Developing a Predictive and Quantitative Understanding of RNA Ligand Recognition
| dc.contributor.advisor | Al-Hashimi, Hashim M | |
| dc.contributor.advisor | Oas, Terrence G | |
| dc.contributor.author | Orlovsky, Nicole | |
| dc.date.accessioned | 2022-02-11T21:38:19Z | |
| dc.date.issued | 2021 | |
| dc.department | Biochemistry | |
| dc.description.abstract | RNA recognition frequently results in conformational changes that optimize intermolecular binding. As a consequence, the overall binding affinity of RNA to its binding partners depends not only on the intermolecular interactions formed in the bound state, but also on the energy cost associated with changing the RNA conformational distribution. Measuring these conformational penalties is however challenging because bound RNA conformations tend to have equilibrium populations in the absence of the binding partner that fall outside detection by conventional biophysical methods. In this work we employ as a model system HIV-1 TAR RNA and its interaction with the ligand argininamide (ARG), a mimic of TAR’s cognate protein binding partner, the transactivator Tat. We use NMR chemical shift perturbations (CSP) and NMR relaxation dispersion (RD) in combination with Bayesian inference to develop a detailed thermodynamic model of coupled conformational change and ligand binding. Starting from a comprehensive 12-state model of the equilibrium, we estimate the energies of six distinct detectable thermodynamic states that are not accessible by currently available methods. Our approach identifies a minimum of four RNA intermediates that differ in terms of the TAR conformation and ARG-occupancy. The dominant bound TAR conformation features two bound ARG ligands and has an equilibrium population in the absence of ARG that is below detection limit. Consequently, even though ARG binds to TAR with an apparent overall weak affinity ($\Kdapp \approx \SI{0.2}{\milli \Molar}$), it binds the prefolded conformation with a $K_{\ch{d}}$ in the nM range. Our results show that conformational penalties can be major determinants of RNA-ligand binding affinity as well as a source of binding cooperativity, with important implications for a predictive understanding of how RNA is recognized and for RNA-targeted drug discovery. Additionally, we describe in detail the development of our approach for fitting complex ligand binding data to mathematical models using Bayesian inference. We provide crucial benchmarks and demonstrate the robustness of our fitting approach with the goal of application to other systems. This thesis aims to provide new insight into the dynamics of RNA-ligand recognition as well as provide new methods that can be applied to achieve this goal. | |
| dc.identifier.uri | ||
| dc.subject | Biochemistry | |
| dc.subject | Thermodynamics | |
| dc.subject | Statistics | |
| dc.subject | Bayesian inference | |
| dc.subject | Binding | |
| dc.subject | Dynamics | |
| dc.subject | NMR | |
| dc.subject | RNA | |
| dc.title | Developing a Predictive and Quantitative Understanding of RNA Ligand Recognition | |
| dc.type | Dissertation | |
| duke.embargo.months | 23.17808219178082 | |
| duke.embargo.release | 2024-01-18T00:00:00Z |
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