Abstract
Stable isotope tracers have been invaluable assets in physiological research for over 80 years. The application of substrate-specific stable isotope tracers has permitted exquisite insight into amino acid, fatty-acid and carbohydrate metabolic regulation (i.e. incorporation, flux, and oxidation, in a tissue-specific and whole-body fashion) in health, disease and response to acute and chronic exercise. Yet, despite many breakthroughs, there are limitations to 'substrate-specific' stable isotope tracers, which limit physiological insight, e.g. the need for intravenous infusions and restriction to short-term studies (hours) in controlled laboratory settings. In recent years significant interest has developed in alternative stable isotope tracer techniques that overcome these limitations, in particular deuterium oxide (D2 O or heavy water). The unique properties of this tracer mean that through oral administration, the turnover and flux through a number of different substrates (muscle proteins, lipids, glucose, DNA (satellite cells)) can be monitored simultaneously and flexibly (hours/weeks/months) without the need for restrictive experimental control. This makes it uniquely suited for the study of 'real world' human exercise physiology (amongst many other applications). Moreover, using D2 O permits evaluation of turnover of plasma and muscle proteins (e.g. dynamic proteomics) in addition to metabolomics (e.g. fluxomics) to seek molecular underpinnings, e.g. of exercise adaptation. Here, we provide insight into the role of stable isotope tracers, from substrate-specific to novel D2 O approaches, in facilitating our understanding of metabolism. Further novel potential applications of stable isotope tracers are also discussed in the context of integration with the snowballing field of 'omic' technologies.
Highlights
Daniel Wilkinson (Assistant Professor), Matthew Brook (Post-Doctoral Research Associate), Ken Smith (Principal Research Fellow) and Philip Atherton (Professor) work within the MRC-ARUK Centre for Musculoskeletal Ageing Research at the University of Nottingham
Their research is involved in identification of the central mechanisms regulating metabolism in human musculoskeletal tissues, those that govern the regulation of protein metabolism in response to ageing and disease
Recent developments within the group have focused on the application of novel deuterium oxide (D2O)-based stable isotope tracer techniques and how these can be integrated alongside ‘omic’ techniques, such as proteomics and metabolomics, to provide a better holistic understanding of the regulation of metabolism
Summary
Daniel Wilkinson (Assistant Professor), Matthew Brook (Post-Doctoral Research Associate), Ken Smith (Principal Research Fellow) and Philip Atherton (Professor) work within the MRC-ARUK Centre for Musculoskeletal Ageing Research at the University of Nottingham. The group has extensive experience of using and developing stable isotope tracer techniques and applying them to human metabolic research. Recent developments within the group have focused on the application of novel D2O-based stable isotope tracer techniques and how these can be integrated alongside ‘omic’ techniques, such as proteomics and metabolomics, to provide a better holistic understanding of the regulation of metabolism.
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