Nuclear magnetic resonance (NMR) studies of complex cellular responses: isotopomer sub-spaces, 'lost' ATP and 'tunable' anisotropy. Red blood cells (RBCs) transport oxygen around the body but they have other roles that are mediated by complex interconnecting metabolic pathways that generate myriad metabolites including ATP. A longstanding conundrum is the inability to account for ~60% of ATP turnover in human RBCs. Processes that may consume this 'lost' ATP, include autonomous motion of the cel ....Nuclear magnetic resonance (NMR) studies of complex cellular responses: isotopomer sub-spaces, 'lost' ATP and 'tunable' anisotropy. Red blood cells (RBCs) transport oxygen around the body but they have other roles that are mediated by complex interconnecting metabolic pathways that generate myriad metabolites including ATP. A longstanding conundrum is the inability to account for ~60% of ATP turnover in human RBCs. Processes that may consume this 'lost' ATP, include autonomous motion of the cell membrane called 'flickering', and maintenance of the biconcave-disc shape. NMR spectroscopy of quadrupolar nuclei in chiral aligned media, and isotopomer analysis will be used to define the kinetics of metabolism and membrane processes and thus help define the molecular basis of major blood disorders. Read moreRead less
NMR Spectroscopy of Complex Cellular Processes. The Theme is the cell viewed as a complex regulated molecular assembly. The Aim is to establish an integrated mathematical model of red cell metabolism, membrane transport, shape, and mechanical properties, principally by using NMR spectroscopy. The Significance will be discovery of new aspects of cellular structure and function, and new NMR theory for molecular bioscience. Outcomes will include new NMR measurements of kinetics of metabolic reactio ....NMR Spectroscopy of Complex Cellular Processes. The Theme is the cell viewed as a complex regulated molecular assembly. The Aim is to establish an integrated mathematical model of red cell metabolism, membrane transport, shape, and mechanical properties, principally by using NMR spectroscopy. The Significance will be discovery of new aspects of cellular structure and function, and new NMR theory for molecular bioscience. Outcomes will include new NMR measurements of kinetics of metabolic reactions, rates of membrane transport, solute diffusion, and functions of key membrane- and cytoskeletal proteins. Practical applications will include strategies for modelling complex biochemical systems, and circumventing metabolic defects arising from inheritance, the environment, and therapies.Read moreRead less