Leaf Canopy as a Dynamic System: Ecophysiology and Optimality in Leaf Turnover

doi:10.1093/aob/mci050

AOBPreview originally published online on December 7, 2004
Annals of Botany 2005 95(3):521-533; doi:10.1093/aob/mci050

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Annals of Botany 95/3 © Annals of Botany Company 2004; all rights reserved

REVIEW

Leaf Canopy as a Dynamic System: Ecophysiology and Optimality in Leaf Turnover

KOUKI HIKOSAKA^*

Graduate School of Life Sciences, Tohoku University, Aoba, Sendai 980-8578, Japan

^* For correspondence. E-mail hikosaka{at}mail.tains.tohoku.ac.jp

Received: 21 July 2003 Returned for revision: 6 November 2003 Accepted: 13 April 2004 Published electronically: 7 December 2004

• Background and Aims In a leaf canopy, there is a turnoverof leaves; i.e. they are produced, senesce and fall. These processesdetermine the amount of leaf area in the canopy, which in turndetermines canopy photosynthesis. The turnover rate of leavesis affected by environmental factors and is different amongspecies. This mini-review discusses factors responsible forleaf dynamics in plant canopies, focusing on the role of nitrogen.

• Scope Leaf production is supported by canopy photosynthesisthat is determined by distribution of light and leaf nitrogen.Leaf nitrogen determines photosynthetic capacity. Nitrogen takenup from roots is allocated to new leaves. When leaves age ortheir light availability is lowered, part of the leaf nitrogenis resorbed. Resorbed nitrogen is re-utilized in new organsand the rest is lost with dead leaves. The sink–sourcebalance is important in the regulation of leaf senescence. Severalmodels have been proposed to predict response to environmentalchanges. A mathematical model that incorporated nitrogen usefor photosynthesis explained well the variations in leaf lifespanwithin and between species.

• Conclusion When leaf turnover is at a steady state, theratio of biomass production to nitrogen uptake is equal to theratio of litter fall to nitrogen loss, which is an inverse ofthe nitrogen concentration in dead leaves. Thus nitrogen concentrationin dead leaves (nitrogen resorption proficiency) and nitrogenavailability in the soil determine the rate of photosynthesisin the canopy. Dynamics of leaves are regulated so as to maximizecarbon gain and resource-use efficiency of the plant.

Key words: Canopy photosynthesis, canopy structure, cost–benefit analysis, evolutionarily stable strategy, leaf area index, leaf lifespan, leaf senescence, leaf turnover, nitrogen resorption, nitrogen turnover, nitrogen use efficiency, optimality model

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