2016
DOI: 10.1093/aob/mcw143
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CN-Wheat, a functional–structural model of carbon and nitrogen metabolism in wheat culms after anthesis. I. Model description

Abstract: Background and Aims Improving crops requires better linking of traits and metabolic processes to whole plant performance. In this paper, we present CN-Wheat, a comprehensive and mechanistic model of carbon (C) and nitrogen (N) metabolism within wheat culms after anthesis.Methods The culm is described by modules that represent the roots, photosynthetic organs and grains. Each of them includes structural, storage and mobile materials. Fluxes of C and N among modules occur through a common pool and through transp… Show more

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Cited by 38 publications
(24 citation statements)
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“…Carbon concentration in wheat grain was affected by treatments and was greater in the SB45, SB90, NB45, NB90 than in FB and SB ( Table 1). The accumulation of N in grain has positive correlation with C in the grain 34 , and SB45, SB90, NB45, NB90 plots had greater N than in FB and SB plots. This could be the reason for greater concentrations of C in the N applied treatments than in the plots without N application.…”
Section: Wheat Tissue Carbon (C) and Phosphorus (P)mentioning
confidence: 89%
“…Carbon concentration in wheat grain was affected by treatments and was greater in the SB45, SB90, NB45, NB90 than in FB and SB ( Table 1). The accumulation of N in grain has positive correlation with C in the grain 34 , and SB45, SB90, NB45, NB90 plots had greater N than in FB and SB plots. This could be the reason for greater concentrations of C in the N applied treatments than in the plots without N application.…”
Section: Wheat Tissue Carbon (C) and Phosphorus (P)mentioning
confidence: 89%
“…This equilibrium state would depend on the speed of dynamic acclimation and the degree of linearity in the response of plant traits to changes in irradiance. These dynamics have been captured in simulation models either (i) by implementing a goalseeking behavior that calculates steady-state acclimation from optimization theory (Yin et al, 2019) or (ii) by simulating protein turnover dynamically (Thornley, 1998;Kull and Kruijt, 1999;Barillot et al, 2016;Pao et al, 2019a). Experimental evidence exists that coordination across leaves may be achieved through cytokinins carried by the transpiration stream (Pons et al, 2001), as transpiration will vary according to the irradiance profile.…”
Section: Dynamic Acclimation May Never Reach a Steady Statementioning
confidence: 99%
“…Experimental evidence exists that coordination across leaves may be achieved through cytokinins carried by the transpiration stream (Pons et al, 2001), as transpiration will vary according to the irradiance profile. This mechanism has been included in a recent mechanistic model of wheat incorporating plant carbon and N balances, but has not yet been validated experimentally (Barillot et al, 2016).…”
Section: Dynamic Acclimation May Never Reach a Steady Statementioning
confidence: 99%
“…Numerous mathematical models on growth of various plants have been developed (e.g., Thornley and Johnson, 1990 ; Chew et al, 2014 , 2017 ; Feller et al, 2015 ; Barillot et al, 2016a , b ). Among them, two multiscale models of A. thaliana include the circadian clock sub-model and are able to quantitatively predict growth (Chew et al, 2014 , 2017 ).…”
Section: Discussionmentioning
confidence: 99%