A Dynamic, Architectural Plant Model Simulating Resource-dependent Growth

doi:10.1093/aob/mch078

AOBPreview originally published online on March 31, 2004

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Annals of Botany 93: 591-602, 2004
© 2004 Annals of Botany Company

A Dynamic, Architectural Plant Model Simulating Resource-dependent Growth

HONG-PING YAN¹, MENG ZHEN KANG¹, PHILIPPE DE REFFYE² and MICHAEL DINGKUHN^*^,3

¹ NLPR, Institute of automation, CAS, 2728, 100081, Beijing, China, ² INRIA-Rocquencourt B.P. 105, 78153 Le Chesnay Cedex (France) and ³ Cirad-amis,TA 40/01 Ave Agropolis, 34398 Montpellier, France Cedex 5

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

Received: 12 September 2003; Returned for revision: 24 October 2003; Accepted: 7 January 2004 Published electronically: 31 March 2004

• Background and Aims Physiological and architectural plantmodels have originally been developed for different purposesand therefore have little in common, thus making combined applicationsdifficult. There is, however, an increasing demand for cropmodels that simulate the genetic and resource-dependent variabilityof plant geometry and architecture, because man is increasinglyable to transform plant production systems through combinedgenetic and environmental engineering.

• Model GREENLAB is presented, a mathematical plant modelthat simulates interactions between plant structure and function.Dual-scale automaton is used to simulate plant organogenesisfrom germination to maturity on the basis of organogenetic growthcycles that have constant thermal time. Plant fresh biomassproduction is computed from transpiration, assuming transpirationefficiency to be constant and atmospheric demand to be the drivingforce, under non-limiting water supply. The fresh biomass isthen distributed among expanding organs according to their relativedemand. Demand for organ growth is estimated from allometricrelationships (e.g. leaf surface to weight ratios) and kineticsof potential growth rate for each organ type. These are obtainedthrough parameter optimization against empirical, morphologicaldata sets by running the model in inverted mode. Potential growthrates are then used as estimates of relative sink strength inthe model. These and other ‘hidden’ plant parametersare calibrated using the non-linear, least-square method.

• Key Results and Conclusions The model reproduced accuratelythe dynamics of plant growth, architecture and geometry of variousannual and woody plants, enabling 3D visualization. It was alsoable to simulate the variability of leaf size on the plant andcompensatory growth following pruning, as a result of internalcompetition for resources. The potential of the model’sunderlying concepts to predict the plant’s phenotypicplasticity is discussed.

Key words: Plant architecture, phenotypic plasticity, demand functions, competition among sinks, source–sink relationships, structural-functional models.

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