Effect of ionizing irradiation of low intensity on the viability of Escherichia coli bacteria, cultivated in the salt buffer

The influence of 60Co gamma-ray irradiation of low intensity (0.35 Gy/min) on the viability of Escherichia coli B/r and Escherichia coli BS-1 bacteria cultivated in salt buffer in concentration of 10(8) cell/ml was investigated. It was shown that under the doses induced the cell killing about 60-75%, the irradiated bacteria, like intact cell, were killed during the incubation process, while after the doses induced the cell killing above 99% of cell population, the bacteria viability of the both strains was increased. The increase reaches a certain value on the 2-5 the days of bacterial incubation in this conditions. The nature of observed phenomenology is vague for the present.     

The influence of ionizing radiation of high intensity on the viability of Escherichia coli bacteria, cultivated in the salt buffer without nutrient additions

The influence of 60Co gamma-ray radiation of high intensity (85 Gy/min) on the viability of E. coli B/r and E. coli BS-1 bacteria, cultivated in salt buffer with the concentration about 10(8) cells/ml, was studied. It was determined that under the doses, which induce about 80% of death of the cells, the irradiated bacteria, just like the intact cells, die during the incubation processes, while under the doses induced the death of cells above 95%, the cells viability of the both strains increases and reaches the constant value by the byhend 2nd-5th days of incubation in these conditions. In the result of the differences of the reactions of the intact and irradiated with different doses of radiation microorganisms on the incubation during their postradiational period in the phosphate buffer we have the fact of the absence of the dependence of the effect from the dose, or the decreasing of the consequences of the radiation under the increasing of the dose of the radiation. The nature of this phenomenology while stays not understood.     

The effects of electromagnetic radiation of extremely high frequency and low intensity on the growth rate of bacteria Escherichia coli and the role of medium pH

It has been shown that coherent electromagnetic irradiation (EMI) of extremely high frequency (45-53 GHz) or millimeter waves (wavelength 5.6-6.7 mm) of low intensity (flux capacity 0.06 mW/cm2) of Escherichia coli K12, grown under anaerobic conditions during the fermentation of sugar (glucose) for 30 min or 1 h, caused a decrease in their growth rate, the maximum inhibitory effect being achieved at a frequency of 51.8 or 53 GHz. This effect depended on medium pH when the maximal action was determined at pH 7.5. In addition, separate 30-min of 1-h irradiation (frequency 51.8 or 53 GHz) of doubly distilled water or some inorganic ions contained in Tris-phosphate buffer where the cells were transferred induced oppositely directed changes in further growth of these bacteria under anaerobic conditions; irradiation of water caused a decrease in the growth rate of bacteria. A significant change in pH of water (0.5-1.5 unit) was induced by a 30-irradiation at a frequency of 49, 50.3, 51.8, or 53 GHz, when the initial pH value was 6.0 or 8.0, but not 7.5. These results indicate the changes in the properties of water and its role in the effects of EMI of extremely high frequency. The marked effect of EMI on bacteria disappeared upon repeated irradiation for 1 h at a frequency of 51.8 or 53 GHz with an interval of 2 hours. This result indicates some compensatory mechanisms in bacteria.     

R46 and pKM101 plasmid-mediated resistance to ionizing radiation in Escherichia coli

The ability of the R46 R factor and its derivative pKM101 to modify sensitivity to 60Co gamma radiation was studied. In Escherichia coli K12 both plasmids enhanced bacterial survival after 60Co gamma irradiation. This effect was dependent on recA+ genotype but not on recB+, recB+ recC+, and recF+ genotypes. 5-Fluorouracil eliminated the R46 R factor from the parent and its rec- mutant strains. These strains lost not only the antibiotic resistance coded for R46 R factor but their radioresistance as well.     

Mutagenic effect on Escherichia coli bacteria of 8-hydroxy-2'-deoxyguanosine--a DNA base damage product induced by oxygen radicals and ionizing radiation]

The effect of 8-oxo-2'-deoxyguanosine (8-oxo-dG) (8-hydroxydeoxyguanosine)--a DNA base damage product induced by oxygen radicals and irradiation on survival and mutagenesis in Escherichia coli strains C-600 and P-687 was investigated. Survival and mutagenesis curves, in dependence of 8-oxo-dG concentrations in the medium, ranging from 0.2 through 10 mM, were obtained. Bacterial survival at all 8-oxo-dG concentrations tested was shown to be no lesser than in the control. The mutagenic effect of 8-oxo-dG was tested by frequency of reversions in the absence of leucine and threonine. A non-linear dependence of mutagenesis on the concentration was observed. Linear increase in the amount of revertants took place at concentrations of 8-oxo-dG lower than 1 mM, and being kept constant at higher concentrations. Induction of SOS repair under the action of 8-oxo-dG in E. coli PQ37 strain was estimated according to alteration of activity of beta-galactosidase in the SOS chromotest. Weak induction of the SOS response was observed within the wide range of 8-oxo-dG concentration values, which points to a lack of genotoxicity and independence of mutagenesis on SOS repair.     

Interactions stabilizing DNA tertiary structure in the Escherichia coli chromosome investigated with ionizing radiation

The structure of the bacterial chromosome was investigated after introducing breaks in the DNA with gamma irradiation. It is demonstrated that irradiation of the chromosome in the cell prior to isolation results in partial unfolding of the isolated condensed DNA, while irradiation of the chromosome after it is released from the cell has no demonstrable effect on DNA folding. The results indicate that RNA/DNA interactions which stabilize DNA folds are unstable when breaks are introduced in the DNA prior to isolation of the chromosome. It is suggested that the supercoiled state of the DNA is required for the initial stabilization of some of the critical RNA/DNA interaction in the isolated nucleoid. However, some of these interactions are not affected by irradiation of the cells. Remnant supercoiling in partially relaxed chromosomes containing a limited number of DNA breaks has the same superhelical density as the unirradiated chromosome. This suggests that restraints on rotation of the packaged DNA are formed prior to the physical unwinding which occurs at the sites of the radiation induced DNA breaks. — Analysis of the in vitro irradiated chromosomes shows that there are 100+-30 domains of supercoiling per genome equivalent of DNA. The introduction of up to 50 double-strand breaks per nucleoid does not influence rotor speed effects of the sedimentation coefficient of the chromosome.     

Influence of low doses of ionizing radiation on tenascin expression in hybridoma cell systems

One of the achievements of the modern radiation ecology is the preparation and application of stable eukariotic cell lines to solve various problems occurring under exposure to ionizing radiation, especially to low doses. The detection of onco-fetal protein--tenascin in different embryonic and tumor cells of humans and animals supposes the probability of appropriate gene expression in lymphoid cells, including hybridomal cells. Using the immunochemical method, the study of tenascin expression in two mouse hybridomal lines was carried out. Tenascin was revealed in hybridomal lines MLC-1 and K-48. Further hybridomal cell lines were exposed to X-ray radiation (120 KV) with doses 2.10,15 cGy. The obtained results demonstrated the sensitivity of tenascin expression to low doses of ionizing radiation, that may be used as a convenient model of studying of genotoxic effects of various damaging ionizing agents on a cell level.     

Effect of laser radiation and combined ionizing and laser radiation on the cell-division time of bacteria

Irradiation of E. coli K-12 cells of the wild-type AB 1157 strain with helium-neon continuous laser radiation leads to a temporary delay in their division. The delay was found to be the same in cells exposed to ionizing radiation alone and in cells exposed to a combination of ionizing and laser radiation.     

Randomness of base substitution mutations induced in the lacI gene of Escherichia coli by ionizing radiation

The lacI system of Escherichia coli provides a method for monitoring mutational events at a large number of sites. Using this system, we have previously determined the mutational spectra for gamma-ray and beta-particle emissions resulting from the decay of tritium. Analysis of these mutational spectra reveals that base substitution mutations induced by ionizing radiation are distributed nearly randomly throughout the lacI gene and include all detectable substitution events. The distribution of ionizing radiation-induced mutagenesis is similar to the low frequency of occurrence mutational events induced by other SOS-dependent mutagens. The lack of an apparent nonrandom or high frequency of occurrence component seen with other SOS-dependent mutagens can be best explained as the result of the random interaction of ionizing radiation with the DNA bases leading to production of a variety of base substitutions.     

Influence of far-ultraviolet radiation on the permeability of the outer membrane of Escherichia coli

Far-ultraviolet radiation (254 nm) at a dose of 10, 20, and 30 J/m2 was found to disrupt the outer membrane permeability barrier of Escherichia coli to various antibiotics, dyes, and detergents. The degree of sensitization to these agents was proportional to the radiation dose. The irradiated cells showed a significant increase in the sensitivity of hydrophilic antibiotics (ampicillin, carbenicillin, penicillin), whereas much less sensitization was found towards hydrophobic probes (kanamycin, erythromycin, rifamycin SV, crystal violet, phenol, novobiocin) and detergents (dodecyl sulfate, bile salt, Triton X-100). The biochemical data and ultrastructural analysis of the outer membrane by freeze-etching have shown that the increase in phospholipid:protein ratio after irradiation had changed the architecture of the outer membrane from a highly asymmetric bilayer structure with densely packed lipopolysaccharide--protein particles on the outer half, to one predominantly exhibiting smooth phospholipid bilayer characteristics. The structure, composition, and barrier function of the outer membrane were restored to normal within 3 h of postirradiation incubation in nonproliferative medium. During this period, the acquisition of resistance towards a hydrophilic antibiotic (ampicillin) was faster than that for a hydrophobic agent (phenol).