Modelling leaf shape dynamics in rice

Abstract

Modelling leaf shape is a helpful tool for designing optimal plant shape and visualizing plant growth. The objectives of this study were to characterize the changes in patterns of leaf growth characteristics during plant development, and to model the changes in morphology of the different leaves of the rice ( Oryza sativa L.) plant. In four experiments, time course observations were made on length and width of the leaves on the main stem and tillers of rice plants grown under different experimental conditions. Three experiments provided the data for developing a model. The results show that the expansion process of a single leaf on the main stem and tillers against growing degree days (GDD) followed a slow–rapid–slow pattern that was described well by a logistic function. The changes in final length of the regular leaves positioned on the main stem were described by a quadratic function that differed from the function for the flag leaf. Final leaf length on the tillers followed the ratio of the length of the simultaneously expanding leaves on the tiller to the length of the corresponding leaves on the main stem. The changes in leaf width with leaf length in relation to GDD for a single leaf on the main stem and tillers were described by a quadratic function. The general relationships between final leaf length and final leaf width for the first fully expanded leaves and the flag leaves on the main stem and tillers were described by exponential functions, whereas for the other leaves quadratic functions were needed. The effects of nitrogen level and water regime on leaf growth were quantified by using leaf-nitrogen and leaf-water contents. The model, which was validated with the independent data from the fourth experiment, predicted the time course morphological changes of leaves on the main stem and tillers of rice grown with different nitrogen and water levels well. The results of this study can lead to a more accurate description of the rice leaf in a 3D space by integrating the model with the morphogenesis models of sheath, internode and panicle within the framework of plant topology. In addition, the present leaf architecture model may be combined with a leaf emergence model and a leaf curvature model for digital representation of light interception and utilization within the leaf canopy of rice.