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| Author | : Christopher Bryant Westberg |
| Publisher | : |
| Total Pages | : 194 |
| Release | : 2002 |
| Genre | : |
| ISBN | : |
| Author | : Stacey Lynn Hull |
| Publisher | : |
| Total Pages | : |
| Release | : 2002 |
| Genre | : RNA viruses |
| ISBN | : |
Abstract: The central focus of this dissertation is the identification and characterization of retroviral posttranscriptional control elements that affect protein production from unspliced viral RNA. We identify and characterize a new posttranscriptional control element in the Mason-Pfizer monkey virus 52 long terminal repeat (LTR) that modulates translational efficiency by augmentation of translational initiation. MPMV RU5 is necessary for cytoplasmic expression of HIV-1 gag-pol reporter RNA and also enhances cytoplasmic expression of intronless luc RNA by stimulation of ribosome loading. MPMV RU5 functions independently of any viral proteins and instead directs functional interaction with cellular posttranscriptional modulators to facilitate translational enhancement. This research has illuminated an essential step in viral gene expression and provides a new paradigm for understanding cellular control of the translation process. Secondly, we tested the hypothesis that combination of the MPMV constitutive transport element (CTE) and the MPMV or spleen necrosis virus (SNV) RU5 translational enhancer on a single RNA synergistically augments posttranscriptional gene expression. MPMV CTE functions compatibly with MPMV and SNV RU5 to increase cytoplasmic expression of HIV-1 gag-pol reporter RNA in monkey COS, but not 293 cells. The CTE-interactive cellular proteins, Tap and NXT1, are necessary and sufficient to rescue increased cytoplasmic expression of HIV-1 gag-pol reporter RNA in 293 cells. This work produced the realization that differences in cellular posttranscriptional modulators dramatically affect retroviral protein production. Thirdly, we evaluated the role of SNV RU5 on metabolism of homologous SNV RNA. SNV RU5 increases SNV Gag-GFP fusion protein production from unspliced genomic RNA. The increase in protein is attributable, at least in part, to increased cytoplasmic accumulation of the unspliced SNV transcript. RU5 exerts a distinct effect on the spliced env transcript. Deletion of RU5 has no effect on cytoplasmic accumulation of env RNA, but increases splicing efficiency. Therefore, SNV RU5 modulates metabolism of both unspliced and spliced SNV transcripts and is speculated to contain a RNA splicing suppressor. In summary, this dissertation has identified and characterized a new posttranscriptional control element in MPMV and synergistic interactions among functionally distinct retroviral posttranscriptional control elements and their cellular protein partners. This work also demonstrated an important role for SNV RU5 in SNV genomic RNA.
| Author | : Kathryn Sandberg |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 318 |
| Release | : 2013-03-09 |
| Genre | : Medical |
| ISBN | : 1475764464 |
RNA binding proteins are an exciting area of research in gene regulation. A multitude of RNA-protein interactions are used to regulate gene expression including pre-mRNA splicing, polyadenylation, editing, transport, cytoplasmic targeting, translation and mRNA turnover. In addition to these post-transcriptional processes, RNA-protein interactions play a key role in transcription as illustrated by the life cycle of retroviruses. Unlike DNA, the structure of RNA is highly variable and conformationally flexible, thus creating a number of unique binding sites and the potential for complex regulation by RNA binding proteins. Although there is a wide range of topics included in this volume, general themes have been repeated, highlighting the overall integrative nature of RNA binding proteins. The chapters have been separated into three different sections: Translational Control; mRNA Metabolism; and Hormonal and Homeostatic Regulation. The chapters of this volume were written with the seasoned investigator and student in mind. Summaries of key concepts are reviewed within each chapter as well as guiding questions that can be used to stimulate class discussions. The Editors of this volume hope that this compendium educates, enthralls, and stimulates the readers to look to the future possibilities in this rapidly evolving field.
| Author | : Faye Maryann Lee |
| Publisher | : |
| Total Pages | : 148 |
| Release | : 1999 |
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| Author | : Nicole M. Placek |
| Publisher | : |
| Total Pages | : 156 |
| Release | : 2007 |
| Genre | : Cellular control mechanisms |
| ISBN | : |
Abstract: Both retroviruses and cellular genes rely on post-transcriptional mechanisms to regulate the timing and abundance of their protein product. The post-transcriptional control element (PCE) has been identified in the 5' untranslated regions of mRNAs from selected retroviruses and the cellular gene JunD. PCE containing mRNAs rely on the DExH/D box helicase RNA helicase A (RHA) to specifically facilitate robust synthesis of their protein product. Study of retroviruses has developed approaches to understand both cellular control of gene expression and the dyregulation that contributes to cancer and immunodeficiency. JunD, a member of the activator protein -1 (AP-1) family of transcription factors, is important for transcriptional regulation of growth control genes. Dysregulation of JunD is implicated in cancer and metabolic disease via defects in cell- proliferation and disease-associated apoptosis and can also modulate viral persistence. Studies described here build on the previous characterization of SNV and JunD PCE function in HIV gag-pol reporter plasmids and investigate the parental SNV provirus. The results presented validate the role of PCE in combination with a newly identified a distal element, designated the I,II element, in regulation of balanced expression and translational utilization of SNV mRNA. A key conclusion is that PCE and the distal I,II element comprise a bipartite element that interacts with RNA helicase A to selectively modulate post-transcriptional expression of the unspliced SNV gag mRNA. This thesis also reviews the current and historical literature of JunD gene regulation. Three core areas are described and intriguing essential issues are discussed: i) transcription regulation by AP-1 complexes containing JunD protein, ii) post-translational modification of JunD by Jun-terminal kinase (Jnk) and protein:protein interactions, and iii) regulation of translation intiation by JunD PCE. Lessons learned from the study of retrovirus genes have produced essential knowledge of the JunD transcription factor and contributed to the characterization of a novel axis of transational control of complex RNAs.
| Author | : Zdravko Lorkovic |
| Publisher | : CRC Press |
| Total Pages | : 174 |
| Release | : 2012-08-10 |
| Genre | : Science |
| ISBN | : 149871336X |
Gene expression in eukaryotes is regulated at different levels, which need to be coordinated to implement the information in the genome. Now it is clear that post-transcriptional regulation of gene expression such as pre-mRNA splicing, mRNA transport, editing, turnover and translation are as important as the control of transcription. In all aspects
| Author | : Tiffiney Marie Roberts |
| Publisher | : |
| Total Pages | : |
| Release | : 2003 |
| Genre | : RNA |
| ISBN | : |
Abstract: Retroviruses achieve translation of their unspliced genome-length RNA despite a long and highly structured 52 untranslated region and lack of intron removal. By contrast typical cellular pre-mRNAs either undergo complete splicing and nuclear export or become degraded in the nucleus. Retroviral pre-mRNA interacts with viral or cellular proteins that alter typical posttranscriptional gene expression. Complex retroviruses like human immunodeficiency virus (HIV) encode a specialized regulatory protein whereas simple retroviruses like spleen necrosis virus (SNV) rely solely on cellular posttranscriptional modulators. Our lab identified a novel posttranscriptional control element in SNV RU5 RNA that facilitates expression of unspliced HIV-1 gag reporter RNA. This dissertation research identified that SNV RU5 functions, at least in part, by enhancing translational utilization of unspliced RNA; characterized primary sequence and secondary structure motifs necessary for SNV RU5 activity; and identified a cellular protein that interacts with SNV RU5 and conveys activity. RNA and protein quantitation determined that SNV RU5 enhances translation of nonviral luciferase RNA 8- to 10-fold but does not function as an internal ribosomal entry site. Detailed ribosomal profile analysis determined that SNV RU5 enhances translation initiation by increasing association of the RNA with multiple ribosomes by at least 3.5-fold as compared to a deletion mutant. Deletion and point mutagenesis defined two functionally redundant and synergistic regions necessary for activity. Enzymatic mapping determined that the regions are stable stem-loop structures and that both secondary structure and primary sequence motifs are necessary for activity. The loss-of-function mutations did not effect steady-state level or cytoplasmic accumulation of RU5-gag RNA but eliminated translational utilization. To identify cellular proteins that interact with SNV RU5, four techniques were utilized. First, overexpression assays evaluated three selected cellular proteins for stimulation of SNV RU5 activity. Second, RNA electromobility shift assays verified that binding is recapitulated in vitro. Third, UV-crosslinking experiments determined the relative sizes of SNV RU5-interactive proteins. Finally, affinity chromatography isolated a protein identified as RNA helicase A (RHA), which binds wildtype but not antisense SNV RU5 RNA and increases SNV RU5 activity in overexpression assays. RHA is co-localized with polysomes and correlates with increased translational utilization by SNV RU5.
| Author | : Cheryl Giles Bolinger |
| Publisher | : |
| Total Pages | : |
| Release | : 2008 |
| Genre | : Messenger RNA. |
| ISBN | : |
Abstract: Mechanisms governing retrovirus translation are a topic of great interest and controversy. Motifs located within the untranslated region (UTR) of retroviral mRNA have established roles in virus replication, and a growing volume of literature is revealing a necessary role of the UTR in control of viral protein synthesis. Two elements implicated in retrovirus translation control are a cap-dependent post-transcriptional control element (PCE) that is responsive to cellular protein RNA helicase A (RHA), or a cap-independent internal ribosome entry site (IRES). We have utilized stringent RNA and protein analyses to show that the 5' UTR (specifically the RU5 region) of spleen necrosis virus (SNV), reticuloendotheliosis virus A (REV-A), and human T-cell leukemia virus type 1 (HTLV-1) exhibit PCE activity, but not IRES. PCE activity was also conferred by the 5' UTR of HIV-1 and feline and bovine leukemia viruses, increasing the number of PCE-containing retroviruses to eight viruses spanning 6 genera. SNV, REV-A and HTLV-1 PCE require RHA for activity and it is expected that RHA regulates translation of all PCE-containing mRNA. Direct association of RHA with HTLV-1 and HIV-1 5' RU5 has been demonstrated, and a combination of ribosomal profile analyses and metabolic labeling experiments determined that RHA is necessary for translation of HTLV-1 and HIV-1 gag from genomic mRNA. These results provide direct evidence that RHA is necessary for efficient HTLV-1 and HIV-1 replication. Targeted RHA mutational analysis identified specific amino acid residues that modulate HTLV-1 PCE activity. The conserved residues that define the redundant N-terminal double-stranded RNA binding domain (dsRBD), the C-terminal arginine-glycine-rich (RGG) bi-directional nuclear transport domain, and central ATPase domain are essential for HTLV-1 translation. Identified transdominant RHA mutants accumulate in cytoplasmic stress granules, presumably with stalled translation complexes. We propose that RHA operates a selective translation control switch of retroviral mRNAs; PCE interaction with RHA through the dsRBD and RGG motif in conjunction with RNP remodeling by the ATPase domain facilitates cap-dependent translation. In the realm of translational research, each new insight into retroviral protein synthesis offers a prospective target for antiviral therapy and strategic improvement of gene transfer vectors.
| Author | : Gerrit Martin Daubner |
| Publisher | : |
| Total Pages | : |
| Release | : 2013 |
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| Author | : Joshua Jaeger Wolf |
| Publisher | : |
| Total Pages | : 148 |
| Release | : 2010 |
| Genre | : |
| ISBN | : |
RNA-binding proteins can regulate the stability, localization, and translation of their target mRNAs. Post-transcriptional regulation can orchestrate dynamic changes in gene expression, and can coordinate multiple cellular processes in response to various stimuli. Filamentous growth in Saccharomyces cerevisiae is a morphogenetic switch that occurs in response to nitrogen starvation and requires alterations in cell growth, cell cycle, and cell wall functions. Tyl element retrotransposition is also induced under conditions of nitrogen starvation. I describe a role for the RNA-binding protein Khdl in regulating these two responses to environmental stress through its mRNA targets. I identified the RNA targets of Khdl using in vivo crosslinking and immunoprecipitation (CLIP), combined with deep sequencing. This produced a high-resolution map of Khdl binding sites across the transcriptome, and provided unprecedented insight into its biological functions. Khdl regulates multiple post-transcriptional regulatory loops to coordinate the components of filamentous growth and Tyl retrotransposition. Although similar mechanisms were known to transcriptionally regulate these processes, the posttranscriptional coordination is a novel discovery. The feed-forward regulation that Khdl confers on FLO11, which encodes a protein required for filamentous growth, enables asymmetric expression between mother and daughter cells to switch between filamentous and yeast form growth. In this thesis, I describe regulation of gene expression by RNA-binding proteins, methods to identify their target transcripts and recognition sequences, the KH domain, known functions of Khdl, and the phenotypes it coordinates. My work represents the first application of CLIP to budding yeast, and the growing understanding of RNA-binding proteins in this organism facilitated the placement of Khdl into its posttranscriptional regulatory network. While many questions remain regarding the role Khdl plays in regulating cellular activities, this thesis addresses its direct role in key processes.
