clinical PR tumours also presented large areas of stromal fibrosis with presence of focal residual tumour. In a characterization of intracellular signalling response, EGFR dephosphorylation in the residues Y1068 and Y1173 was not concordant and only the former was significantly reduced. pAkt Ser473/Akt and Thr308/Akt ratios were significantly reduced but observed among both, clinical responders and resistant patients. Interestingly, reduction in pEGFR Y1068 was significantly associated with increase in tumour cellularity (p=0.047), Ki-67 index (p=0.018) and tumour growth (p=0.019) with a residual perinuclear localization been detected, suggesting a novel mechanism of resistance involving receptor internalization. Finally, we determined that the EGFR protein remains stable up to one hour of post resection ischemia but two to three tumour samples are necessary for an adequate tumour representation. Furthermore, EGFR cytoplasmic compartment presented the best association with clinical response in our cohort. Taking all together, we were able to generate the first clinical trial exploring the use of an EGFR TKI in early NSCLC, characterizing for the first time the histopathological and signalling responses to these agents with an evidence of a potential novel mechanism of resistance. Finally, we observed that multiple samples collection for an adequate tumour representation, and assessment of the cytoplasmic compartment, are warrant. lung cancer NSCLC neoadjuvant EGFR EGFR TKI response histopathological response molecular response Intratumoural heterogeneity ischemia 0992
5	Targeting L-Arginine Metabolism to Control Small Cell Lung Cancer Transformation Burns, Robert L, Jr. 01 January 2022 (has links) (PDF) Cancer is known for its unregulated and mutagenic characteristics. The topic of targeting cancer by inhibiting the metabolic pathways it uses to thrive has been a focus of modern cancer research. Specifically, in lung cancer, the transformation from non-small cell lung cancer (NSCLC) to small cell lung cancer (SCLC) is a focus. This transformation often comes with a grimmer prognosis and reduced survival rate. This is primarily due to SCLC being resistant to epidermal growth factor receptor (EGFR) inhibitors. This frontline treatment for EGFR mutant NSCLC has shown to be quite effective until transformation to SCLC occurs. To further study the metabolic factors responsible for this transformation, a metabolic screening was conducted on SCLC transformed lung tissues and tumor adjacent normal lung tissues. This analysis revealed that the amino acid L-arginine and intermediates in its biosynthetic pathway were severely dysregulated. While L-arginine supplementation has shown to inhibit the growth of breast and colorectal cancers, there is little literature about its effects on lung cancer. Using cell viability and gene expression screening tools, we have identified arginine metabolizing genes ARG2, GATM, and OAT as being upregulated in NSCLC treated with high concentrations of an EGFR inhibitor. These high treatments also correlate with increased expression of neuronal differentiation factor 1 (NEUROD1), which has been shown to drive tumorigenesis, metastasis, and SCLC transformation. These findings show a role for altering arginine metabolism to accomplish drug resistance through SCLC transformation. These findings will hopefully pave the way for later clinical use of arginine converting enzymes and NEUROD1 expression levels as predictive markers of early drug resistance and SCLC transformation. neuroendocrine lineage plasticity small cell transformation EGFR-TKI cancer metabolism qPCR Oncology
6	Sphingosine kinase 1, transition épithélio-mésenchymateuse et résistance primaire aux inhibiteurs pharmacologiques de l'EGFR / Sphingosine kinase 1, epithelial-mesenchymal transition and primary resistance to EGFR pharmacological inhibitors Castelain, Lauriane 07 December 2016 (has links) Une transition épithélio-mésenchymateuse (TEM) et une expression élevée de la sphingosine kinase 1 (SPHK1) sont souvent observées dans les cancers. Notre étude du génome et du transcriptome d'adénocarcinomes pulmonaires (AP) montre que l'expression élevée de SPHK1 est en rapport, d'une part, avec des gains de la région incluant le locus SPHK1 et, d'autre part, avec une signature d'expression génique de TEM dans des tumeurs invasives. L'expression de SPHK1 est restreinte aux cellules tumorales. La surexpression de SPHK1 dans des cellules d'AP et l'exposition à son produit, la sphingosine-1-phosphate (S1P), entraînent une TEM, de manière réversible pour la S1P. La surexpression de SPHK1 active aussi NF-kB. La surexpression du facteur anti-apoptotique FLIP active NF-kB, induit une TEM et augmente l'expression de SPHK1, suggérant une boucle d'amplification entre NF-kB et SPHK1. Une TEM et la surexpression de FLIP ont été impliquées dans la résistance primaire aux inhibiteurs pharmacologiques de l'EGFR (EGFR TKI). Nous montrons que la surexpression de SPHK1 dans des cellules A549 diminue modestement la sensibilité au gefitinib, alors que l'inhibition de SPHK1 ou la déplétion du sérum en S1P l'augmentent modestement. L'invalidation de SPHK1 entraîne l'apoptose d'A549 y compris quand FLIP est surexprimé. L'activation et le maintien d'une TEM sont généralement attribués à des signaux contextuels du stroma. Cette thèse montre que les cellules tumorales elles-mêmes favorisent la surexpression de SPHK1 qui peut induire une TEM de façon autonome. De plus, la surexpression de FLIP impliquée dans la résistance aux EGFR TKI, n'empêche pas l'apoptose induite par l'invalidation de SPHK1. / Epithelial-mesenchymal transition (EMT) and sphingosine kinase 1 (SPHK1) high expression are often seen in cancers. Our study of genomic and gene expression data in pulmonary adenocarcinomas (AP) shows that SPHK1 high expression correlates with both gains in the region encompassing the SPHK1 locus, and an EMT gene expression signature in invasive tumors. SPHK1 expression is restricted to tumors cells. SPHK1 overexpression in AP cells, as well as exposure to its productsphingosine-1-phosphate (S1P),induce an EMT -in a reversible manner for S1P. SPHK1 overexpression also activates NF-kB. Overexpression of FLIP – an antiapoptotic factor - activates NF-kB, induces an EMT, and increases SPHK1 expression, suggesting an amplification loop between NF-kB and SPHK1. EMT and FLIP overexpression are known to favor primary resistance to EGFR pharmacological inhibitors (EGFR TKI). We show that SPHK1 overexpression in A549 cells slightly decreases cell sensitivity to gefitinib, while pharmacologic inhibition of SPHK1 or serum S1P depletionincrease it. Downregulation of SPHK1 expression induces apoptosis of A549 cells even when FLIP is overexpressed. Activation and maintenance of EMT are generally attributed to contextual signals from the stroma. Here, we show that tumor cells themselves favor SPHK1 overexpression, which can led to EMT in cell-autonomous manner. In addition, FLIP overexpression which is implicated in EGFR TKI resistance, cannot prevent apoptosis that is induced by SPHK1 invalidation. Adénocarcinome pulmonaire Transition épithélio-mésenchymateuse SPHK1 S1P Résistance primaire EGFR TKI Epithelial-mesenchymal transition Primary resistance SPHK1 572.8

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