Salinity and Drought Stress in Rice. In: Sangwan RS, Sangwan-norreel BS, editors. The Impact of Biotechnology on Agriculture. Dordrecht: Springer Netherlands; 1990. pp. 391-402. [DOI: 10.1007/978-94-009-0587-0_24]

Genetic analysis of proline concentration under osmotic stress in sunflower (Helianthus annuus L.)

Proline concentration has been often suggested as an indicator of osmotic stress. A better understanding of the genetics of this trait is however needed. In the present study, proline concentration has been assessed, together with root and stem growth, potassium, calcium and total soluble sugars concentration and stress injury symptoms, in seedlings of sunflower hybrids and their parents grown under control and osmotic conditions. Proline strongly accumulated with osmotic stress. Its concentration exhibited a large variation among genotypes and was higher in hybrids than in parental lines. A positive association was noted between proline concentration and osmotic adjustment that was reflected in a reduction of osmotic stress induced injury, as showed by the reduced number of calli in the hybrids with higher proline concentration. Broad and narrow sense heritability was higher under osmotic stress suggesting applying the selection in osmotic stress condition. In the control treatment, dominance effects explained most of the genetic variation for proline concentration while under osmotic stress both dominance and additive variance were high. The importance of dominance and additive effects suggested that several genomic regions are controlling this trait. Good general combiners, presumably carrying positive additive alleles affecting proline concentration, were identified.

Characterization and regeneration of salt- and water-stress mutants from protoplast culture of Nicotiana plumbaginifolia (Viviani)

Protoplast-derived colonies of haploid N. plumbaginifolia leaves were used to select for resistance to NaCl, KCl and polyethylene glycol 6000 (PEG). Salt-and PEG-tolerant cell lines were isolated on the basis of growth in a culture medium containing inhibitory concentrations of either NaCl or KCl (200 mM) or PEG (25%). The frequency of resistant lines ranged from 10(-5) to 10(-6). One resistant line from each treatment was regenerated into plants. All resistant lines produced 10-25 times more proline than the wild type when grown on a non-selective medium. Similar values were also observed in the leaves of resistant progeny plants. In each mutant line, salt or PEG resistance was transmitted as a single dominant nuclear gene as shown by segregation ratios in progenies of crosses between resistant and wild-type plants. The latter observation demonstrates clearly the existence of a genetic basis for increased salt tolerance.