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Metabolism of Abscisic Acid and Its Regulation in Xanthium Leaves during and after Water Stress ¹

MSU-DOE Plant Research Laboratory, Michigan State University, East Lansing, Michigan 48824

Metabolism of abscisic acid was compared in stressed and in rehydrated leaf blades of Xanthium strumarium L. Chicago strain that were either detached or left intact on the plant. Under all conditions, phaseic acid was the major metabolite. The high level of phaseic acid that was observed in intact plants 1 day after recovery from stress declined slowly and had not yet reached the prestress level 1 week later. The glucosyl ester of abscisic acid, -D-glucopyranosyl abscisate, accumulated at a low rate during periods of prolonged stress. Repeated stress-recovery cycles resulted in a gradual increase in the level of the glucosyl ester, which did not decline following relief of stress for at least 34 days. The level of the glucosyl ester of abscisic acid may therefore serve as a cumulative indicator of the water stresses to which a particular leaf has been exposed.

Darkness stimulated abscisic acid metabolism in both detached and attached leaves. Treatment of Xanthium leaves in light with ethylene or chemicals that release ethylene also resulted in a faster breakdown of abscisic acid. Inasmuch as darkness is known to stimulate ethylene production, it is proposed that enhancement of abscisic acid metabolism in darkness is mediated by ethylene.

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