Allostery is a regulatory process whereby a perturbation by an effector at one discrete locus creates a conformational change that stimulates a functional change at another. The two sites communicate through networks of interacting residues that respond in a concerted manner to the allosteric perturbation. These allosteric networks are traditionally mapped with high resolution structure determination techniques to understand the conformational changes that regulate protein function as well as its modulation by allosteric ligands and its dysfunction caused by disease-related mutations (DRMs). However, high resolution structural determination techniques, such as X-ray crystallography, cryo-electron microscopy and nuclear Overhauser effect NMR spectroscopy are not always amenable for systems plagued by poor solubility and line broadening caused by μs-ms dynamics or systems where allostery relies primarily on dynamical rather than structural changes. This dissertation discusses methodologies to map the allosteric sites and pathways for such challenging systems. The foundation of this approach is to model allosteric pathways in the context of their respective thermodynamic cycles. In chapter 2, the thermodynamic cycle of a DRM in the hyperpolarization-activated cyclic nucleotide-gated ion channel 4 (HCN4) is analyzed with respect to structure, dynamics and kinetics, revealing how the DRM remodels the free energy landscape of HCN4 and results in a loss-of-function disease phenotype. In chapter 3, the mechanism of action of an uncompetitive inhibitor for the exchange protein activated by cAMP is elucidated by characterizing its selectivity for distinct conformations within the thermodynamic cycle that are trapped using a combination of mutations and ligand analogs. In chapter 4, we discuss two new protocols for the chemical shift covariance analysis (CHESCA). The CHESCA is an approach that identifies allosteric signaling pathways by measuring concerted residue responses to a library of chemical perturbations that stabilize conformational equilibria at different positions. Overall, the approaches discussed in this dissertation are widely applicable for mapping the mechanisms of allosteric perturbations that arise from ligand binding, post-translational modifications and mutations, even in systems where traditional structure determination techniques remain challenging to implement. / Thesis / Doctor of Philosophy (PhD) / Allostery is a regulatory mechanism for proteins, which controls functional properties of one distinct site through the perturbation of another distinct, and often distant, site. The two sites are connected via a series of residues that undergo conformational changes once perturbed by the allosteric effector. Mapping these communication pathways reveals mechanisms of protein regulation, which are invaluable for developing pharmacological modulators to target these pathways or for understanding the mechanisms of disease mutations that disrupt these pathways. Allosteric pathways have been traditionally determined using structure determination approaches that provide a static snapshot of the protein’s structure. However, these approaches are typically not effective when allostery relies extensive changes in dynamics. The goal of this thesis was to develop methods to characterize systems that are dynamic or otherwise unsuitable for traditional structure determination. Herein, we utilize NMR spectroscopy to analyze the allosteric mechanisms of three cAMP-binding proteins involved in cardiovascular health.
| Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/23697 |
| Date | January 2018 |
| Creators | Boulton, Stephen |
| Contributors | Melacini, Giuseppe, Health Sciences |
| Source Sets | McMaster University |
| Language | English |
| Detected Language | English |
| Type | Thesis |
Page generated in 0.0023 seconds