Global ETD Search

1	RNA Editing in Trypanosomes: Substrate Recognition and its Integration to RNA Metabolism Hernandez, Alfredo J. 2010 December 1900 (has links) RNA editing in trypanosomes is the post-transcriptional insertion or deletion of uridylates at specific sites in mitochondrial mRNAs. This process is catalyzed by a multienzyme, multisubunit complex through a series of enzymatic cycles directed by small, trans-acting RNA molecules. Despite impressive progress in our understanding of the mechanism of RNA editing and the composition of the editing complex, fundamental questions regarding RNP assembly and the regulation of catalysis remain. This dissertation presents studies of RNA-protein interactions between RNA editing complexes and substrate RNAs and the determination of substrate secondary structural determinants that govern them. Our results suggest that substrate association, cleavage and full-round editing by RNA editing complexes in vitro obey hierarchical determinants that increase in complexity as editing progresses and we propose a model for substrate recognition by RNA editing complexes. In addition, this dissertation also presents the characterization of a novel mitochondrial RNA helicase, named REH2 and its macromolecular interactions. Our data suggest that REH2 is intimately involved in interactions with macromolecular complexes that integrate diverse processes mediating mitochondrial gene expression. These results have implications for the mechanism of substrate RNA recognition by RNA editing complexes as well as for the integration of RNA editing to other facets of mitochondrial RNA metabolism. RNA Editing guide RNA RNase III DExD/H-box
2	Growth-regulated expression and G0-specific turnover of the mRNA that encodes AH49, a mammalian protein highly related to the mRNA export protein UAP56 Pryor, Anne M. January 2003 (has links) No description available. Chemistry, Biochemistry UAP56 AH49 mRNA stability DExD/H box RNA helicase mRNA splicing and export
3	CHARACTERIZATION OF G-PATCH MOTIF CONTRIBUTION TO PRP43 FUNCTION IN THE PRE-MESSENGER RNA SPLICING AND RIBOSOMAL RNA BIOGENESIS PATHWAYS Banerjee, Daipayan 01 January 2013 (has links) The DExD/H-box protein Prp43 is essential for two biological processes: nucleoplasmic pre-mRNA splicing and nucleolar rRNA maturation. The biological basis for the temporal and spatial regulation of Prp43 remains elusive. The Spp382/Ntr1, Sqs1/Pfa1 and Pxr1/Gno1 G-patch proteins bind to and activate the Prp43 DExD/H box-helicase in pre-mRNA splicing (Spp382) and rRNA processing (Sqs1, Pxr1). These Prp43-interacting proteins each contain the G-patch domain, a conserved sequence of ~48 amino acids that includes 6 highly conserved glycine (G) residues. Five annotated G-patch proteins in baker’s yeast (i.e., Spp382, Pxr1, Spp2, Sqs1 and Ylr271) and with the possible exception of the uncharacterized Ylr271 protein, all are associated with ribonucleoprotein (RNP) complexes. Understanding the role of G-patch proteins in modulating the DExD/H box protein Prp43 biological function was the motivation of this thesis. The G-patch domain has been proposed as a protein-protein or a protein-RNA interaction module for RNP proteins. This study found that the three Prp43-associated G-patch domains interact with Prp43 in a yeast 2 hybrid (Y2H) assay but differ in apparent relative affinities. Using a systemic Y2H analysis, I identified the conserved Winged-helix (WH) domain in Prp43 as a major binding site for G-patch motif. Intriguingly, removal of the non-essential N-terminal domain (NTD) of Prp43 (amino acids 2-94), greatly improves G-patch binding, suggesting that the NTD may play a role in modulating enzyme activity by the G-patch effectors. I identify a second site within the Pxr1 that strongly binds Prp43 but, unlike the G-patch, is dispensable for Pxr1 function in vivo. By constructing chimeric proteins, I demonstrated that individual G-patch peptides differ in the ability to reconstitute Spp382 and Pxr1 function in support of pre-mRNA splicing and rRNA biogenesis, respectively. Through amino acid sequence comparisons and selective mutagenesis I identified several residues within the G-patch motif critical for Prp43-stimulated pre-mRNA splicing without greatly altering its ability to bind Prp43. These data lead me to propose that the G-patch motif is not a simple Prp43 binding interface but may contribute more directly to substrate selection or Prp43 enzyme activation in the biologically distinct pre-mRNA splicing and rRNA processing pathways. Prp43 DExD/H box helicase G-patch domain RNA splicing ribosome biogenesis. Biology Cell Biology Molecular Biology Molecular genetics
4	Strukturelle Charakterisierung der C-terminalen Domäne des spleißosomalen DExD/H-Box Proteins hPrp22 / Strutural characterization of the C-terminal domain of the spliceosomal DExD/H-Box protein hPrp22 Kudlinzki, Denis 22 January 2008 (has links) No description available. 570 Biowissenschaften, Biologie WA 000 Mathematics and Natural Science Prp22 Prp2 hPrp22 DExD/H-Box DEAD-Box DEAH-box RNA-Helikase Spleißen Spleißosom helicase unwinding splicing spliceosome 30.42
5	Kristallstrukturanalyse des spleißosomalen DEAD-Box Proteins hPrp28 / Crystal structure analysis of the spliceosomal DEAD-box protein hPrp28 Möhlmann, Sina 23 January 2008 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science hPrp28 Prp28 U5-100K Spleißosom DEAD-Box DExD/H-Box Struktur RS Domäne hPrp28 Prp28 U5-100K spliceosome DEAD-box DExD/H-box structure RS domain 42.13 WF 200: Molekularbiologie

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