Physiological characterization of 'stay green' mutants in durum wheat.

Four mutants with delayed leaf senescence were selected from seed of durum wheat mutagenized with ethylmethane sulphonate. Changes in net photosynthetic rate, efficiency of photosystem II and chlorophyll concentration during the maturation and senescence of the flag leaves of both mutant and parental plants were determined under glasshouse conditions. The four mutant lines maintained photosynthetic competence for longer than the parental line and are therefore functionally 'stay green'. The mutant lines also had higher seed weights and grain yields per plant than the parental line.

Enhanced osmotolerance of a wheat mutant selected for potassium accumulation.

A mutant of durum wheat was identified by screening a M4 population (sodium azide) for genotypes with enhanced capacity for potassium accumulation in leaves. The mutant (designated 422) was grown in field, controlled environment, hydroponic culture and NaCl salinized soil. Mutant 422 accumulates about 5 mg/g dry weight more K than the wild-type and is less salt sensitive, based on leaf growth and germination. During vegetative growth exists a specific tolerance of the 422 mutant to K(+) ion and a moderate tolerance to Cl(-) ion, in hydroponic culture. Under severe stress imposed by salts and mannitol, the mutant germinates better than wild type (WT). In soil containing increasing NaCl, mutant 422 had higher potassium amount than WT, but did not show augmented capacity to concentrate the ion in the leaves as salt stress increased. The capability to accumulate potassium could improve tissue hydration, because water content of 422 leaves was greater than WT and increased linearly in relation to leaf K(+) concentration.

Bound Water in Durum Wheat under Drought Stress.

To study drought stress effects on bound water, adsorption isotherms and pressure-volume curves were constructed for two durum wheat (Triticum durum Desf.) cultivars: Capeiti 8 (drought tolerant) and Creso (drought sensitive). Plants were grown under well-watered and water-stressed conditions in a controlled environment. Differential enthalpy (DeltaH) was calculated through van't Hoff analysis of adsorption isotherms at 5 and 20 degrees C, which allowed us to determine the strength of water binding. DeltaH reached the most negative values at approximately 0.06 gram H(2)O/gram dry weight and then increased rapidly for well-watered plants (until 0.10 gram H(2)O/gram dry weight) or more slowly for drought-stressed plants (until 0.15-0.20 gram H(2)O/gram dry weight). Bound water values from pressure-volume curves were greater for water-stressed (0.17 gram H(2)O/gram dry weight) than for well-watered plants (0.09 gram H(2)O/gram dry weight). They may be estimates of leaf moisture content where DeltaH reaches the less negative values and hence some free water appears. With respect to the well-watered plants, tightly bound water tended to be less bound during drought, and more free water was observed in cv Creso compared to cv Capeiti 8 at moisture contents >0.10 gram H(2)O/gram dry weight.