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The mesenchymal-like phenotype of metastatic breast cancer is maintained by the transcription factor RUNX1Ariffin, Nur Syamimi January 2017 (has links)
Breast cancer is the most prevalent cancer in women in the UK with over 50,000 new cases diagnosed each year. Almost all breast cancer deaths are due to metastatic disease. The RUNX1-CBFbeta transcription factor complex has been implicated in the development of human breast cancer and recent evidence from our laboratory indicated that it might have a role in metastasis. The aim of this project was therefore to determine the role of the RUNX1 transcription factor in breast cancer metastasis. Initial experiments to knockdown RUNX1 by shRNA also decreased the expression of RUNX2. Therefore, due to the off-target effect of shRUNX1, CRISPR-Cas9n was used to establish a RUNX1-negative cell line by targeting the first exon of the RUNX1 gene. Migration and invasion capacity of the cells decreased in the absence of RUNX1 and it was comparable to the absence of RUNX2 and CBFbeta respectively, which are known to play roles in migration and invasion of MDA-MB-231 cells. The cells also formed spherical clusters in 3D culture which was associated with the changes in cell morphology from stellate to round shape in the absence of RUNX1. The expression of the metastasis-related genes MMP13, MMP9, OPN and SLUG also decreased in parallel with the loss of the mesenchymal-like phenotype whilst the expression of the epithelial markers cytokeratin, desmoplakin and E-cadherin increased concomitantly. Importantly, re-expression of RUNX1 in the RUNX1-negative cell lines using an inducible expression system rescued migration and invasion. Therefore, RUNX1 is required to maintain the mesenchymal-like phenotype of MDA-MB-231 cells and hence is important for the epithelial to mesenchyme transition (EMT), a key characteristic of metastatic cells. The transcription factor SLUG is a known regulator of EMT. Data obtained shows that RUNX1 down-regulates the expression of SLUG. ChIP analysis demonstrated that RUNX1 was bound to the SLUG promoter and RUNX1 was subsequently shown to activate the promoter activity. Finally, experiments to inhibit the activity of the RUNX transcription factors pharmacologically showed changes in cell differentiation and also affected cell viability, possibly by off-target effects. Taken together, data presented in this work demonstrates that RUNX1 is required for EMT in the metastatic breast cancer cells and it is therefore a potential therapeutic target to prevent breast cancer metastasis.
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Signalisation et ciblage thérapeutique du récepteur tyrosine kinase AXL dans les cancers / Signaling and targeting of the Tyrosine Kinase Receptor AXL in cancerLeconet, Wilhem 28 January 2014 (has links)
AXL est un récepteur tyrosine kinase (RTK) impliqué dans de nombreux mécanismes cellulaires tels que la migration, l'invasion, l'angiogenèse et la prolifération des cellules. Sa surexpression a été observée dans de nombreux cancers et est souvent liée à un mauvais pronostic vital pour le patient. De plus, ce récepteur semble agir dans un mécanisme important dans la formation de métastases et la résistance aux thérapies anticancéreuses : la transition épithélio-mésenchymateuse (EMT). Nous avons dans un premier temps généré des anticorps monoclonaux murins spécifiques du récepteur AXL. Deux de ces anticorps ont ensuite été sélectionnés pour leurs propriétés inhibitrices de l'expression d'AXL à la surface et de l'activation de ce récepteur par son ligand GAS6. En effet ces deux anticorps, le 20G7D9 et le 3E3E8, entraine l'internalisation et la dégradation lysosomale d'AXL.Nous avons dans un deuxième temps étudié l'expression et le rôle de ce récepteur dans le cancer du pancréas qui possède un manque cruel de solutions thérapeutiques aujourd'hui et dont le taux de survie reste très faible (moins 5% des patients survivent 5 ans après son diagnostic). Nous avons ainsi observé une expression d'AXL dans une majorité des tumeurs de patients (76%), notamment au niveau du front invasif de ces tumeurs. Le ciblage d'AXL par nos deux anticorps inhibe sa signalisation et permet une réduction in vitro et in vivo de la croissance tumorale.Enfin, l'importante expression d'AXL dans le front invasif des tumeurs nous a incité à étudier le rôle d'AXL au cours de la transition épithélio-mésenchymateuse. Nous avons ainsi démontré que le couple AXL/GAS6 induit l'EMT dans des modèles invasifs de cancer du sein triple négatifs. De plus, l'expression du récepteur dans des tumeurs de cancer du sein de type basal-like est corrélée à celle de différents marqueurs importants dans l'EMT. L'application de nos anticorps anti-AXL dans ce type de cancer permet d'inhiber l'induction de l'EMT par le récepteur ainsi que l'invasion cellulaire in vitro et in vivo.Cette thèse a ainsi permis de démontrer l'importance du récepteur tyrosine kinase AXL dans des mécanismes oncogéniques clés et l'efficacité de son ciblage par des anticorps monoclonaux dans des modèles précliniques de cancer. / The Tyrosine Kinase Receptor (TKR) AXL is implicated in various cellular mechanisms (migration, invasion, angiogenesis and cell proliferation). Its overexpression has been observed in many cancers and is often correlated with poor prognosis. Moreover, this receptor seems to be important in Epithelial to Mesenchymal Transition (EMT), a mechanism related to metastasis formation and resistance to anticancer therapies.We have generated several AXL specific murine monoclonal antibodies. Two of them, 20G7D9 and 3E3E8, have been selected for their inhibition properties in AXL expression and activation by its ligand GAS6. In fact, both antibodies induce internalization and lysosomal degradation of AXL.Then we decided to study AXL expression and role in pancreatic cancer, which is characterized by a dramatic overall survival (<5%, 5 years after diagnosis) and a lack of efficient therapeutic solutions. We observed an ectopic expression of AXL in a majority of patient' pancreatic tumors (76%), notably in the invasive front of the tumor. Targeting AXL with both 20G7D9 and 3E3E8 inhibits its signaling and decreases tumor growth in vitro and in vivo.As AXL is mainly expressed in the invasive front of tumors, we analyzed its role during EMT. We observed that AXL/GAS6 signaling induces EMT in triple negative breast cancer cell lines. Furthermore, its expression is correlated with well-defined EMT markers in basal-like breast cancer tumors. In vitro and in vivo application of our antibodies inhibits AXL-dependant EMT signaling and cellular migration and invasion.In conclusion, this thesis demonstrates the importance of AXL Tyrosine Kinase Receptor in oncogenic processes and the efficacy of targeting this receptor with monoclonal antibodies in cancer preclinical models.
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The Role of Rankl in Prostate Cancer Progression and Bone MetastasisChu, Chia-Yi 06 December 2011 (has links)
This study focused on the role of RANKL in prostate cancer EMT progression and metastasis. Activation of RANK, a receptor activator of NF-kB, by its ligand RANKL, in a paracrine manner is responsible for osteoclast differentiation and bone remodeling. RANK activation in cancer cells, however, is thought to be promoted by both autocrine and paracrine mechanisms because RANKL has been shown to be derived from either tumor or its microenvironment, such as osteoblasts, infiltrating inflammatory cells and stromal fibroblasts. In the present study, we demonstrated that autocrine and paracrine RANKL-RANK signaling could be responsible for driving prostate cancer bone metastasis by promoting epithelial to mesenchymal transition (EMT). We further characterized a novel converging RANKL-c-Met signaling network in which the activation of RANKL was found to promote the expression of both RANKL and c-Met in an autocrine manner in prostate cancer cells. The induced RANKL and c-Met in prostate cancer cells is biologically functional and contributes to increased osteoclastogenesis, epithelial to mesenchymal transition (EMT), cell motility, migration and invasion and conferred bone and soft tissue metastases. Remarkably, RANKL expression by 1,000 prostate cancer cells can provoke bone and soft tissue metastases of a “dormant” population of prostate cancer cells which by themselves failed to form tumors and colonize mouse skeleton, suggesting RANKL can serve as a factor in “reawakening” cancer dormancy to initiate the re-growth and metastasis of cancer cells. We also showed that RANKL-induced RANKL feed-forward autocrine regulation is mediated through cMyc transactivation, allowing the establishment of a “vicious cycle” further promoting prostate cancer growth and metastasis. The converging RANKL-c-Met signaling network is therefore a novel target that could be further manipulated for delaying the lethal progression of castration-resistant human prostate cancer bone metastasis.
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Επιθηλιακή προς μεσεγχυματική μετατροπή και καρκίνωμα του λάρυγγος : ο ρόλος του μοριακού μονοπατιού μεταγωγής σήματος της ILK και των υποδοχέων ανδρογόνων και οιστρογόνων / Epithelial to mesenchymal transition and laryngeal carcinoma : the role of the molecular pathway of ILK and the androgen and estrogen receptorsΓουλιούμης, Αναστάσιος 05 May 2009 (has links)
Η επιθηλιακή προς μεσεγχυματική μετατροπή είναι ένα φαινόμενο που πιθανότατα εμπλέκεται στην παθογένεια του καρκίνου του λάρυγγα. Η ΕΜΤ εξελισσόμενη μέσα από δαιδαλώδη μονοπάτια μεταγωγής σήματος καταλήγει να προσδώσει στο καρκινικό κύτταρο δομικά και λειτουργικά χαρακτηριστικά που το καθιστούν ικανό να μπορεί να διεισδύει στους ιστούς και να μεθίσταται.
Κεντρικό μόριο στα μοριακά μονοπάτια που διαμεσολαβούν την ΕΜΤ στον καρκίνο του λάρυγγα είναι μια κινάση, η ILK, που δέχεται σήματα από τις ιντεγκρίνες και τους υποδοχείς αυξητικών παραγόντων. Στους επιθηλιακούς καρκίνους αναφέρεται η εμπλοκή της σε λειτουργίες όπως ρύθμιση του κυτταρικού κύκλου, αποφυγή της απόπτωσης, νεοαγγειογένεση, απώλεια των δομών συνοχής του κυττάρου, έκφραση μεταλλοπρωτεασών και αναδιαμόρφωση του κυτταροσκελετού. Στο λαρυγγικό καρκίνο όμως κρίσιμα φαινόμενα για τον μεταστατικό-επιθετικό χαρακτήρα των κυττάρων, όπως, η εξαφάνιση των E-cadherin, η μετακίνηση των β-catenin στον πυρήνα και η συσχέτιση μεταξύ τους, που διαπιστώθηκαν, δεν βρέθηκε να συνδέονται με την υπερέκφραση της ILK καθιστώντας προφανώς άλλους μηχανισμούς υπεύθυνους για την επιτέλεση αυτών των λειτουργιών. Ιδιαίτερα ενδιαφέρουσα όμως ήταν και η εντόπιση της ILK στον πυρήνα των κυττάρων του καρκίνου του λάρυγγα δίνοντας μια νέα προοπτική στην έρευνα για τον ρόλο της ILK στον καρκίνο.
Στο μονοπάτι μεταγωγής σήματος της ILK στο λαρυγγικό καρκίνο βρέθηκε πως συμμετέχει και η ενεργοποιημένη Akt με την οποία επίσης σχετίζονται πολλές κρίσιμες λειτουργίες για το καρκινικό κύτταρο. Ωστόσο η p-Akt στο λαρυγγικό καρκίνο φαίνεται πως έχει κάποιο ρόλο αντίθετο με την λειτουργία του καρκινικού κυττάρου καθώς χαρακτηρίζει όγκους καλύτερης διαφοροποίησης.
Ο λαρυγγικός καρκίνος τέλος διαπιστώθηκε πως χαρακτηρίζεται από την έκφραση υποδοχέων ανδρογόνων και οιστρογόνων καθιστώντας πολύ πιθανό το ρόλο αυτών των μορίων στην παθογένεια της νόσου. Ενδιαφέρουσα για την πιθανότητα εμπλοκής των υποδοχέων στερεοειδών ορμονών του φύλου στην ΕΜΤ ίσως να είναι η συσχέτιση των υποδοχέων ανδρογόνων και οιστρογόνων με την ILK και p-Akt αντίστοιχα. Οι υποδοχείς οιστρογόνων μάλιστα χαρακτηρίζοντας όγκους λάρυγγα αρχικών σταδίων ίσως θα μπορούσε να αποδειχτεί μόριο με προγνωστική αξία αλλά και θεραπευτικός στόχος.
Τέλος η μελέτη της έκφρασης της ILK, της p-Akt και των υποδοχέων στεροειδών ορμονών του φύλου δεν ανέδειξε μια διαφορετική έκφραση μεταξύ υπεργλωττιδικών και γλωττιδικών καρκίνων του λάρυγγος ώστε να υποστηρίξει την ύπαρξη ενός μοριακού υποβάθρου στην παρατήρηση της ανόμοιας κλινικής συμπεριφοράς μεταξύ όγκων από τις δύο αυτές ανατομικά διακριτές περιοχές. / Epithelial to mesenchymal transition (EMT) is a process possibly implicated in the pathogenesis of laryngeal cancer. EMT is a type of epithelial cell plasticity which is characterized by long lasting phenotypic and molecular modifications of the epithelial cell as a result of a transforming procedure leading to a cell of mesenchymal type. This molecular procedure seems to be pivotal for the metastasis of epithelial cancers and its attribution to the epithelial cells is the gain of structural and functional traits which enable them to invade the tissues and metastaze.
In the current study ILK expression, which is a central molecule in the signal transduction pathways of EMT, seems to be implicated in human laryngeal carcinoma. Furthermore, localization of ILK in the nucleus possibly suggests novel nuclear functions of ILK. In addition, enhanced ILK expression in laryngeal carcinoma correlates with activation of Akt. Moreover, while activated Act seems to characterize well differentiated tumors, loss of E-cadherin and activation of β-catenin were correlated with high grade carcinomas. Finally, in laryngeal cancer, mechanisms other than ILK overexpression seem to account for downregulation of E-cadherin and activation of β-catenin.
Additionaly this study concluded that estrogen and androgen receptors are expressed in laryngeal carcinomas, indicating their possible role in the pathogenesis of this disease. It is interesting that the receptors of gender-related steroid hormones could have a possible relation to epithelial to mesenchymal transition phenomenon since a correlation between androgen and estrogen receptors with ILK and p-Akt respectively, was revealed. Moreover estrogen receptors characterize primary TMN-stage laryngeal carcinomas. This can be very important as it makes a prospect of using ER as a prognostic factor but even more as a novel hormonal therapy for laryngeal carcinomas.
Finally the study of molecules like ILK, p-Akt, estrogen and androgen receptors did not reveal any differentiantal expression between glotic and supraglotic laryngeal carcinomas in order to support the existence of a molecular background, at least as far as those molecules are concerned, to the distinct clinical outcome of those different anatomically-derived laryngeal carcinomas.
Metastasis is a rapid development in the ominous course of cancer. The effort to interpret the molecular basis of this phenomenon is not a subject of simple academic interest since the exploit of the molecular mechanisms so as to gain the control of metastasis could be the ‘‘bet’’ for a futuristic ‘‘molecular surgery’’.
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Células estromais mesenquimais multipotentes promovem a metástase de melanoma pela ativação da transição epitélio-mesenquimal / Multipotent mesenchymal stromal cells promote melanoma metastasis through activation of the epithelial-to-mesenchymal transitionLucas Eduardo Botelho de Souza 11 June 2012 (has links)
A interação entre células tumorais e células estromais tem um papel central na progressão neoplásica. As células estromais mesenquimais multipotentes (MSCs) podem se integrar ao microambiente tumoral onde modulam o crescimento dos tumores por meio de distintos mecanismos. Entretanto, pouco se sabe sobre o papel das MSCs na metástase, a principal causa de morte em pacientes com câncer. Utilizando um modelo de melanoma murino ortotópico, nós demonstramos que MSCs obtidas da medula óssea de camundongos (MO-MSCs) ocupam o nicho perivascular nos tumores primários e aumentam 2,5 vezes a incidência de micrometástases pulmonares quando co-infundidas com células de melanoma B16. Observamos ainda que o meio condicionado das MO-MSCs não altera o potencial de colonização pulmonar das células B16 infundidas sistemicamente. Isto indica que as MO-MSCs modulam as fases iniciais da cascata metastática, durante a qual ocorrem os processos de invasão e intravasão nos vasos sangüíneos. Em correlação com estes efeitos pró-metastáticos, o secretoma das MO-MSCs induziu a transição epitélio-mesenquimal (EMT) nas células de melanoma in vitro. Após cultivo em meio condicionado das MO-MSCs, as células B16 adquiriram uma morfologia evidentemente fibroblástica. Ao mesmo tempo, houve o rearranjo dos filamentos de actina e o aumento da expressão de marcadores mesenquimais como fibronectina, vimentina, FSP1, N-caderina e ZEB2, acompanhado da repressão transcricional de E-caderina. A ativação da EMT pelo secretoma das MO-MSCs resultou na aquisição de propriedades metastáticas nas células de melanoma. Após cultivo em meio condicionado de MO-MSCs, as células B16 tiveram seu potencial de ancoragem à fibronectina reduzido, ao passo que houve o aumento na mobilidade e no potencial de invasão em matrizes tridimensionais. Utilizando inibidores competitivos de ATP contra o receptor tirosina-cinase Met, demonstramos que a aquisição de todas as propriedades metastáticas avaliadas e a ativação da EMT nas células de melanoma é mediada pela ativação da via HGF/Met. Estes dados destacam o papel das MOMSCs no microambiente tumoral como fonte perivascular de moléculas indutoras da EMT, cuja ativação leva a aquisição de traços metastáticos nas células de melanoma. Além disso, a inibição da via HGF/Met pode neutralizar os efeitos das MO-MSCs sobre as células tumorais, contribuindo para a repressão de propriedades fundamentais que sustentam a progressão e a disseminação neoplásica. Estas informações são importantes para o desenvolvimento seguro das MO-MSCs como ferramenta terapêutica e demonstram a importância da sinalização entre MSCs e células tumorais na disseminação metastática. Mais especificamente, estas observações reforçam a inibição da via HGF/Met como uma abordagem promissora para o tratamento da metástase. / The crosstalk between tumor cells and stromal cells can profoundly impact tumor progression. Multipotent mesenchymal stromal cells (MSCs) have been reported to integrate the tumor microenvironment where they are described to modulate tumor growth by distinct mechanisms. However, little is known about the impact of MSCs on metastasis, the main cause of death in patients with cancer. Using an orthotopic mouse melanoma model, we showed that mouse bone marrow-derived MSCs (BMMSCs) occupy the perivascular niche within primary tumors and increased by 2.5-fold the incidence of lung micrometastases after co-infusion with B16 melanoma cells. Also, MO-MSCs conditioned medium did not affect the lung colonization ability of systemically infused B16 cells. This indicates that MO-MSCs induces the initial steps of the metastatic cascade, during which the invasion and intravasion occurs. Correlating with these metastatic effects, the BM-MSCs\' secretome activated the epithelial-to-mesenchymal transition (EMT) in B16 cells in vitro. After culture in BMMSCs\' conditioned medium, B16 cells acquired an evident fibroblastic morphology. Simultaneously, we observed the rearrangement of actin filaments and the upregulation of mesenchymal markers such as fibronectin, vimentin, FSP1, Ncadherin and ZEB2. In agreement with the loss of epithelial phenotype, BM-MSCs\' secretome also suppressed E-cadherin expression in B16 cells. The activation of EMT by BM-MSCs leaded to the acquisition of metastatic traits in melanoma cells. After culture in BM-MSCs\' conditioned medium, B16 cells displayed reduced anchorage to fibronectin and increased motility and invasiveness in threedimensional matrix plugs. Inhibition of Met receptor with competitive ATP inhibitors demonstrated that the induction of EMT and the resultant acquisition of metastatic traits are driven by activation of HGF/Met signaling pathway. Taken together, these evidences highlight the role of BM-MSCs as a perivascular source of EMT-inductive signals, whose activation leads to acquisition of metastatic traits in melanoma cells. Furthermore, inhibition of HGF/Met signaling pathway can neutralize the effects of BM-MSCs on tumor cells, thereby allowing the repression of fundamental properties which support tumor progression and metastasis. This information is useful to safely develop BM-MSCs as therapeutic tool and demonstrate the relevance of the signaling between MSCs and tumor cells during metastasis. More specifically, it reinforces that inhibition of Met signaling can be a promissory approach for the treatment of metastasis.
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Role of Heat Shock Transcription Factor 1 in Ovarian Cancer Epithelial-Mesenchymal Transition and Drug SensitivityPowell, Chase David 17 November 2017 (has links)
The heat shock response (HSR) is a robust cellular reaction to mitigate protein damage from heat and other challenges to the proteome. This protective molecular program in humans is controlled by heat shock transcription factor 1 (HSF1). Activation of HSF1 leads to the induction of an array of cytoprotective genes, many of which code for chaperones. These chaperones, known as heat shock proteins (HSPs), are responsible for maintaining the functional integrity of the proteome. HSPs achieve this by promoting proper folding and assembly of nascent proteins, refolding denatured proteins, and processing for degradation proteins and aggregates which cannot be returned to a functional conformation. The powerful ability of the heat shock response to promote cell survival makes its master regulator, HSF1, an important point of research. To garner a better understanding of HSF1, we reviewed the role of the highly dynamic HSF1 protein structure and investigated how HSF1 affects cancer cell behavior and drug response.
Cancers can be characterized in part by abhorrent replication, self-sufficient growth signaling, invasion, and evasion of apoptosis. HSF1 has been found to promote proliferation, invasion, and drug resistance in several types of cancer; including lung and ovarian cancer. Ovarian cancer has elevated levels of HSF1, but the role of HSF1 in ovarian cancer behavior had not been previously examined. Researching the role of HSF1 in ovarian cancer is merited, because treatment outcomes are poor due to the high frequency of late stage detection and drug resistance. We hypothesized that HSF1 is important in the malignant growth and drug resistance of ovarian cancer.
We have created ovarian cancer cell lines with inducible knockdown of HSF1 to investigate how HSF1 contributes to the behavior of ovarian cancer. This allowed us to examine the behavior of cells in the absence HSF1. Both 2D and 3D spheroid tissue culture models were used to study how HSF1 contributes to the growth and invasion of ovarian cancer cells after treatment with the transforming growth factor β (TGFβ) cytokine. Additionally, we studied how HSF1 reduction modulates the response to multiple therapeutic drugs. Our research shows that HSF1 induces epithelial-mesenchymal transition (EMT) in a 3D growth model. Our work also demonstrates that reduction of HSF1 sensitizes ovarian cancer cells to multiple drugs.
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Rôle de la Ténascine-X dans l’activation du TGF bêta latent / Role of Tenascin-X in latent TGF beta activationAlcaraz, Lindsay 09 September 2015 (has links)
La Ténascine-X (TNX) est une glycoprotéine architecturale de la matrice extracellulaire. Outre ce rôle, la TNX est également considérée comme une protéine matricellulaire qui est capable de réguler le comportement de cellules normales et tumorales. Toutefois, aucun mécanisme moléculaire et cellulaire ne permettait d'expliquer les effets cellulaires de la TNX, avant notre étude. Au laboratoire, nous avons démontré que le domaine C-terminal de type fibrinogène (FBG) de la TNX était capable d'induire l'activation du Transforming Growth Factor (TGF) bêta latent. En effet, les trois isoformes du TGF bêta sont sécrétées sous la forme de complexes inactifs formés à partir de liaisons non covalentes entre le TGF bêta mature et son propeptide N-terminal LAP (Latency Associated Peptide). Nous avons montré que le domaine FBG de la TNX interagissait physiquement avec le TGF bêta latent, in vitro et in vivo, et induisait un changement de conformation du complexe latent, afin de permettre son activation en une molécule bioactive. De plus, nous avons identifié l'intégrine alpha11 bêta1 comme un récepteur membranaire pour la TNX et nous avons montré que cette intégrine était cruciale pour le processus d'activation du TGF bêta latent par le domaine FBG. Nous avons également démontré que les Méprines alpha et bêta deux protéases de la famille des astacines, pouvaient cliver la TNX, permettant ainsi de libérer des fragments contenant le domaine FBG, capables d'activer le TGF bêta latent. Enfin, nous avons entamé une étude de la pertinence biologique de l'activation du TGF bêta latent par la TNX in vivo en analysant la voie de signalisation du TGF bêta dans des souris déficientes ou non en TNX / Tenascin-X (TNX) is an architectural glycoprotein of the extracellular matrix. Beyond this role, TNX is also considered as a matricellular protein that is able to regulate the behavior of normal and tumor cells. However, no molecular and cellular mechanism has been described to explain TNX cellular effects before our study. In the laboratory, we showed that the C-terminal fibrinogen-like domain (FBG) of TNX was able to induce the latent transforming growth factor (TGF beta activation. Indeed, the three TGF beta isoforms are secreted as inactive complexes formed from non-covalent bonds between the mature TGF beta and its N-terminal propeptide, called LAP (Latency Associated Peptide). We showed that the FBG domain of TNX physically interacted with the latent TGF beta, in vitro and in vivo, and induced a conformational change of the latent complex to allow its activation into a bioactive molecule. Furthermore, we identified alpha1 beta1 integrin as a cell-surface receptor for TNX and showed that this integrin was crucial for the FBG-induced latent TGF beta activation. We also demonstrated that Meprins alpha and beta, two proteases belonging to the astacin family, could cleave the TNX, thereby releasing fragments containing the FBG domain capable of activating latent TGF beta. Finally, we have initiated a study regarding the biological relevance of latent TGF beta activation by TNX in vivo by analyzing the TGF beta signaling pathway in wild type or TNX-deficient mice
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Rôle des ARN hélicases Ddx5 et Ddx17 dans la progression tumorale / Role of RNA helicases DDX5 and DDX17 in tumor progressionDardenne, Étienne 31 March 2014 (has links)
La progression tumorale, qui conduit à la formation de métastases, est le résultat de profondes modifications des différents niveaux de régulation de l'expression des gènes comme la transcription ou l'épissage alternatif. Au cours de ma thèse, j'ai étudié le rôle de DDX5 et DDX17, deux ARN hélicases qui, au cours de la progression tumorale, sont impliquées dans la régulation transcriptionnelle, l'épissage alternatif et la biogénèse des microARNs. Pour cela, j'ai utilisé deux modèles de progression tumorale : le modèle murin 4T1, composé de cellules cancéreuses qui présentent des propriétés métastatiques différentes, et les cellules humaines MCF10A qui, après traitement au TGF-beta, sont capables de réaliser la transition épithélio-mésenchymateuse, un processus de trans-différenciation qui contribue à la formation des métastases. Dans le modèle 4T1, j'ai montré que Ddx17 et Ddx5 contribuent à l'invasivité des cellules tumorales en contrôlant des programmes transcriptionnels et d'épissage alternatif. Plus précisément, j'ai démontré que Ddx5 et Ddx17 favorisent l'agressivité des cellules cancéreuses en régulant l'épissage des variants de l'histone macroH2A1 qui, à leur tour, contrôlent l'expression de gènes impliqués dans la progression tumorale. Dans le modèle MCF10A où la transition épithélio-mésenchymateuse peut être induite sous TGF-beta, j'ai montré que DDX5 et DDX17 orchestrent dynamiquement des programmes transcriptionnels et d'épissage. Le travail effectué pendant ma thèse met en évidence l'importance des ARN hélicases DDX5 et DDX17 comme régulateurs clés de la progression tumorale, et souligne le rôle de l'épissage alternatif lors de la progression tumorale. De plus, ce travail met l'accent sur l'importance d'intégrer les différents niveaux de régulation de l'expression des gènes (transcription, épissage, microARN) pour une compréhension globale de la progression tumorale / Tumor progression leading to the formation of metastases result from deep modifications of gene expression programs at several levels, including transcription and splicing. During my PhD, I investigated the role in tumor progression of DDX5 and DDX17, two highly related multifunctional DEAD box RNA helicases that are involved in transcription and splicing as well as in microRNA biogenesis. For this purpose, I used two breast cancer models of tumor progression : the 4T1 mouse model composed of cancer cells that exhibit different metastatic properties and MCF10a human cells that undergo epithelial-to-mesenchymal transition upon Tgf-beta treatment, a trans-differentiation process contributes to metastasis formation. In the 4T1 mouse model, I showed that Ddx17 and Ddx5 contribute to tumor-cell invasiveness by controlling both transcriptional and splicing programs. More specifically, I demonstrated that Ddx5 and Ddx17 promote cancer cells aggressiveness by regulating the splicing of the macroH2A1 histone which in turn impacts on the expression of genes implicated in tumor cell invasiveness. In the Tgf-beta induced epithelial-to-mesenchymal trans-differentiation model, I showed that DDX5 and DDX17 dynamically orchestrate transcription, microRNA and splicing programs. The work performed during my PhD highlights the importance of DDX5 and DDX17 RNA helicases as key regulators of tumor progression in breast cancer, and also underlines the role of alternative splicing during tumor progression. Furthermore, this work emphasizes the importance of integrating the different layers of the gene expression process (transcription, splicing, microRNA) for a comprehensive understanding of tumor progression
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Rôle de HCaRG/COMMD5 dans le carcinome à cellules rénales : une histoire de transition.Verissimo, Thomas 03 1900 (has links)
Dans les années 2000, la Dre Johanne Tremblay et son équipe identifient un gène régulé négativement par le calcium extracellulaire dans les glandes parathyroïdiennes de rat hypertendu (SHR). Initialement nommé Hypertension-related calcium regulated gene (HCaRG), puis COMM domain-containing 5 (COMMD5), ce gène codant pour une petite protéine de 24,67 kDa fait partie d’une famille de 10 protéines ayant une structure carboxy-terminale homologue nommée domaine COMM. De nombreux rôles ont été associés à cette famille de protéines et l’analyse expressionnelle dans différents types de cancers montre une modulation, laissant penser qu’elles auraient un rôle oncogénique ou suppresseur de tumeurs.
Les études ont démontré que COMMD5 entraine une maturation des jonctions cellulaires, une diminution de la prolifération et favorise la migration cellulaire. La surexpression de COMMD5 dans les tubules proximaux de rein accélère la réparation suite à un dommage aigu en limitant d’une part la prolifération tout en favorisant la migration et la re-différenciation cellulaire. Partant de ces observations, nous avons focalisé nos études sur le développement du carcinome à cellules rénales, une pathologie affectant 300 000 personnes chaque année dans le monde.
L’hypothèse que nous avons émise était que COMMD5 puisse potentiellement jouer un rôle anti-oncogénique dans le cancer du rein en contrôlant la prolifération et la différenciation cellulaires. Afin de vérifier notre hypothèse, nous avons étudié le rôle de COMMD5 dans le maintien de l’intégrité épithéliale des cellules via la régulation de la transition épithélio-mésenchymateuse (EMT) et le contrôle du récepteur du facteur de croissance épidermique (EGFR).
Nos résultats ont démontré que COMMD5 est diminuée dans les carcinomes rénaux et est corrélée avec la survie des patients. La présence du facteur de transcription induit par l’hypoxie 1 (HIF1α), exprimé dans la majorité des tumeurs solides rénales a induit une diminution de COMMD5. La perte de COMMD5 dans les cellules de tubules proximaux de reins humains (HK-2) a favorisé la dé-différenciation et la tumorigénicité des cellules, médiées par l’activation de la transition épithélio-mésenchymateuse. De plus, cette perte de COMMD5 a entrainé également une réorganisation du cytosquelette d’actine ayant pour conséquence la dérégulation endosomale du récepteur de l’EGF et favorisant une activation prolongée. Dans les carcinomes rénaux, la surexpression de COMMD5 a diminué la prolifération cellulaire suivie d’une re-différenciation grâce à deux mécanismes. D’une part, COMMD5 a régulé négativement la protéine HIF1α, induisant ainsi une transition mésenchymo-épithéliale (MET), tout en séquestrant le facteur de transcription SNAIL dans le cytoplasme. D’autre part, COMMD5 contrôle négativement l’expression transcriptionnelle des récepteurs ErbB par une hyperméthylation de leurs promoteurs.
Dans son ensemble, les résultats innovant de cette thèse démontrent que COMMD5 est un gène ayant des caractéristiques anti-oncogéniques en contrôlant la différenciation cellulaire via le mécanisme de transition épithélio-mésenchymateux et la régulation de l’expression des récepteurs ErbB. / In the 2000s, Dr. Johanne Tremblay and her team identified a gene that was negatively
regulated by extracellular calcium in hypertensive rat parathyroid glands. Originally named
Hypertension-related calcium regulated gene (HCaRG) and renamed COMM Domaincontaining
5 (COMMD5), this gene encoding a small protein of 24.67 kDa is part of a family of
10 proteins sharing a homologous structure in the carboxy-terminal position named COMM
domain. Many roles have been associated and expressional analysis of different types of
cancer shows a modulation suggesting that they have an oncogenic or tumor suppressor roles.
Studies have shown that COMMD5 induces maturation of the cell junctions, decreased cell
proliferation and promotes migration. The overexpression of COMMD5 in the renal proximal
tubules accelerates repair by promoting cell proliferation and ultimately induces cell migration
and redifferentiation after acute injury. Based on these observations, we focused on the
development of renal cell carcinoma, a disease affecting 300,000 people each year worldwide.
Our hypothesis is that COMMD5 plays a tumor suppressor role in kidney cancer by
controlling cell proliferation and differentiation. To test our hypothesis, we investigated the
role of COMMD5 in maintaining the epithelial integrity of cells through the regulation of
epithelial to mesenchymal transition (EMT) and the control of epidermal growth factor
receptors (EGFR).
The results showed that COMMD5 is decreased in kidney carcinomas resulting of a
great negative indicator of the survival prognostic. The presence of hypoxia-inducible factor
1a (HIF1α), expressed in the majority of solid tumors, leads to a decrease of COMMD5 in the proximal tubule cells (HK-2). Inhibition of COMMD5 promotes dedifferentiation and
tumorigenicity of cells mediated by epithelial to mesenchymal transition. The loss of COMMD5
induces a reorganization of the actin cytoskeleton resulting in endosomal dysregulation of the
EGFR receptor and promoting its activation.
In renal cell carcinoma, COMMD5 overexpression decreases cell proliferation and
induces their redifferentiation by two mechanisms: firstly, COMMD5 induces an inhibition of
the HIF1α protein expression resulting in a mesenchymal to epithelial transition and
sequesters the SNAIL transcription factor in the cytoplasm; secondly, COMMD5 negatively
regulates the transcriptional expression of the ErbB receptors.
Taken together, these results of this thesis show that COMMD5 is a gene showing
tumor suppressor characteristics by controlling cellular differentiation and by regulating the
expression of ErbB receptors.
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A NOVEL BRAF SIGNALING CASCADE THROUGH p-21 ACTIVATED KINASES REGULATES THYROID CANCER CELL MOTILITYMcCarty, Samantha Keiko 06 August 2013 (has links)
No description available.
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