Global ETD Search

1	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.
2	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.
3	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.
4	Molecular Mechanism of the Ded1p-eIF4F Complex Gao, Zhaofeng 01 September 2016 (has links) No description available. Biochemistry
5	Caracterização fenotípica de linhagens mutantes das RNA helicases DEAD-box de Caulobacter crescentus em condições de baixa temperatura. / Phenotypic characterization of mutant lines of DEAD-box RNA helicases from Caulobacter crescentus under low temperature conditions. Durán, Angel Alfonso Aguirre 20 July 2017 (has links) As RNA helicases da família DEAD-box são enzimas que alteram as estruturas secundárias do RNA e auxiliam a formação de complexos ribonucleoproteicos, e são muito importantes em processos basais como a degradação dos RNAs e a biogênese dos ribossomos. A α-proteobactéria criotolerante Caulobacter crescentus é um modelo experimental interessante para compreender o papel destas enzimas em baixa temperatura. A caracterização fenotípica de linhagens mutantes simples de quatro RNA helicases DEAD-box permitiu demonstrar que a RNA helicase RhlE é necessária para o crescimento em baixa temperatura. Os mutantes duplos mostraram redução do crescimento à temperatura normal e em baixa temperatura, com perda de viabilidade e alterações morfológicas. Através de ensaios de complementação cruzada mostrou-se que seus papéis fisiológicos são até certo ponto redundantes. O mutante rhlE também apresentou redução na formação de biofilme. A medida da expressão relativa dos genes que codificam as RNA helicases mostrou um aumento na expressão de três destes genes em estresse frio, e a análise dos perfis ribossomais mostrou a possível participação destas três RNA helicases na biogênese do ribossomo. / The RNA helicases of the DEAD-box family are enzymes that modify RNA secondary structures and help the formation of ribonucleoprotein complexes, and are very important in basal processes such as RNA degradation and ribosome biogenesis. The cryotolerant α-proteobacterium Caulobacter crescentus is an interesting experimental model to understand the role of these enzymes at low temperature. The phenotypic characterization of strains with single mutations of four DEAD-box RNA helicases showed that RNA helicase RhlE is required for growth at low temperature. The double mutants showed reduction in growth at both normal and low temperatures, with loss of viability and morphological changes. Through cross-complementation assays it has been shown that their physiological roles are to some extent redundant. The rhlE mutant also showed reduction in biofilm formation. The relative expression of the genes encoding the RNA helicases showed an increase in the expression of three of these genes under cold stress, and the analysis of the ribosomal profiles showed the possible participation of these three RNA helicases in ribosome biogenesis. Caulobacter crescentus Caulobacter crescentus Cold stress DEAD-box RNA helicases Estresse frio Ribosomes Ribossomos RNA helicases DEAD-box
6	Single Molecule Visualization of the DEAH-Box ARPase Prp22 Interacting with the Spliceosome: A Dissertation Anderson, Eric G. 05 January 2016 (has links) In eukaryotes, the spliceosome is a macromolecular ribonucleoprotein machine that excises introns from pre-mRNAs through two sequential transesterification reactions. The chemistry and fidelity of pre-mRNA splicing are dependent upon a series of spliceosomal rearrangements, which are mediated by trans-acting splicing factors. One key class of these factors is the DEAH-box ATPase subfamily of proteins, whose members couple ATP hydrolysis to promote RNP structural rearrangements within the spliceosome. This is typified by Prp22, which promotes release of the spliced mRNA from the spliceosome and ensures fidelity of the second step of splicing. This role is well documented through classical biochemical and yeast genetics methods. Yet very little is known regarding the comings and goings of Prp22 relative to the spliceosome. My thesis research investigated the dynamics of Prp22 during splicing by using single-molecule fluorescence methods that allowed direct observation of these events. To do this, I helped construct a toolkit that combined yeast genetics, chemical biology and Colocalization Single Molecule Spectroscopy (CoSMoS) with in vitro splicing assays. Specifically, my thesis research consisted of CoSMoS splicing experiments in which fluorescently labeled pre-mRNA, spliceosome components and Prp22 were directly visualized and analyzed. Using these methods, I found that Prp22’s interactions with the spliceosome are highly dynamic and reversible. By simultaneously monitoring Prp22 and individual spliceosome subcomplexes, I was able to frame these Prp22 binding events in context relative to specific steps in spliceosome assembly and splicing. These experiments provide insight into how Prp22 promotes mRNA release from the spliceosome and maintains splicing fidelity. Spliceosomes DEAH-Box ARPase Prp22 Dissertations, UMMS DEAD-box RNA Helicases Structural Biology
7	Small RNA Regulation of the Innate Immune Response: A Role for Dicer in the Control of Viral Production and Sensing of Nucleic Acids: A Dissertation Nistler, Ryan J. 09 December 2015 (has links) All organisms exist in some sort of symbiosis with their environment. The food we eat, air we breathe, and things we touch all have their own microbiota and we interact with these microbiota on a daily basis. As such, we employ a method of compartmentalization in order to keep foreign entities outside of the protected internal environments of the body. However, as other organisms seek to replicate themselves, they may invade our sterile compartments in order to do so. To protect ourselves from unfettered replication of pathogens or from cellular damage, we have developed a series of receptors and signaling pathways that detect foreign bodies as well as abnormal signals from our own perturbed cells. The downstream effector molecules that these signaling pathways initiate can be toxic and damaging to both pathogen and host, so special care is given to the regulation of these systems. One method of regulation is the production of endogenous small ribonucleic acids that can regulate the expression of various receptors and adaptors in the immune signaling pathways. In this dissertation, I present work that establishes an important protein in small ribonucleic acid regulation, Dicer, as an essential protein for regulating the innate immune response to immuno-stimulatory nucleic acids as well as regulating the productive infection of encephalomyocarditis virus. Depleting Dicer from murine embryonic fibroblasts renders a disparate type I interferon response where nucleic acid stimulation in the Dicer null cells fails to produce an appreciable interferon response while infection with the paramyxovirus, Sendai, induces a more robust interferon response than the wild-type control. Additionally, I show that Dicer plays a vital role in controlling infection by the picornavirus, encephalomyocarditis virus. Encephalomyocarditis virus fails to grow efficiently in Dicer null cells due to the inability for the virus to bind to the outside of the cell, suggesting that Dicer has a role in modulating viral infection by affecting host cellular protein levels. Together, this work identifies Dicer as a key protein in viral innate immunology by regulating both the growth of virus and also the immune response generated by exposure to pathogen associated molecular patterns. Understanding this regulation will be vital for future development of small molecule therapeutics that can either modulate the innate immune response or directly affect viral growth. innate immunity Dicer small nuclear RNA viruses Dissertations, UMMS Immunity, Innate Ribonuclease III DEAD-box RNA Helicases Encephalomyocarditis virus Immunity Immunology of Infectious Disease Virology
8	Estudo da RNA helicase DEAD-box codificada pelo gene CC0835 em Caulobacter crescentus. / Study of the DEAD-box RNA helicase encoded by the gene CC0835 in Caulobacter crescentus. Vicente, Alexandre Magno 17 February 2017 (has links) Com a construção da linhagem RlhE fusionada a um epitopo, fomos capazes de investigar o acúmulo da proteína após choque frio, em fase estacionária, durante o ciclo celular de Caulobacter crescentus, sob diferentes condições de estresses e, finalmente, após a adição de cloranfenicol, para o estudo a estabilidade protéica. Foi observado um aumento no acúmulo da proteína após choque frio. Além disso, quando em diferentes condições de estresses, RlhE obteve uma leve indução na presença de NaCl e Sacarose; mas permanaceu constante em fase estacionária e durante o ciclo celular. Finalmente, vimos que a estabilidade de RlhE varia de acordo com a temperatura, tendo um aumento da estabilidade a 10°C. As análises de expressão do gene rhlE foram realizadas por ensaios de atividade de betagalactosidase. Demonstramos que a presença da região 5UTR é importante para a indução, e que rlhE possui, pelo menos em parte, uma regulação pós-transcricional. Uma análise transcriptômica global da linhagem selvagem e mutante para rhlE, após o choque frio, foi realizada por RNAseq, o qual nos auxiliou na identificação de genes envolvidos em diversos processos biológicos. Finalmente, a co-imunoprecipitação e identificação dos RNAs por sequenciamento em larga escala revelou que RlhE interage com 51 mRNAs. / Here, we constructed a strain in which the RhIE protein was fusioned to an epitope that allowed the investigation of the protein profile after cold-shock, at stationary phase, during cell cycle of Caulobacter crescentus, under different environmental stresses, and, finally, after chloramphenicol addition to study protein stability. The results showed an increase in protein concentration after cold shock stress. When exposed to different stresses RhlE was slightly induced in the presence of NaCl and Sucrose; but its abundance remained constant at stationary phase and during C. crescentus cell cycle. Lastly, the protein stability varies depending on temperature - increasing at low temperature. Gene expression analysis was performed using beta-galactosidase assays. We showed that the presence of the 5UTR is important for the induction of rhlE, and that RhlE is posttranscriptionally regulated. A global transcriptome analysis was performed using RNAseq after cold shock stress of the wild type strain and null mutant for rhlE, and several genes involved in a wide range of biological process were identified. Finally, High-throughput sequencing of RNA isolated by crosslinking immunoprecipitation revealed interactions of RhlE with 51 mRNAs. Caulobacter crescentus Caulobacter crescentus Bacterial stress response Biologia molecular DEAD-box RNA helicases Gene regulation Microbiologia Microbiology Molecular biology Regulação gênica Resposta bacteriana a estresses RNA helicases da família DEAD-box
9	A Novel Role of UAP56 in piRNA Mediated Transposon Silencing: A Dissertation Zhang, Fan 02 August 2013 (has links) Transposon silencing is required to maintain genome stability. The non-coding piRNAs effectively suppress of transposon activity during germline development. In the Drosophila female germline, long precursors of piRNAs are transcribed from discrete heterochromatic clusters and then processed into primary piRNAs in the perinuclear nuage. However, the detailed mechanism of piRNA biogenesis, specifically how the nuclear and cytoplasmic processes are connected, is not well understood. The nuclear DEAD box protein UAP56 has been previously implicated in protein-coding gene transcript splicing and export. I have identified a novel function of UAP56 in piRNA biogenesis. In Drosophila egg chambers, UAP56 co-localizes with the cluster-associated HP1 variant Rhino. Nuage is a germline-specific perinuclear structure rich in piRNA biogenesis proteins, including Vasa, a DEAD box with an established role in piRNA production. Vasa-containing nuage granules localize directly across the nuclear envelope from cluster foci containing UAP56 and Rhino, and cluster transcripts immunoprecipitate with both Vasa and UAP56. Significantly, a charge-substitution mutation that alters a conserved surface residue in UAP56 disrupts co-localization with Rhino, germline piRNA production, transposon silencing, and perinuclear localization of Vasa. I therefore propose that UAP56 and Vasa function in a piRNA-processing compartment that spans the nuclear envelope. DEAD-box RNA Helicases DNA Transposable Elements Drosophila Proteins Drosophila melanogaster Germ Cells Nuclear Envelope Small Interfering RNA Dissertations, UMMS RNA, Small Interfering Biochemistry Genetics Genomics Molecular Biology Molecular Genetics
10	Recruitment of the complete hTREX complex is required for Kaposi's sarcoma-associated herpesvirus intronless mRNA nuclear export and virus replication Boyne, J. R., Colgan, K. J., Whitehouse, A. January 2008 (has links) A cellular pre-mRNA undergoes various post-transcriptional processing events, including capping, splicing and polyadenylation prior to nuclear export. Splicing is particularly important for mRNA nuclear export as two distinct multi-protein complexes, known as human TREX (hTREX) and the exon-junction complex (EJC), are recruited to the mRNA in a splicing-dependent manner. In contrast, a number of Kaposi's sarcoma-associated herpesvirus (KSHV) lytic mRNAs lack introns and are exported by the virus-encoded ORF57 protein. Herein we show that ORF57 binds to intronless viral mRNAs and functions to recruit the complete hTREX complex, but not the EJC, in order assemble an export component viral ribonucleoprotein particle (vRNP). The formation of this vRNP is mediated by a direct interaction between ORF57 and the hTREX export adapter protein, Aly. Aly in turn interacts directly with the DEAD-box protein UAP56, which functions as a bridge to recruit the remaining hTREX proteins to the complex. Moreover, we show that a point mutation in ORF57 which disrupts the ORF57-Aly interaction leads to a failure in the ORF57-mediated recruitment of the entire hTREX complex to the intronless viral mRNA and inhibits the mRNAs subsequent nuclear export and virus replication. Furthermore, we have utilised a trans-dominant Aly mutant to prevent the assembly of the complete ORF57-hTREX complex; this results in a vRNP consisting of viral mRNA bound to ORF57, Aly and the nuclear export factor, TAP. Strikingly, although both the export adapter Aly and the export factor TAP were present on the viral mRNP, a dramatic decrease in intronless viral mRNA export and virus replication was observed in the absence of the remaining hTREX components (UAP56 and hTHO-complex). Together, these data provide the first direct evidence that the complete hTREX complex is essential for the export of KSHV intronless mRNAs and infectious virus production. Active transport; Cell nucleus Metabolism DEAD-box RNA Helicases Exodeoxyribonucleases Herpesvirus 8; Human; Physiology Humans Multiprotein complexes Nuclear cap-binding protein complex Nuclear export signals Nuclear proteins Phosphoproteins RNA Processing; Post-transcriptional RNA Transport Messenger Viral RNA-binding proteins Transcription factors Viral proteins Virus replication REF 2014

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