Yuntao Ma1, Youjia Chen1, Jinyu Zhu2, Lei Meng3, Yan Guo1, Baoguo Li1, Gerrit Hoogenboom4. 1. Key Laboratory of Arable Land Conservation (North China), Ministry of Agriculture, College of Resources and Environmental Sciences, China Agricultural University, Beijing. 2. Institute of Vegetables and Flowers, Chinese Academy of Agricultural Science, Beijing, China. 3. Department of Geography & Institute of the Environment and Sustainability, Western Michigan University, Kalamazoo, MI, USA. 4. Institute for Sustainable Food Systems & Department of Agricultural and Biological Engineering, University of Florida, Gainesville, FL, USA.
Abstract
Background and Aims: Failure to account for the variation of kernel growth in a cereal crop simulation model may cause serious deviations in the estimates of crop yield. The goal of this research was to revise the GREENLAB-Maize model to incorporate source- and sink-limited allocation approaches to simulate the dry matter accumulation of individual kernels of an ear (GREENLAB-Maize-Kernel). Methods: The model used potential individual kernel growth rates to characterize the individual potential sink demand. The remobilization of non-structural carbohydrates from reserve organs to kernels was also incorporated. Two years of field experiments were conducted to determine the model parameter values and to evaluate the model using two maize hybrids with different plant densities and pollination treatments. Detailed observations were made on the dimensions and dry weights of individual kernels and other above-ground plant organs throughout the seasons. Key Results: Three basic traits characterizing an individual kernel were compared on simulated and measured individual kernels: (1) final kernel size; (2) kernel growth rate; and (3) duration of kernel filling. Simulations of individual kernel growth closely corresponded to experimental data. The model was able to reproduce the observed dry weight of plant organs well. Then, the source-sink dynamics and the remobilization of carbohydrates for kernel growth were quantified to show that remobilization processes accompanied source-sink dynamics during the kernel-filling process. Conclusions: We conclude that the model may be used to explore options for optimizing plant kernel yield by matching maize management to the environment, taking into account responses at the level of individual kernels.
Background and Aims: Failure to account for the variation of kernel growth in a cereal crop simulation model may cause serious deviations in the estimates of crop yield. The goal of this research was to revise the GREENLAB-Maize model to incorporate source- and sink-limited allocation approaches to simulate the dry matter accumulation of individual kernels of an ear (GREENLAB-Maize-Kernel). Methods: The model used potential individual kernel growth rates to characterize the individual potential sink demand. The remobilization of non-structural carbohydrates from reserve organs to kernels was also incorporated. Two years of field experiments were conducted to determine the model parameter values and to evaluate the model using two maize hybrids with different plant densities and pollination treatments. Detailed observations were made on the dimensions and dry weights of individual kernels and other above-ground plant organs throughout the seasons. Key Results: Three basic traits characterizing an individual kernel were compared on simulated and measured individual kernels: (1) final kernel size; (2) kernel growth rate; and (3) duration of kernel filling. Simulations of individual kernel growth closely corresponded to experimental data. The model was able to reproduce the observed dry weight of plant organs well. Then, the source-sink dynamics and the remobilization of carbohydrates for kernel growth were quantified to show that remobilization processes accompanied source-sink dynamics during the kernel-filling process. Conclusions: We conclude that the model may be used to explore options for optimizing plant kernel yield by matching maize management to the environment, taking into account responses at the level of individual kernels.
Authors: Yan Guo; Yuntao Ma; Zhigang Zhan; Baoguo Li; Michael Dingkuhn; Delphine Luquet; Philippe De Reffye Journal: Ann Bot Date: 2006-01-03 Impact factor: 4.357
Authors: Yuntao Ma; Baoguo Li; Zhigang Zhan; Yan Guo; Delphine Luquet; Philippe de Reffye; Michael Dingkuhn Journal: Ann Bot Date: 2006-12-07 Impact factor: 4.357
Authors: Kenneth J Boote; James W Jones; Jeffrey W White; Senthold Asseng; Jon I Lizaso Journal: Plant Cell Environ Date: 2013-05-22 Impact factor: 7.228
Authors: Jingrui Wu; Shai J Lawit; Ben Weers; Jindong Sun; Nick Mongar; John Van Hemert; Rosana Melo; Xin Meng; Mary Rupe; Joshua Clapp; Kristin Haug Collet; Libby Trecker; Keith Roesler; Layton Peddicord; Jill Thomas; Joanne Hunt; Wengang Zhou; Zhenglin Hou; Matthew Wimmer; Justin Jantes; Hua Mo; Lu Liu; Yiwei Wang; Carl Walker; Olga Danilevskaya; Renee H Lafitte; Jeffrey R Schussler; Bo Shen; Jeffrey E Habben Journal: Proc Natl Acad Sci U S A Date: 2019-11-04 Impact factor: 11.205
Authors: Jacob C Douma; Jorad de Vries; Erik H Poelman; Marcel Dicke; Niels P R Anten; Jochem B Evers Journal: Plant Cell Environ Date: 2019-03 Impact factor: 7.228