Evidence has been obtained which is consistent with 9'-cis-neoxanthin being a major precursor of abscisic acid (ABA) in higher plants. A mild, rapid procedure was developed for the extraction and analysis of carotenoids from a range of tissues. Once purified the carotenoids were identified from their light-absorbance properties, reactions with dilute acid, high-performance liquid chromatography Rts, mass spectra and the quasiequilibria resulting from iodine-catalysed or chlorophyllsensitised photoisomerisation. Two possible ABA precursors, 9'-cis-neoxanthin and 9-cis-violaxanthin, were identified in extracts of light-grown and etiolated leaves (of Lycopersicon esculentum, Phaseolus vulgaris, Vicia faba, Pisum sativum, Cicer arietinum, Zea mays, Nicotiana plumbaginifolia, Plantago lanceolata and Digitalis purpurea), and roots of light-grown and etiolated plants (Lycopersicon, Phaseolus and Zea). The 9,9'-di-cisisomer of violaxanthin was synthesised but its presence was not detected in any extracts. Levels of 9'-cis-neoxanthin and all-trans-violaxanthin were between 20- to 100-fold greater than those of ABA in light-grown leaves. The levels of 9-cis-violaxanthin were similar to those of ABA but unaffected by water stress. Etiolated Phaseolus leaves contained reduced amounts of carotenoids (15-20% compared with light-grown leaves) but retained the ability to synthesise large amounts of ABA. The amounts of ABA synthesised, measured as increases in ABA and its metabolites phaseic acid and dihydrophaseic acid, were closely matched by decreases in the levels of 9'-cis-neoxanthin and all-trans-violaxanthin. In etiolated seedlings grown on 50% D2O, deuterium incorporation into ABA was similar to that into the xanthophylls. Relative levels of carotenoids in roots and light-grown and etiolated leaves of the ABA-deficient mutants, notabilis, flacca and sitiens were the same as those found in wild-type tomato tissues.
A mutant of Nicotiana plumbaginifolia, CKR1, isolated on the basis of its enhanced resistance to cytokinins was found to have a greater tendency to wilt than the wild type (Blonstein et al., 1991, Planta 183, 244-250). Further characterisation has shown that the wiltiness in the mutant is not caused by an insensitivity to abscisic acid (ABA) because the external application of ABA leads to stomatal closure and phenotypic reversion. The basal ABA level in the mutant is < 20% of that in the wild type. Following stress, the ABA level in wild-type leaves increases by approx 9-to 10-fold while the mutant shows only a slight increase. This deficiency in ABA is unlikely to be the consequence of accelerated catabolism as the levels of two major metabolites of ABA, phaseic and dihydrophaseic acid, are also much reduced in the mutant. The qualitative and quantitative distributions of carotenoids, the presumed presursors of ABA, are the same for the leaves of both wild type and mutant. Biosynthesis of ABA at the C15 level was investigated by feeding xanthoxin (Xan) to detached leaves. Wild-type leaves convert between 9-19% of applied Xan to ABA while the mutant converts less than 1%. The basal level of trans-ABA-alcohol (t-ABA-alc) is 3-to 10-fold greater in the mutant and increases by a further 2.5-to 6.0-fold after stress. This indicates that the lesion in the wilty mutant of N. plumbaginifolia affects the conversion of ABA-aldehyde to ABA, as in the flacca and sitiens mutants of tomato and the droopy mutant of potato (Taylor et al., 1988, Plant Cell Environ. 11, 739-745; Duckham et al., 1989, J. Exp. Bot. 217, 901-905). Wild-type tomato and N. plumbaginifolia leaves can convert trans-Xan into t-ABA-alc, and Xan into ABA, while those of flacca and the wilty N. plumbaginifolia mutant convert both Xan and t-Xan to t-ABA-alc.
The in vitro activity of polysomal polyadenylated RNA (poly(A)RNA) was studied using chick-pea (Cicer arietinum L.) embryonic axes subjected to treatments retarding germination (H2O 30°C and abscisic acid [ABA] 30°C) or inducing a false germination (thiourea 30°C) in which normal protein synthesis and growth did not occur. All treatments induced a smaller proportion of poly(A)RNA compared with the control (H2O 25°C). However, poly(A)RNA obtained in the presence of ABA had a similar in vitro activity to that of the control. The translation of mRNA from embryonic axes germinated at high temperatures was extensively blocked (70%) by methyl-7-guanosine-5'-triphosphate, whereas mRNA translation from axes treated with H2O-25°C and ABA was completely blocked (100%), indicating a greater cap dependence in the latter cases. Polyacrylamide gel electrophoresis showed that ABA and H2O-30°C each induced the synthesis of a polypeptide with an approximate Mr of 32 kDa, probably a germination regulator. It is suggested that ABA and high temperatures could regulate germination at the translational level as well as affecting ionic-exchange properties, as has been previously demonstrated (Hernández-Nistal et al. 1983, Physiol. Plant. 57, 273-278).
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