Participation of the cyanide-resistant pathway in respiration of winter rape leaves as affected by plant cold acclimation

Leaf slices sampled from winter rape plants ( Brassica napus L., var. oleifera L., cv. GórczaánAski), grown in cold (5°C), showed an increase in the dark respiration rate (measured at 25°C) as compared to slices cut from control plants (grown at 20/15°C). The effect of low temperature was most pronounced after 4 days of plant growth in the cold. Oxygen uptake by control slices was 60% inhibited by 1 m M KCN and was insensitive to 2.5 m M salicylhydroxamic acid (SHAM). On the contrary, respiration of leaf slices from cold-pretreated plants was more resistant to cyanide (35% inhibition after 4 days of cold treatment) and was 30% inhibited by SHAM. The patterns of cold-induced changes in total respiratory activity and in the estimated activity of alternative pathway were similar. It seems that in leaf slices from plants grown in the cold, the cyanide-resistant, alternative pathway participates in oxygen uptake. Cold treatment of plants also brought about a 4-fold increase in the level of soluble sugars, which reached a maximum on day 4 of exposure to cold. Addition of sucrose to the incubation medium resulted in an immediate increase in oxygen uptake by slices with low endogenous sugar level. The respiration stimulated by sucrose addition was more resistant to cyanide than the basal respiration and it was inhibited by SHAM. It is concluded that the operation of the alternative pathway is responsible for the increased oxygen uptake by the cold-grown winter rape leaves and it may be induced by an increased sugar supply for respiratory processes.     

Wheat catalase expressed in transgenic rice can improve tolerance against low temperature stress

We examined whether the expression of wheat catalase (EC 1.11.1.6) cDNA in transgenic rice ( Oryza sativa L.) could enhance tolerance against low temperature injury. Transgenic rice plants expressing wheat CAT protein showed an increase of activities in leaves at 25°C, 2- to 5-fold that in non-transgenic rice. At 5°C, catalase activities were about 4–15 times higher than those in non-transgenic rice were. A comparison of damage observed in leaves as they withered due to chilling at 5°C showed that transgenic rice displayed an increased capability to resist low temperature stress. The exposure of these plants to low temperature at 5°C for 8 days resulted in decreased catalase activities in leaves at 25°C, but the transgenic plants indicated 4 times higher residual catalase activities than those of non-transgenic ones. The concentration of H₂O₂ in leaves was kept lower in transgenic rice than that of the control plants during the 8 days chilling. These results suggest that the improved tolerance against low temperature stress in genetically engineered rice plants be attributed to the effective detoxification of H₂O₂ by the enhanced catalase activities.     

Frost resistance of winter rape leaves as related to the changes in water potential and growth capability

Differential thermal analysis indicated that the frost resistance of winter rape leaves ( Brassica napus L. var. oleifera L. cv. Gòrczanski), collected from plants grown in the cold (5/2°C), relies mainly on their ability to supercool to −9 to −11°C, i.e. consists in freezing avoidance. Initiation of ice formation in the cold-acclimated leaves resulted in the death of more than 50% of the cells as determined with a conductivity method. The development of freezing tolerance appeared to be an attribute of the second stage of plant hardening and was induced by the exposure of plants to a slightly subzero temperature (−5°C) for 18 h. Such a treatment brought about a sudden and persistent water potential decrease in the leaves, despite the fact that they had reabsorbed water from the medium prior to water potential measurements. Water potential changes were associated with a higher growth capability of the leaves as checked by determinations of disk area increments. It is suggested that the increased frost tolerance of the cold-grown winter rape leaves, subjected to subfreezing temperature, is related to the decreased water potential of the tissue caused by changes in turgor and/or in osmotic pressures of the cells.     

Effects of temperature and moisture stress on the accumulation of abscisic acid in bean

Levels of abscisic acid (ABA) and several indicators of leaf-water status were measured in excised and intact primary leaves of bean ( Phaseolus vulgaris cv. Kinghorn) exposed to different temperature and moisture regimes. After 2 h at 5°, 25° or 45°C under moist conditions, the water status of detached leaves showed only minor changes, and there was no increase in ABA. Under conditions favoring water loss, ABA rose over 10-fold at 25°C, and trends towards higher ABA levels were observed at 5° and 45°C. When intact leaves on whole plants were exposed to the same temperatures for 10 h, there was still no evidence of a temperature-dependent rise in ABA that was not associated with a disturbance in the water balance of the plant. These data suggest that the rapid accumulation of ABA during temperature stress is a function of induced moisture deficits and does not result from high or low temperatures per se.     

Differential responses of Brassica napus and Petunia hybrida to leaf protoplast isolation stress

Changes in the response to abiotic stress during the isolation of leaf protoplasts were compared between a recalcitrant species of Brassica napus and regenerating species of Petunia hybrida . Initially, levels of soluble free putrescine (put), spermidine (spd) and spermine (spm) in leaves and protoplasts were determined. The sum of these three polyamines increased in petunia and B. napus leaf protoplasts by 1.6-fold and 1.1-fold, respectively. The soluble free fraction of spd and spm decreased in B. napus but not in petunia protoplasts. During the isolation of leaf protoplasts from B. napus , the ratio of soluble free put to the total PAs almost doubled, but that of spd and spm declined significantly. Petunia leaf protoplasts treated with cyclohexylamine (CHA), an inhibitor of spermidine synthase, accumulated ammonia and soluble putrescine, but lost the soluble spermidine. The soluble polyamine levels of CHA-treated petunia leaf protoplasts corresponded with those in B. napus . Leaves were subjected to abiotic stress during the isolation of protoplasts, namely wounding and osmotic stress which changed soluble free polyamine levels in B. napus and petunia, respectively. Both B. napus and petunia leaf protoplasts showed an increase in ammonia, but total free amino acid content and activation of proteases were only enhanced in B. napus leaf protoplasts. These results suggest that in B. napus wounding initiated senescence of leaf protoplasts during their isolation, leading to a constant production of ethylene early in the culture.