Global ETD Search

651	Co-transcriptional recruitment of the U1 snRNP Kotovic, Kimberly Marie 16 November 2004 (has links) It is currently believed that the splicing of most pre-mRNAs occurs, at least in part, co-transcriptionally. In order to validate this principle in yeast and establish an experimental system for monitoring spliceosome assembly in vivo, I have employed the chromatin immunoprecipitation (ChIP) assay to study co-transcriptional splicing events. Here, I use ChIP to examine key questions with respect to the recent proposal that RNA polymerase II (Pol II) recruits pre-mRNA splicing factors to active genes. In my thesis, I address: 1) whether the U1 snRNP, which binds to the 5¡¦ splice site of each intron, is recruited co-transcriptionally in vivo and 2) if so, where along the length of active genes the U1 snRNP is concentrated. U1 snRNP accumulates on downstream positions of genes containing introns but not within promoter regions or along intronless genes. More specifically, accumulation correlated with the presence and position of the intron, indicating that the intron is necessary for co-transcriptional U1 snRNP recruitment and/or retention (Kotovic et al., 2003). In contrast to capping enzymes, which bind directly to Pol II (Komarnitsky et al., 2000; Schroeder et al., 2000), the U1 snRNP is poorly detected in promoter regions, except in genes harboring promoter-proximal introns. Detection of the U1 snRNP is dependent on RNA synthesis and is abolished by intron removal. Microarray data reveals that intron-containing genes are preferentially selected by ChIP with the U1 snRNP furthermore indicating recruitment specificity to introns. Because U1 snRNP levels decrease on downstream regions of intron-containing genes with long second exons, our lab is expanding the study to 3¡¦ splice site factors in hopes to address co-transcriptional splicing. In my thesis, I also focus on questions pertaining to the requirements for recruitment of the U1 snRNP to sites of transcription. To test the proposal that the cap-binding complex (CBC) promotes U1 snRNP recognition of the 5¡¦ splice site (Colot et al., 1996), I use a ?´CBC mutant strain and determine U1 snRNP accumulation by ChIP. Surprisingly, lack of the CBC has no effect on U1 snRNP recruitment. The U1 snRNP component Prp40p has been identified as playing a pivotal role in not only cross-intron bridging (Abovich and Rosbash, 1997), but also as a link between Pol II transcription and splicing factor recruitment (Morris and Greenleaf, 2000). My data shows that Prp40p recruitment mirrors that of other U1 snRNP proteins, in that it is not detected on promoter regions, suggesting that Prp40p does not constitutively bind the phosphorylated C-terminal domain (CTD) of Pol II as previously proposed. This physical link between Pol II transcription and splicing factor recruitment is further tested in Prp40p mutant strains, in which U1 snRNP is detected at normal levels. Therefore, U1 snRNP recruitment to transcription units is not dependent on Prp40p activity. My data indicates that co-transcriptional U1 snRNP recruitment is not dependent on the CBC or Prp40p and that any effects of these players on spliceosome assembly must be reflected in later spliceosome events. My data contrasts the proposed transcription factory model in which Pol II plays a central role in the recruitment of mRNA processing factors to TUs. According to my data, splicing factor recruitment acts differently than capping enzyme and 3¡¦ end processing factor recruitment; U1 snRNP does not accumulate at promoter regions of intron-containing genes or on intronless genes rather, accumulation is based on the synthesis of the intron. These experiments have lead me to propose a kinetic model with respect to the recruitment of splicing factors to active genes. In this model, U1 snRNP accumulation at the 5¡¦ splice site requires a highly dynamic web of protein-protein and protein-RNA interactions to occur, ultimately leading to the recruitment and/or stabilization of the U1 snRNP. info:eu-repo/classification/ddc/570 ddc:570
652	Unraveling transcript-based variability of host responses to Tuberculosis Domaszewska, Teresa 01 April 2019 (has links) Jedes Jahr treten weltweit über zehn Millionen Fälle von Tuberkulose (TB) auf. Die Weltgesundheitsorganisation (WHO) schätzt, dass ein Drittel der Weltbevölkerung mit dem Erreger Mycobacterium tuberculosis (Mtb) infiziert ist. Bei fünf bis zehn Prozent aller latent Infizierten bricht Tuberkulose im Laufe des Lebens aus. Dennoch sind bereits 100 Jahre seit der Entdeckung von Mtb vergangen, ohne dass die entscheidenden Faktoren für den unterschiedlichen Infektionsverlauf bekannt wären. In dieser Arbeit untersuche ich die unterschiedlichen Reaktionen auf eine Tuberkuloseinfektion in verschiedenen Wirten. In meinem ersten Ansatz habe ich öffentlich zugängliche Transkriptom-Datensätze von Tuberkulosepatienten und gesunden Probanden ausgewertet. Mit Hilfe der Gensatzanreicherungs-Analyse (eng. Gene Set Enrichment Analysis, GSEA) habe ich die Transkriptionsprofile von Tuberkulosepatienten betrachtet. Das besondere Augenmerk lag hierbei auf der Interferon (IFN)-Signalkaskade, die für den Krankheitsverlauf von besonderer Bedeutung ist. In dieser Arbeit zeige ich zunächst, dass Patienten ohne eine IFN-Signatur in der untersuchten Kohorte vorkommen und widme mich im Anschluss der Frage, ob diese Patienten einen anderen Phänotypus haben als jene mit einer starken IFN-Antwort. Indem ich nur Patienten ohne IFN-Antwort betrachte, werden Mechanismen deutlich, die allen Patientengruppen gemein sind, aber vorher von der starken IFN-Signatur überlagert wurden. Ich belege in dieser Arbeit, dass eine starke IFN-Regulation auch mit einer ausgeprägten Lungenpathologie in Tuberkulosepatienten einhergeht. Passend hierzu weisen auch gesunde Probanden nach Verabreichung des Impfstoffs FLUAD® einen erhöhten Blutwert IFN-induzierter Zytokine auf. Mit Hilfe maschinellen Lernens konnte ich Transkriptomsignaturen der Patienten mit bzw. ohne IFN-Antwort identifizieren und vergleichen. Im zweiten Ansatz widme ich mich den unterschiedlichen Transkriptionsantworten auf Mtb-Infektionen in humanen Kohorten und zwei verschiedenen Mausmodellen. Der humanen und der murinen Immunantwort auf Infektionen unterliegen gravierende Unterschiede. Trotzdem sind einige Elemente des Immunsystems in beiden Arten konserviert. In dieser Arbeit präsentiere ich einen neuen Ansatz der Datenintegration, der die Identifizierung von übereinstimmenden und nicht übereinstimmenden Regulationselementen der Genexpression in heterogenen Datensätzen ermöglicht. Die Analyse basiert auf öffentlich zugänglichen sowie de-novo-generierten Datensätzen, zu denen ich durch wissenschaftliche Kollaborationen meiner Kollegen in der Abteilung Immunologie sowie der zentralen Einheit Microarray des Max-Planck-Instituts für Infektionsbiologie, Zugang erhalten habe. Des Weiteren liegt ein Schwerpunkt auf der vergleichenden Analyse humaner und muriner Transkriptionsantworten auf Tuberkulose in Vollblut und Makrophagen. Die erhaltenen Ergebnisse weisen auf einen signifikanten Unterschied in der Regulierung der angeborenen sowie der erworbenen Immunität in Mensch und Maus als Reaktion auf eine Mtb-Infektion hin. In dieser Arbeit charakterisiere ich die unterschiedliche Regulierung von T-Zell bezogenen Genen, die mit unterschiedlich ausgeprägten Phänotypen bei stark oder schwach TB-anfälligen Mausstämmen korrespondiert. Darüber hinaus habe ich den 21. Tag nach einer Tuberkuloseinfektion in Mäusen als Zeitpunkt ermittelt, der die Transkriptionsantworten in den untersuchten humanen Kohorten am besten widerspiegelt. Die angewandten Ansätze erleichtern die Auswahl des am besten geeigneten Tiermodells für die Erforschung der humanen Immunantwort auf eine ausgewählte Krankheit und liefern die Basis für ein besseres Verständnis der unterschiedlichen Krankheitsverläufe in Mtb-infizierten Patienten. / Over 10 million tuberculosis (TB) cases are being reported annually and the World Health Organization (WHO) estimates that up to the 1/3 of the world population is infected with Mycobacterium tuberculosis (Mtb). Between 5 and 10% of the latently infected individuals develop TB during their lifetime. Yet, despite over 100 years of research since Mtb has been identified, we are not able to define all the factors which are responsible for the different infection outcomes in the hosts. In this thesis I investigate the variability in the response to TB presented by different hosts. In one approach, I collect publicly available transcriptomic datasets from TB patients and healthy donors. Using Gene Set Enrichment Analysis (GSEA) I examine transcriptional profiles of individuals with TB. In particular, focus is brought to interferon (IFN) signaling which has been previously described as crucial for the disease outcome. I show that patients lacking IFN signature are present in the studied cohorts and investigate whether these patients present different phenotype than patients with strong regulation of IFN responses. Moreover, by focusing on patients lacking IFN response I try to unearth mechanisms present in all patient groups but dominated by the signal of IFN response. I show that strong regulation of IFN genes is related to severe pathology in the lungs of TB patients and that it is reflected by the levels of IFN-inducible cytokines in blood of healthy volunteers after vaccination with FLUAD® vaccine. Using Machine Learning (ML) methods, I identify and compare transcriptomic signatures of the patients presenting and lacking the IFN response. In the second approach I study the differences in the transcriptional responses to Mtb infection in human cohorts and two different mouse models. The immunity in infection, inflammation and malignancy differs markedly in man and mouse. Nevertheless, there are elements of immune system which have been conserved between the species. I propose a novel data integration approach which identifies concordant and discordant elements of gene expression regulation in heterologous datasets. The analysis is based on publicly available as well as novel experimental data acquired thanks to collaboration with my colleagues from the Department of Immunology and Microarray Core Facility of Max Planck Institute for Infection Biology (MPIIB). Additionally, I focus on the comparison of human and murine transcriptional responses to TB in whole blood (WB) and in macrophages. The results indicate profound differences between regulation of innate and adaptive immunity in man and mouse upon Mtb infection. I characterize differential regulation of T-cell related genes corresponding to the differences in phenotype between TB high and low susceptible mouse strains and identify the time point of 21 days p.i. of mice as best reflection of transcriptional responses in the studied human cohorts. The implemented approaches facilitate the choice of an appropriate animal model for studies of the human immune response to a particular disease and provide the basis for better understanding of differences in the outcomes of Mtb infection in individual hosts. Tuberkulose Transkriptomsignatur Machinelles Lernen Mausmodellen Interferon tuberculosis transcriptional signature machine learning mouse model interferon 570 Biowissenschaften; Biologie XG 2704 YE 1604 YE 1612 YE 1613 YE 1618 ddc:570
653	OperomeDB: database of condition specific transcription in prokaryotic genomes and genomic insights of convergent transcription in bacterial genomes Chetal, Kashish 27 October 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / My thesis comprises of two individual projects: 1) we have developed a database for operon prediction using high-throughput sequencing datasets for bacterial genomes. 2) Genomics and mechanistic insights of convergent transcription in bacterial genomes. In the first project we developed a database for the prediction of operons for bacterial genomes using RNA-seq datasets, we predicted operons for bacterial genomes. RNA-seq datasets with different condition for each bacterial genome were taken into account and predicted operons using Rockhopper. We took RNA-seq datasets from NCBI with distinct experimental conditions for each bacterial genome into account and analyzed using tool for operon prediction. Currently our database contains 9 bacterial organisms for which we predicted operons. User interface is simple and easy to use, in terms of visualization, downloading and querying of data. In our database user can browse through reference genome, genes present in that genome and operons predicted from different RNA-seq datasets. Further in the second project, we studied the genomic and mechanistic insights of convergent transcription in bacterial genomes. We know that convergent gene pairs with overlapping head-to-head configuration are widely spread across both eukaryotic and prokaryotic genomes. They are believed to contribute to the regulation of genes at both transcriptional and post-transcriptional levels, although factors contributing to their abundance across genomes and mechanistic basis for their prevalence are poorly understood. In this study, we explore the role of various factors contributing to convergent overlapping transcription in bacterial genomes. Our analysis shows that the proportion of convergent overlapping gene pairs (COGPs) in a genome is affected due to endospore formation, bacterial habitat, oxygen requirement, GC content and the temperature range. In particular, we show that bacterial genomes thriving in specialized habitats, such as thermophiles, exhibit a high proportion of COGPs. Our results also conclude that the density distribution of COGPs across the genomes is high for shorter overlaps with increased conservation of distances for decreasing overlaps. Our study further reveals that COGPs frequently contain stop codon overlaps with the middle base position exhibiting mismatches between complementary strands. Further, for the functional analysis using cluster of orthologous groups (COGs) annotations suggested that cell motility, cell metabolism, storage and cell signaling are enriched among COGPs, suggesting their role in processes beyond regulation. Our analysis provides genomic insights into this unappreciated regulatory phenomenon, allowing a refined understanding of their contribution to bacterial phenotypes. Operon prediction RNA-seq Transciptional regulation Genome organization Transcript structure Gene regulation Genomics Gene order Transcriptional interference Bacterial genomes Nucleotide sequence Genomes -- Regulation Operons Database design Genetic transcription Gene conversion
654	Role of post-transcriptional regulation in human liver Chaturvedi, Praneet 11 February 2015 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / My thesis comprises of two individual projects which revolve around the importance of post-transcriptional regulation in liver. My first project is studying the integrated miRNA – mRNA network in NAFLD. For fulfillment of the study we conducted a genome-wide study to identify microRNAs (miRs) as well as the miR-mRNA regulatory network associated with hepatic fat and NAFLD. Hepatic fat content (HFC), miR and mRNA expression were assessed in 73 human liver samples. Liver histology of 49 samples was further characterized into normal (n=33) and NAFLD (n=16). Liver miRNome and transcriptome were significantly associated with HFC and utilized to (a) build miR-mRNA association networks in NAFLD and normal livers separately based on the potential miR-mRNA targeting and (b) conduct pathway enrichment analyses. We identified 62 miRs significantly correlated with HFC (p < 0.05 with q < 0.15), with miR-518b and miR-19b being most positively and negatively correlated with HFC, respectively (p < 0.008 for both). Integrated network analysis showed that six miRs (miRs-30b, 612, 17, 129-5p, 204 and 20a) controlled ~ 70% of 151 HFC-associated mRNAs (p < 0.001 with q < 0.005). Pathway analyses of these HFC-associated mRNA revealed their key effect (p<0.05) in inflammation pathways and lipid metabolism. Further, significant (p<2.47e-4, Wilcoxon test) reduction in degree of negative associations for HFC-associated miRs with HFC-associated mRNAs was observed in NAFLD as compared to normal livers, strongly suggesting highly dysfunctional miR-mRNA post-transcriptional regulatory network in NAFLD. Our study makes several novel observations which provide clues to better understand the pathogenesis and potential treatment targets of NAFLD. My second project is based on uncovering important players of post-transcriptional regulation (RBPs) and how they are associated with age and gender during healthy liver development. For this study, we performed an association analysis focusing on the expression changes of 1344 RNA Binding proteins (RBPs) as a function of age and gender in human liver. We identify 88 and 45 RBPs to be significantly associated with age and gender respectively. Experimental verification of several of the predicted associations in the mouse model confirmed our findings. Our results suggest that a small fraction of the gender-associated RBPs (~40%) are likely to be up-regulated in males. Altogether, these observations show that several of these RBPs are important developmentally conserved regulators. Further analysis of the protein interaction network of RBPs associated with age and gender based on the centrality measures like degree, betweenness and closeness revealed that several of these RBPs might be prominent players in liver development and impart gender specific alterations in gene expression via the formation of protein complexes. Indeed, both age and gender-associated RBPs in liver were found to show significantly higher clustering coefficients and network centrality measures compared to non-associated RBPs. The compendium of RBPs and this study will help us gain insight into the role of post-transcriptional regulatory molecules in aging and gender specific expression of genes. Post-transcriptional regulation Liver NAFLD RBP- RNA binding proteins miRNA - microRNA Small interfering RNA Gene silencing Non-coding RNA Messenger RNA RNA RNA-protein interactions Protein binding Fatty liver Fatty liver -- Etiology
655	Long-term culture-expanded alveolar macrophages restore their full epigenetic identity after transfer in vivo Subramanian, Sethuraman, Busch, Clara Jana-Lui, Molawi, Kaaweh, Geirsdottir, Laufey, Maurizio, Julien, Vargas Aguilar, Stephanie, Belahbib, Hassiba, Gimenez, Gregor, Yuda, Ridzky Anis Advent, Burkon, Michaela, Favret, Jérémy, Najjar, Sara Gholamhosseinian, de Laval, Berengère, Kandalla, Prashanth Kumar, Sarrazin, Sandrine Sarrazin Zentrum für Regenerative, Alexopoulou, Lena, Siewake, Michael H. 26 August 2022 (has links) Alveolar macrophages (AMs) are lung tissue-resident macrophages that can be expanded in culture, but it is unknown to what extent culture affects their in vivo identity. Here we show that mouse long-term ex vivo expanded AMs (exAMs) maintained a core AM gene expression program, but showed culture adaptations related to adhesion, metabolism and proliferation. Upon transplantation into the lung, exAMs reacquired full transcriptional and epigenetic AM identity, even after several months in culture and could self-maintain long-term in the alveolar niche. Changes in open chromatin regions observed in culture were fully reversible in transplanted exAMs and resulted in a gene expression profile indistinguishable from resident AMs. Our results indicate that long-term proliferation of AMs in culture did not compromise cellular identity in vivo. The robustness of exAM identity provides new opportunities for mechanistic analysis and highlights the therapeutic potential of exAMs. info:eu-repo/classification/ddc/610 ddc:610
656	Transcriptional regulation of ATF4 is critical for controlling the Integrated Stress Response during eIF2 phosphorylation Dey, Souvik 29 October 2012 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / In response to different environmental stresses, phosphorylation of eIF2 (eIF2P) represses global translation coincident with preferential translation of ATF4. ATF4 is a transcriptional activator of the integrated stress response, a program of gene expression involved in metabolism, nutrient uptake, anti-oxidation, and the activation of additional transcription factors, such as CHOP/GADD153, that can induce apoptosis. Although eIF2P elicits translational control in response to many different stress arrangements, there are selected stresses, such as exposure to UV irradiation, that do not increase ATF4 expression despite robust eIF2P. In this study we addressed the underlying mechanism for variable expression of ATF4 in response to eIF2P during different stress conditions and the biological significance of omission of enhanced ATF4 function. We show that in addition to translational control, ATF4 expression is subject to transcriptional regulation. Stress conditions such as endoplasmic reticulum stress induce both transcription and translation of ATF4, which together enhance expression of ATF4 and its target genes in response to eIF2P. By contrast, UV irradiation represses ATF4 transcription, which diminishes ATF4 mRNA available for translation during eIF2∼P. eIF2P enhances cell survival in response to UV irradiation. However, forced expression of ATF4 and its target gene CHOP leads to increased sensitivity to UV irradiation. In this study, we also show that C/EBPβ is a transcriptional repressor of ATF4 during UV stress. C/EBPβ binds to critical elements in the ATF4 promoter resulting in its transcriptional repression. The LIP isoform of C/EBPβ, but not the LAP version is regulated following UV exposure and directly represses ATF4 transcription. Loss of the LIP isoform results in increased ATF4 mRNA levels in response to UV irradiation, and subsequent recovery of ATF4 translation, leading to enhanced expression of its target genes. Together these results illustrate how eIF2P and translational control, combined with transcription factors regulated by alternative signaling pathways, can direct programs of gene expression that are specifically tailored to each environmental stress. Transcriptional regulation ATF4 Gene expression Gene regulatory networks Genetic translation Stress (Physiology) Transcription factors RNA-protein interactions Cell receptors -- Research RNA -- Metabolism Proteins -- Metabolism -- Regulation Proteins -- Synthesis Proteomics -- Methodology Cellular signal transduction Eukaryotic cells
657	Genomic Analysis of Nematode-Environment Interaction Adhikari, Bishwo 15 July 2010 (has links) (PDF) The natural environments of organisms present a multitude of biotic and abiotic challenges that require both short-term ecological and long-term evolutionary responses. Though most environmental response studies have focused on effects at the ecosystem, community and organismal levels, the ultimate controls of these responses are located in the genome of the organism. Soil nematodes are highly responsive to, and display a wide variety of responses to changing environmental conditions, making them ideal models for the study of organismal interactions with their environment. In an attempt to examine responses to environmental stress (desiccation and freezing), genomic level analyses of gene expression during anhydrobiosis of the Antarctic nematode Plectus murrayi was undertaken. An EST library representative of the desiccation induced transcripts was established and the transcripts differentially expressed during desiccation stress were identified. The expressed genome of P. murrayi showed that desiccation survival in nematodes involves differential expression of a suite of genes from diverse functional areas, and constitutive expression of a number of stress related genes. My study also revealed that exposure to slow desiccation and freezing plays an important role in the transcription of stress related genes, improves desiccation and freezing survival of nematodes. Deterioration of traits essential for biological control has been recognized in diverse biological control agents including insect pathogenic nematodes. I studied the genetic mechanisms behind such deterioration using expression profiling. My results showed that trait deterioration of insect pathogenic nematode induces substantial overall changes in the nematode transcriptome and exhibits a general pattern of metabolic shift causing massive changes in metabolic and other processes. Finally, through field observations and molecular laboratory experiments the validity of the growth rate hypothesis in natural populations of Antarctic nematodes was tested. My results indicated that elemental stoichiometry influences evolutionary adaptations in gene expression and genome evolution. My study, in addition to providing immediate insight into the mechanisms by which multicellular animals respond to their environment, is transformative in its potential to inform other fundamental ecological and evolutionary questions, such as the evolution of life-history patterns and the relationship between community structure and ecological function in ecosystems. Plectus murrayi Heterorhabditis bacteriophora Scottnema lindsayae stress survival complementary DNA library subtractive hybridization comparative transcriptomics transcriptional profiling functional analysis Antarctic nematode desiccation anhydrobiosis stoichiometry McMurdo Dry Valleys microarray analysis trait deterioration Biology
658	Defining the functions and mechanisms of mRNA targeting to the mitotic apparatus Patel, Dhara 07 1900 (has links) La localisation des ARNm dans différents compartiments subcellulaires est conservée dans un large éventail d'espèces et de divers types cellulaires. Le trafic est médié par l'interaction entre les protéines de liaison à l'ARN (RBP) et l'ARNm. Les RBP reconnaissent les éléments cis-régulateurs de l'ARNm, également appelés éléments de localisation. Ceux-ci sont définis par leur séquence et/ou leurs caractéristiques structurelles résidant dans la molécule d'ARNm. La localisation des ARNm est essentielle pour la résolution subcellulaire et temporelle. De plus, les ARNm se sont avérés enrichis dans de nombreux compartiments cellulaires, notamment les mitochondries, l'appareil mitotique, et le réticulum endoplasmique. En outre, des études ont démontré que les RBP et les ARNm sont associés aux structures de l'appareil mitotique. Cependant, le rôle que joue la localisation de l'ARNm au cours de la mitose reste largement inexploré. Ma thèse de doctorat vise à comprendre comment le trafic d'ARNm est impliqué lors de la mitose. La première partie de cette thèse porte sur l'interaction post-transcriptionnelle qui se produit entre les deux ARNm, cen et ik2. Les gènes qui se chevauchent sont une caractéristique frappante de la plupart des génomes. En fait, il a été constaté que le chevauchement des séquences génomiques module différents aspects de la régulation des gènes tels que l'empreinte génomique, la transcription, l'édition et la traduction de l'ARN. Cependant, la mesure dans laquelle cette organisation influence les événements réglementaires opérant au niveau post-transcriptionnel reste incertaine. En étudiant les gènes cen et ik2 de Drosophila melanogaster, qui sont transcrits de manière convergente avec des régions 3' non traduites qui se chevauchent, nous avons constaté que la liaison physique de ces gènes est un déterminant clé dans la co-localisation de leurs ARNm aux centrosomes cytoplasmiques. Le ciblage du transcrit ik2 dépend de la présence et de l'association physique avec l'ARNm de cen, qui est le principal moteur de la co-localisation centrosomale. En interrogeant les ensembles de données de séquençage de fractionnement, nous constatons que les ARNm codés par des gènes qui se chevauchent en 3' sont plus souvent co-localisés par rapport aux paires de transcrits aléatoires. Ce travail suggère que les interactions post-transcriptionnelles des ARNm avec des séquences complémentaires peuvent dicter leur destin de localisation dans le cytoplasme. La deuxième partie de cette thèse consiste à étudier le rôle que jouent les RBP au cours de la mitose. Auparavant, les RBP se sont avérés être associés au fuseau et aux centrosomes. Cependant, leur rôle fonctionnel au niveau de ces structures reste à étudier. Grâce à un criblage par imagerie avec plus de 300 anticorps, nous avons identifié 30 RBP localisés dans les structures mitotiques des cellules HeLa. Ensuite, pour évaluer les rôles fonctionnels de ces RBP, nous avons utilisé l'interférence ARN (ARNi) pour évaluer si la fidélité du cycle cellulaire était compromise dans les cellules HeLa et les embryons de Drosophila melanogaster. Fait intéressant, nous avons identifié plusieurs candidats RBP pour lesquels le knockdown perturbe la mitose et la localisation de l'ARNm dans les cellules HeLa. De plus, la perte des orthologues a entraîné des défauts de développement chez l'embryon de mouche. Grâce à ce travail, nous avons démontré que les RBP sont impliquées pour assurer une mitose sans erreur. En résumé, les travaux que j'ai menés mettent en lumière l'implication de la régulation post-transcriptionnelle au cours de la mitose. En définissant les fonctions et le mécanisme de localisation des ARNm en mitose, ce travail permettra de définir de nouvelles voies moléculaires impliquées dans la régulation de la mitose. Puisque la division cellulaire non contrôlée peut mener à des maladies tel le cancer, étudier le contrôle du cycle cellulaire sous cet angle « centré sur l'ARN » peut aider à développer de nouvelles approches thérapeutiques pour trouver des solutions aux problèmes de santé. / The localization of mRNAs to different subcellular compartments is conserved in a wide range of species and diverse cell types. Trafficking is mediated by the interaction between RNA binding proteins (RBPs) and mRNA. RBPs recognize mRNA cis regulatory motifs, otherwise known as localization elements. These are defined by their sequence and/or structural features residing within the mRNA molecule. Localization of mRNAs is essential for subcellular and temporal resolution. Furthermore, mRNAs have been found to be enriched in many cellular compartments including the mitochondria, mitotic apparatus, and endoplasmic reticulum. Moreover, studies have demonstrated that RBPs and mRNAs are associated with mitotic apparatus structures. However, the role that mRNA localization plays during mitosis remains largely unexplored. My PhD thesis aims to understand how the trafficking of mRNAs is implicated during mitosis. The first part of this thesis encompasses the post-transcriptional interaction that occurs between the two mRNAs, cen and ik2. Overlapping genes are a striking feature of most genomes. In fact, genomic sequence overlap has been found to modulate different aspects of gene regulation such as genomic imprinting, transcription, RNA editing and translation. However, the extent to which this organization influences regulatory events operating at the post-transcriptional level remains unclear. By studying the cen and ik2 genes of Drosophila melanogaster, which are convergently transcribed with overlapping 3’untranslated regions, we found that the physical linkage of these genes is a key determinant in co-localizing their mRNAs to cytoplasmic centrosomes. Targeting of the ik2 transcript is dependent on the presence and physical association with cen mRNA, which serves as the main driver of centrosomal colocalization. By interrogating global fractionation-sequencing datasets, we find that mRNAs encoded by 3’overlapping genes are more often co-localized as compared to random transcript pairs. This work suggests that post-transcriptional interactions of mRNAs with complementary sequences can dictate their localization fate in the cytoplasm. The second part of this thesis involves investigating the role that RBPs play during mitosis. Previously, RBPs have been found to be associated with the spindle and centrosomes. However, their functional role at these structures was yet to be investigated. Through an imaging screen with >300 antibodies, we identified 30 RBPs localized to mitotic structures in HeLa cells. Then, to assess the functional roles of these RBPs, we used RNA interference (RNAi) to assess whether cell cycle fidelity was compromised in HeLa cells and Drosophila melanogaster embryos. Interestingly, we identified several RBP candidates for which the knockdown disrupted mitosis and mRNA localization in HeLa cells. Furthermore, loss of the orthologs led to developmental defects in the fly embryo. Through this work, we demonstrated that RBPs are involved in ensuring an error-free mitosis. In summary, the work that I have conducted sheds light on the involvement of post-transcriptional regulation during mitosis. By defining the functions and mechanism of mRNA localization in mitosis, this work will help define new molecular pathways involved in mitosis regulation. As uncontrolled cell division can lead to diseases such as cancer, studying cell cycle control from this ‘RNA-centric’ angle may help to develop new therapeutic approaches to find solutions to health problems. mRNA Localiation Mitosis RNA Binding Proteins Post-Transcriptional Regulation Cis-Natural Antisense Transcripts Drosophila Embryonic Development Mitose Localisation de l'ARN Protéines de Liaison à l'ARN Régulation Post-Transcriptionnelle Transcrit Naturel Antisense en Cis Drosophile Développement Embryonnaire
659	Optimisation d'antiœstrogènes dans le traitement du cancer du sein positif pour le récepteur des œstrogènes Diennet, Marine 10 1900 (has links) Deux tiers des cancers du sein expriment le récepteur des œstrogènes alpha (ERα), un facteur de transcription ligand dépendant responsable de la prolifération oncogénique de ces cellules. Ces tumeurs, dites ER positives (ER+), bénéficient de thérapies endocrines comme les antiœstrogènes (AE). Les AE sont des ligands compétitifs de ERα qui inhibent son activité transcriptionnelle. Le tamoxifène est l’antiœstrogène le plus utilisé en première ligne de traitement chez les patientes ayant un cancer du sein ER+. Malgré un bon pronostique initial, plus du tiers d’entre elles finiront par développer une résistance, parfois après de nombreuses années. L’absence de résistance croisée avec le tamoxifène place le fulvestrant comme seul dé-régulateur sélectif de ER (SERD) autorisé en clinique contre les tumeurs mammaires avancées résistantes. Malgré son profil antagoniste pur, le fulvestrant ne s’est pas révélé supérieur au tamoxifène en première ligne de traitement, cela étant attribué à sa faible biodisponibilité. D’autres SERD oralement disponibles sont en cours d’évaluation clinique. Des mutations du gène ESR1 (ERα) sont retrouvées dans environ 20% des tumeurs avancées résistantes à l’hormonothérapie et contribuent à la résistance au fulvestrant. Les mutations sont toutes retrouvées dans le domaine de liaison au ligand. La maladie progressera éventuellement avec le développement de métastases qui sont incurables. Il est donc crucial de (1) comprendre les mécanismes moléculaires médiant l’antiestrogénicité pure et l’impact des altérations génétiques impliquées dans la résistance aux AE pour (2) développer des thérapies ciblées plus efficaces qui pourraient lutter contre les tumeurs avancées résistantes. Les résultats prometteurs de plusieurs études in vitro et en clinique combinant un AE avec un inhibiteur d’histones désacétylases (HDACi) ont mené à la création de molécules hybrides combinant les deux fonctionnalités en une seule molécule. Nos travaux montrent que ces molécules hybrides dérivées du tamoxifène démontrent des propriétés inhibitrices améliorées par l’ajout d’un groupe fonctionnel inhibiteur des HDAC sur le squelette du tamoxifène. Ces composés sont antagonistes contre ERα et plusieurs HDAC et l’un d’eux possède une activité antiproliférative accrue par rapport aux composés parentaux dans les cellules de cancer du sein ER+ MCF-7. Notre étude fournit une preuve de concept que la combinaison d’une fonction pharmacologique HDACi sur le noyau d’un AE est prometteuse. Afin de mieux comprendre les déterminants moléculaires liés à l’induction de la SUMOylation de ERα et l’inhibition de son activité transcriptionnelle par le fulvestrant, nous avons testé l’impact de différentes mutations sur l’activité de plusieurs SERD, comprenant le fulvestrant. Nos résultats valident l’importance du résidu L536 dans la SUMOylation et la répression transcriptionnelle de ERα en réponse aux SERD. Les mutations ponctuelles L536P, Q et R, trouvées en clinique, compromettent la réponse au fulvestrant et à une sélection de SERD oraux in vitro. En résumé, nos résultats participent à une meilleure compréhension des caractéristiques moléculaires liées au mécanisme d’action du fulvestrant et de plusieurs SERD oraux de nouvelle génération. L’ensemble de nos résultats devraient aider au développement de nouvelles molécules plus efficaces contre les tumeurs résistantes, y compris des composés avec une double fonction inhibitrice AE-HDACi. / Two thirds of breast tumors are classified as positive for estrogen receptor alpha (ERα), a ligand-dependent transcription factor driving breast cancer cell proliferation. ER-positive (ER+) tumors benefit from endocrine therapies such as antiestrogens (AE). AE compete with ERα natural ligands and inhibit its transcriptional activity. Tamoxifen is the gold-standard for antiestrogenic therapy in patients with primary ER+ breast cancer. Despite a good initial prognosis, more than one-third will eventually develop resistance, sometimes after long periods of latency. Fulvestrant, known as a “pure” AE, is the only selective ER deregulator (SERD) approved in advanced breast cancer even after development of resistance to tamoxifen. Despite its pure antagonistic profile, fulvestrant has not proven superior to tamoxifen in first-line treatment, which is attributed to poor pharmacological properties. New generation SERDs with orally bioavailable properties are currently tested in the clinic. Mutations of ERα are found in about 20% of hormone-resistant advanced tumors and contribute to resistance to fulvestrant. The mutations are all located in the ligand binding domain. Resistant tumors will eventually progress and develop metastases which are deadly. It is therefore crucial to (1) understand the molecular determinants of pure antiestrogenicity and the impact of genetic alterations involved in AE resistance to (2) develop treatments with improved cytotoxic activities to achieve a more efficient suppression of advanced tumors. Promising results from several in vitro and clinical studies combining an AE with a histone deacetylase inhibitor (HDACi) have led to the design of hybrid molecules combining both functionalities into a single molecule. Our work shows that tamoxifen-derived hybrids display properties by the addition of an HDAC inhibitory functional group (HDACi) on the tamoxifen backbone. These compounds have inhibitory activities against ERα and several HDACs. One hybrid exhibits an improved cytotoxic activity against ER+ MCF-7 breast cancer cells compared to parental molecules. Our study provides proof of concept that combining HDACi function to the core of an AE is promising. To better understand the molecular determinants related to the induction of ERα SUMOylation and transcriptional repression by fulvestrant, we evaluated the impact of different mutations on the activity of several SERDs, including fulvestrant. Our results validate the importance of residue L536 in SUMOylation and transcriptional repression of ERα in response to SERDs. L536P, Q, and R point mutations are found in the clinic compromise the response to fulvestrant and to several oral SERDs in vitro. In summary, our results give better insights into the mechanism of action of fulvestrant and new generation oral SERDs and on the impact of naturally occurring mutations on transcriptional responses to these AE. Taken together, our results should help in the design of more efficient molecules, including compounds with dual AE-HDACi inhibitory function. Cancer du sein Récepteur des œstrogènes alpha Antiœstrogènes Inhibiteur d’histone désacétylase Molécules hybrides Mutations SUMOylation Répression transcriptionnelle Breast cancer Estrogen receptor alpha Antiestrogens Histone deacetylase inhibitor Hybrid molecules Transcriptional repression
660	La régulation de Staufen1 dans le cycle et la prolifération cellulaires Gonzalez Quesada, Yulemi 02 1900 (has links) Staufen1 (STAU1) est une protéine de liaison à l’ARN essentielle dans les cellules non-transformées. Dans les cellules cancéreuses, le niveau d’expression de la protéine est critique et étroitement lié à des évènements d’apoptose et des altérations dans la prolifération cellulaire. Le dsRBD2 de STAU1 lie des facteurs protéiques qui sont fondamentaux pour les fonctions de la protéine, telles que la liaison aux microtubules qui garantit sa localisation au fuseau mitotique et l’interaction avec les coactivateurs de l’E3 ubiquitine-ligase APC/C, ce qui garantit la dégradation partielle de STAU1 en mitose. Nous avons cartographié un nouveau motif F39PxPxxLxxxxL50 (motif FPL) dans le dsRBD2 de STAU1. Ce motif est fondamental pour l’interaction de la protéine avec les co-activateurs de l’APC/C, CDC20 et CDH1, et sa dégradation subséquente. Nous avons ensuite identifié un total de 15 protéines impliquées dans le processus inflammatoire qui partagent cette séquence avec STAU1. Nous avons prouvé, par des essais de co-transfection et de dégradation, que MAP4K1, l’une des protéines qui partagent ce motif, est aussi dégradé via ce motif FPL. Cependant, le motif de MAP4K1 n’est pas la cible de l’APC/C. Des techniques de biotinylation des protéines à proximité de STAU1 nous ont permis d’identifier TRIM25, une E3 ubiquitine ligase impliquée dans la régulation immunitaire et l’inflammation, comme protéine impliquée dans la dégradation de STAU1 et de MAP4K1 via le motif FPL. Ceci suggère des rôles de STAU1 dans la régulation du processus inflammatoire, ce qui est consistent avec des études récentes qui associent STAU1 à ce processus. Nous considérons que le motif FPL pourrait être à la base de la coordination de la régulation des protéines impliquées dans l’inflammation et la régulation de la réponse immune. Nos études sur l’effet anti-prolifératif de STAU1 lorsque surexprimé dans les cellules transformées ont identifié le domaine dsRBD2 de STAU1 comme responsable de ce phénotype. Des mutants qui miment les différents états de phosphorylation de la serine 20, située dans le domaine dsRBD2, sont à la base des changements dans la régulation de la traduction et la dégradation des ARNm liés à STAU1. Ces changements dans la régulation des ARNm par STAU1 sont associés aux altérations dans la prolifération des cellules transformées observées lors de la surexpression de STAU1. Nous avons aussi découvert que, après la transfection de STAU1, la cellule déclenche rapidement des évènements d’apoptose, et que ces évènements sont aussi dépendants de l’état de phosphorylation de la sérine 20 dans dsRBD2 de STAU1. Ces résultats suggèrent que STAU1 est un senseur qui contrôle la balance entre la survie et la prolifération cellulaire et que l’état de phosphorylation de son dsRBD2 est à la base de ce contrôle. Nos résultats indiquent que le dsRBD2 de STAU1 est le domaine de régulation du niveau d’expression protéique et un modulateurs des rôles de la protéine comme facteur post-transcriptionnel. Nous pensons que cibler la régulation de STAU1 et ses fonctions situées dans son domaine dsRBD2, serait important dans l’étude des maladies qui impliquent des événements d’apoptose, d’inflammation et de prolifération cellulaire telles que le cancer. / Staufen1 (STAU1) is an RNA-binding protein essential in untransformed cells. In cancer cells, the level of expression of the STAU1 protein is critical and it has been closely linked to events of apoptosis and to cell proliferation impairments. STAU1's dsRBD2 binds protein factors that are fundamental for the protein's functions, such as microtubules components that ensure the protein localization to the mitotic spindle and its interaction with E3 ubiquitin-ligase APC/C coactivators, which guarantees the partial degradation of STAU1 during mitosis. By mapping a novel F39PxPxxLxxxxL50 motif (FPL motif) in the dsRBD2 of STAU1, responsible of the interaction with the co-activators of APC/C, CDC20 and CDH1, and its subsequent degradation, we were able to identify a total of 15 proteins mostly involved in the inflammatory process that share this sequence with STAU1. We proved, by co-transfection and degradation assays that, MAP4K1, one of the proteins that shares this motif, is also degraded via this FPL motif. However, we demonstrated that this motif on MAP4K1 is not the target of APC/C. Biotinylation techniques of proteins near STAU1 allowed us to identify TRIM25, an E3 ubiquitin ligase involved in immune regulation and inflammation, as a protein involved in the degradation of STAU1 and MAP4K1 via the FPL motif. This suggests roles of STAU1 in the regulation of the inflammatory events, which is consistent with recent studies that associate STAU1 with this process. We consider that the FPL motif could be at the basis of the coordination of the regulation of proteins involved in inflammation and the regulation of the immune response. Our studies on the anti-proliferative effect of STAU1 when overexpressed in transformed cells identified the domain dsRBD2 of STAU1 as responsible for this phenotype. Mutants 8 that mimic different phosphorylation states of serine 20, located in dsRBD2, underlie changes in the regulation of translation and degradation of STAU1-linked mRNAs. These STAU1-dependent changes in mRNA regulation are associated with the proliferation impairment of transformed cells that is observed upon overexpression of STAU1. We also discovered that, after STAU1 transfection, the cell rapidly triggers apoptotic events, and that these events are also dependent on the phosphorylation state of serine 20 in dsRBD2 of STAU1. These results suggest that STAU1 is a sensor that controls the balance between cell survival and cell proliferation and that the state of phosphorylation of its dsRBD2 is the basis of this control. Our results indicate that the dsRBD2 of STAU1 is the regulatory domain of the level of protein expression and a modulator of the protein roles as a post-transcriptional factor. We believe that targeting the regulation of STAU1 and its functions located in its dsRBD2 domain, would be important in the study of diseases that involve apoptosis, inflammation and cell proliferation events such as cancer. Staufen1 régulation pos-transcriptionnel apoptose cycle cellulaire prolifération cellulaire SMD inflammation cancer dégradation E3 ubiquitine ligase post-transcriptional regulation apoptosis cell cycle cell proliferation degradation E3 ubiquitin ligase Biochemistry / Biochimie (UMI : 0487)

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