Engineering for drought avoidance: expression of maize NADP-malic enzyme in tobacco results in altered stomatal function

doi:10.1093/jexbot/53.369.699

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Journal of Experimental Botany, Vol. 53, No. 369, pp. 699-705, April 1, 2002
© 2002 Oxford University Press

Original Papers

Engineering for drought avoidance: expression of maize NADP-malic enzyme in tobacco results in altered stomatal function

Marianne M. Laporte¹, Bo Shen and Mitchell C. Tarczynski²

Pioneer Hi-Bred International, Inc., A DuPont Company, 7300 N.W. 62nd Avenue, Johnston, Iowa 50131, USA

Water is a principal limitation to agricultural production duringdrought and in arid regions of the world. Mechanisms that plantsuse to cope with drought can be grouped into two different strategies:drought tolerance and drought avoidance. Previous efforts towardengineering plants for improved performance during drought havefocused on drought tolerance, the ability to adjust to dry conditions.This report addresses the engineering of a drought-avoidancephenotype, which allows for the conservation of water duringplant growth. The majority of water lost from plants occursthrough stomata. When stomata are open, potassium, chlorideand/or malate are present at high concentrations in guard cells.The accumulation of large numbers of ions during stomatal openingincreases the turgor pressure of the guard cells, which resultsin increased pore size. Expression of a single gene from maize,NADP-malic enzyme (ME), which converts malate and NADP to pyruvate,NADPH, and CO₂, resulted in altered stomatal behaviour and waterrelations in tobacco. The ME-transformed plants had decreasedstomatal conductance and gained more fresh mass per unit waterconsumed than did the wild type, but they were similar to thewild type in their growth and rate of development. Providingchloride via the transpiration stream partially reversed theeffects of ME expression on stomatal aperture size, which isconsistent with the interpretation that expression of ME alteredmalate metabolism in guard cells. These results suggest a rolefor malic enzyme in the mechanism of stomatal closure, as wellas a potential mechanism for genetically altering plant wateruse.

Key words: Drought, drought avoidance, guard cells, NADP-malic enzyme, stomata, transgenic plants.

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