Abstract
The study of metabolic fuel provision and its regulation has reached an exciting stage where specific molecular events can be correlated with parameters of the organism's ecology. This paper examines substrate supply pathways from storage sites to locomotory muscle mitochondria and discusses ecological implications of the limits for maximal flux through these pathways. The relative importance of the different oxidative fuels is shown to depend on aerobic capacity. Very aerobic, endurance-adapted animals such as long distance migrants favor the use of lipids and intramuscular fuels over carbohydrates and circulatory fuels. The hypothesis of functional co-adaptation between oxygen and metabolic fuel supply systems allows us to predict that the capacity of several biochemical processes should be scaled with maximal oxygen consumption. Key enzymes, transmembrane transporter proteins, glucose precursor supply and soluble fatty acid transport proteins must all be geared to support higher maximal glucose and fatty acid fluxes in aerobic than in sedentary species.
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References
Bailey, E., Insect Biochemistry and Function. Eds D. J. Candy and B. A. Kilby. Chapman and Hall, London 1975.
Baker, R. R., The Evolutionary Ecology of Animal Migration. Holmes and Meyer, New York 1978.
Baldwin, S. A., and Lienhard, G. E., Glucose transport across plasma membranes: facilitated diffusion systems. T.I.B.S. August (1981) 208–211.
Brooks, G. A., Lactate: glycolytic end product and oxidative substrate during sustained exercise in mammals — The “lactate shuttle”, in: Circulation, Respiration, and Metabolism. Current Comparative Approaches. Ed. R. Gilles. Springer-Verlag, New York 1985.
Bulow, J., Subcutaneous adipose tissue blood flow and triacylglycerol mobilization during prolonged exercise in dogs. Pflügers Arch.392 (1982) 230–234.
Burczynski, F. J., Cai, Z. S., Moran, J. B., and Forker, E. L., Palmitate uptake by cultured hepatocytes: albumin binding and stagnant layer phenomena. Am. J. Physiol.257 (1989) G584-G593.
Cahill, G. F. J., Physiology of gluconeogenesis, in: Hormonal Control of Gluconeogenesis, vol. 1, pp. 3–13. Ed. N. Kraus-Freidman. CRC Press, Inc, Boca Raton, Florida 1986.
Calles, J., Cunningham, J. J., Jacob, R., Loke, J., Husgar, J., and Felig, P., Influence of exercise on urea, creatinine, and 3-methylhistidine excretion in normal man. Am. J. Physiol.246 (1984) E334-E338.
Carraro, F., Hartl, W. H., Stuart, C. A., Layman, D. K., Jahoor, F., and Wolfe, R. R., Whole body and plasma protein synthesis in exercise and recovery in human subjects. Am. J. Physiol.258 (1990) E821-E831.
Carruthers, A., Facilitated diffusion of glucose. Physiol. Rev.70 (1990) 1135–1176.
Clarke, S. D., and Armstrong, M. K., Cellular lipid binding proteins: expression, function, and nutritional regulation. FASEB J.3 (1989) 2480–2487.
Felig, P., Owen, O. E., Wahren, J., and Cahill, G. F., Amino acid metabolism during prolonged starvation. J. clin. Invest.48 (1969) 584–594.
Felig, P., and Wahren, J., Fuel homeostasis in exercise. New Engl. J. Med.293 (1975) 1078–1084.
French, C. J., Hochachka, P. W., and Mommsen, T. P., Metabolic organization of liver during spawning migration of Sockeye salmon. Am. J. Physiol.245 (1983) R827-R830.
Friedman, M. I., Ramirez, I., Bowden, C. R., and Tordoff, M. G., Fuel partitioning and food intake: role for mitochondrial fatty acid transport. Am. J. Physiol.258 (1990) R216-R221.
Fushiki, T., Wells, J. A., Tapscott, E. B., and Dohm, G. L., Changes in glucose transporters in muscle in response to exercise. Am. J. Physiol.256 (1989) E580–587.
Gessaman, J. A., and Nagy, K. A., Energy metabolism: errors in gas-exchange conversion factors. Physiol. Zool.61 (1988) 507–513.
Glatz, J. F. C., Van der Vusse, G. J., and Veerkamp, J. H., Fatty acid-binding proteins and their physiological significance. N.I.P.S.3 (1988) 41–43.
Gleeson, T. T., and Dalessio, P. M., Lactate: a substrate for reptilian muscle gluconeogenesis following exhaustive exercise. J. comp. Physiol. B160 (1990) 331–338.
Goodyear, L. J., Hirshman, M. F., King, P. A., Horton, E. D., Thompson, C. M., and Horton, E. S., Skeletal muscle plasma membrane glucose transport and glucose transporters after exercise. J. appl. Physiol.68 (1990) 193–198.
Goodyear, L. J., King, P. A., Hirshman, M. F., Thompson, C. M., Horton, E. D., and Horton, E. S., Contractile activity increases plasma membrane glucose transporters in absence of insulin. Am. J. Physiol.258 (1990) E667-E672.
Gould, G. W., and Bell, G. I., Facilitative glucose transporters: an expanding family. T.I.B.S.15 (1990) 18–23.
Green, H. J., Reichemann, H., and Pette, D., Fibre type specific transformation in the enzyme activity pattern of rat vastus lateralis muscle by prolonged endurance training. Pflugers Arch. ges. Physiol. 399 (1983) 216–222.
Groen, A. K., Van Roermund, C. W. T., Vervoorn, R. C., and Tager, J. M., Control of gluconeogenesis in rat liver cells. Biochem. J.237 (1986) 379–389.
Hirshman, M. F., Waalberg-Henriksson, H., Wardzala, L. J., Horton, E. D., and Horton, E. S., Acute exercise increases the number of plasma membrane glucose transporters in rat skeletal muscle. FEBS Letters238 (1988) 235–239.
Hochachka, P. W., Fuels and pathways as designed systems for support of muscle work. J. exp. Biol.115 (1985) 149–164.
Hochachka, P. W., Dobson, G. P., and Mommsen, T. P., Role of isozymes in metabolic regulation during exercise: Insights from comparative studies, in: Isozymes: Current Topics in Biological and Medical Research, vol. 8, pp. 91–113. Eds M. C. Rattazzi, J. G. Scandalics and G. S. Whitt. Alan R. Liss, New York 1983.
Hochachka, P. W., and Somero, G. N., Strategies of Biochemical Adaptation. W. B. Saunders, Philadelphia 1973.
Hue, L., The role of futile cycles in the regulation of carbohydrate metabolism in the liver. Adv. Enzymol.52 (1980) 247–331.
Hultman, E., and Harris, R. C., Carbohydrate metabolism, in: Principles of Exercise Biochemistry, vol. 27, pp. 78–119. Ed. J. R. Poortmans. Karger, Basel 1988.
Hurley, B. F., Nemeth, P. M., Martin, W. H. I., Hagberg, J. M., Dalsky, G. P., and Holloszy, J. O., Muscle triglyceride utilization during exercise: effect of training. J. appl. Physiol.60 (1986) 562–567.
James, D. E., Strube, M., and Mueckler, M., Molecular cloning and characterization of an insulin-regulatable glucose transporter. Nature338 (1989) 83–87.
Jenni-Eiermann, S., and Jenni, L., Metabolic responses to flight and fasting in night-migrating passerines. J. comp. Physiol.161 (1991) 465–474.
Kaufmann, M., Simoneau, J.-A., Veerkamp, J. H., and Pette, D., Electrostimulation-induced increases in fatty acid-binding protein and myoglobin in rat fast-twitch muscle and comparison with tissue levels in heart. FEBS Lett.245 (1989) 181–184.
Martin, B. R., Metabolic Regulation. A Molecular Approach. Blackwell Scientific Publications, Oxford 1987.
Miyoshi, H., Shulman, G. I., Peters, E. J., Elahi, D., and Wolfe, R. R., Hormonal control of substrate cycling in humans. J. clin. Invest.81 (1988) 1545–1555.
Molé, P. A., Exercise metabolism, in: Exercise Medicine: Physiological Principles and Clinical Applications, pp. 43–88. Eds. A. A. Bove and D. T. Lowenthal. Academic Press, New York 1983.
Mommsen, T. P., Comparative gluconeogenesis in hepatocytes from salmonid fishes. Can. J. Zool.64 (1986) 1110–1115.
Mommsen, T. P., French, C. J., and Hochachka, P. W., Sites and patterns of protein and amino acid utilization during the spawning migration of salmon. Can. J. Zool.58 (1980) 1785–1799.
Moon, T. W., Adaptation, constraint, and the function of the gluconeogenic pathway. Can. J. Zool.66 (1988) 1059–1068.
Newsholme, E. A., Application of knowledge of metabolic integration to the problem of metabolic limitations in sprints, middle distance and marathon running, in: Principles of Exercise Biochemistry, vol. 27, pp. 194–211. Ed. J. R. Poortmans. Karger, Basel 1988.
Nordlie, R. C., Metabolic regulation by multifunctional glucose-6-phosphatase, in: Current Topics in Cellular Regulation, vol. 8, pp. 33–117. Eds B. L. Horecker and E. R. Stadtman. Academic Press, New York 1974.
Peters, R. H., The Ecological Implications of Body Size. Cambridge University Press, Cambridge 1983.
Pilkis, J. S., Claus, T. H., and Raafat El-Maghrabi, M., The role of cyclic AMP in rapid and long-term regulation of gluconeogenesis and glycolysis. Advances in Second Messenger and Phosphoprotein Research22 (1988) 175–191.
Rennie, M. J., Edwards, R. H. T., Halliday, D., Davies, C. T. M., Matthews, D. E., and Millward, D. J., Protein metabolism during exercise, in: Nitrogen Metabolism in Man, pp. 509–523. Eds J. C. Waterlow and J. M. L. Stephen. Applied Science Publishers, London 1981.
Roberts, T. J., Weber, J.-M., and Taylor, C. R., Does fuel preference dependend on aerobic capacity? Fat and carbohydrate oxidation in running coyotes, dogs, and goats. The Physiologist33 (1990) A-110.
Rose, C. P., and Goresky C. A., Constraints on the uptake of labeled palmitate by the heart. Circ. Res.41 (1977) 534–545.
Sahlin, K., Metabolic changes limiting muscle performance, in: Biochemistry of Exercise, vol. 6, pp. 323–343. Ed. B. Saltin. Human Kinetics Publishers, Champaign, IL 1986.
Sams, G. H., Hargis, B. M., and Hargis, P. S., Isolation and characterization of a fatty acid binding protein in adipose tissue of Gallus domesticus. FASEB J.4 (1990) A779.
Sinclair, A. R. E., The function of distance movements in vertebrates, in: The Ecology of Animal Movement, pp. 240–258. Eds I. R. Swingland and P. J. Greenwood, Clarendon Press, Oxford 1983.
Soop, M., Bjorkman, O., Cederblad, G., hagenfeld, L., and Wahren, J., Influence of carnitine supplementation on muscle substrate and carnitine metabolism during exercise. J. appl. Physiol.64 (1988) 2394–2399.
Stewart, J. M., and Driedzic, W. R., Fatty acid binding proteins in teleost fish. Can. J. Zool.66 (1988) 2671–2675.
Stremmel, W., Fatty acid uptake by isolated rat heart myocytes represents a carrier-mediated transport process. J. clin. Invest.81 (1988) 844–852.
Stremmel, W., and Berk, P. D., Hepatocellular influx of [14C]oleate reflects membrane transport rather than intracellular metabolism or binding. Proc. natl Acad. Sci.83 (1986) 3086–3090.
Stremmel, W., Strohmeyer, G., and Berk, P. D., Hepatocellular uptake of oleate is energy dependent, sodium linked, and inhibited by an antibody to a hepatocyte plasma membrane fatty acid binding protein. Proc. natl Acad. Sci.83 (1986) 3584–3588.
Suarez, R. K., and Mommsen, T. P., Gluconeogenesis in teleost fish. Can. J. Zool.65 (1987) 1869–1882.
Taylor, C. R., Scaling limits of metabolism to body size: implications for animal design, in: A Companion to Animal Physiology, pp. 161–170. Eds C. R. Taylor, K. Johansen and L. Bolis Cambridge University Press, Cambridge 1982.
Taylor, C. R., Karas, R. H., Weibel, E. R., and Hoppeler, H., Adaptive variation in the mammalian respiratory system in relation to energetic demand. Resp. Physiol.69 (1987) 1–127.
Van der Horst, D. J., Lipid transport function of lipoproteins in flying insects. Biochim. biophys. Acta1047 (1990) 195–211.
Vilaro, S., Palacin, M., Pilch, P. F., Testar, X., and Zorzano, A., Expression of an insulin-regulatable glucose carrier in muscle and fat endothelial cells. Nature342 (1989) 798–800.
Wasserman, D. H., and Cherrington, A. D., Hepatic fuel metabolism during muscular work: role and regulation. Am. J. Physiol.260 (1991) E811-E824.
Weber, J-M., Design of exogenous fuel supply systems: adaptive strategies for endurance locomotion. Can. J. Zool.66 (1988) 1116–1121.
Weber, J-M., Effect of endurance swimming on the lactate kinetics of rainbow trout. J. exp. Biol.158 (1991) 463–476.
Weber, J.-M., Brill, R. W., and Hochachka, P. W., Mammalian metabolite flux rates in a teleost: lactate and glucose turnover in tuna. Am. J. Physiol.250 (1986) R452-R458.
Weber, J.-M., Parkhouse, W. S., Dobson, G. P., Harman, J. C., Snow, D. H., and Hochachka, P. W., Lactate kinetics in exercising thorough-bred horses: regulation of turnover rate in plasma. Am. J. Physiol.253 (1987) R896-R903.
Weibel, E. R., The Pathway for Oxygen. Structure and Function in the Mammalian Respiratory System. Harvard University Press, Cambridge, MA 1984.
Weibel, E. R., and Taylor, C. R., Design of the mammalian respiratory system. Respir. Physiol.44 (1981) 1–164.
Weibel, E. R., Taylor, C. R., and Hoppeler, H., The concept of symmorphosis: a testable hypothesis of structure-function relationship. Proc. natl. Acad. Sci.88 (1991) 10357–10361.
Widnell, C. C., Baldwin, S. A., Davies, A., Martin, S., and Pasternak, C. A., Cellular stress induces a redistribution of the glucose transporter. FASEB J.4 (1990) 1634–1637.
Wolfe, R. R., Does exercise stimulate protein breakdown in humans? Isotopic approaches to the problem. Med. Sci. Sports Exercise19 (1987) 172–178.
Wolfe, R. R., Klein, S., Carraro, F., and Weber, J.-M., Role of triglyceride-fatty acid cycle in controlling fat metabolism in humans during and after exercise. Am. J. Physiol.258 (1990) E382-E389.
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Weber, J.M. Pathways for oxidative fuel provision to working muscles: Ecological consequences of maximal supply limitations. Experientia 48, 557–564 (1992). https://doi.org/10.1007/BF01920239
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DOI: https://doi.org/10.1007/BF01920239