Global ETD Search

11	The DEAD-Box Helicase Family Member Ded1 Plays a Role in the Cellular Stress Response Rodela, Emily Cristina, Rodela, Emily Cristina January 2016 (has links) The DEAD-Box RNA helicase family is a conserved group of enzymes that function in gene expression through ATP-dependent RNA unwinding and ribonucleoprotein (RNP) remodeling. DEAD-Box helicases function in multiple cellular processes, including pre-mRNA processing, translation, mRNA export, and mRNA decay. Although DEAD-Box proteins are critical for gene expression, much of their mechanistic activities are poorly understood. DEAD-Box proteins have increasingly been linked to tumorigenesis in humans, and better defining their activity at the mechanistic level will aid in understanding the underlying disease pathology. In this study, we used the model organism Saccharomyces cerevisiae to study the human DEAD-Box protein DDX3 orthologue, Ded1, and its role in translation initiation during cellular stress. Recently, we have found that Ded1 is an important mediator of the cellular stress response in a TOR-dependent manner. TOR regulates protein synthesis dependent on energy availability in the cell by regulating the assembly of the eukaryotic translation initiation complex. Human DDX3 has been found to interact with translation initiation complex subunit eIF4E and Ded1 has been found to interact with the translation initiation complex subunit eIF4G. In this study, we examined the purported interaction region between Ded1 and eIF4G on the C-terminus of Ded1 and found that ded1 Δ591-604 prevents eIF4G degradation under rapamycin treatment and confers resistance to rapamycin-induced growth inhibition. We also examined putative regulatory phosphorylation sites in the purported Ded1 eIF4G binding region. We propose that the Ded1/eIF4G interaction is critical for the repression of translation by Ded1 and that eIF4G degradation may be regulated by Ded1 under stress conditions. Ded1 eIF4G RNA helicase Translation Initiation Cellular and Molecular Medicine DEAD-Box proteins
12	Characterizing the Role of the DEAD-box Protein Dbp2 in RNA Structure Remodeling and Pre-mRNA Processing Yu-Hsuan Lai (5929919) 10 June 2019 (has links) RNA helicases are found in all kingdoms of life, functioning in all aspects of RNA biology mainly through modulating structures of RNA and ribonucleoprotein (RNP) complex. RNA structures have fundamental impacts on steps in gene expression, including transcription, pre-mRNA processing, and translation. However, the precise roles and regulatory mechanisms of RNA structures in co- and post-transcriptional processes remain elusive. By probing genome-wide RNA structures in vivo, a recent study suggested that ATP-dependent factors, such as RNA helicases, maintain the actively unfolded state of RNAs. Among all RNA helicases, DEAD-box proteins form the largest family in eukaryotes, and have been shown to remodel RNA/RNP structures both in vitro and in vivo. Nevertheless, for the majority of these enzymes, it is largely unclear what RNAs are targeted and where they modulate RNA/RNP structures to regulate co-transcriptional processes. To fill the gap, my research focused on identification of the RNAs and structures targeted by the DEAD-box protein Dbp2 in S. cerevisiae to uncover the cellular processes that Dbp2 is involved in.<br><div><div>My studies revealed a role of Dbp2 in transcriptional termination. Dbp2 binds to ~34% of yeast mRNAs and all snoRNAs, and loss of DBP2 leads to a termination defect as evidenced by RNA polymerase II (RNAPII) accumulation at 3’ ends of these genes. In addition, the binding pattern of Dbp2 in mRNAs is highly similar to Nrd1 and Nab3 in the Nrd1-Nab3-Sen1 (NNS) termination complex, and deletion of DBP2 leads to reduced recruitment of Nrd1 to its target genomic loci. In Dbp2 and NNS targeted 3’ UTRs, RNA structural changes resulted from DBP2 deletion also overlap polyadenylation elements and correlate with inefficient termination, and loss of stable structure in the 3’ UTR bypasses the requirement for Dbp2. These findings lead to a model that Dbp2 promotes efficient termination of transcription through RNA structure remodeling.</div><div>Interestingly, my research also revealed the requirement of DBP2 for efficient splicing, as loss of DBP2 leads to accumulation of unspliced pre-mRNAs. Moreover, this function is dependent on the helicase activity of Dbp2. Further studies are needed to characterize the molecular mechanism of how Dbp2 facilitates splicing in cells. Overall, my research demonstrated that DEAD-box RNA helicases remodel mRNA structure in vivo and that structural alteration can be essential for proper gene expression.</div></div> Molecular Biology Bioinformatics Genomics RNA helicases DEAD-box proteins RNA structure CLIP-seq ChIP-seq
13	Une nouvelle fonction pour la DEAD-box ARN hélicase p68/DDX5 dans la Dystrophie Myotonique de type 1 Laurent, François-Xavier 30 September 2011 (has links) (PDF) La Dystrophie Myotonique de type 1 (DM1) est cause par l'expansion anormale d'un triplet CTG dans la partie 3'UTR du gène DMPK, entrainant l'agrégation du transcrit mutant dans des inclusions ribonucléoprotéiques appelées foci. D'après plusieurs études structurales sur des courtes répétitions CUG, il a été proposé que les expansions CUG se replient en une structure en tige-boucle qui interfère avec l'activité de plusieurs facteurs lié au métabolisme de l'ARN et altère leur fonction cellulaire. Le facteur d'épissage muscleblind-like 1 (MBNL1) a été identifié par sa capacité à interagir avec les répétitions CUG. In vivo, ces répétitions entrainent la séquestration de cette protéine aboutissant en une déplétion nucléaire. Un autre facteur d'épissage, la CUG Binding protein (CUGBP1), est également impliqué dans la pathologie. Au lieu d'être séquestré par les répétitions, la stabilité protéique de CUGBP1 est augmentée dans les tissus DM1 entrainant un gain d'activité pour ce facteur. La séquestration de MBNL1 et la stabilisation de CUGBP1 résultent en la dérégulation de l'épissage alternatif de plusieurs transcrits musculaires et du cerveau et la réexpression d'isoformes protéiques fœtales dans les tissus adultes. Cependant, de récentes études suggèrent que d'autres facteurs ou voies de signalisation que celles faisant intervenir MBNL1 et CUGBP1 pourraient être impliquées dans la pathologie DM1.Le but de mon travail de thèse a été d'identifier de nouveaux facteurs ayant la capacité d'interagir avec les répétitions CUG. A l'aide d'une purification sur chromatographie d'affinité utilisant un ARN contenant 95 répétitions CUG comme appât, nous avons identifié l'ARN hélicase p68/DDX5. p68 fait partie de la famille des protéines DEAD-box, caractérisée par un core protéique conservé constitué de neufs domaines hautement conservés, dont le motif DEAD, à l'origine du nom de ces protéines. p68 est impliquée dans de nombreux aspects du métabolisme de l'ARN, dont la transcription, l'épissage, l'export, la traduction et la dégradation des ARN. Nous avons montré, que p68 colocalise avec les foci CUG dans un modèle cellulaire exprimant la partie 3'UTR du gène DMPK contenant de longues répétitions CTG. Nous avons identifié que p68 augmente l'interaction de MBNL1 sur les répétitions CUG et une structure secondaire particulière d'un élément régulateur de l'ARN pré-messager cardiac Troponin T (TNNT2), dont l'épissage est dérégulé dans la pathologie. L'insertion de mutations dans le core de l'hélicase de p68 abolit l'effet de p68 sur la fixation de MBNL1 ainsi que la colocalisation de p68 avec les expansions CUG in vivo, suggérant que le remodelage des structures secondaires ARN de manière ATP-dépendante par p68 facilite l'interaction de MBNL1. Nous trouvons également que la compétence de p68 pour réguler l'inclusion de l'exon alternatif 5 de TNNT2 dépend de l'intégrité des sites de fixation de MBNL1.Nous proposons que p68 agit comme un modificateur de l'activité de MBNL1 sur ces cibles d'épissage ainsi que sur les expansions CUG à l'origine de la pathologie. Epissage alternatif Dystrophie myotonique Dead Box
14	Functional Role of Dead-Box P68 RNA Helicase in Gene Expression Lin, Chunru 31 July 2006 (has links) How tumor cells migrate and metastasize from primary sites requires four major steps: invasion, intravasation, extravasation and proliferation from micrometastases to malignant tumor. The initiation of tumor cell invasion requires Epithelial-Mesenchymal Transition (EMT), by which tumor cells lose cell-cell interactions and gain the ability of migration. The gene expression profile during the EMT process has been extensively investigated to study the initiation of EMT. In our studies, we indicated that tyrosine phosphorylation of human p68 RNA helicase positively associated with the malignant status of tumor tissue or cells. Studying of this relationship revealed that p68 RNA helicase played a critical role in EMT progression by repression of E-cadherin as an epithelial marker and upregulation of Vimentin as a mesenchymal marker. Insight into the mechanism of how p68 RNA helicase represses E-cadherin expression indicated that p68 RNA helicase initiated EMT by transcriptional upregulation of Snail. Human p68 RNA helicase has been documented as an RNA-dependent ATPase. The protein is an essential factor in the pre-mRNA splicing procedure. Some examples show that p68 RNA helicase functions as a transcriptional coactivator in ATPase dependent or independent manner. Here we indicated that p68 RNA helicase unwound protein complexes to modulate protein-protein interactions by using protein-dependent ATPase activity. The phosphorylated p68 RNA helicase displaced HDAC1 from the chromatin remodeling MBD3:Mi2/NuRD complex at the Snail promoter. Thus, our data demonstrated an example of protein-dependent ATPase which modulates protein-protein interactions within the chromatin remodeling machine. p68 phosphorylation EMT Snail HDAC1 NuRD ATPase DEAD-box transcriptional regulation protein-protein interaction Biology, general
15	Studies on the DEAD-box RNA-helicase Dbp5 and the ABC-protein Rli1 in translation termination and identification of a novel function of Dbp5 in ribosomal transport Neumann, Bettina 20 April 2015 (has links) No description available. 570 DEAD-box RNA-helicase Dbp5 Rat8 Gle1 nuclear transport Rli1 translation termination Biologie (PPN619462639)
16	The requirement of the DEAD-box protein DDX24 for the packaging of human immunodeficiency virus type 1 RNA / Ma, Jing, 1978- January 2008 (has links) Human immunodeficiency virus (HIV) is the causing agent of the acquired immune deficiency syndrome (AIDS). Like all retroviruses, HIV carries two copies of viral genomic RNA in each virion. HIV genome encodes three structural genes, including gag, pol and env, as well as two regulatory genes (rev and tat) and four accessory genes (vif, vpr, vpu and nef). It is noted that none of these nine viral proteins bears the helicase activity. Helicases are able to unwind RNA duplex and remodel the structure of RNA-protein (RNP) complexes using energy derived from hydrolysis of nucleotide triphosphates (NTPs). They are involved in every step of cellular RNA metabolisms. It is conceivable that HIV needs to exploit cellular RNA helicases to promote the replication of its RNA at various steps such as transcription, folding and transport. / In this study, we found that a DEAD-box protein named DDX24 associates with HIV-1 Gag in an RNA-dependent manner but is not found within virus particles. Knockdown of DDX24 inhibits the packaging of HIV-1 RNA and thus diminishes viral infectivity. The decreased viral RNA packaging as a result of DDX24-knockdown is observed only in the context of the Rev/RRE (Rev response element)-dependent but not the CTE (constitutive transport element)-mediated nuclear export of viral RNA, which is explained by the specific interaction of DDX24 with the Rev protein. We propose that DDX24 acts at the early phase of HIV-1 RNA metabolism prior to nuclear export and the consequence of this action extends to the viral RNA packaging stage during virus assembly. HIV-1 -- physiology. Virus Assembly -- physiology. RNA, Viral -- metabolism. DEAD-box RNA Helicases -- metabolism.
17	Post-transcriptional gene regulation in Drosophila an investigation into the roles of RNA silencing and the DEAD-box helicase Belle / Natalin, Pavel. January 2009 (has links) Heidelberg, Univ., Diss., 2008.
18	Analysis of interactions between the germline RNA helicases (GLHs) and their regulators KGB-1 and CSN-5 in Caenorhabditis elegans Orsborn, April Marie, January 2006 (has links) Thesis (Ph. D.)--University of Missouri-Columbia, 2006. / The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Vita. Includes bibliographical references.
19	Identification et caractérisation d'ARN régulateurs impliqués dans la réponse au stress et la virulence chez Enterococcus faecalis / Identification and characterization of regulatory RNA involved in stress response and virulence in Enterococcus faecalis Salze, Marine 09 May 2019 (has links) E. faecalis est une bactérie à gram positif, responsable d’infections nosocomiales. Dans cette étude, nous avons identifié par RNA-seq 65 ARN régulateurs potentiels induits en conditions de stress et/ou d’infection chez ce pathogène opportuniste. Parmi ceux-ci, trois ARN surexprimés in vivo, en présence de sels biliaires et à pH acide ont fait l’objet d’une étude approfondie.Le premier, SRC65, s’est avéré être un petit ARN (sARN) agissant probablement en trans. Il présenterait des fonctions redondantes avec son homologue SRC90. Différentes cibles potentielles ont été identifiées et des expériences de physiologie ont révélé un rôle de SRC65 dans le déclenchement de la phase exponentielle de croissance.Le 2ème ARN étudié est une région 5’ régulatrice non traduite (5’UTR), appelée 5’1515. Elle formerait un atténuateur et agirait de manière répressive sur le gène ef1515. EF1515 est un antiterminateur de la famille BglG/SacY capable de se fixer sur 5’1515 pour réguler son expression et celle du gène ef1516 localisé en aval et codant un système de transport des sucres de type PTS. L’antiterminateur EF1515 contrôle aussi l’expression du gène ef3023 codant une protéine impliquée dans la virulence d’E. faecalis.Le dernier ARN régulateur étudié est également une 5’UTR. Celle-ci participerait à la régulation d’une hélicase à motif DEAD (CshA) codée en aval de la 5’UTR. Sa caractérisation s’inscrit dans une étude plus large concernant les éléments du métabolisme des ARN, impliquant les ribonucléases et les autres hélicases à motif DEAD d’E. faecalis. CshA aurait un rôle prépondérant pour la bactérie, en étant impliquée dans la réponse au stress, le fitness et la virulence. L’identification de l’interactome de CshA a notamment permis d’identifier l’énolase comme partenaire privilégié. / E. faecalis is a gram-positive bacterium responsible for nosocomial infections. Using RNA-seq, we identified 65 putative regulatory RNA induced under stress and/or during infection. Of these, three RNA overexpressed in vivo, in the presence of bile salts and at acidic pH have were more deeply studied.The first, SRC65, was found to be a small RNA (sRNA) probably acting in trans. It would present redundant functions with its homologous sRNA SRC90. Different potential targets were identified and physiology experiments revealed a role for SRC65 in triggering the exponential growth phase.The 2nd studied RNA is a 5’ untranslated region (5'UTR), called 5'1515 which would form an attenuator and act repressively on the ef1515 gene. EF1515 is an antiterminator of the BglG/SacY family capable of binding at 5'1515 to regulate its expression and that of the downstream gene ef1516 encoding a PTS-type sugar transporter. The EF1515 antiterminator also controls the expression of the ef3023 gene encoding a protein involved in E. faecalis virulence.The last regulatory RNA studied is also a 5'UTR. It would participate in the regulation of a DEAD-box helicase (CshA) encoded downstream of the 5'UTR. Its characterization is part of a broader study of the elements of RNA metabolism, involving ribonucleases and other DEAD-box helicases of E. faecalis. CshA would have a prominent role for the bacteria, being involved in stress response, fitness and virulence. The identification of the CshA interactome made it possible to identify enolase as a preferred partner. 5'UTR Hélicase à motif DEAD Antiterminateur DEAD-box helicase Antiterminator
20	The requirement of the DEAD-box protein DDX24 for the packaging of human immunodeficiency virus type 1 RNA / Ma, Jing, 1978- January 2008 (has links) No description available. DEAD-box RNA Helicases -- metabolism. RNA, Viral -- metabolism. HIV-1 -- physiology. Virus Assembly -- physiology.

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