Aim. Analysis of physiological and biochemical characteristics and grain productivity traits of transgenic common wheat
plants (Triticum aestivum L.) with a double-stranded RNA suppressor of the proline dehydrogenase gene (pdh) compared
to non-transgenic genotypes under conditions of soil drought. Methods. Biochemical assays: spectrophotometric
measurements of antioxidant enzymes (SOD, APX) activity, proline dehydrogenase activity and free L-proline content;
biotechnological assays: Agrobacterium-mediated transformation in planta; physiological: morphometric traits and elements
of grain productivity; mathematical statistics. Results. The presence of a double-stranded RNA suppressor of the
gene pdh in transgenic plants leads not only to a decrease in enzyme activity (on average 2 times compared to the nontransgenic
plants), but also to an increase in the content of free L-proline both under optimal conditions and under soil
drought (2.6–4.1 times). Under soil moisture defi ciency, transgenic plants with reduced pdh gene activity in terms of yield
structure signifi cantly exceeded the corresponding values of grain productivity elements for the non-transformed ones.
In terms of the grain weight from the main stem, the biotechnological plants under soil moisture defi ciency exceeded the
control plants 1.5–1.6 times, while the number of grains did not differ signifi cantly. The grain productivity of the whole
plant in the transformed lines under conditions of soil moisture defi ciency was somewhat inferior to those in the nontransformed
plants grown under optimal conditions. Soil drought caused a signifi cant increase in SOD and APX activity
(by 40 and 11 %, respectively) in plants of the original variety. On the contrary, the activity of both antioxidant enzymes
under drought conditions in transgenic plants decreased: SOD – down to 73–76 %, APX – down to 82–86 %, compared
with the variant of 70 % of fi eld capacity. Conclusions. The analysis of physiological and biochemical characteristics,
as well as economic and grain productivity elements of transgenic common wheat plants with a double-stranded RNA
suppressor of the proline dehydrogenase gene showed their increased tolerance to soil drought, compared with non-transgenic
genotypes, which may be associated with higher proline accumulation and an increase in the antioxidant enzymes
activity. Under soil moisture defi ciency, transgenic wheat plants with reduced pdh gene activity signifi cantly exceeded the
corresponding values of grain productivity elements for non-transformed plants. The analysis of the antioxidant enzymes
activity in the chloroplasts of transgenic plants showed that under physiological conditions, the antioxidant system works
more actively in comparison with non-transgenic genotypes, which may be a prerequisite for increasing the tolerance of
these plants to the infl uence of stressors of various origin. It is likely that the positive relationship between the level of free
L-proline and the resistance of transgenic wheat plants to osmotic stress is associated either with the effect of L-proline
on the expression of other genes of the stress-strain response of plants, or with the positive effect of the increased content
of this amino acid on resistance at the early stages of stress development. It has been suggested that an increase in the
antioxidant enzymes activity in biotechnological plants can be caused by the expression of heterologous genes.
Changes in the ionome of genetically modified corn plants with double-stranded RNA-suppressor of proline dehydrogenase gene
