Abscisic acid biosynthesis in roots. II. The effects of water-stress in wild-type and abscisic-acid-deficient mutant (notabilis) plants of Lycopersicon esculentum Mill

The ubiquity of the apo-carotenoid abscisic acid (ABA) biosynthetic pathway elucidated in water-stressed, etiolated leaves of Phaseolus vulgaris (see A.D. Parry and R. Horgan, 1991, Physiol. Plant. 82, 320-326), has been difficult to establish. Light-grown leaves contain very high carotenoid:ABA ratios, preventing correlative studies, and no etiolated leaves so far studied, other than those of Phaseolus, have been found capable of synthesising significant amounts of ABA in response to stress. Roots are known to synthesise ABA and contain low carotenoid levels; therefore ABA biosynthesis was investigated in soil- and hydroponically grown roots of Lycopersicon esculentum Mill. Hydroponically grown roots were stressed by immersion in 100 mM mannitol and soil-grown roots by withholding water. In both cases stress led to an increase in ABA levels and a decrease in the levels of specific xanthophylls, namely all-trans- and 9'-cis-neoxanthin and all-trans-violaxanthin. In hydroponically grown roots, and soil-grown roots stressed after removal of the shoot, ratios of xanthophyll cleaved:ABA synthesised of approx. 1:1 were obtained. These findings are consistent with the operation of an apo-carotenoid pathway in roots, involving the conversion of all-trans-violaxanthin via all-trans-neoxanthin, to 9'-cis-neoxanthin, and the specific cleavage of 9'-cis-neoxanthin to yield the C15 ABA precursor xanthosin. Similar experiments with roots of the "leaky", ABA-deficient mutant of Lycopersicon, notabilis, indicate that the mutation does not affect the perception or transduction of stress, or the ability of the plant to cleave carotenoids. Rather, it appears that notabilis possesses an enzyme with reduced substrate specificity which cleaves more all-trans- than 9'-cis-neoxanthin.