Effects of Reduced Renal Mass and Dietary Protein Intake on Amino Acid Release and Glucose Uptake by Rat Muscle In Vitro

Abstract

Epitrochlearis muscles obtained from normal male Holtzman rats used as controls (C) and rats with reduced renal mass (Nx) fed isocaloric diets of varying protein content were incubated in Krebs-Ringer buffer containing 5 mM glucose for 1 or 3 h with or without insulin. Alanine (ALA) release rates from muscles of Nx rats were increased 40% above C values after 1 h of incubation regardless of protein intake. Addition of insulin decreased the ALA release from muscles of Nx rats to C values in animals fed 10 and 20% casein and chow but did not in rats fed 40% casein. After 3 h of incubation, all ALA release rates decreased by ≅40%. The ALA release from muscles of Nx rats fed 10% casein was comparable to C values and decreased further with the addition of insulin. On the other hand, ALA release from muscles of Nx rats fed 20 and 40% casein as well as chow remained significantly elevated above C values, but responded to the addition of insulin with a reduction in release rates to C values, except from the muscles of Nx animals fed 40% casein. Tyrosine (TYR) and phenylalanine (PHE) release rates also were increased in muscles from Nx rats compared with C after 1 h of incubation. Release rates were highest in the Nx group fed 10% casein and decreased with increasing protein intake. Addition of insulin decreased the release rates of Nx rats to C values in each group. After 3 h of incubation, release rates of TYR and PHE in muscles from Nx rats remained significantly above C values for all groups, but responded to the addition of insulin with a decrease to C values. Glutamine and glutamate release were not significantly affected by reduction in renal mass. Base-line glucose uptake by all groups of muscles from Nx rats was significantly greater than corresponding C values, but maximal insulin-stimulated glucose uptake was comparable in all groups. Tissue pool sizes for glycogen, ATP, phosphocreatine, ALA, glutamate, and glutamine were unaffected by reduction in renal mass. The results indicate that Nx is associated with accelerated ALA, TYR, and PHE release from muscle. ALA release rose with increasing protein intake and decreased to values observed from C muscles after addition of insulin except in Nx animals fed 40% casein. TYR and PHE release decreased with increasing protein intake and also decreased to C values with the addition of insulin. The data also suggest that ALA release is not dependent upon glucose uptake in muscles from either C or Nx rats.