Riboswitches are cis-acting gene regulatory RNAs, which function without involvement of proteins. They have been implicated as drug targets and are attractive systems for the study of RNA-ligand binding and RNA folding. The purine riboswitch was used as a model system for RNA-ligand docking. Published binding data was successfully reproduced in silico and compounds predicted to bind the riboswitch in a virtual screening were tested experimentally. Structural data confirming the predicted binding mode for several cases was obtained. The problems encountered were not specific to RNA-ligand docking but known from the far more explored field of protein-ligand docking.The SAM-I riboswitch was also subjected to virtual ligand screening. This receptor is a system of greater complexity than the purine riboswitch and consequently posed a harder challenge to the docking protocol. After initial validation of the docking setup based on previously published data, a set of compounds selected from the in-house database of commercially available compounds was screened. One compound identfied in silico was cofirmed to bind experimentally.The k-turn motif found in the SAM-I riboswitch was investigated with respect to its folding. The k-turn motif was found to be foldable in context of the SAMI riboswitch as well as in isolation as was expected. Furthermore, mutations disrupting key interactions within the k-turn motif were found to be prohibitive of k-turn folding in isolation as well as in context of the riboswitch, leading to a loss of ligand binding. Interestingly, two sequences were identfied which fold in context of the riboswitch but do not fold in isolation. This confirms the contribution of tertiary interactions to k-turn folding. This conclusion was backed up with structural data is a system of greater complexity than the purine riboswitch and consequently posed a harder challenge to the docking protocol. After initial validation of the to its folding. The k-turn motif was found to be foldable in context of the SAMI riboswitch as well as in isolation as was expected. Furthermore, mutations disrupting key interactions within the k-turn motif were found to be prohibitive of k-turn folding in isolation as well as in context of the riboswitch, leading to a loss of ligand binding. Interestingly, two sequences were identi ed which fold in context of the riboswitch but do not fold in isolation. This con rms the contribution of tertiary interactions to k-turn folding. This conclusion was backed
| Identifer | oai:union.ndltd.org:bl.uk/oai:ethos.bl.uk:578816 |
| Date | January 2011 |
| Creators | Daldrop, Peter |
| Publisher | University of Dundee |
| Source Sets | Ethos UK |
| Detected Language | English |
| Type | Electronic Thesis or Dissertation |
| Source | https://discovery.dundee.ac.uk/en/studentTheses/db338d42-75c1-43a6-be6a-11399f04989e |
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