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Le rôle de l'extrémité C-terminale de la protéine Merline dans sa fonction anti-tumorale / The role of the C-terminus Merlin in its tumor suppressor functionMandati, Vinay 02 September 2013 (has links)
La neurofibromatose de type 2 (NF2) est une maladie autosomique causée soit par l'inactivation du gène NF2, soit par la perte de la protéine issue due ce gène, Merline. Cela entraîne à son tour la formation de plusieurs tumeurs nerveuse bénignes (non invasives) comme les schwannomes, méningiomes et les épendymomes. De plus, une diminution de l'expression de Merline est observée dans les cancers du sein invasifs, toutefois le rôle de Merline dans ces tumeurs invasives est peu étudié. Merline est la seule protéine ayant un rôle de suppresseur de tumeur dans la famille des ERM (Ezrin / Radixin / Moesin). Nous, ainsi que d'autres groupes, avons montré que la partie C-terminale de Merline est importante pour sa fonction inhibitrice de la croissance cellulaire. Par conséquent, j'ai cherché à mettre en évidence de nouveaux partenaires d'interaction non décrits à ce jour, ainsi que de nouveaux sites de phosphorylation sur l'extrémité C-terminale de Merline qui pourrait expliquer la fonction de suppresseur de tumeur de Merlin. L'utilisation d’expériences d'immunoprécipitation couplées à la spectrométrie de masse nous a permis d’identifier de nouveaux interacteurs ainsi que de nouveaux sites de phosphorylation sur ce domaine C-terminal de Merline. Nous avons analysé l'importance d'un nouvel interacteur, AmotL1, ainsi que d'un nouveau site de phosphorylation sur la threonine 581 (T581), dans la fonction suppresseur de tumeur de Merline. La protéine AmotL1 appartient à la famille des motines, qui sont connues pour être impliquées dans la régulation de la migration cellulaire. A cet égard, nous avons montré qu’AmotL1 est un nouveau partenaire d'interaction de Merline. Nous avons étudié l'importance de cette interaction entre Merline et AmotL1 dans la migration cellulaire et nos données suggèrent fortement que Merlin pourrait inhiber la migration cellulaire médiée par AmotL1 dans les cellules du cancer du sein, via notamment la régulation de son expression et de sa localisation. Enfin, nous avons également identifié plusieurs nouveaux interacteurs de Merline, qui pourraient expliquer comment Merlin pourrait agir comme une protéine d'échafaudage à la membrane plasmique, en interagissant avec des composants essentiels de la voie Hippo, comme AmotL1, Kibra, Lats et YAP, pour réguler la prolifération et la migration cellulaire. Dans la deuxième partie, nous avons identifié un nouveau site de phosphorylation spécifique à l'isoforme 1 de Merline, la T581, et nous avons démontré que la phosphorylation de cette threonine est importante pour la progression en mitose au moment approprié. De plus, dans cette étude, nous avons montré que Merlin est un substrat potentiel de la kinase Aurora A, un oncogène majeur, au cours de la mitose et de l'interphase, dans des lignées cellulaires de cancer du sein. Enfin, nous avons fourni des données préliminaires sur la façon dont Aurora A régule la signalisation Hippo et la fonction de DCAF1 en phosphorylant Merline. En résumé, cette thèse met en évidence deux fonctions importantes de Merline : premièrement comment Merline régule la migration/invasion cellulaire dans des tumeurs non-nerveuses telles que les cancers du sein et deuxièmement, comment Merline est régulé au cours de la mitose et de l'interphase dans des lignées de cancer du sein, en agissant comme un substrat pour la kinase Aurora A qui est surexprimée dans plusieurs cancers comme celui du sein, du côlon et l'HCC. Prise dans son ensemble, notre étude montre le rôle potentiel de Merline dans les tumeurs invasives telles que celles rencontrées dans les cancers du sein. / Neurofibromatosis type 2 (NF2) is an autosomal disorder caused by inactivation of NF2 gene or loss of the NF2 product, Merlin. This in turn results in formation of multiple benign (noninvasive) nerve tumors such as schwannomas, meningiomas and ependymomas. Additionally reduced expression of Merlin is observed in invasive breast cancers however the role of Merlin in these invasive tumors is poorly investigated. Merlin is the only tumor suppressor protein in Ezrin/Radixin/Moesin (ERM) family proteins. Previously we and others have shown that C-terminus of Merlin is important for its growth suppressive function. In this regard, I set out to investigate whether there were undiscovered interacting partners and novel phosphorylation sites on the C-terminus of Merlin that could account for tumor suppressor function of Merlin. Using immunoprecipitation coupled to mass spectrometry we have identified new interactors as well as novel phosphorylation on this C-terminus domain of Merlin. We analyzed importance of new interactor, AmotL1, as well as novel phosphorylation site on T581 in the tumor suppressor function of Merlin. AmotL1 belongs to AMOT family proteins which are known to involve in the regulation of cell migration. In this regard, we have shown that AmotL1 is novel interacting partner of Merlin. We have investigated the importance of Merlin and AmotL1 interactions in cell migration and our data strongly suggest that Merlin might inhibit AmotL1 mediated cell migration in breast cancer cells by regulating its expression and localization. Finally, we have also found several new interactors of Merlin and that could explain how Merlin might acts as scaffolding protein at the plasma membrane by interacting with Hippo core components such as AmotL1, Kibra, Lats and YAP to regulate cell proliferation and migration. In the second part, we have identified a novel phosphorylation site at T581 which is specific to Merlin isoform 1 and demonstrated that phosphorylation of Merlin on T581 is important for the timely mitotic progression. Further in this study, we have shown that Merlin is a potential substrate for major oncogene Aurora kinase A in mitosis as well as in interphasic breast cancer cell lines. Finally we have provided initial clues how Aurora A regulates Hippo signaling and DCAF1 function by phosphorylating Merlin. In the summary, this thesis highlights two important functions of Merlin: firstly how Merlin regulates the cell migration/invasion in non-nerve tumors such as breast cancers and secondly how Merlin is regulated in mitosis and interphasic breast cancer cells by acting as a substrate to Aurora Kinase A which is over expressed in several cancers such as breast, colon and HCC. All together our study indicates the potential role for Merlin in invasive tumors such as breast cancers.
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Development and Application of Microarray-Based Comparative Genomic Hybridization : Analysis of Neurofibromatosis Type-2, Schwannomatosis and Related TumorsBuckley, Patrick January 2005 (has links)
<p>Neurofibromatosis type-2 (NF2) is an autosomal dominant disorder with the clinical hallmark of bilateral eighth cranial nerve schwannomas. However, the diagnostic criterion is complicated by the presence of a variable phenotype, with the severe form presenting with additional tumors such as peripheral schwannoma, meningioma and ependymoma. We constructed a microarray spanning 11Mb of 22q, encompassing the <i>NF2 </i>gene, to detect deletions in schwannoma. Forty seven patients were analyzed and heterozygous deletions were detected in 45% of tumors. Using this array-based approach, we also detected genetic heterogeneity in a number of samples studied. Despite the high sensitivity and the comprehensive series of studied schwannomas, no homozygous deletions affecting the <i>NF2</i> gene were detected <b>(paper I)</b>. In order to detect more subtle deletions within the <i>NF2</i> locus, a higher-resolution gene-specific array was developed, for the detection of disease-causing<b> </b>deletions using a PCR-based non-redundant strategy. This novel approach for array construction significantly increased the reliability and resolution of deletion-detection within the <i>NF2 </i>locus <b>(paper II)</b>. To further expand the coverage of the 11 Mb microarray, we constructed the first comprehensive microarray representing a human chromosome for analysis of DNA copy number. This 22q array covers 34.7 Mb, representing 1.1% of the genome, with an average resolution of 75 kb <b>(paper III)</b>. Using this array, we analyzed sporadic and familial schwannomatosis samples, which revealed two commonly deleted regions within the immunoglobulin lambda locus and the <i>GSTT1/CABIN1</i> locus. These regions were further characterized using higher-resolution non-redundant arrays, bioinformatic tools, positional cloning and mutational screening. Missense mutations were detected in the <i>CABIN1</i> gene, which may contribute to the pathogenesis of schwannomatosis and therefore requires further study <b>(paper IV)</b>. Meningioma is the second most common NF2-associated tumor and loss of 1p has been previously established as a major genetic factor for disease initiation/progression and also correlates with increased morbidity. We analyzed 82 meningiomas using a chromosome 1 tiling-path genomic microarray. The distribution of aberrations detected supports the existence of at least four regions on chromosome 1, which are important for meningioma tumorigenesis <b>(paper V)</b>.</p>
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Microarray-Based Comparative Genomic Hybridization in Neurofibromatoses and DiGeorge SyndromeMantripragada, Kiran K. January 2005 (has links)
<p>Microarray-based comparative genomic hybridization (array-CGH) has emerged as a versatile platform with a wide range of applications in molecular genetics. This thesis focuses on the development of array-CGH with a specific aim to approach disease-related questions through improved strategies in array construction and enhanced resolution of analysis. In <b>paper I</b>, we applied an array covering 11 Mb of 22q, encompassing the <i>NF2</i> locus, for deletion detection in sporadic schwannoma. Hemizygous deletions and tumor heterogeneity were identified. Array-CGH was established as a reliable platform for detection of DNA dosage alterations. <b>Paper II</b> described the construction of the<i> NF2</i> gene-specific microarray for high-resolution scanning of deletions in the <i>NF2</i> locus. We report a novel PCR-based non-redundant strategy for microarray fabrication, which considerably improved the sensitivity and reliability of deletion detection. <b>Paper III</b> reported the first tiling-path array comprehensively covering a human chromosome. The usefulness of the 22q-array was demonstrated by applying it to detect DNA dosage-alterations in 22q-associated disorders. In <b>paper IV</b>, we optimized array-CGH protocols for deletion detection in 22q11 deletion-syndrome. We showed that genomic and cDNA clones are not optimal for analysis of 22q11 locus and that PCR-based non-redundant strategy is reliable for deletion detection in such regions. In <b>paper V</b>, we utilized the 22q-array for understanding the genetic basis of schwannomatosis. Two commonly deleted regions were identified within the <i>IGL</i> and the <i>GSTT1/CABIN1</i> loci. Further investigations using high-resolution arrays, bioinformatic analysis and mutational screening were performed. Missense mutations, specific to the schwannomatosis- and NF2 samples, were identified in the <i>CABIN1 </i>gene. <b>Paper VI</b> described the first array-CGH study for comprehensive and high-resolution profiling of deletions spanning the 17q11 locus. Both typical and atypical deletions were identified in NF1 samples. Bioinformatic analysis revealed novel segmental duplications, which can potentially mediate 17q11 deletions.</p>
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Development and Application of Human Chromosome 22 Genomic Microarray : Chromosome 22-Associated Disorders Analyzed by Array-Based Comparative Genomic HybridizationBenetkiewicz, Magdalena January 2006 (has links)
<p>The array-based form of comparative genomic hybridization (array-CGH) is a new methodology that has shown to be of significant importance. This thesis focuses on the development of array-CGH with the aim to define candidate regions/genes on chromosome 22 in a wide spectrum of cancer-related conditions. In <b>paper I</b>, we developed and applied the first comprehensive genomic microarray, representing human chromosome 22, for analysis of DNA copy number. Using this array-based approach, we identified gene copy number alterations, including heterozygous/homozygous deletions, amplifications, IGLV/IGLC locus instability and the breakpoints of imbalanced translocation, in several 22q-associated disorders. In <b>paper II</b>, we applied the same array to perform DNA copy number profiling of a series of ovarian carcinoma. cDNA arrays were also used in this study to correlate gene expression levels with DNA-copy number. In the course of this analysis, we determined a small 3.5 Mb candidate 22q telomeric region and suggested a number of specific candidate genes. <b>Paper III</b> described the comprehensive and high-resolution analysis of chromosome 22 in a large set of various stage breast cancers. Multiple distinct patterns of genetic aberrations were observed. The smallest identified candidate locus was 220 kb in size and mapped to a gene-rich region in the vicinity of telomere of 22q. Intriguing result of this study was the detection of high frequency (26.6%) of intra-tumoral clonal variation in gene copy number profiles, which should be viewed as a high number, considering that we study in detail only a single human chromosome. In <b>paper IV</b>, we profiled a series of 28 Wilms tumor samples using 22q-array in order to assess specific regions affected with DNA dosage-alterations. The distribution of aberrations defined a complex amplifier genotype and delimited two tumor suppressor/oncogene candidate loci. These results open up for several avenues for continued research of these tumor forms. These findings also demonstrate the power of array-CGH in the precise determination of minute DNA copy number alterations and strengthen the notion that further studies, preferentially in the context of the entire human genome, are needed.</p>
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Analysis of Genetic Alterations in Patients Affected with Neurofibromatosis Type 2 and its Associated TumorsHansson, Caisa Marie January 2006 (has links)
<p>Neurofibromatosis type 2 (NF2) is an autosomal dominant disorder with the clinical hallmark of bilateral vestibular schwannomas (VS). Patients affected by a severe NF2 phenotype also presents with peripheral schwannomas, meningiomas and ependymomas. The closely related disorder schwannomatosis also displays multiple schwannomas, but never VS. Mutation screening of the <i>NF2</i> gene in the above mentioned tumors did not identify mutations in numerous of cases. We analyzed the DNA sequence covering the <i>NF2</i> locus in order to identify evolutionarily conserved non-genic sequences (CNGs) with unknown regulatory function (paper I). The aim was to analyze CNGs for mutations in DNA derived from patients affected by NF2 associated tumors. During mutation analysis of the coding part of <i>NF2</i> and within the CNGs defined in paper I, were mutations detected in 39% of sporadic meningiomas (paper II). Two candidate regions were identified on 22q using array-CGH. Methylation profiling did not identify methylation of the <i>NF2</i> promoter in these tumors. Sporadic schwannomas were profiled for CNV using a 22q genomic array in the search for putative gene(s) that in addition to <i>NF2</i> could be involved in the development of schwannoma and/or schwannomatosis (paper III). The predominant aberration identified was monosomy 22. Terminal and interstitial deletions encompassing the <i>NF2</i> gene were detected in tumor DNA and eight loci affected by CNV in constitutional DNA. Some of these CNVs are unlikely to be phenotypically neutral, considering their size and gene content. Two schwannomatosis candidate regions were identified on 22q using array-CGH (paper IV). These regions were further characterized by a PCR-product based array with higher resolution. Rearrangements of the immunoglobulin lambda (<i>IGL</i>) locus detected were restricted to schwannomatosis patients. In the second candidate region spanning <i>GSTT1</i> and <i>CABIN1</i> genes, was frequent copy number polymorphism at the <i>GSTT1</i> locus identified. We further describe missense mutations in the <i>CABIN1 </i>gene, making this gene a plausible candidate which may contribute to the pathogenesis of these disorders. </p>
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Development and Application of Microarray-Based Comparative Genomic Hybridization : Analysis of Neurofibromatosis Type-2, Schwannomatosis and Related TumorsBuckley, Patrick January 2005 (has links)
Neurofibromatosis type-2 (NF2) is an autosomal dominant disorder with the clinical hallmark of bilateral eighth cranial nerve schwannomas. However, the diagnostic criterion is complicated by the presence of a variable phenotype, with the severe form presenting with additional tumors such as peripheral schwannoma, meningioma and ependymoma. We constructed a microarray spanning 11Mb of 22q, encompassing the NF2 gene, to detect deletions in schwannoma. Forty seven patients were analyzed and heterozygous deletions were detected in 45% of tumors. Using this array-based approach, we also detected genetic heterogeneity in a number of samples studied. Despite the high sensitivity and the comprehensive series of studied schwannomas, no homozygous deletions affecting the NF2 gene were detected <b>(paper I)</b>. In order to detect more subtle deletions within the NF2 locus, a higher-resolution gene-specific array was developed, for the detection of disease-causing<b> </b>deletions using a PCR-based non-redundant strategy. This novel approach for array construction significantly increased the reliability and resolution of deletion-detection within the NF2 locus <b>(paper II)</b>. To further expand the coverage of the 11 Mb microarray, we constructed the first comprehensive microarray representing a human chromosome for analysis of DNA copy number. This 22q array covers 34.7 Mb, representing 1.1% of the genome, with an average resolution of 75 kb <b>(paper III)</b>. Using this array, we analyzed sporadic and familial schwannomatosis samples, which revealed two commonly deleted regions within the immunoglobulin lambda locus and the GSTT1/CABIN1 locus. These regions were further characterized using higher-resolution non-redundant arrays, bioinformatic tools, positional cloning and mutational screening. Missense mutations were detected in the CABIN1 gene, which may contribute to the pathogenesis of schwannomatosis and therefore requires further study <b>(paper IV)</b>. Meningioma is the second most common NF2-associated tumor and loss of 1p has been previously established as a major genetic factor for disease initiation/progression and also correlates with increased morbidity. We analyzed 82 meningiomas using a chromosome 1 tiling-path genomic microarray. The distribution of aberrations detected supports the existence of at least four regions on chromosome 1, which are important for meningioma tumorigenesis <b>(paper V)</b>.
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Microarray-Based Comparative Genomic Hybridization in Neurofibromatoses and DiGeorge SyndromeMantripragada, Kiran K. January 2005 (has links)
Microarray-based comparative genomic hybridization (array-CGH) has emerged as a versatile platform with a wide range of applications in molecular genetics. This thesis focuses on the development of array-CGH with a specific aim to approach disease-related questions through improved strategies in array construction and enhanced resolution of analysis. In <b>paper I</b>, we applied an array covering 11 Mb of 22q, encompassing the NF2 locus, for deletion detection in sporadic schwannoma. Hemizygous deletions and tumor heterogeneity were identified. Array-CGH was established as a reliable platform for detection of DNA dosage alterations. <b>Paper II</b> described the construction of the NF2 gene-specific microarray for high-resolution scanning of deletions in the NF2 locus. We report a novel PCR-based non-redundant strategy for microarray fabrication, which considerably improved the sensitivity and reliability of deletion detection. <b>Paper III</b> reported the first tiling-path array comprehensively covering a human chromosome. The usefulness of the 22q-array was demonstrated by applying it to detect DNA dosage-alterations in 22q-associated disorders. In <b>paper IV</b>, we optimized array-CGH protocols for deletion detection in 22q11 deletion-syndrome. We showed that genomic and cDNA clones are not optimal for analysis of 22q11 locus and that PCR-based non-redundant strategy is reliable for deletion detection in such regions. In <b>paper V</b>, we utilized the 22q-array for understanding the genetic basis of schwannomatosis. Two commonly deleted regions were identified within the IGL and the GSTT1/CABIN1 loci. Further investigations using high-resolution arrays, bioinformatic analysis and mutational screening were performed. Missense mutations, specific to the schwannomatosis- and NF2 samples, were identified in the CABIN1 gene. <b>Paper VI</b> described the first array-CGH study for comprehensive and high-resolution profiling of deletions spanning the 17q11 locus. Both typical and atypical deletions were identified in NF1 samples. Bioinformatic analysis revealed novel segmental duplications, which can potentially mediate 17q11 deletions.
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Development and Application of Human Chromosome 22 Genomic Microarray : Chromosome 22-Associated Disorders Analyzed by Array-Based Comparative Genomic HybridizationBenetkiewicz, Magdalena January 2006 (has links)
The array-based form of comparative genomic hybridization (array-CGH) is a new methodology that has shown to be of significant importance. This thesis focuses on the development of array-CGH with the aim to define candidate regions/genes on chromosome 22 in a wide spectrum of cancer-related conditions. In <b>paper I</b>, we developed and applied the first comprehensive genomic microarray, representing human chromosome 22, for analysis of DNA copy number. Using this array-based approach, we identified gene copy number alterations, including heterozygous/homozygous deletions, amplifications, IGLV/IGLC locus instability and the breakpoints of imbalanced translocation, in several 22q-associated disorders. In <b>paper II</b>, we applied the same array to perform DNA copy number profiling of a series of ovarian carcinoma. cDNA arrays were also used in this study to correlate gene expression levels with DNA-copy number. In the course of this analysis, we determined a small 3.5 Mb candidate 22q telomeric region and suggested a number of specific candidate genes. <b>Paper III</b> described the comprehensive and high-resolution analysis of chromosome 22 in a large set of various stage breast cancers. Multiple distinct patterns of genetic aberrations were observed. The smallest identified candidate locus was 220 kb in size and mapped to a gene-rich region in the vicinity of telomere of 22q. Intriguing result of this study was the detection of high frequency (26.6%) of intra-tumoral clonal variation in gene copy number profiles, which should be viewed as a high number, considering that we study in detail only a single human chromosome. In <b>paper IV</b>, we profiled a series of 28 Wilms tumor samples using 22q-array in order to assess specific regions affected with DNA dosage-alterations. The distribution of aberrations defined a complex amplifier genotype and delimited two tumor suppressor/oncogene candidate loci. These results open up for several avenues for continued research of these tumor forms. These findings also demonstrate the power of array-CGH in the precise determination of minute DNA copy number alterations and strengthen the notion that further studies, preferentially in the context of the entire human genome, are needed.
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Analysis of Genetic Alterations in Patients Affected with Neurofibromatosis Type 2 and its Associated TumorsHansson, Caisa Marie January 2006 (has links)
Neurofibromatosis type 2 (NF2) is an autosomal dominant disorder with the clinical hallmark of bilateral vestibular schwannomas (VS). Patients affected by a severe NF2 phenotype also presents with peripheral schwannomas, meningiomas and ependymomas. The closely related disorder schwannomatosis also displays multiple schwannomas, but never VS. Mutation screening of the NF2 gene in the above mentioned tumors did not identify mutations in numerous of cases. We analyzed the DNA sequence covering the NF2 locus in order to identify evolutionarily conserved non-genic sequences (CNGs) with unknown regulatory function (paper I). The aim was to analyze CNGs for mutations in DNA derived from patients affected by NF2 associated tumors. During mutation analysis of the coding part of NF2 and within the CNGs defined in paper I, were mutations detected in 39% of sporadic meningiomas (paper II). Two candidate regions were identified on 22q using array-CGH. Methylation profiling did not identify methylation of the NF2 promoter in these tumors. Sporadic schwannomas were profiled for CNV using a 22q genomic array in the search for putative gene(s) that in addition to NF2 could be involved in the development of schwannoma and/or schwannomatosis (paper III). The predominant aberration identified was monosomy 22. Terminal and interstitial deletions encompassing the NF2 gene were detected in tumor DNA and eight loci affected by CNV in constitutional DNA. Some of these CNVs are unlikely to be phenotypically neutral, considering their size and gene content. Two schwannomatosis candidate regions were identified on 22q using array-CGH (paper IV). These regions were further characterized by a PCR-product based array with higher resolution. Rearrangements of the immunoglobulin lambda (IGL) locus detected were restricted to schwannomatosis patients. In the second candidate region spanning GSTT1 and CABIN1 genes, was frequent copy number polymorphism at the GSTT1 locus identified. We further describe missense mutations in the CABIN1 gene, making this gene a plausible candidate which may contribute to the pathogenesis of these disorders.
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