A Metabolic Roadmap for Somatic Stem Cell Fate.

While metabolism was initially thought to play a passive role in cell biology by generating ATP to meet bioenergetic demands, recent studies have identified critical roles for metabolism in the generation of new biomass and provision of obligate substrates for the epigenetic modification of histones and DNA. This review details how metabolites generated through glycolysis and the tricarboxylic acid cycle are utilized by somatic stem cells to support cell proliferation and lineage commitment. Importantly, we also discuss the evolving hypothesis that histones can act as an energy reservoir during times of energy stress. Finally, we discuss how cells integrate both extrinsic metabolic cues and intrinsic metabolic machinery to regulate cell fate.

Measuring Mitochondrial Substrate Utilization in Skeletal Muscle Stem Cells.

Skeletal muscle stem cells (MuSCs) derived from the somatic mesoderm play a critical role in successful muscle regeneration following injury and trauma. MuSCs have been found to undergo rapid changes in metabolism following a change in cell state, such as that which occurs during the transition from quiescence to an actively proliferating state. There is mounting evidence that metabolism is critically important in the regulation of quiescence, activation, and differentiation and thus the development of new techniques that aim to further probe the metabolism of MuSCs is essential. The Seahorse XF Bioanalyzer is a powerful tool that simultaneously measures the extracellular rate of change in oxygen partial pressure and pH, providing a method to measure mitochondrial respiration and lactate production. In this chapter, we describe the use of key metabolic inhibitors that allow for the investigation of mitochondrial substrate utilization in primary MuSCs.

A metabolic link to skeletal muscle wasting and regeneration.

Due to its essential role in movement, insulating the internal organs, generating heat to maintain core body temperature, and acting as a major energy storage depot, any impairment to skeletal muscle structure and function may lead to an increase in both morbidity and mortality. In the context of skeletal muscle, altered metabolism is directly associated with numerous pathologies and disorders, including diabetes, and obesity, while many skeletal muscle pathologies have secondary changes in metabolism, including cancer cachexia, sarcopenia and the muscular dystrophies. Furthermore, the importance of cellular metabolism in the regulation of skeletal muscle stem cells is beginning to receive significant attention. Thus, it is clear that skeletal muscle metabolism is intricately linked to the regulation of skeletal muscle mass and regeneration. The aim of this review is to discuss some of the recent findings linking a change in metabolism to changes in skeletal muscle mass, as well as describing some of the recent studies in developmental, cancer and stem-cell biology that have identified a role for cellular metabolism in the regulation of stem cell function, a process termed "metabolic reprogramming."