RBE of densely ionizing radiation for wild-type and radiosensitive mutants of yeast

Survival curves were obtained for haploid and diploid yeasts, Saccharmyces cerevisiae, of wild-type strains and radiosensitive mutants exposed to γ-rays and α-particles. A correlation between the values of the relative biological effectiveness (RBE) of high-LET radiation and cell-repair capacity was found. The difference in radiosensitivities of the wild-type diploid strain and homozygous rad mutants incapable of recovery was significantly higher after low-LET radiation than after high-LET radiation. Possible reasons for the observed radiation responses to low- and high-LET exposure of yeast cells with various genotype are discussed.     

Genetic instability of colonies' morphologic characteristics in the yeast Saccharomyces cerevisiae. The influence of mutations of radiosensitivity]

The exposure to ionizing radiation of radiosensitive mutants of diploid yeast Saccharomyces cerevisiae deficient in double-strand break repair results in formation of morphologically unstable colonies. Some characteristics of this process were studied. The results obtained are consistent with the hypothesis on relationship between DNA double-strand breaks or their repair with the formation of unstable clones of diploid yeast cells.     

Comparative study of RBE of densely ionizing radiation for various types of cell death in yeast

A comparative study of the relative biological effectiveness (RBE) of alpha-particles 249Pu for reproductive and interphase forms of killing of haploid and diploid yeast cells of wild-type and their radiosensitive mutants has been carried out. The correlation between the RBE of alpha-particles and cell repair capacity was confirmed for reproductive death: it was the highest for diploid cells, smaller for haploid cells and the smallest for their radiosensitive mutants. To achieve the interphase cell killing much higher irradiation doses were used after which cells were incapable of liquid-holding recovery during the storing of exposed cells in non-nutrient media at 30 degrees C. The RBE values for this form of killing were significantly lower in comparison with reproductive death. These data are an additional argument supporting the point of view that the RBE of densely ionizing radiation is determined not merely by physical processes of energy absorption as it is traditionally believed but also by ability of cells to recover from DNA damages inflicted by ionizing radiation.     

Survival of diploid yeasts after gamma irradiation: genetic control of the maturation effect

A study was made of the influence of rad mutation, leading to radiosensitivity increase, on the effect of additional growth in diploid Saccharomyces cerevisiae yeast exposed to gamma-radiation. The most radiosensitive mutants of this series, rad52/rad52 and rad54/rad54, did not virtually vary from the wild type cells in the value of the additional growth effect. Some other mutants, for instance, rad53/rad53 and rad55/rad55, exhibited a significantly lesser effect of additional growth. It was shown that the effect of additional growth did not depend upon the rate of rapid and slow postirradiation recovery of the wild type cells. The results of the studies prompt the conclusion that the processes responsible for the additional growth effect and those responsible for recovery of cells from radiation damages are mutually independent.     

Survival and recovery of yeast cells after combined treatment with ionizing radiation and heat

Cell survival, recovery kinetics and inactivation forms after successive and simultaneous treatments with gamma rays (60Co) and high temperatures were studied in diploid yeast cells capable of recovery. Both the extent and the rate of the recovery were shown to be greatly decreased with increase in the duration of heat treatment (60 degrees C) followed by radiation and with increase in exposure temperature after simultaneous treatment with heat and radiation. A quantitative approach describing the recovery process was used to estimate the probability of recovery per unit time and the irreversible component of damage after the combined treatment with heat and radiation. It was shown that the probability of recovery was independent of the conditions of the treatment with heat and radiation, while the irreversible component gradually increased as a function of the duration of heat treatment (60 degrees C) after sequential treatment with heat and radiation and as a function of the exposure temperature after simultaneous treatment with heat and radiation. The increase in the irreversible component was accompanied by an increase in cell death without postirradiation division. It is concluded on this basis that the synergistic interaction of ionizing radiation and hyperthermia in yeast cells is not related to the impairment of the recovery capacity itself and that it may be attributed to an increased yield of irreversible damage.     

Dark recovery of diploid yeast cells after simultaneous exposure to UV-irradiation and hyperthermia

Quantitative regularities of dark recovery of wild-type diploid yeast cells of Saccharomyces cerevisiae simultaneously treated with UV-light (254 nm) and high temperatures (53-56 degrees C) were studied. Under this combined action, the constant of recovery, which defines the probability of elimination of the UV-radiation induced damage per unit of time, did not depend on the temperature of irradiation. It was shown that both the irreversible component of cell damage and the number of cells that died without division gradually increased as the temperature of exposure increased. It is concluded, on this basis, that the mechanism of synergistic interaction of UV-radiation and hyperthermia is related not to the inhibition of dark recovery itself, but to the increase in the shape of irreversibly damaged cells incapable of recovering from the induced damage.     

Caffeine enhancement of radiation killing in different strains of Saccharomyces cerevisiae.

Summary Haploid and diploid wild type strains, and three classes of radiation-sensitive mutants of Saccharomyces cerevisiae were tested for enhancement of UV-inactivation by caffeine in growth medium. In addition, the sensitizing effect of caffeine was studied in a haploid and a diploid wild type strain after gamma-irradiation. The drug sensitized the UV-irradiated cells of all strains except those reported to be only slightly UV-sensitive but highly sensitive to ionizing radiation. After gamma-irradiation, no caffeine-enhancement of killing was observed in stationary phase cells of either the haploid or the diploid strain. However, log-phase cells of both strains were partially sensitized.The results of both sets of experiments suggested that caffeine interferes with a recombinational repair occurring in cells in S or G2 phase.     

Overexpression of genes involved in vesicular trafficking to the vacuole defends against lethal effects of oxidative damage.

Anticancer bleomycins and structurally-related analogs are oxidative agents that mimic ionizing radiation in many of their cellular effects. The current study was designed to better understand this class of radiomimetic and oxidative drugs, and how cells defend against them to become resistant. Based on some of the properties conferred by the blm5-1 mutation of Saccharomyces cerevisiae, a multi-step cloning strategy was developed to search for genes that protect cells against oxidative damage and lethal effects of bleomycin treatments. The strategy employed blm5-1 mutant strains to search for genes that rescued the drug hypersensitivities conferred by the mutation, and utilized the inability of homozygous blm5-1 mutant diploid strains to grow at elevated temperatures. This approach identified the VPS3, VPS8 and PEP7 genes that function in vesicular trafficking between the endosome and the yeast vacuole via the carboxypeptidase Y (CpY) pathway. Mutant blm5-1 strains possess several phenotypic characteristics consistent with CpY mutants, including reduced mitotic growth rates and sporulative abilities. However, blm5-1 strains were not found to be defective in the transport of CpY into the vacuole. We suggest that the ability of the VPS3, VPS8 and PEP7 genes to rescue lethal effects of oxidative damage resulted from the overexpression of these genes.     

Qantitative description of mammalian cell recovery after combined exposure to ionizing radiation with chemical agents

The parameters of recovery of mammalian cells after exposure to ionizing radiation combined with chemical agents were calculated based on a mathematical model of post-radiation recovery. The data presented, in contrast to the previously published results, indicate that the inhibition of the recovery may be due either to the damage or disruption of the process of recovery or the increase in the part of irreversible damages from which the cells are incapable to recover; or both of these processes can be realized simultaneously. It is concluded that the combination of ionizing radiation with chemical agents that inhibit the recovery processes through the formation of irreversible damages or affect the probability of recovery can be a perspective way in terms of finding the most effective means to increase radiosensitivity.     

The evaluation of the role of recovery from potentially lethal and sublethal damages in the RBE of densely ionizing radiation

The new data confirming the relations between RBE and recovery of cells are presented. The quantitative evaluation of the contribution of potentially lethal and sublethal damage recovery in radiosensitivity of cells of various origin after exposure to low- and high-LET ionizing radiation was carried out. The conclusion about the greater contribution of potentially lethal damage recovery in the magnitude of RBE in comparison with sublethal damage recovery was made.     

The prognosis of the portion of irreversible radiation damages after simultaneous action of hyperthermia and ionizing radiation on yeast cells

The results of experimental research of diploid yeasts cells survival after simultaneous action of hyperthermia and ionizing radiation (60Co) have been described. It was shown that the cell ability to liquid holding recovery decreased with an increase in the temperature, at which the exposure was carried out. due to the increase in the irreversible component determining the relative part of radiation damage which cells are incapable to recover. To predict theoretically the relative part of irreversible radiation damage after combined action, the mathematical model was suggested taking into account the synergistic interaction of agents. Good correlation between experimental results and model prediction was demonstrated. The importance of the results obtained for the interpretation of the mechanism of synergistic interaction of various factors is discussed.     

Use of a genome-wide approach to identify new genes that control resistance of Saccharomyces cerevisiae to ionizing radiation

We have used the recently completed set of all homozygous diploid deletion mutants in budding yeast, S. cerevisiae, to screen for new mutants conferring sensitivity to ionizing radiation. In each strain a different open reading frame (ORF) has been replaced with a cassette containing unique 20-mer sequences that allow the relative abundance of each strain in a pool to be determined by hybridization to a high-density oligonucleotide array. Putative radiation-sensitive mutants were identified as having a reduced abundance in the pool of 4,627 individual deletion strains after irradiation. Of the top 33 strains most sensitive to radiation in this assay, 14 contained genes known to be involved in DNA repair. Eight of the remaining deletion mutants were studied. Only one, which deleted for the ORF YDR014W (which we name RAD61), conferred reproducible radiation sensitivity in both the haploid and diploid deletions and had no problem with spore viability when the haploid was backcrossed to wild-type. The rest showed only marginal sensitivity as haploids, and many had problems with spore viability when backcrossed, suggesting the presence of gross aneuploidy or polyploidy in strains initially presumed haploid. Our results emphasize that secondary mutations or deviations from euploidy can be a problem in screening this resource for sensitivity to ionizing radiation.     

Postreplication repair and PCNA modification in Schizosaccharomyces pombe

Ubiquitination of proliferating cell nuclear antigen (PCNA) plays a crucial role in regulating replication past DNA damage in eukaryotes, but the detailed mechanisms appear to vary in different organisms. We have examined the modification of PCNA in Schizosaccharomyces pombe. We find that, in response to UV irradiation, PCNA is mono- and poly-ubiquitinated in a manner similar to that in Saccharomyces cerevisiae. However in undamaged Schizosaccharomyces pombe cells, PCNA is ubiquitinated in S phase, whereas in S. cerevisiae it is sumoylated. Furthermore we find that, unlike in S. cerevisiae, mutants defective in ubiquitination of PCNA are also sensitive to ionizing radiation, and PCNA is ubiquitinated after exposure of cells to ionizing radiation, in a manner similar to the response to UV-irradiation. We show that PCNA modification and cell cycle checkpoints represent two independent signals in response to DNA damage. Finally, we unexpectedly find that PCNA is ubiquitinated in response to DNA damage when cells are arrested in G2.     

Dependence of the radiosensitivity of yeast cells on the LET of radiations. Experiments on haploid cells

The previously developed model was used to study the dependence of radiosensitivity (D0(-1) of Saccharomyces cerevisiae (the wild type and radiosensitive mutant) on linear energy transfer (LET) of ionizing radiation. D0(-1) (L) of haploid yeasts was shown to be associated, to a certain extent, with the capacity of radiation damages repair. As to the wild-type cells, the above function was represented by a curve showing a maximum, while a descending curve was characteristic of the radiosensitive mutant cells deficient in radiation damages repair. The influence of the repair processes on cell radiosensitivity decreased with increasing LET.     

Quantitative estimation of the recovery parameters of yeast cells irradiated in the presence of cysteamine

Study of the postirradiation recovery parameters of diploid yeast cells showed that the irreversible component of radiation damage was identical after the cell exposure in the presence and absence of cysteamine. On this basis, it is concluded that the radioprotector equally reduced the number of both irreversible and repairable primary radiation damages. Application of the mathematical model of recovery processes to the results obtained allowed us to draw a conclusion that the probability of cell recovery from the radiation damage per time unit was also identical after cell exposure in the presence and absence of cysteamine.     

Comparisons of the effects of vacuum-uv and far-uv synchrotron radiation on dry yeast cells of different uv sensitivities

Far-uv-sensitive (rad l/rad l) and wild-type cells of diploid Saccharomyces cerevisiae were irradiated in vacuum at 155, 170, 220, and 250 nm using synchrotron radiation (SR). Inactivation, gene conversion at leu l, and membrane damage as judged by methylene blue penetration were measured. Radiations of all these wavelengths killed dry yeast cells. In the vacuum uv, radiation at 155 and 170 nm induced membrane damage but not gene conversion, whereas far-uv radiation at 220 and 250 nm induced gene conversion but not membrane damage. The far-uv-sensitive strain showed no enhanced sensitivity to vacuum-uv radiation. These results indicate that damage to the cell membrane is considerably more important than to nuclear DNA for yeast cell inactivation by vacuum-uv radiation.     

Recovery of yeast cells after exposure to ionizing radiation and hyperthermia

Quantitative regularities of recovery of wild-type diploid yeast cells irradiated with gamma-rays (60Co) simultaneously with exposure to high temperatures were studied. It was shown that in conditions of such a combined action the constant of recovery did not depend on the temperature at which the irradiation was carried out. However, with an increase of acting temperature an augmentation in the portion of irreversible component was registered. The analysis of cell inactivation revealed that the augmentation of the irreversible component was accompanied by a continuous increase of cell killing without any postirradiation division after which cells are incapable of recovery. The reproductive death was mainly exerted after ionizing radiation applied alone while in conditions of simultaneous thermoradiation action the interphase killing (cell death without division) predominated. It is concluded on this base that the mechanism of synergistic interaction of ionizing radiation and hyperthermia may be related with cardinal change in mechanisms of cell killing.