Bimodal changes in germinability of pea seeds under the influence of low doses of gamma-radiation

Pea seeds (cv. 'Nemchinovskii-85', harvest of 2002, 80%-germination percentage) were exposed to gamma-radiation with doses ranging from 19 cGy to 100 Gy. One week after the irradiation with doses of 19 cGy and 3 Gy. the germination percentage decreased to 58 and 45%, respectively; at doses of 7 and 10 Gy it was 73 and 70% respectively. At greater doses (25, 50, and 100 Gy), germination percentage decreased in proportion. Anomalous changes in seed germination percentage (as a function of irradiation dose) were caused by the redistribution of irradiated seeds between fractions I and II. The measurements of room temperature phosphorescence in air-dry seeds and the phosphorescence of endogenous porphyrines of imbibing seeds showen that the germination decrease after the irradiation with low doses (19 cGy and 3 Gy) was caused by the increase in the number of weak seeds of fraction II, which had high rates of water uptake and suffered from hypoxia under seed coat. Some of these seeds suffocated from hypoxia, and other seeds produced seedlings with morphological defects (such seeds were considered incapable of germination). During storage of seeds irradiated at doses 19 cGy-10 Gy, the recovery of germination percentage (after its initial decrease) was caused by the decrease in seed number in fraction II. The subsequent germination decrease was caused by seed death. The higher was the irradiation dose, the faster were changes in germination percentage during storage of irradiated seeds. Bimodal changes in pea seed germination with the increase of y-irradiation dose has apparently the same origin as the changes in seed germination during accelerated ageing.     

The disruption of aquaporin function in cell membranes as a cause of changes in germinability of pea seeds after exposure to low doses of gamma-radiation

Pea seeds (Pisum sativum L.) from the seed lot with 80% germinability were separated in fractions according to room temperature phosphorescence: strong seeds were assigned to fraction I, and weak seeds formed to fraction II. During imbibition, the seeds of fraction II exhibited twofold higher rates of water uptake and experienced hypoxia. Some of these seeds suffocated from hypoxia, and other seeds produced seedlings with morphological defects (such seeds were considered incapable of germination). One week after irradiation with the dose of 3 Gy, germination percentage decreased to 45%, which was caused by the increase of number of weak seeds. The germinability of seeds subjected to gamma-irradiation at doses of 7 and 10 Gy was similar to that of control seeds. In these sub-lots, there appeared so-called "improved" seeds, which were similar to non-irradiated seeds in terms of phosphorescence level, the rate of water uptake and germination percentage. It was shown with the use of PCMB that the difference in the rates of water uptake by seeds of fraction I and II depended on the permeability of cell membranes. The permeability was determined by the state of aquaporins ("open"-"closed"). The experiments with phosphatase inhibitor (NaF) shown that in seeds irradiated with dose of 3 Gy (fraction II), the mechanism of aquaporins closing was broken (phosphatase was inactivated). In "improved" seeds (after irradiation with dose of 10 Gy), aquaporins were closed irreversibly in air-dry state, when aquaporin dephosphorylation was unlikely. It was concluded that the abnormal increase (following the initially decrease) in germination of pea seeds after irradiation can be explained without invoking the hypothesis on hyper function of reparatory mechanism of at low doses of irradiation.     

Features of action of low doses of gamma-radiation on yeast cells

Lethal effect of low doses and adaptive response to low doses of prolonged irradiation were investigated in experiments on yeast cells. The phenomenon of hypersensitivity at low dozes was not found in yeast cells at gamma-irradiation. The adaptive response was observed after exposure to low doses of prolonged irradiation, the degree of the reaction depends on a dose rate. The adaptive reaction was kept for some time after the termination of adaptive irradiation then the sensitivity of cells increased even in comparison with unirradiated ones.     

Delayed luminescence of air-dry soybean seeds as a measure of their viability

Delayed luminescence (DL) excited by visible light has been observed in air-dry seeds of various plants. Changes in seeds of soybeans ( Glycine max L. W.) which occur during natural and accelerated aging were reflected in subsequent loss of vigor and DL increase. The increase of the luminescence is caused by the changes in seed biopolymers, leading to a decrease in their ability to take up water. The method makes it possible to measure DL from a single seed. With aging, the DL was shifted toward higher intensities and there was greater variability. By monitoring the DL of seeds it may be possible to evaluate their quality and storage capability.     

Glucokinase of pea seeds.

1. Glucokinase (ATP : D-glucose 6-phosphotransferase, EC 2.7.1.2) was extracted from pea seeds and purified by fractionation with (NH4)2SO4 and chromatography on DEAE-cellulose and Sephadex. 2. The relative rates of phosphorylation of glucose, mannose and fructose (final concentration 5 mM) were 100, 64 and 11. 3. The Km for glucose of pea-seed glucokinase was 70 muM and the Km for mannose was 0.5 mM. The Km for fructose was much higher (30 mM). 4. Mg2+ ions were essential for activity. Mn2+ could partially replace Mg2+. 5. Enzyme activity was not inhibited by glucose 6-phosphate. A number of other metabolites had no effect on glucokinase activity. 6. Pea-seed glucokinase was inhibited by relatively low concentrations of ADP.     

The influence of the null le-2 mutation on gibberellin levels in developing pea seeds

The Le gene of pea encodes a gibberellin 3-hydroxylase. Heterologous expression of the le-2 allele indicated that a truncated protein was produced, confirming that le-2 is a null mutation. The Le expression product was unable to metabolise GA12, but was able to produce a small quantity of GA8 from GA29. The le-2 mutation had no effect on the levels of GA1, GA4 or GA8 in developing seeds. Measurements of mRNA levels indicate that the Le gene is only weakly expressed in young pea seeds. These results explain why mutant alleles at the Le locus have no major impact on seed development, even though 3-hydroxylated GAs are essential for normal seed development in pea. Rather, a second 3-hydroxylase, with a different substrate specificity, may be expressed in young seeds, resulting in a different biosynthetic pathway leading to the biologically active GAs.     

The effects of low doses of low-level gamma-radiation and phenozan injection on structural characteristics of mice spleen DNA

It is well known that AKR mice with spontaneous leucosis are more sensitive to ionizing irradiation as compared to normal F1 (CBA x C57BL) mice. A study on changes of the structural characteristics of spleen DNA and level of protein p53 in the blood serum under the action of low-level gamma-irradiation in a dose of 1.2 cGy and injections of 10(-14) or 10(-4) mol/kg phenozan was performed. The changes in the structural characteristics of DNA (the adsorption on nitrocellulose filters and number of double-strand breaks) and p53 content were observed for each line of mice under gamma-irradiation and each phenozan concentration. Both factors showed long-time post-effects, and structural changes in AKR DNA were consistent with the life span of these mice. Phenozan in the above doses has abolished the induction of double-strand breaks in case of irradiation of F1 mice in a dose of 1.2 cGy and showed long-time post-irradiation effect. These facts suggest a radioprotection property of phenozan.     

The role of membrane receptors in stimulating cell multiplication under the influence of low doses of atomic radiation]

In experiments with Raji cells, it has been shown that the serum growth factors activate the growth of gamma-irradiated (0.36 mGy/day) culture. The authors discuss the role of radiation stimulation of membrane receptors in recepting natural effectors.