BACKGROUND AND AIMS: Light interception is a critical factor in the production of biomass. The study presented here describes a method used to take account of architectural changes over time in sunflower and to estimate absorbed light at the organ level. METHODS: The amount of photosynthetically active radiation absorbed by a plant is estimated on a daily or hourly basis through precise characterization of the light environment and three-dimensional virtual plants built using AMAP software. Several treatments are performed over four experiments and on two genotypes to test the model, quantify the contribution of different organs to light interception and evaluate the impact of heliotropism. KEY RESULTS: This approach is used to simulate the amount of light absorbed at organ and plant scales from crop emergence to maturity. Blades and capitula were the major contributors to light interception, whereas that by petioles and stem was negligible. Light regimen simulations showed that heliotropism decreased the cumulated light intercepted at the plant scale by close to 2.2% over one day. CONCLUSIONS: The approach is useful in characterizing the light environment of organs and the whole plant, especially for studies on heterogeneous canopies or for quantifying genotypic or environmental impacts on plant architecture, where conventional approaches are ineffective. This model paves the way to analyses of genotype-environment interactions and could help establish new selection criteria based on architectural improvement, enhancing plant light interception.
BACKGROUND AND AIMS: Light interception is a critical factor in the production of biomass. The study presented here describes a method used to take account of architectural changes over time in sunflower and to estimate absorbed light at the organ level. METHODS: The amount of photosynthetically active radiation absorbed by a plant is estimated on a daily or hourly basis through precise characterization of the light environment and three-dimensional virtual plants built using AMAP software. Several treatments are performed over four experiments and on two genotypes to test the model, quantify the contribution of different organs to light interception and evaluate the impact of heliotropism. KEY RESULTS: This approach is used to simulate the amount of light absorbed at organ and plant scales from crop emergence to maturity. Blades and capitula were the major contributors to light interception, whereas that by petioles and stem was negligible. Light regimen simulations showed that heliotropism decreased the cumulated light intercepted at the plant scale by close to 2.2% over one day. CONCLUSIONS: The approach is useful in characterizing the light environment of organs and the whole plant, especially for studies on heterogeneous canopies or for quantifying genotypic or environmental impacts on plant architecture, where conventional approaches are ineffective. This model paves the way to analyses of genotype-environment interactions and could help establish new selection criteria based on architectural improvement, enhancing plant light interception.
Authors: Guillermo A A Dosio; Hervé Rey; Jérémie Lecoeur; Natalia G Izquierdo; Luis A N Aguirrezábal; François Tardieu; Olivier Turc Journal: J Exp Bot Date: 2003-09-25 Impact factor: 6.992
Authors: Jochem B Evers; Jan Vos; Christian Fournier; Bruno Andrieu; Michael Chelle; Paul C Struik Journal: New Phytol Date: 2005-06 Impact factor: 10.151
Authors: Raphaël P A Perez; Jean Dauzat; Benoît Pallas; Julien Lamour; Philippe Verley; Jean-Pierre Caliman; Evelyne Costes; Robert Faivre Journal: Ann Bot Date: 2018-04-18 Impact factor: 4.357
Authors: Gábor Horváth; Judit Slíz-Balogh; Ákos Horváth; Ádám Egri; Balázs Virágh; Dániel Horváth; Imre M Jánosi Journal: Sci Rep Date: 2020-12-09 Impact factor: 4.379
Authors: Péter Takács; Zoltán Kovács; Dénes Száz; Ádám Egri; Balázs Bernáth; Judit Slíz-Balogh; Magdolna Nagy-Czirok; Zsigmond Lengyel; Gábor Horváth Journal: Front Plant Sci Date: 2022-03-17 Impact factor: 5.753