Mutants of Nicotiana plumbaginifolia with specific resistance to auxin.

We have isolated nine independent auxin-resistant mutants of Nicotiana plumbaginifolia by culturing M2 seedlings in the presence of indole-3-acetic acid ethyl ester or 1-naphthaleneacetic acid at concentrations which significantly inhibit hypocotyl elongation of the wild type. The mutations were induced by treating seed with ethyl methanesulphonate and were found in the course of screening 10,000 individual M2 families. Auxin resistance was in all cases the result of a mutation at a single, nuclear locus. The dominance relationships of two of the mutants could be defined as recessive or dominant; all other mutants showed partial dominance. In contrast to previously described mutants of Arabidopsis and N. plumbaginifolia, all of the present mutants were specifically resistant to auxin; the mutants were cross-resistant to several auxins, but showed no increased resistance to cytokinin, abscisic acid, ethylene or 1-amino-cyclopropane-1-carboxylic acid. The importance of the choice of the selection criterion for the isolation of specific resistance traits is discussed.

Abscisic-acid metabolism in a wilty mutant of Nicotiana plumbaginifolia.

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.

A cytokinin-resistant mutant of Nicotiana plumbaginifolia is wilty.

Selection for cytokinin resistance by incubating M2 seed of Nicotiana plumbaginifolia, after ethylmethanesulphonate mutagenesis, on 20 µM 6-benzylami-nopurine resulted in the isolation of a monogenic, recessive mutant, CKR1. Germination of the mutant is less sensitive to cytokinin inhibition than the wild type, and leaf development of the mutant occurs at cytokinin concentrations inhibitory to the wild type. Germination of the mutant is also resistant to auxin but not to abscisic acid. Three other traits jointly inherited with cytokinin resistance in the F2 are lack of root branching, precocious germination and wiltiness. The wilty phenotype is the consequence of the failure of stomatal closure during water stress.