A Dynamic Model for Nitrogen-stressed Lettuce

doi:10.1093/aob/mcg069

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Annals of Botany 91: 623-635, 2003
© 2003 Annals of Botany Company

A Dynamic Model for Nitrogen-stressed Lettuce

IDO SEGINER¹

¹ Civil Engineering Department, Division of Agricultural Engineering, Technion, Haifa 32000, Israel

* For correspondence. E-mail segineri{at}tx.technion.ac.il

Received: 11 September 2002; Returned for revision: 6 December 2002; Accepted: 20 January 2003

A previously developed dynamic lettuce model, designed to predictgrowth and nitrate content under the normal range of glasshouseenvironmental conditions, has been extended to cover high nitrogen-stresssituations. Under severe shortage of nitrogen, lettuce has beenobserved to grow at a very slow rate, as well as to have abnormallylow water content, low reduced-nitrogen content and negligiblenitrate content. The new model mimics these observations byadding to the original model a storage compartment for ‘excess’carbon. The resulting model has three compartments: (1) ‘vacuole’,where the soluble non-structural material is stored, and thenitrate : carbon ratio may vary as needed to maintaina constant osmotic potential; (2) ‘structure’, ametabolically active compartment with fixed chemical composition;and (3) ‘excess-carbon’, which serves as a long-termstorage of ‘waterless’ carbohydrates. Simulationswith the model illustrate its ability to predict the effectof light, temperature and nitrogen in the nutrient solutionon the long-term growth and composition of lettuce. They alsoillustrate the effects of plant size, and the associated relativegrowth rate, on the characteristic times of transient responsesresulting from step changes in the environment.

Key words: Lactuca sativa L., glasshouse, N-stress, dynamic response, Nicolet.

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