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Structure / Function Relationship of Archaeal Box C/D and H/ACA ProteinsBosmeny, Michael 01 May 2016 (has links)
Ribonucleoprotein complexes are responsible for some of the post-transcriptional modifications of RNA that occur within the cell, including 2'-O-methylation and pseudouridylation. These modifications contribute, among other things, to RNA folding, inhibition of degradation, and general cellular viability. In this study, we identify residues within the proteins of these complexes that are important to the functioning of the Box C/D and Box H/ACA complexes. Candidates were selected based on previous work and mutant versions of the proteins were introduced in-vivo. Assays were done to determine the functionality of the mutant complex. This work is divided into three parts, focused on the three proteins investigated. The first part is concerned with Nop5, a protein in the Box C/D RNP complex. Nop5 is known to interact with all other proteins and RNAs in the complex, and is believed to serve a primarily structural role, aligning the other components. Mutagenesis study of suspected significant amino acids in this protein showed that it is difficult to disrupt the operation of Nop5 with single changes, but is possible with more extensive mutation. The second part concerns Fibrillarin, the catalytic protein of the Box C/D ribonucleoprotein complex. Previous mutagenesis work identified several important amino acids involved with AdoMet transfer and complex formation. The methylation ability of these mutant complexes were further examined in this work by confirming that the same modification, or lack thereof, occurred at a second rRNA position. The final part of this work is about Nop10, part of the Box H/ACA complex. This work is only preliminary, but begins the process of testing suspected essential amino acids in the structure.
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Studying the RNA-Recognition Site of RNase U2 for a More Diverse Bioanalytical Toolbox in RNA Modification MappingSolivio, Beulah Mae Ann 18 October 2019 (has links)
No description available.
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Transcriptome maps of general eukaryotic RNA degradation factors and identification and functional characterization of the novel mRNA modification N<sup>3</sup>-methylcytidineHofmann, Katharina Bettina 06 May 2019 (has links)
No description available.
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Understanding the Cleavage Characteristics of Ribonucleases Cusativin and MC1 used in RNA Modification MappingThakur, Priti January 2021 (has links)
No description available.
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Mass Spectrometry Analysis of Methylated Ribosomal RNARohlfs, Rebecca L. 30 September 2013 (has links)
No description available.
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Ap4A-RNA v IgE aktivovaných žírných buňkách / Ap4A-RNA in IgE activated mast cellsPotužník, Jiří František January 2021 (has links)
Mast cells are tissue resident members of the immune system. They have a wide range of functions and receptors including the FcεRI receptor, which gets activated by binding to IgE bound to an antigen. When the cells are activated in this manner, a process termed the LysRS- Ap4A-MITF signalling pathway occurs, resulting in the translocation of the Lys tRNA synthetase into the nucleus and an activation of its moonlighting activity - the production of diadenosine tetraphosphate (Ap4A). Ap4A is a dinucleoside polyphosphate, a type of ubiquitous molecule present in all domains of life. They are made up of two nucleosides joined together by a 5' to 5' phosphodiester bridge of variable lengths. Recently, these molecules have been shown to serve as non-canonical initiating nucleotides during bacterial transcription, where they function as 5' RNA caps, similar to the well-known 7- methylguanosine eukaryotic mRNA cap. In this thesis, I present proof of existence of Ap 4A capped RNA in mast cells, a previously unknown 5' RNA structure in eukaryotic cells, and I attempt to pinpoint its role in the activation of these cells and in the wider context of mast cell mediated immune response. Keywords: mast cells, RNA caps, Dinucleoside polyphosphates, Ap 4A, RNA modification, IgE, FcεRI receptor, Lysine tRNA synthetase
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Entwicklung neuer Methoden zur Analytik von nicht-codierender RNABoss, Marcel 22 June 2020 (has links)
Ziel dieser Arbeit war die Entwicklung neuer Methoden zur Untersuchung zirkulärer RNA. Das erste Projekt dieser Arbeit beschäftigte sich mit der Erstellung eines universell einsetzbaren Protokolls zur Generierung einer funktionalisierten zirkulären RNA. Hierbei konnte zunächst erfolgreich eine Vorschrift zur Herstellung unmodifizierter circRNA etabliert werden. Im zweiten Schritt gelang auch die Generierung einer zirkulären RNA mit Alkin-Funktionalisierung. Geringe Ausbeuten gaben Anlass zur Entwicklung eines alternativen Verfahrens, bei dem die Zyklisierung von Kopf-Schwanz modifizierter RNA durch CuAAC vorgenommen werden sollte. Dabei konnte zunächst eine 5‘-azidmodifizierte RNA durch in vitro Transkription gebildet werden, die anschließend am 3‘-Terminus mit einem 3‘ alkinmodifizierten Baustein mit Aminfunktionalität versehen wurde. Daraufhin konnte erfolgreich eine Zyklisierung mittels CuAAC vorgenommen werden. Ein grundlegendes Problem bei diesen Arbeiten war der Nachweis, dass die gebildete RNA tatsächlich in zirkulärer Form vorlag.
Im Rahmen des zweiten Projektes dieser Arbeit wurde ein Assay zur direkten Unterscheidung von zirkulären und linearen Transkripten etabliert. Mittels reverser Transkription konnte ein rolling circle Mechanismus mit dem zirkulären Transkript durchgeführt werden, was in einer multimeren cDNA resultierte. Nach Amplifizierung über qPCR ermöglichteeine Gelanalyse den Nachweis eines spezifischen Bandenmusters für das circRNA-Transkript, wohingegen das lineare Transkript lediglich eine monomere Bande generierte. Anschließend erfolgte die Weiterentwicklung des Assays zu einer spezifischen Nachweismethode für zirkuläre RNA in biologischen Proben.Dabei kann eine abschließende Gelanalyse zur Identifizierung von falsch-positiven Ergebnissen genutzt werden. Die hier etablierte Methode ermöglicht künftig einen schnellen und einfachen Nachweis von circRNA beim Screeningvon biologischen Proben. / Circular RNAs belong to the group of long, non-coding RNAs and have gene regulating functions, comparable to miRNA. However, the field of circRNA research is proceeding slowly due to the lack of efficient analytical methods. That‘s the reason why the development of new analytical methods plays a keyrole within characterisation and identification of circRNAs.
This thesis comprises two projects dealing on one hand with the creation of a protocol for the generation of functional circRNA on and the other hand, an assay to differentiate circular and linear RNA.
For the generation of circRNA a non-modified circRNA was produced as positiv control by using T4 RNA ligase 2. After the addition of a modification step with T4 RNA ligase 1, it was possible to generate circRNA with alkyne functionalization. Due to limited yields of modified circRNA, the protocol was adapted and a protocol for chemical ligation was established. In this new procedure a RNA with 5‘-azido modification was generated by in vitro transcription, followed by incorporation of a 3‘-alkyne modified building block with additional amine funktionality at the RNA-3‘-end. Consecutively, it was possible to perform a cyclization with the double modified RNA by CuAAC.
The second project comprises the establishment of an assay in order to differentiate circular and linear RNA. A rolling circle mechanism was utilized by reverse transcription of a circular RNA transcript, resulting in a multimeric cDNA. Following DNA amplification by qPCR, a specific fragmentation pattern for circRNA was verified by gel electrophoresis. In contrast to this, for linear RNA, a monomeric DNA pattern was seen. Subsequently the assay was advanced to a detection method for circular RNA in biological samples. A final gel electrophoresis allows the identification of false-positive results. In the future, the here developed method can be applied for fast and easy detection of circRNAs in biological samples.
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Studies on RNA Modification and Editing in <i>Trypanosoma brucei</i>Fleming, Ian Murray Cameron 08 June 2016 (has links)
No description available.
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