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Characterization of E coli Hfq structure and its RNA binding propertiesSun, Xueguang 07 December 2005 (has links)
Hfq is a bacterial RNA-binding protein recently shown to contain the Sm motif, a characteristic of Sm proteins that function in RNA processing in archaea and eukaryotes. Hfq plays a major role in RNA-RNA interactions regulating translation. Comparative structural modeling and amino acid sequence alignment were used to predict the 3-D structure of Hfq and the model was in excellent agreement with the crystal structure which determined for S. aureus Hfq. The evolution of Hfq was explored by a BLAST search of microbial genomes followed by phyletic analysis. About half of the genomes examined contain at least one gene coding for Hfq. The presence and absence of Hfq closely followed major bacterial clades. The potential RNA binding residues on the two surfaces of the Hfq hexamer were proposed based on the bioinformatics studies and the mutant Hfq proteins with either single or double mutations on the two surfaces of the Hfq hexamer were generated. Their RNA binding properties was biophysically studied by gel-shift assay, fluorescence anisotropy and fluorescence quenching techniques. Results indicated that 1) point mutations on the distal surface of the Hfq hexamer, Y25A and K31A, have a major effect on A18 binding. Both reduce binding by about 1000 fold. Mutations on the proximal surface have a small or no influence on A18 binding. 2) Two mutations, F39A and R16A, on the proximal surface of the Hfq structure reduce binding to the DsrA domain II by 10 fold. Other mutations reduce binding by less than 2 fold. 3) An amino acid covariance was observed in L12 and F39. Mutation L12F can partially restore F39A in DsrA RNA binding. 4) It appears that two Hfq hexamers cooperatively bind one RNA for both DsrADII and A18.
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Transcriptional regulation of estrogen receptor alpha target genes by hexamethylene bisacetamide-inducible gene 1 (HEXIM1) and its role in mammary gland development and breast cancer /Ogba, Ndiya January 2010 (has links)
Thesis (Ph. D.)--Case Western Reserve University, 2010. / [School of Medicine] Department of Pharmacology. Includes bibliographical references.
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Kinetoplastid RNA editing : in vitro RNA editing and functional analysis of the editosome /Wang, Bingbing. January 2003 (has links)
Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (leaves 117-127).
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Coordinated Post-transcriptional Regulation by MicroRNAs and RNA- binding ProteinsSekikawa, Akiko 27 November 2013 (has links)
Both microRNAs (miRNAs) and RNA-binding proteins (RBPs) regulate post- transcriptional events, but the post-transcriptional contribution to the global mammalian transcriptomes is still not well understood. In this study we study the synergistic interaction between microRNAs that inhibit gene production, and a special RBP, HuR, that positively regulates mRNA stability. We examined their relationship in terms of spatial, conservational and expressional perspective. We show comprehensive mapping of HuR binding sites by combination of its structural and sequential preferences; and cross-platform normalization method within a process of refining miRNA and HuR binding site mapping. Finally, we observed co-evolution of miRNA and HuR binding sites by looking at their proximity and conservation levels. Collectively, our data suggest that mammalian microRNAs and HuR, with seemingly opposing regulatory effects, cooperatively regulate their mutual targets.
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Analysis of RBM5 and RBM10 expression throughout H9C2 skeletal and cardiac muscle cell differentiation.Loiselle, Julie Jennifer 31 July 2013 (has links)
RNA Binding Motif (RBM) domain proteins RBM5 and RBM10 have been shown to influence apoptosis, cell cycle arrest and splicing in transformed cells. In this study, RBM5 and RBM10 were examined in non-transformed cells in order to gain a wider range of knowledge regarding their function. Expression of Rbm5 and Rbm10, as well as select splice variants, was examined at the mRNA and protein level throughout H9c2 skeletal and cardiac myoblast differentiation. Results suggest that Rbm5 and Rbm10 may (a) be involved in regulating cell cycle arrest and apoptosis during skeletal myoblast differentiation and (b) undergo post-transcriptional or translational regulation throughout myoblast differentiation. All in all, the expression profiles obtained in the course of this study will help to suggest a role for Rbm5 and Rbm10 in differentiation, as well as possible differentiation-specific target genes with which they may interact.
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The functional role of the RNA-binding protein HuR in the regulation of muscle cell differentiation /Beauchamp, Pascal. January 2008 (has links)
Muscle tissue development (myogenesis) involves the formation of specific fibers (myotubes) from muscle cells (myoblasts). For this to occur, the sequential expression of Myogenic Regulatory Factors (MRFs), such as MyoD and myogenin, is required. The expression of these MRFs is regulated posttranscriptionally by the RNA-binding protein HuR, whereby HuR associates with the 3'-untranslated regions of MyoD and myogenin mRNA, leading to a significant increase in their half-lives. Here we show that the cleavage of HuR by caspases at the aspartate (D) 226 residue is one of the main regulators of its pro-myogenic function. This proteolytic activity generates two cleavage products (CPs), HuR-CP1 and HuR-CP2, that differentially affect the myogenic process. Myoblasts overexpressing HuR-CP1 or the non-cleavable mutant of HuR, HuRD226A, are not able to engage myogenesis, while overexpressing HuR-CP2 enhances myotube formation. HuR-CP2 but not -CP1 promotes myogenesis by stabilizing the MyoD and myogenin mRNAs to the same levels as wt-HuR. Conversely, the inhibitory effects of HuR-CP1 and HuRD226A depend on their abilities to associate during myogenesis with the HuR import receptor, Trn2, leading to HuR accumulation in the cytoplasm. Therefore, we propose a model whereby the caspase-mediated cleavage of HuR generates two CPs that collaborate to regulate myogenesis; HuR-CP1 by interfering with the Trn2-mediated import of HuR and HuR-CP2 by participating in the stabilization of mRNAs encoding key MRFs.
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Post-transcriptional Gene Regulation in the Vascular Endothelium: Implications of HypoxiaHo, Jr Jyun 09 January 2014 (has links)
Cellular messenger RNAs (mRNAs) exist almost exclusively in the context of ribonucleoprotein complexes (RNPs), which are largely responsible for the coordinated regulation of mRNA fate, and in particular, the post-transcriptional regulation of mRNA stability and translation. RNA- binding proteins, antisense RNAs, and microRNAs represent three major classes of post- transcriptional regulatory factors that interact with target mRNAs. Significantly, these interactions are dynamically regulated under both basal and stress conditions, such as hypoxia. Given the prominent contributions of post-transcriptional regulation to overall gene expression, a more comprehensive understanding of the underlying mechanisms is required.
In this thesis, we present exciting new evidence for the functional importance of post- transcriptional gene regulation, especially in the vascular endothelium. Firstly, we show that the formation of hnRNP E1-containing RNPs contributes significantly to the remarkable basal stability of endothelial nitric oxide synthase (eNOS) mRNAs in endothelial cells by protecting them from inhibitory post-transcriptional forces. However, hypoxia impairs such RNP formation through hnRNP E1 serine phosphorylation and nuclear localization. Together, these mechanisms contribute significantly to decreased eNOS expression and activity in chronic hypoxia.
ii
Secondly, we reveal an important functional relationship between the microRNA pathway and the HIF-mediated cellular hypoxic response. Specifically, the down-regulation of Dicer and an important number of Dicer-dependent microRNAs in chronic hypoxia represents an important adaptive mechanism that serves to maintain the cellular hypoxic response through HIF-α- and microRNA-dependent mechanisms, with significant implications for the development of RNAi- based therapies. Finally, we provide evidence that the up-regulation of specific microRNAs in acute hypoxia is a potentially important mechanism that serves to suppress global translation initiation in order to conserve energy and ensure cellular survival.
Collectively, the findings presented in this thesis provide important new mechanistic insight into the post-transcriptional regulation of eNOS, as well as the functional integration of the microRNA and the cellular hypoxic response pathways.
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Post-transcriptional Gene Regulation in the Vascular Endothelium: Implications of HypoxiaHo, Jr Jyun 09 January 2014 (has links)
Cellular messenger RNAs (mRNAs) exist almost exclusively in the context of ribonucleoprotein complexes (RNPs), which are largely responsible for the coordinated regulation of mRNA fate, and in particular, the post-transcriptional regulation of mRNA stability and translation. RNA- binding proteins, antisense RNAs, and microRNAs represent three major classes of post- transcriptional regulatory factors that interact with target mRNAs. Significantly, these interactions are dynamically regulated under both basal and stress conditions, such as hypoxia. Given the prominent contributions of post-transcriptional regulation to overall gene expression, a more comprehensive understanding of the underlying mechanisms is required.
In this thesis, we present exciting new evidence for the functional importance of post- transcriptional gene regulation, especially in the vascular endothelium. Firstly, we show that the formation of hnRNP E1-containing RNPs contributes significantly to the remarkable basal stability of endothelial nitric oxide synthase (eNOS) mRNAs in endothelial cells by protecting them from inhibitory post-transcriptional forces. However, hypoxia impairs such RNP formation through hnRNP E1 serine phosphorylation and nuclear localization. Together, these mechanisms contribute significantly to decreased eNOS expression and activity in chronic hypoxia.
ii
Secondly, we reveal an important functional relationship between the microRNA pathway and the HIF-mediated cellular hypoxic response. Specifically, the down-regulation of Dicer and an important number of Dicer-dependent microRNAs in chronic hypoxia represents an important adaptive mechanism that serves to maintain the cellular hypoxic response through HIF-α- and microRNA-dependent mechanisms, with significant implications for the development of RNAi- based therapies. Finally, we provide evidence that the up-regulation of specific microRNAs in acute hypoxia is a potentially important mechanism that serves to suppress global translation initiation in order to conserve energy and ensure cellular survival.
Collectively, the findings presented in this thesis provide important new mechanistic insight into the post-transcriptional regulation of eNOS, as well as the functional integration of the microRNA and the cellular hypoxic response pathways.
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Coordinated Post-transcriptional Regulation by MicroRNAs and RNA- binding ProteinsSekikawa, Akiko 27 November 2013 (has links)
Both microRNAs (miRNAs) and RNA-binding proteins (RBPs) regulate post- transcriptional events, but the post-transcriptional contribution to the global mammalian transcriptomes is still not well understood. In this study we study the synergistic interaction between microRNAs that inhibit gene production, and a special RBP, HuR, that positively regulates mRNA stability. We examined their relationship in terms of spatial, conservational and expressional perspective. We show comprehensive mapping of HuR binding sites by combination of its structural and sequential preferences; and cross-platform normalization method within a process of refining miRNA and HuR binding site mapping. Finally, we observed co-evolution of miRNA and HuR binding sites by looking at their proximity and conservation levels. Collectively, our data suggest that mammalian microRNAs and HuR, with seemingly opposing regulatory effects, cooperatively regulate their mutual targets.
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Post-transcriptional Regulation of Membrane-associated RNAsJagannathan, Sujatha January 2013 (has links)
<p>RNA localization provides the blueprint for compartmentalized protein synthesis in eukaryotic cells. Current paradigms indicate that RNAs encoding secretory and membrane proteins are recruited to the endoplasmic reticulum (ER), via positive selection of a `signal peptide' tag encoded in the protein. Thus RNA sorting to the ER follows protein sorting and the RNA is considered a passive player. However, RNAs have been shown to access the ER independent of the signal peptide and display a wide range of affinities to the ER that does not correlate with signal peptide strength. How and why mRNAs localize to the ER to varying extents and whether such localization serves a purpose besides protein sorting is poorly understood. To establish the cause and consequence of RNA binding to the ER membrane, I pose three primary questions: 1. How are mRNAs targeted to the ER? 2. Once targeted, how are mRNAs anchored to the ER membrane? 3. Are ER localized mRNAs subject to transcript-specific regulation? </p><p>I address cytosolic mRNA targeting to the ER by comparing the partitioning profiles of cytosolic/nuclear protein-encoding mRNA population (mRNACyto) to that of mRNAs encoding a signal peptide (mRNAER). I show that, at a population level, mRNACyto display a mean ER enrichment that is proportional to the amount of ER-bound ribosomes. Thus, I propose that targeting of mRNACyto to the ER is stochastic and over time, the specific interactions engaged by an individual mRNACyto with the ER determines its steady state partitioning profile between the cytoplasm and the ER. </p><p>To address the modes of direct binding of mRNA to the ER, I examined the association of various RNA populations with the ER after disrupting membrane-bound ribosome's interaction with its ER receptor. mRNACyto and most of mRNAs encoding secretory proteins (mRNACargo) are released upon disruption of ribosome-receptor interactions, indicating no direct mRNA-ER interactions. However, the population of mRNAs that encode resident proteins of the endomembrane organelles such as the ER, lysosome, endosome and the Golgi apparatus (mRNARes) maintain their association with the ER despite the disruption of ribosome-receptor interactions. These results indicate direct binding of mRNARes to the ER, further suggesting that the function of the encoded proteins dictates the mode of association of corresponding mRNA with the ER. </p><p>To uncover the mode of mRNARes binding directly to ER, I performed differential proteomic analysis of cytosolic and membrane bound RNA-protein complexes, which revealed a network of RNA binding proteins that interact uniquely with the ER-anchored mRNAs. The anchoring of endomembrane resident protein-encoding RNAs to the ER through these RNA binding proteins may reflect an imprinting of the ER with the information necessary for the continued biogenesis of the endomembrane organelle system even in situations where translation-dependent ER targeting of an mRNA is compromised. </p><p>Finally, I address whether ER-bound mRNAs can be regulated differentially by comparing the fates of two signal peptide-encoding RNAs, B2M and GRP94, during the unfolded protein response (UPR). I show that in response to ER stress, GRP94 mRNA, but not B2M, relocates to stress-induced RNA granules, thus escaping an RNA decay program that operates at the ER membrane during the UPR. Hence, I propose that the mode of RNA association to the ER is subject to regulation and influences the fate of RNAs during cellular stress. Thus, by demonstrating diverse modes of mRNA localization to the ER and differential regulation of ER bound mRNAs during cellular stress, my work has helped establish an emerging role for the ER as a post-transcriptional gene regulatory platform.</p> / Dissertation
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