Modelling leaf expansion in a fluctuating environment: are changes in specific leaf area a consequence of changes in expansion rate?

F. TARDIEU; C. GRANIER; B. MULLER

doi:10.1046/j.1469-8137.1999.00433.x

Abstract

Leaf expansion rate varies with leaf temperature, photon flux density (PPFD), evaporative demand and soil water status. In most simulation models, it is calculated every day by multiplying the amount of carbohydrate available to leaves by specific leaf area (SLA). However, leaf expansion rate is considerably reduced by mild water deficits which do not affect photosynthesis, and is not affected by a reduction in the PPFD intercepted during rapid leaf expansion. Specific leaf area undergoes a several-fold variability depending on PPFD, soil water status and time of day. It is increased when environmental conditions have a greater depressive effect on expansion rate than on photosynthesis, and is decreased in the opposite case. It is therefore appropriate to model leaf expansion independently of the plant carbon budget. Consistent characteristics can be deduced from a series of experiments, allowing a model of leaf expansion to be proposed. (i) Time courses of relative leaf expansion rate and of epidermal cell division rate are well conserved within a plant and across a large range of environmental conditions, provided that durations and rates are expressed in thermal time. Maximum relative rates are common to all zones of a leaf and to all leaves of a plant, in maize and sunflower. (ii) A water deficit, or a reduction in intercepted PPFD, imposed in the first half of the period of leaf development affects the relative expansion rate in the deficit only, but permanently affects the absolute expansion rate. In contrast, a reduction in PPFD causes no effect on leaf expansion if imposed in the rapid expansion period when the leaf is autotrophic. (iii) Expansion rate is related to evaporative demand and to the concentration of ABA in the xylem sap with relationships that apply under both field and laboratory conditions. (iv) Tissue expansion and epidermal cell division behave as independent processes which determine epidermal cell area at each time.

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Tardieu, François and Granier, Christine 2000. The Plant Cell Cycle. p. 11.

Muller, Bertrand Reymond, Matthieu and Tardieu, François 2001. The elongation rate at the base of a maize leaf shows an invariant pattern during both the steady‐state elongation and the establishment of the elongation zone. Journal of Experimental Botany, Vol. 52, Issue. 359, p. 1259.

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van Oosterom, E.J Carberry, P.S and Muchow, R.C 2001. Critical and minimum N contents for development and growth of grain sorghum. Field Crops Research, Vol. 70, Issue. 1, p. 55.

Garnier, E. Shipley, B. Roumet, C. and Laurent, G. 2001. A standardized protocol for the determination of specific leaf area and leaf dry matter content. Functional Ecology, Vol. 15, Issue. 5, p. 688.

van Oosterom, E.J Carberry, P.S Hargreaves, J.N.G and O’Leary, G.J 2001. Simulating growth, development, and yield of tillering pearl millet. Field Crops Research, Vol. 72, Issue. 1, p. 67.

Muller, Bertrand Reymond, Matthieu and Tardieu, François 2001. The elongation rate at the base of a maize leaf shows an invariant pattern during both the steady‐state elongation and the establishment of the elongation zone. Journal of Experimental Botany, Vol. 52, Issue. 359, p. 1259.

van Delden, A Kropff, M.J and Haverkort, A.J 2001. Modeling temperature- and radiation-driven leaf area expansion in the contrasting crops potato and wheat. Field Crops Research, Vol. 72, Issue. 2, p. 119.

Richter, Goetz M. Jaggard, Keith W. and Mitchell, Rowan A.C. 2001. Modelling radiation interception and radiation use efficiency for sugar beet under variable climatic stress. Agricultural and Forest Meteorology, Vol. 109, Issue. 1, p. 13.

Wang, E. Robertson, M.J. Hammer, G.L. Carberry, P.S. Holzworth, D. Meinke, H. Chapman, S.C. Hargreaves, J.N.G. Huth, N.I. and McLean, G. 2002. Development of a generic crop model template in the cropping system model APSIM. European Journal of Agronomy, Vol. 18, Issue. 1-2, p. 121.

Hammer, G.L. Kropff, M.J. Sinclair, T.R. and Porter, J.R. 2002. Future contributions of crop modelling—from heuristics and supporting decision making to understanding genetic regulation and aiding crop improvement. European Journal of Agronomy, Vol. 18, Issue. 1-2, p. 15.

Lafarge, T.A and Hammer, G.L 2002. Predicting plant leaf area production:. Field Crops Research, Vol. 77, Issue. 2-3, p. 137.

Wang, Enli and Engel, Thomas 2002. Simulation of growth, water and nitrogen uptake of a wheat crop using the SPASS model. Environmental Modelling & Software, Vol. 17, Issue. 4, p. 387.

Gratani, Loretta and Ghia, Emanuela 2002. Changes in morphological and physiological traits during leaf expansion of Arbutus unedo. Environmental and Experimental Botany, Vol. 48, Issue. 1, p. 51.

Fernández, Roberto J. Wang, Mengben and Reynolds, James F. 2002. Do morphological changes mediate plant responses to water stress? A steady‐state experiment with two C4 grasses. New Phytologist, Vol. 155, Issue. 1, p. 79.

Ortega, Leandro and Taleisnik, Edith 2003. Elongation growth in leaf blades ofChloris gayana under saline conditions. Journal of Plant Physiology, Vol. 160, Issue. 5, p. 517.

Gutschick, Vincent P. and BassiriRad, Hormoz 2003. Extreme events as shaping physiology, ecology, and evolution of plants: toward a unified definition and evaluation of their consequences. New Phytologist, Vol. 160, Issue. 1, p. 21.

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Marshall, John D and Monserud, Robert A 2003. Foliage height influences specific leaf area of three conifer species. Canadian Journal of Forest Research, Vol. 33, Issue. 1, p. 164.

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Modelling leaf expansion in a fluctuating environment: are changes in specific leaf area a consequence of changes in expansion rate?

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Modelling leaf expansion in a fluctuating environment: are changes in specific leaf area a consequence of changes in expansion rate?

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