Abstract
Underfeeding (50% ad libitum) resulted in marked retardation of growth which was nearly a 50% reduction at 12 months of age for males and a 34% reduction for females. The retardation of female growth was not as severe as that of male. Various organ weights showed a pattern similar to total body growth. Moisture content tends to decrease with age but it is statistically insignificant. Protein concentration of male showed a gradual increase up to eight months, then remained constant throughout the test period. Unlike protein content in the male, female protein concentration remained fairly constant from one to twelve months in ad libitum feeding. However, protein levels in 50% ad libitum female tissues tended to decrease with age. Zinc content in liver, kidney, and brain showed a gradual increase to 8 months then decreased. Zinc content in bone showed a rapid increase before leveling off. The zinc level in the bone was consistently higher than any other tissues examined. A gradual increase was observed in copper content of liver and kidney in the ad libitum fed groups whereas a rapid increase was observed in the 50% ad libitum fed group before leveling off to relatively constant concentrations. Manganese levels in all tissues remained constant except in the brain. Brain manganese content tended to increase with age. Among the parameters studied, there was a significant retardation of organ and body growth with diet manipulation. Supplementation of trace minerals (Cu, Mn, Zn) in the diet reduced mortality rate. Protein content was the only significant difference observed between sexes or dietary groups.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Burch, R. E., Sullivan, J. F., Jetton, M. M., and Hahn, H.K.J.: The effect of aging on trace element content of various rat tissue. I. Early Stages of Aging. Age, 2:103–107, 1979.
McCay, C. M., Crowell, M. F., and Maynard, L. A.: Effect of retarded growth upon length of life span and upon ultimate body size. J. Nutr., 10:63–79, 1935.
McCay, C. M., Maynard, L. A., Sperling, G., and Barnes, L. L.: Retarded growth, life span, ultimate body size and age changes in the albino rat after feeding diets restricted in calories. J. Nutr., 18:1–13, 1939.
Berg, B. N., and Simms, H. S.: Nutrition and longevity in rat. II. Longevity and onset of disease with different levels of food intake. J. Nutr., 71:255–263, 1960.
Ross, M. H.: Length of life and nutrition in the rat. J. Nutr., 75:197–210 (1961).
Nolen, G. A.: Effect of various restricted dietary regimes on the growth, health and longevity of albino rats. J. Nutr., 102:1477–1494, 1972.
Barrows, Jr., C. H., and Kokkonen, G. C.: Protein synthesis, development, growth and life span. Growth, 39:525–533, 1975.
Ross, M. H.: Length of life and caloric intake. Am. J. Clin. Nutr., 25:834–838, 1972.
Barrows, Jr., C. H., and Roeder, L. M.: The effect of reduced dietary intake on enzymatic activities and life span of rats. J. Gerontol., 20:69–71, 1965.
Ross, M. H., and Bras, G.: Influence of protein under and over nutrition on spontaneous tumor prevalence in the rat. J. Nutr., 103:944–963, 1973.
Nakagawa, I., Sasaki, A., Kajinoto, M., Fukuyama, T., Suzuki, T., and Yama, E.: Protein nutrition and aging. J. Nutr. Sci. Vitaminol, 21:217–222, 1975.
French, C. E., Ingram, R. H., Uram, J. A., Barron, G. P., and Swift, R. W.: The influence of dietary fat and carbohydrate on growth and longevity in rats. J. Nutr., 51:329–339, 1953.
Silberberg, M., and Silberberg, R.: Factors modifying the lifespan of mice. Am. J. Physiol., 177: 23–26, 1954.
Linder, M. C., and Munro, H. N.: Iron and copper metabolism during development. Enzyme, 15:111–138, 1973.
Persigehl, M., Schicka, H., Kasperik, K., and Klein, H. J.: Trace element concentration in human organs in dependence of age. Bertr. Path., 161:209–220, 1977.
Hsu, J. M.: Current knowledge on zinc, copper and chromium in aging. Wid. Rev. Nutr. Diet., 33:42–69, 1979.
Schumuker, D. L., and Wang, R. K.: Effect of animal age and phenobarbitol on rat liver glucose-6-phosphatase activity. Exp. Geront., 15:7–13, 1980.
Gold, G., and Widnell, C. C.: Reversal of age-related changes in microsomal enzyme activities following the administration of triam-cinolone, triodothyronine and phenobarbitol. Biochim. Biophys. Acta., 334:75–85, 1974.
Kaneta, N.: Histochemical studies on the diencephalon of senescent rats. Tohoku U. Expl. Med., 90: 249–258, 1966.
Nutrient Requirements of Laboratory Animals, National Academy of Sciences, Washington, D.C., 1978.
Wilson, P. D.: Enzyme patterns in young and old mouse liver and lungs. Gerontologia, 18:36–54, 1972.
Report of the AIN Ad Hoc Committee on Standards for Nutritional Studies, J. Nutr. 107:1340–1348, 1977.
Lowry, O. H., Rosebrough, N. J., Farr, A. L., and Randall, R. J.: Protein measurement with the folin pehnol reagent. J. Biol. Chem., 193:265–275, 1951.
Hahn, H.K.J., Tuma, D. J., and Sullivan, J. L.: Rapid and simple continuous radiochemical separation of copper, magnesium, zinc and manganese in biological materials. Anal. Chem., 40:974–976, 1968.
Analytical methods for atomic absorption spectrophotometry. Perkin Elmer Corp., Norwalk, Conn., 1976.
Author information
Authors and Affiliations
About this article
Cite this article
Burch, R.E., Hahn, H.K.J. The effect of aging on rat tissue content of moisture, protein, zinc, copper, and manganese with partial food deprivation: II. Middle stages of aging. AGE 5, 80–86 (1982). https://doi.org/10.1007/BF02431712
Issue Date:
DOI: https://doi.org/10.1007/BF02431712