Global ETD Search

11	Identificação e validação das interações miRNA-mRNA na metamorfose de Apis mellifera / Identification and characterization of miRNA-target interactions in the metamorphosis of Apis mellifera Natalia Helena Hernandes 31 March 2016 (has links) A metamorfose em insetos é um dos mais complexos e belos eventos biológicos conhecidos, dirigido por sucessivas alterações morfo-fisiológicas. Este intricado processo é coordenado por componentes moleculares como ecdisteroides (20E) e hormônio juvenil (HJ), fatores de transcrição e microRNAs (miRNAs). Os miRNAs regulam a expressão de genes-alvo, que por sua vez orquestram alterações fisiológicas e anatômicas necessárias para o completo desenvolvimento do organismo. Apesar do enorme esforço, os circuitos genéticos e endócrinos que regulam a metamorfose em insetos sociais, como a abelha Apis mellifera, estão longe de serem completamente esclarecidos. Os miRNAs são importantes componentes da maquinaria celular e parecem ser ubíquos no controle de processos biológicos. Desvendar novas interações miRNA-mRNAs alvo envolvidas com a metamorfose e a regulação das cascatas de 20E e HJ lançará uma luz sobre esse complexo evento. Em nosso estudo nós investigamos os papéis de miR-34, miR-281, miR-252a e miR-252b, conhecidos como reguladores da metamorfose em insetos, no modelo A. mellifera. Todos estes miRNAs revelaram alto grau de conservação filogenética, bem como responderam ao tratamento com 20E, sofrendo flutuações na abundância de transcritos. Usando as informações disponíveis e nossos bancos de dados, nós identificamos interações envolvendo estes miRNAs e genes participantes nas cascatas de HJ e 20E: ultraspiracle (Usp), fushi tarazu-transcription factor 1 (ftz-f1), ecdysone receptor (EcR), calponin (chd64), insulin receptor 2 (inr2), e Krüppel homolog 1 (Krh1). A predição das interações miRNA-mRNAs alvo revelou que os receptores de ecdisteroides EcR e Usp, bem como o fator de transcrição ftz-f1 são alvos importantes dos miRNAs estudados, apresentando sítios para os quatros miRNAs investigados. Observamos também que os seis genes codificadores de proteína são putativamente alvejados por miR-34. Por meio do ensaio da luciferase, pudemos validar as interações entre miR-34 e os alvos Kr-h1, chd64 e inr2; miR-252a e os alvos ftz-f1 e EcR; miR-252b e os alvos chd64 e ftz-f1; miR-281 e os alvos ftz-f1, EcR e Usp. A investigação dos perfis de expressão dos miRNAs ao longo do desenvolvimento larval (L3-PP3) e pupal (Pw), contrastados com os perfis de seus respectivos alvos, apontou muitos casos de relações positivas miRNA-mRNA. Estes resultados complementaram os resultados de validação, e expuseram a regulação exercida pelo miRNA sobre seus alvos. Juntos, os nossos resultados apontam para novas interações miRNA-mRNAs, envolvidas com a metamorfose em A. mellifera. As regulações por nós propostas e validadas bem como suas caracterizações e relações com os hormônios reguladores da metamorfose, são inéditas e acrescentam muito ao conhecimento sobre a regulação da metamorfose em A. mellifera. Nesse contexto, nossa pesquisa definitivamente contribui para uma melhor compreensão dos eventos moleculares envolvidos com a metamorfose de abelhas. / Insect metamorphosis is one of the most complex and beautiful of known biological events; it consists of successive morphological and physiological alterations. This intricate process is coordinated by various molecular components, including ecdysteroids (20E), juvenile hormone (JH), transcription factors and microRNAs (miRNAs). The miRNAs regulate gene expression, which in turn orchestrates physiological and anatomical changes necessary for successful insect ontogeny. Despite enormous efforts, the endocrine and genetic circuits that regulate metamorphosis in social insects, such as honey bees (Apis mellifera), are far from being completely elucidated. The miRNAs are a substantial component of this molecular machinery and seem to be ubiquitously involved in the control of biological processes. Disclosing new miRNA-target interactions involved in metamorphosis and in the regulation of 20E and JH cascades can shed light on these poorly understood events. In this study, we provide new pieces to this puzzle. We investigated the roles of miR-34, miR-281, miR-252a and miR-252b, known to be important regulators of insect metamorphosis, in the A. mellifera model. All of these miRNAs revealed a high degree of phylogenetic conservation and responded to treatment with 20E, which altered transcript abundance. Using available information and our databases, we identified interactions involving these miRNAs and the component genes of JH and 20E pathways: ultraspiracle (Usp), fushi tarazu-transcription factor 1 (ftz-f1), ecdysone receptor (EcR), calponin (chd64), insulin receptor 2 (inr2), and Krüppel homolog 1 (Kr-h1). Prediction of miRNA-target interactions revealed that the ecdysteroid receptors EcR and Usp and the transcription factor ftz-f1 are highly targeted by miRNAs involved in metamorphosis; they presented binding sites for all four miRNAs. We also observed that all six-protein coding genes are putatively targeted by miR-34. Using the luciferase assay, we were able to validate the interactions of miR-34 with the targets Krh1, chd64 and inr2; miR-252a with the targets ftz-f1 and EcR; miR-252b with the targets chd64 and ftz-f1; and miR-281 with the targets ftz-f1, EcR and Usp. Investigation of miRNA expression profiles during larval (L3-PP3) and pupal (Pw) development, as a function of the profiles of their respective targets, demonstrated many cases of positive miRNA-mRNA relationships. These results complemented the validation results, showing how the miRNAs regulate their targets. In conclusion, we identified various previously unknown miRNA-mRNA interactions involved in the metamorphosis of A. mellifera. The regulatory pathways proposed and validated by us, as well as their characterizations and relationships with metamorphosis regulator hormones, are unique and add to the understanding of the regulation of metamorphosis in A. mellifera. In this context, our research contributes to a better understanding of the molecular events involved in honey bee metamorphosis. Apis mellifera Ensaio da luciferase Interação miRNA-mRNAs Metamorfose Redes de interação gênica Apis mellifera Gene interaction network Luciferase assay Metamorphosis miRNA-mRNAs interactions
12	La régulation transcriptionnelle de Neuroligine-1 par les facteurs de transcription de l’horloge Hannou, Lydia 12 1900 (has links) No description available. Neuroligine-1 Transcription Protéines de l’horloge Essai luciférase Expression génique Souris Neuroligin-1 Transcription Clock proteins Luciferase assay Gene expression Mice
13	Characterization of a novel regulator of the unfolded protein response in Ustilago maydis and mammals Martorana, Domenica 05 June 2019 (has links) No description available. 570 UPR IRE1a XBP1s XBP1u Ustilago maydis cell culture clonogenic survival transcriptional activity luciferase assay Cib1u unfolded protein response Cib1s bZIP transcription factor Ustilago maydis Biologie (PPN619462639)
14	Study of Cancer Related Proteins: LRG-1 and PD-L1 Zheng, Qiaoyun 26 May 2017 (has links) No description available. Biomedical Research Health Sciences Pharmacy Sciences Molecular Biology
15	Molecular pathological investigation of the pathophysiology of fatal malaria Prapansilp, Panote January 2012 (has links) Malaria remains one of the world's major health problems, especially in developing countries. A better understanding of the pathology and pathophysiology of severe malaria is key to develop new treatments. Different approaches have been used in malaria research including the in vitro co-culture models with endothelial cells and both murine and simian animal models. However these are open to controversy due to disagreement on their representativeness of human disease. Using human post-mortem tissue in malaria research is another important approach but is practically challenging, limiting the availability of post mortem samples from malaria patients. The work in this thesis had two main themes. First I examined the role of the endothelial signalling Angiopoetin-Tie-2 receptor pathway in malaria. Ang-2 has been shown to be a significant biomarker of severe and fatal malaria. I examined the tissue specific expression of proteins from this pathway in post-mortem brain tissues from fatal malaria cases, but found no difference between cerebral malaria and non-cerebral malaria cases. Ang-2 correlated with the severity of malaria in these patients. An attempt to examine the interaction of hypoxia and the Ang-Tie-2 pathway in vitro using a co-culture model of human brain endothelial cells was unsuccessful due to contamination of the cell line. The second part of the thesis aimed to utilise molecular pathology techniques including miRNA and whole-genome microarrays. I have shown for the first time that these can be successfully applied to human post-mortem tissue in malaria. First I used archival tissues to examine the microRNA signature in the kidney of patients with malaria associated renal failure. Second I optimised a protocol to preserve post mortem tissue for molecular pathology, from an autopsy study in Mozambique. Using the subsequent total mRNA transcriptomic data and bioinformatics analysis this work has expanded our knowledge of differential gene expression and the families of genes which are dysregulated in the brain in response to malaria infection. 616.9
16	La voie de régulation de la traduction de l’ARNm ASH1 : une concertation entre Khd1, Puf6 et Loc1 Forget, Amélie 05 1900 (has links) La localisation des ARNm par transport dirigé joue un rôle dans le développement, la motilité cellulaire, la plasticité synaptique et la division cellulaire asymétrique. Chez la levure Saccharomyces cerevisiæ, la localisation d’ARNm est un phénomène dont les mécanismes de régulation sont conservés auprès de nombreux autres organismes. Lors de la division de la levure, plus d’une trentaine de transcrits sont localisés par transport actif à l’extrémité du bourgeon de la cellule-fille. Parmi ceux-ci, l’ARNm ASH1 est le mieux caractérisé et constitue le modèle utilisé dans cette étude. Pour exercer sa fonction, la protéine Ash1 doit être produite uniquement après la localisation de l’ARNm ASH1. Pour ce faire, les mécanismes de régulation de la traduction de l’ARNm ASH1 empêchent son expression durant le transport. Ce projet de recherche vise à étudier les mécanismes de régulation de la traduction de l’ARNm ASH1 par les répresseurs traductionnels connus, soit Khd1, Puf6 et Loc1. Les études antérieures se sont penchées sur ces facteurs de manière individuelle. Cependant, dans cette étude, nous avons exploré la présence d’une collaboration entre ceux-ci. Ainsi, nous avons voulu déterminer si les répresseurs traductionnels peuvent être intégrés en une seule voie de régulation de la traduction de l’ARNm ASH1. De plus, nous avons cherché à identifier le mécanisme de recrutement des répresseurs traductionnels sur l’ARNm ASH1, qui correspond au point initial des voies de régulations de l’ARNm ASH1. Nos résultats montrent que les répresseurs traductionnels de l’ARNm ASH1, soit Khd1 et Puf6, font partie d’une même voie de régulation de la traduction. Le rôle du facteur nucléaire Loc1 dans la voie de régulation de la traduction, quant à elle, a été examinée à partir d’expériences permettant l’étude du mécanisme de recrutement des répresseurs traductionnels dans le noyau. Ainsi, nos travaux montrent que Puf6 et Loc1 sont associés de manière ARN-dépendant avec la machinerie de transcription, notamment au facteur d’élongation de la transcription Spt4-Spt5/DSIF. Par ailleurs, notre laboratoire a précédemment montré que la localisation nucléaire de la protéine de liaison à l’ARN She2 est essentielle au recrutement des facteurs Loc1 et Puf6 sur l’ARNm ASH1. Des expériences d’immunoprécipitation de la chromatine (ChIP) supportent l’hypothèse que le recrutement de Loc1 est essentiel à celui de Puf6, qui s’effectue ultérieurement. Ainsi, à partir des résultats de cette étude et des résultats publiés précédemment dans notre laboratoire, nous avons élaboré un modèle de recrutement coordonné des facteurs She2, Loc1 et Puf6 sur l’ARNm ASH1 naissant. De manière générale, cette étude a permis d’établir la présence d’une seule voie de régulation de la traduction de l’ARNm ASH1 et une meilleure connaissance du recrutement des facteurs de répression traductionnelle sur celui-ci. / Directed transport mRNA localization play a role in the development, the cell motility, the synaptic plasticity and asymmetric cellular division. In the yeast Saccharomyces cerevisiæ, this regulation mechanism is conserved among many other species. During yeast cell division, around thirty mRNA are actively localized at the bud tip in the daughter cell. ASH1 mRNA is the best known among them and constitutes the model used in this study. In this model, Ash1 expression is possible only after proper localization of its mRNA. In order to do so, ASH1 mRNA translation is repressed by translational repressors during its active transport. This project investigates the mechanism of ASH1 mRNA translational regulation that is carried out by the translational repressors Khd1, Puf6 and Loc1. Previous studies characterized the action of these factors individually. However, in this study, we now explored the possibility of a collaboration between them. Thus, we sought to determine if these translational repressors are part of the same ASH1 mRNA translational regulation pathway. In addition, we tried to identify the mechanisms of recruitment of these translational repressors on ASH1 mRNA, the molecular mechanisms that initiates this process. In this work, we show that the cytoplasmic translational repressors Khd1 and Puf6 are part of the same ASH1 mRNA translational regulation pathway. In this pathway, the role of the nuclear translational factor Loc1 was determined by the analysis of translational factors recruitment on ASH1 in the nucleus. We demonstrate that Puf6 and Loc1 interact in an RNA-dependent manner with the transcription machinery, via the transcription elongation factor Spt4-Spt5/DSIF. Finally, chromatin immunoprecipitation (ChIP) assays support the model that Loc1 recruitment to nascent ASH1 mRNA is essential for the subsequent recruitment of Puf6 to this transcript. With the results of this study and others previously done in the lab, we elaborated a recruitment model for the She2, Loc1 and Puf6 proteins on the nascent ASH1 mRNA. In conclusion, this study has established that the translational repressors Khd1, Puf6 and Loc1 are part of the same ASH1 mRNA translational regulation pathway and allowed a better understanding of the mechanism of recruitment of translational repressors on their target mRNA. localisation d’ARNm dirigé ARNm ASH1 Saccharomyces cerevisiæ division cellulaire asymétrique répresseurs traductionnels Khd1 Puf6 Loc1 She2 Spt4-Spt5/DSIF co-IP ChIP luciferase assay mRNA localization ASH1 mRNA yeast asymmetric cellular division translation regulation pathway
17	Analysis of genetic variation in microrna-mediated regulation and the susceptibility to anxiety disorders Muiños Gimeno, Margarita 18 December 2009 (has links) We have investigated genetic variation in microRNA-mediated regulation as a susceptibility factor for anxiety disorders following two different approaches. We first studied two isoforms of the candidate gene NTRK3 by re-sequencing its different 3'UTRs in patients with Panic (PD) and Obsessive Compulsive disorders (OCD) as well as controls. Two rare variants that altered microRNA-mediated regulation were identified in PD. Conversely, association of a common SNP with OCD hoarding subtype was found. Moreover, we have also studied a possible involvement of microRNAs in anxiety disorders. Consequently, we have analysed the genomic organisation and genetic variation of miRNA-containing regions to construct a panel of SNPs for association analysis. Case-control studies revealed several associations. However, it is worth remarking the associations of miR-22 and miR-488 with PD; two microRNAs for which functional assays and transcriptome analysis after microRNA overexpression showed significant repression of a subset of genes involved in physiological pathways linked to PD development. / Hem investigat la variació genètica a la regulació mediada per microRNAs com a factors de susceptibilitat pels trastorns d'ansietat seguint dues aproximacions diferents. Primer vam estudiar dues isoformes del gen candidat NTRK3 mitjançant la reseqüenciació dels seus diferents 3'UTRs a pacients de pànic (TP), a pacients amb trastorn obsessiu compulsiu (TOC) i a controls. Dues variants rares que alteren la regulació mediada per microRNAs foren identificades per TP. D'altra banda, es trobà associació d'un SNP comú amb el subtipus acumulador de TOC. A més, també hem estudiat la possible implicació dels microRNAs als trastorns d'ansietat. Conseqüentment, hem analitzat l'organització genòmica i la variació genètica a regions que contenen microRNAs per construir un panell d'SNPs per fer anàlisis d'associació. Els estudis cas-control van revelar algunes associacions. Tanmateix, val la pena destacar les associacions del miR-22 i el miR-488 amb TP; dos microRNAs pels quals assajos funcionals i anàlisis de transcriptoma després de la seva sobreexpressió han mostrat una repressió significativa d'un grup de gens implicats en vies fisiològiques lligades al desenvolupament del TP. isoforma anàlisi de transcriptoma PCR assaig de luciferasa variant comuna variant rara reseqüenciar estudis d'associació poly-miRTS trastorn obsessiu-compulsiu trastorn de pànic trastorn d'ansietat variació genètica intraespecífica SNP NTRK3 gen candidat element regulador microRNA variació genòmica desordres poligènics trets complexes isoform transcriptome analysis PCR luciferase assay common variant rare variant re-sequencing association studies poly-miRTS obsessive-compulsive disorder panic disorder anxiety disorder genetic variation within species SNP NTRK3 candidate gene regulatory element microRNA genome variation polygenic disorders complex traits 57
18	Micro RNA-Mediated regulation of the full-length and truncated isoforms of human neurotrophic tyrosine kinase receptor type 3 (NTRK 3) Guidi, Mònica 13 January 2009 (has links) Neurotrophins and their receptors are key molecules in the development of thenervous system. Neurotrophin-3 binds preferentially to its high-affinity receptorNTRK3, which exists in two major isoforms in humans, the full-length kinaseactiveform (150 kDa) and a truncated non-catalytic form (50 kDa). The twovariants show different 3'UTR regions, indicating that they might be differentiallyregulated at the post-transcriptional level. In this work we explore howmicroRNAs take part in the regulation of full-length and truncated NTRK3,demonstrating that the two isoforms are targeted by different sets of microRNAs.We analyze the physiological consequences of the overexpression of some of theregulating microRNAs in human neuroblastoma cells. Finally, we providepreliminary evidence for a possible involvement of miR-124 - a microRNA with noputative target site in either NTRK3 isoform - in the control of the alternativespicing of NTRK3 through the downregulation of the splicing repressor PTBP1. / Las neurotrofinas y sus receptores constituyen una familia de factores crucialespara el desarrollo del sistema nervioso. La neurotrofina 3 ejerce su funciónprincipalmente a través de una unión de gran afinidad al receptor NTRK3, del cualse conocen dos isoformas principales, una larga de 150KDa con actividad de tipotirosina kinasa y una truncada de 50KDa sin dicha actividad. Estas dos isoformasno comparten la misma región 3'UTR, lo que sugiere la existencia de unaregulación postranscripcional diferente. En el presente trabajo se ha exploradocomo los microRNAs intervienen en la regulación de NTRK3, demostrando que lasdos isoformas son reguladas por diferentes miRNAs. Se han analizado lasconsecuencias fisiológicas de la sobrexpresión de dichos microRNAs utilizandocélulas de neuroblastoma. Finalmente, se ha estudiado la posible implicación delmicroRNA miR-124 en el control del splicing alternativo de NTRK3 a través de laregulación de represor de splicing PTBP1. RISC complex retinoic acid renilla luciferase real-time quantitative PCR PTBP1 pri-miRNA pre-miRNA post-transcriptional regulation piRNA PicTar pGL4.13 PCR P-body p75NTR overexpression NTRK3 NTRK2 NTRK1 non-coding RNAs NGF neurotrophin neurotrophic signaling neuronal differentiation neurodevelopment neuroblastoma nervous system mRNA miRNA target prediction miRNA profiling miRNA mimic miRNA microarray miRNA inhibitor miRanda microRNA microarray luciferase assay Ingenuity Pathway Analysis (IPA) heLa cells gene silencing gene regulation full-length isoform (FL-NTRK3) firefly luciferase ERK disease dicer cancer development BDNF argonaute alternative splicing 3'UTR RNAhybrid RT-PCR SH-SY5Y cells siRNA standard error synaptic plasticity target validation TargetScan transfection translational repression TrkA TrkB TrkC truncated isoform (TR-NTRK3) tyrosine kinase (TK) western blot 575 61

Search results