Parameter Stability of the Functional-Structural Plant Model GREENLAB as Affected by Variation within Populations, among Seasons and among Growth Stages

doi:10.1093/aob/mcl245

AOBPreview originally published online on December 7, 2006
Annals of Botany 2007 99(1):61-73; doi:10.1093/aob/mcl245

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Parameter Stability of the Functional–Structural Plant Model GREENLAB as Affected by Variation within Populations, among Seasons and among Growth Stages

Yuntao Ma¹, Baoguo Li¹, Zhigang Zhan¹, Yan Guo¹, Delphine Luquet², Philippe de Reffye²^,3 and Michael Dingkuhn²^,*

¹ Key Laboratory of Plant–Soil Interactions, Ministry of Education, College of Resources and Environment, China Agricultural University, Beijing 100094, China
² Cirad-amis, TA 40/01 Ave Agropolis, 34398 Montpellier Cedex 5, France
³ INRIA-Rocquencourt, BP 105, 78153 Le Chesnay Cedex, France

^* For correspondence. E-mail dingkuhn{at}cirad.fr

Received: 11 July 2006 Returned for revision: 30 August 2006 Accepted: 4 October 2006 Published electronically: 7 December 2006

BACKGROUND AND AIMS: It is increasingly accepted that crop models, if they are tosimulate genotype-specific behaviour accurately, should simulatethe morphogenetic process generating plant architecture. A functional–structuralplant model, GREENLAB, was previously presented and validatedfor maize. The model is based on a recursive mathematical process,with parameters whose values cannot be measured directly andneed to be optimized statistically. This study aims at evaluatingthe stability of GREENLAB parameters in response to three typesof phenotype variability: (1) among individuals from a commonpopulation; (2) among populations subjected to different environments(seasons); and (3) among different development stages of thesame plants.

METHODS: Five field experiments were conducted in the course of 4 yearson irrigated fields near Beijing, China. Detailed observationswere conducted throughout the seasons on the dimensions andfresh biomass of all above-ground plant organs for each metamer.Growth stage-specific target files were assembled from the datafor GREENLAB parameter optimization. Optimization was conductedfor specific developmental stages or the entire growth cycle,for individual plants (replicates), and for different seasons.Parameter stability was evaluated by comparing their CV withthat of phenotype observation for the different sources of variability.A reduced data set was developed for easier model parameterizationusing one season, and validated for the four other seasons.

KEY RESULTS AND CONCLUSIONS: The analysis of parameter stability among plants sharing thesame environment and among populations grown in different environmentsindicated that the model explains some of the inter-seasonalvariability of phenotype (parameters varied less than the phenotypeitself), but not inter-plant variability (parameter and phenotypevariability were similar). Parameter variability among developmentalstages was small, indicating that parameter values were largelydevelopment-stage independent. The authors suggest that thehigh level of parameter stability observed in GREENLAB can beused to conduct comparisons among genotypes and, ultimately,genetic analyses.

Key words: Plant architecture, functional–structural models, crop simulation, parameter stability, allometric relationships, sink capacity, Zea mays

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