Abstract
A thermodynamic model describing the relation between plant growth and respiration rates is derived from mass-and enthalpy-balance equations. The specific growth rate and the substrate carbon conversion efficiency are described as functions of the metabolic heat rate, the rate of CO2 production, the mean oxidation state of the substrate carbon produced by photosynthesis, and enthalpy changes for conversion of photosynthate to biomass and CO2. The relation of this new model to previous models based only on mass-balance equations is explored. Metabolic heat rate is shown to be a useful additional measure of respiration rates in plant tissues because it leads to a more explicit description of energy relations. Preliminary data on three Zea mays (L.) cultivars are reported. The model suggests new rationales for plant selection, breeding and genetic engineering that could lead to development of plants with more desirable growth rates.
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References
Amthor, J.S. (1989) Respiration and crop productivity. Springer-Verlag, New York
Anekonda, T.S. (1992) Ph.D. Dissertation, University of California, Berkeley
Anekonda, T.S., Criddle, R.S., Breidenbach, R.W., Hansen, L.D. (1994) Respiration rates predict differences in growth of coast redwood. Plant Cell Environ., in press
Beevers, H. (1970) Respiration in plants and its regulation. In: Prediction and measurement of photosynthetic productivity. Proceedings of the IBP/PP Technical Meeting, Trebon, Sept. 1969
Criddle, R.S., Breidenbach, R.W., Rank, D.R., Hopkin, M.S., Hansen, L.D. (1990) Simultaneous calorimetric and respirometric measurements on plant tissues. Thermochim. Acta 172, 213–221
Criddle, R.S., Fontana, A.J., Rank, D.R., Paige, D., Hansen, L.D., Breidenbach, R.W. (1991a) Simultaneous measurement of metabolic heat rate, CO2 production and O2 consumption by microcalorimetry. Anal. Bioch. 194, 413–417
Criddle, R.S., Breidenbach, R.W., Hansen, L.D. (1991b) Plant calorimetry: How to quantitatively compare apples and oranges, Thermochim. Acta 193, 67–90
Criddle, R.S., Hopkin, M.S., McArthur, E.D., Hansen, L.D. (1993) Plant distribution and the temperature coefficient of respiration. Plant Cell Environ., in press
Domalski, E.S. (1972) Selected values of heats of combustion and heats of formation of organic compounds containing the elements C, H, N, O, P, and S. J. Phys. Chem. Ref. Data 1, 221–277
Erickson, L.E. (1987) Energy requirements in biological systems. In: Thermal and energetic studies of cellular biological systems, pp. 14–33, James, A.M., ed. IOP Publishing Limited, Bristol
Fitter, A.H., Hay, R.K.M. (1987) Environmental physiology of plants, 2nd edn., pp. 46–48, Academic Press Inc., San Diego
Geider, R.J., Osborne, B.A. (1989) Respiration and microalgal growth: a review of the quantitative relationship between dark respiration and growth. New Phytol. 112, 327–341
Hansen, L.D., Lewis, E.A., Eatough, D.J., Fowler, D.P., Criddle, R.S. (1989) Prediction of long-term growth rates of larch clones by calorimetric measurement of metabolic heat rates. Can. J. Forestry Res. 19, 606–611
Hansen, L.D., Woodward, R.A., Breidenbach, R.W., Criddle, R.S. (1992) Dark metabolic heat rates and integrated growth rates of coast redwood clones are correlated. Thermochim. Acta 211, 21–32
Hay, R.K.M., Walker, A.J. (1989) An introduction to the physiology of crop yield. Longman Scientific and Technical, Essex
Herms, D.A., Mattson, W.J. (1992) The dilemma of plants: To grow or defend. Quart. Rev. Biol. 67, 283–335
Hopkin, M.S. (1991) Ph.D. Dissertation, Brigham Young University, Provo, Utah
Kraus, E., Aydemir, Y., Duin, S., Kollöffel, C., Lambers, H. (1993) Yield advantage of a ‘slow-’ over a ‘fast-’ respiring population of Lolium perenne cv. S23 depends on plant density. New Phytol. 123, 39–44
Lambers, H. (1985) Respiration in intact plants and tissues: Its regulation and dependence on environmental factors, metabolism and invaded organisms. In: Higher plant cell respiration, pp. 418–473, Douce, R., Day, D.A. eds. Springer-Verlag, Berlin
Loomis R.S. (1982) McDermitt's method for relating elemental composition of plant materials to respiration and yield. Iowa State J. Res. 56, pp. 281–289
McCree, K.J. (1970) An equation for the respiration of white clover plants grown under controlled conditions. In: Prediction and measurement of photosynthetic productivity, pp. 221–229, Setlik, I. ed. Pudoc, Wageningen
McDermitt, D.K., Loomis R.S. (1981) Elemental composition of biomass and its relation to energy content, growth efficiency and growth yield. Ann. Bot. 48, 275–290
Penning de Vries, F.W.T., Brunsting, A.H.M., van Laar, H.H. (1974) Products, requirements and efficiency of biosynthesis: a quantitative approach. J. Theor. Biol. 45, 339–377
Poorter, H., Remkes, C., Lambers, H. (1990) Carbon and nitrogen economy of 24 wild species differing in relative growth rate. Plant Physiol. 94, 621–627
Rank, D.R., Breidenbach, R.W., Hansen, L.D. (1991) Time-temperature responses of tomato cells during high and low-temperature inactivation. Planta 185, 576–582
Robson, M.J. (1982) The growth and carbon economy of selected lines of Lolium perenne cv. S23 with differing rates of dark respiration. 2. Grown as young plants from seed. Ann. Bot. 49, 331–339
Ryle, G.J.A. (1984) Respiration and plant growth. In: The physiology and biochemistry of plant respiration, pp. 3–16, Palmer, I.M. ed. Cambridge University Press, Cambridge, UK
Thornley, J.H.M. (1970) Respiration, growth and maintenance in plants. Nature 227, 304–305
Thornley, J.H.M., Johnson, I.R. (1990) Plant and crop modeling: A mathematical approach to plant and crop physiology. Oxford University Press, Oxford
Wadsö, I. (1988) Thermochemistry of living cell systems. In: Biochemical thermodynamics (2nd edn.), Chpt. 6, Jones, M.N. ed. Elsevier, Amsterdam
Williams, K., Percival, F., Merino, J., Mooney H.A. (1987) Estimation of tissue construction cost from heat of combustion and organic nitrogen content. Plant Cell Environ. 10, 725–734
Wilson, D. (1975) Variation in leaf respiration in relation to growth and photosynthesis of Lolium. Ann. Applied Biol. 80, 323–338
Wilson, D. (1982) Response to selection for dark respiration rate of mature leaves in Lolium perenne and its effects on growth of young plants and simulated swards. Ann. Bot. 49, 303–312
Wilson, D., Jones, J.G. (1982) Effects of selection for dark respiration rate of mature leaves on crop yields of Lolium perenne cv. S23. Ann. Bot. 49, 313–320
Wohl, K., James, W.O. (1942) The energy changes associated with plant respiration. New Phytol. 41, 230–256
Yamaguchi, J. (1978) Respiration and the growth efficiency in relation to crop productivity. J. Fac. Agric. Hokkaido Univ. 59, 59–129
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The authors thank Deann K. Taylor for assistance with laboratory work, Clifford W. Hansen for discussions concerning the form of the equations presented and Pioneer Hi-Bred International, Inc. and Dole Packaged Foods for partial financial support of the work.
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Hansen, L.D., Hopkin, M.S., Rank, D.R. et al. The relation between plant growth and respiration: A thermodynamic model. Planta 194, 77–85 (1994). https://doi.org/10.1007/BF00201037
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DOI: https://doi.org/10.1007/BF00201037