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Browsing by Author "Waltho, Jonathan P."
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Item Assessing the Influence of Mutation on GTPase Transition States by Using X‐ray Crystallography, 19F NMR, and DFT Approaches(Wiley, 2017-08-07) Jin, Yi; Molt, Robert W.; Pellegrini, Erika; Cliff, Matthew J.; Bowler, Matthew W.; Richards, Nigel G. J.; Blackburn, G. Michael; Waltho, Jonathan P.; Biochemistry and Molecular Biology, School of MedicineWe report X‐ray crystallographic and 19F NMR studies of the G‐protein RhoA complexed with MgF3 −, GDP, and RhoGAP, which has the mutation Arg85′Ala. When combined with DFT calculations, these data permit the identification of changes in transition state (TS) properties. The X‐ray data show how Tyr34 maintains solvent exclusion and the core H‐bond network in the active site by relocating to replace the missing Arg85′ sidechain. The 19F NMR data show deshielding effects that indicate the main function of Arg85′ is electronic polarization of the transferring phosphoryl group, primarily mediated by H‐bonding to O3G and thence to PG. DFT calculations identify electron‐density redistribution and pinpoint why the TS for guanosine 5′‐triphosphate (GTP) hydrolysis is higher in energy when RhoA is complexed with RhoGAPArg85′Ala relative to wild‐type (WT) RhoGAP. This study demonstrates that 19F NMR measurements, in combination with X‐ray crystallography and DFT calculations, can reliably dissect the response of small GTPases to site‐specific modifications.Item How to name atoms in phosphates, polyphosphates, their derivatives and mimics, and transition state analogues for enzyme-catalysed phosphoryl transfer reactions (IUPAC Recommendations 2016)(De Gruyter, 2017-05) Blackburn, G. Michael; Cherfils, Jacqueline; Moss, Gerard P.; Richards, Nigel G. J.; Waltho, Jonathan P.; Williams, Nicholas H.; Wittinghofer, Alfred; Chemistry and Chemical Biology, School of ScienceProcedures are proposed for the naming of individual atoms, P, O, F, N, and S in phosphate esters, amidates, thiophosphates, polyphosphates, their mimics, and analogues of transition states for enzyme-catalyzed phosphoryl transfer reactions. Their purpose is to enable scientists in very different fields, e.g. biochemistry, biophysics, chemistry, computational chemistry, crystallography, and molecular biology, to share standard protocols for the labelling of individual atoms in complex molecules. This will facilitate clear and unambiguous descriptions of structural results, as well as scientific intercommunication concerning them. At the present time, perusal of the Protein Data Bank (PDB) and other sources shows that there is a limited degree of commonality in nomenclature, but a large measure of irregularity in more complex structures. The recommendations described here adhere to established practice as closely as possible, in particular to IUPAC and IUBMB recommendations and to “best practice” in the PDB, especially to its atom labelling of amino acids, and particularly to Cahn-Ingold-Prelog rules for stereochemical nomenclature. They are designed to work in complex enzyme sites for binding phosphates but also to have utility for non-enzymatic systems. Above all, the recommendations are designed to be easy to comprehend and user-friendly.