Doctoral Degrees (Molecular Biology and Human Genetics)
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Browsing Doctoral Degrees (Molecular Biology and Human Genetics) by Subject "Amino acid residues"
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- ItemRegulators of dormancy/viability of Mycobacterium tuberculosis inside the human macrophages(Stellenbosch : Stellenbosch University, 2012-03) Botha, Maria Magdalena; Wiid, I. J. F.; Kenyon, C. P.; Stellenbosch University. Faculty of Health Sciences. Dept. of Biomedical Sciences. Molecular Biology and Human Genetics.ENGLISH ABSTRACT: The investigation was aimed to improve the understanding of the binding interactions between DevS and DevR that are implicated in the regulation of the dormancy response in Mycobacterium tuberculosis. These binding interactions could provide good drug targets for the treatment of persistent tuberculosis, the mechanistic understanding of their binding interactions is important for the development of a validated inhibitor screen. A detailed in silico analysis of the amino acid residues that play a role in the binding of receptor DevR to both kinase DevS and the target DNA was undertaken. A reasonable approximation of the DevS structure was produced using homologous protein structures. In silico docking of DevS to DevR merely produced a set of probable candidate structures, since more than one conformation with similar docked energies was observed. The decision on which one is the more correct form can only be estimated by crystallization of this complex. Therefore, the functional expression and purification of the Dev TCS components were pursued. Denaturing HIS™-select nickel affinity gel purification in the form of matrix-assisted refolding led to the production of functional Dev TCS proteins. To understand the binding of DevR to DNA consensus sequences, as well as the nature of these interactions, a model was built of the full length DevR dimer binding to DNA consensus sequences. Based on this model, single mutations were made to DevR in vitro and their effects assessed in order to validate the model built. During Electrophoretic Mobility Shift Assay (EMSA) analysis, it was found that K179I and N183L mutants prevented the binding of DevR to the DNA consensus sequences. If DevR and DevS binding are to be used in a drug development program, it is essential to have the protocols to accurately measure their interaction, in addition to developing a fundamental understanding of how their interactions occur. The binding affinity of DevR to both DevS and the truncated soluble fragment of DevS (DevS201) were explored, using the BIAcore instrument, an SPR-based biosensor. For sufficiently strong binding between a histidine kinase and a response regulator, the KD needs to be in the nM range. The KD was calculated to be 255 nM for DevS201 and 184 nM for DevS. Therefore it can be concluded that DevS201 binds DevR strongly enough to be used in future studies, and that the BIAcore could be used to screen small-molecule inhibitors of DevR-DevS interactions.