Glucose and amino acid metabolism in neonatal rat skeletal muscle in tissue culture

Abstract

The characteristics of glucose and amino acid metabolism over a 98‐hour incubation period were studied in a primary culture of neonatal rat skeletal muscle cells. The cells formed large myotubes in culture, were spontaneously highly contractile, and had cell phosphocreatine levels exceeding ATP concentrations. Medium glucose fell from 7.2±0.2 to 1.5±0.1 mM between 0 and 98 hours; intracellular glucose was readily detectable, indicating glycolysis was limited by phosphorylation, not glucose transport. Alanine levels in the medium increased from 0.06±0.01 to 0.82±0.04 mM between 0 and 48 hours and decreased to 0.72±0.04 mM by 98 hours. The period of net alanine production correlated with the rise in the cell mass action ratio of the alanine aminotransferase reaction. Cell aspartate, glutamate, and calculated oxalacetate levels were inversely related to the cell NADH/NAD^+^ ratio, as represented by the intracellular lactate/pyruvate ratio (r=0.78–0.88). The branched chain amino acids (leucine, isoleucine, valine) were actively utilized, e.g., medium leucine fell from 0.70±0.01 to 0.30±0.06 mM between 0 and 98 hours. In addition, arginine and serine consumption was observed in conjunction with ornithine, proline, and glycine production. Conclusions: (1) A major driving force for the high rates of alanine production by skeletal muscle cells in tissue culture is the active utilization of branched chain amino acids. (2) Intracellular aspartate and glutamate pools are linked, probably via the malate‐aspartate shuttle, to the cell NADH/NAD^+^ redox state. (3) Muscle cells in tissue culture metabolize significant amounts of arginine and serine in association with the production of ornithine and proline, and these pathways may possibly be related to creatine production.