G.P. van der Schans

DNA Strand Break and Rejoining in Cultured Human Fibroblasts Exposed to Fast Neutrons or Gamma Rays

The production and rejoining of DNA single-strand and double-strand breaks have been monitored in monolayer cultures of proliferating human skin fibroblasts by means of sensitive techniques. Cells were irradiated with low doses of either 60Co gamma-rays or 14.6 MeV neutrons at 0 degrees C (0-5 Gy for measurement of single-strand breaks by alkaline elution and 0-50 Gy for double-strand breaks measured by neutral elution). The yield of single-strand breaks induced by neutrons was 30 per cent of that produced by the same dose of gamma-rays; whilst in the induction of double-strand breaks neutrons were 1.6 times as effective as gamma-rays. Upon post-irradiation incubation of cells at 37 degrees C, neutron-induced single-strand and double-strand breaks were rejoined with a similar time-course to gamma-induced breaks. Rejoining followed biphasic kinetics; of the single-strand breaks, 50 per cent disappeared within 2 min after gamma-rays and 6-10 min after neutrons. Fifty per cent of the double-strand breaks disappeared within 10 min, after gamma-rays and neutrons. Cells derived from patients suffering from ataxia-telangiectasia showed the same capacity for repair of single- and double-strand breaks induced by 14.6 MeV neutrons, as cells established from normal donors. The comparison of neutrons and gamma-rays in the induction of DNA breaks did not explain the elevated r.b.e. on high LET radiation. However, a study of the variation in the spectrum of lesions induced by different radiation sources will probably contribute to the clarification of the relative importance of other radio products.

Contribution of various types of damage to inactivation of a biologically-active double-stranded circular DNA by gamma-radiation.

SummaryThe double-stranded circular DNA of the bacteriophage PM2 has been irradiated in oxygenated solution by 60Co gamma rays. The following quantities have been determined as a function of dose: The average number of single-strand breaks and that of double-strand breaks per molecule, the biological activity of the irradiated sample as such, the biological activity after mild denaturation (to denature molecules containing a break) and the biological activity after denaturation and membrane filtration (i.e. the biological activity of DNA without single- and double-strand breaks.)From the collected data it can be deduced that 4·5 ± 0·5 per cent of the inactivation is a consequence of double-strand breaks, 8·5 ± 4·2 per cent of single-strand breaks and 87·0 ± 4·2 per cent of nucleotide damage. Only about 2 per cent of the single-strand breaks is lethal, whereas the efficiency of inactivation of nucleotide damage is about 30 per cent of the nucleotide damage which is lethal if present in single-stranded DNA....

Immunochemical detection of DNA damage induction and repair at different cellular stages of spermatogenesis of the hamster after in vitro or in vivo exposure to ionizing radiation

An immunochemical method has been used to detect quantitatively DNA damage caused by ionizing radiation in germ cells. With this method, DNA strand breaks as well as lesions converted into breaks in alkaline medium are measured as a function of controlled partial unwinding of the DNA, a time-dependent process starting at each breakage site, followed by the determination of the relative amount of single-stranded regions by use of a single-strand specific monoclonal antibody. With this method the induction and repair of DNA damage in different cellular stages of spermatogenesis (spermatocytes, round and elongated spermatids) of the hamster were investigated. Germ cells were irradiated in vitro with 60Co-gamma-rays, at doses between 0 and 5 Gy. A linear dose-response relationship was observed. Spermatocytes and round spermatids had normal, fast repair of the lesions when compared with the repair of these sites in cultured V79 or CHO cells and human lymphocytes. The elongated spermatids, however, showed hardly any repair. Similar results were obtained after the in vivo gamma-irradiation of hamsters with doses of 0. 4, and 8 Gy and subsequent isolation of germ cells. The damage was still detectable in the elongated spermatids at 24 h after exposure. The results of the experiments show substantial differences in repair capacity between different stages of germ cell development. Because DNA is the major target for mutation induction, this assay may be useful for assessment of the genetic risk of exposure of male germ cells to ionizing radiation, in relation to the stage of development.

Induction and repair of DNA single-strand breaks and DNA base damage at different cellular stages of spermatogenesis of the hamster upon in vitro exposure to ionizing radiation

Alkaline elution has been used for quantitative detection of DNA damage caused by ionizing radiation in unlabeled somatic and germ cells. Both the induction and subsequent repair have been studied for two classes of DNA damage, viz. single-strand breaks (SSB), and base damage (BD) recognized by the gamma-endonuclease activity in a cell-free extract of Micrococcus luteus bacteria. The high sensitivity of the assay permitted the measurement of induction and repair of SSB and BD after in vitro exposure of hamster germ cells in different cellular stages of spermatogenesis (spermatocytes, round and elongated spermatids), and of bone-marrow cells, to biologically relevant doses (0-8 Gy) of 60Co gamma-rays. A dose-dependent increase was observed for both types of lesions, which was similar for most cell types. The elongated spermatids, however, showed a lower induction frequency of SSB (and perhaps BD). Spermatocytes, round spermatids and bone-marrow cells had normal, fast repair of the SSB when compared with the repair reported for cultured rodent cells and human lymphocytes. In contrast, the elongated spermatids showed hardly any SSB repair. The initial rate of repair of BD in spermatocytes and bone-marrow cells was in the same range as that for SSB, but only 60-70% of the initial BD was repaired within 1 h, whereas after that period no SSB were detectable. The round spermatids hardly repaired any BD within the first hour after irradiation, but after 7 h only a few BD could be detected. In elongated spermatids repair of BD could not be measured due to a high background level of this type of damage.

The Influence of Oxygen on the Induction of Radiation Damage in DNA in Mammalian Cells after Sensitization by Intracellular Glutathione Depletion

Treatment of mammalian cells with buthionine sulphoximine (BSO) or diethyl maleate (DEM) results in a decrease in the intracellular GSH (glutathione) and non-protein-bound SH (NPSH) levels. The effect of depletion of GSH and NPSH on radiosensitivity was studied in relation to the concentration of oxygen during irradiation. Single- and double-strand breaks (ssb and dsb) and cell killing were used as criteria for radiation damage. Under aerobic conditions, BSO and DEM treatment gave a small sensitization of 10-20 per cent for the three types of radiation damage. Also under severely hypoxic conditions (0.01 microM oxygen in the medium) the sensitizing effect of both compounds on the induction of ssb and dsb and on cell killing was small (0-30 per cent). At somewhat higher concentrations of oxygen (0.5-10 microM) however, the sensitization amounted to about 90 per cent for the induction of ssb and dsb and about 50 per cent for cell killing. These results strengthen the widely accepted idea that intracellular SH-compounds compete with oxygen and other electron-affinic radiosensitizers with respect to reaction with radiation-induced damage, thus preventing the fixation of DNA damages by oxygen. These results imply that the extent to which SH-compounds affect the radiosensitivity of cells in vivo depends strongly on the local concentration of oxygen.

Gamma-ray Induced Double-strand Breaks in DNA Resulting from Randomly-inflicted Single-strand Breaks: Temporal Local Denaturation, a New Radiation Phenomenon?

SummaryThe induction of single- and double-strand breaks in DNA by γ-rays has been measured. The maximum number of nucleotide pairs (a) between two independently induced single-strand breaks in opposite strands of the DNA which cannot prevent the occurrence of a double-strand break was found to amount to about 16. This value did not differ significantly for the four types of bacteriophage DNA investigated (T4, T7 and PM2 DNA, and replicative form DNA of phage ϕX174) and was the same in 10−2 M phosphate buffer containing 0, 0·5 or 1 M NaCl. In 10−3 M phosphate buffer a was 34 nucleotide pairs.Evidence is presented that the relatively large value of a has to be ascribed at least partly to a temporal local denaturation accompanying the induction of a single-strand scission. A contribution of base damage that labilizes the DNA-helix, between two single-strand breaks to the high value of a can not be excluded.

The influence of oxygen and sulphhydryl compounds on the production of breaks in bacteriophage DNA by gamma-rays.

SummaryAfter irradiation of T4 or T7 bacteriophage with γ-rays, the DNA was isolated and analysed for double- and single-strand breaks by sedimentation in a sucrose gradient.In the absence of oxygen, the number of double-strand breaks per krad and per molecular weight of 109 daltons is 0·04. In the presence of oxygen it is 0·08. The yield of single-strand breaks is 10 to 20 times higher than that of double-strand breaks.It is shown that in bacteriophage the increase of the production of DNA breaks by oxygen does not manifest itself as an increased sensitivity of the bacteriophage as a whole, because the presence of oxygen prevents other types of damage, presumably in the protein coat. If sulphhydryl compounds are present the yield of breaks is not much affected, but the amount of other damage is considerably reduced. A normal oxygen effect is then observed.

Detection of DNA Damage in Cells Exposed to Ionizing Radiation by Use of Anti-single-stranded DNA Monoclonal Antibody

An immunochemical method has been developed for quantitative detection of DNA damage in mammalian cells. The method is based on the binding of a monoclonal antibody to single-stranded DNA. The clone producing this antibody (D1B) was obtained as a by-product from fusion of mouse myeloma cells with spleen cells isolated from a mouse immunized with chemically modified DNA. The technique is based upon the determination of the percentage single-strandedness resulting from the time-dependent partial unwinding of cellular DNA under alkaline conditions. Single- and double-strand DNA breaks, or lesions converted into such breaks in alkaline medium, form initiation points for the unwinding. The extent of unwinding from these points under defined conditions is a measure of the number of such sites. The method is rapid, does not require radioactive labelling of DNA or physical separation of single-from double-stranded molecules, is sufficiently sensitive to detect damage induced by 1 Gy of ionizing radiation and needs only small numbers of cells. The usefulness of the technique was demonstrated in a study of the induction of DNA damage and its repair in cultured Chinese hamster cells and in human white blood cells after exposure to 60Co-gamma-rays, and in white blood cells and bone marrow cells of X-irradiated mice. A dose-related DNA unwinding was observed and repair of DNA lesions was observed up to 60 min after irradiation.

Reduction of Intracellular Glutathione Content and Radiosensitivity

The intracellular glutathione (GSH) content of HeLa, CHO and V79 cells was reduced by incubating the cells in growth medium containing buthionine sulphoximine or diethyl maleate (DEM). Clonogenicity, single-strand DNA breaks (ssb) and double-strand DNA breaks (dsb) were used as criteria for radiation-induced damage after X- or gamma-irradiation. In survival experiments, DEM gave a slightly larger sensitization although it gave a smaller reduction of the intracellular GSH. In general, sensitization was larger for dsb than for ssb, also the reduction of the o.e.r. was generally larger for dsb than for ssb. This may be due to the higher dose rate in case of dsb experiments resulting in a higher rate of radiochemical oxygen consumption. In general, no effect was found on post-irradiation repair of ssb and dsb.

Inhibition of repair of X-ray-induced DNA double-strand breaks in human lymphocytes exposed to sodium butyrate

Purpose : Sodium butyrate is known to inhibit histone deacetylase enzymes and to enhance the frequencies of X-ray-induced dicentrics and rings in human lymphocytes. In this study an investigation was made of the mechanisms underlying this enhancement by assessing the effect of sodium butyrate on the extent of X-ray-induced DNA damage and its repair in human peripheral blood lymphocytes. Methods and materials : Unstimulated G 0 lymphocytes were pre-treated for 24h with sodium butyrate at a final concentration of 5 mM, irradiated with different doses of X-rays and then analysed for different endpoints either immediately or after different repair periods. The frequencies of DNA strand breaks were determined biochemically using nucleoid sedimentation, alkaline elution and immunochemical analysis as well as cytogenetically using the premature chromosome condensation (PCC) technique. Results : The results show that sodium butyrate pre-treatment does not lead to a significant increase of DNA double- or single-strand breaks nor to an increase of alkali labile base damage in G 0 lymphocytes. Moreover, sodium butyrate treatment had no effect on the initial frequency of chromosome breaks. However, PCC analysis clearly showed that the presence of sodium butyrate post-irradiation severely inhibited DNA double-strand break (DSB) repair, which most likely accounts for the increase in X-ray-induced chromosome aberrations. Conclusions : Sodium butyrate treatment leading to changes in histone acetylation and increased accessibility of chromatin had no effect on the initial levels of X-ray-induced DNA damage. However, sodium butyrate may affect either the chromatin configuration or the enzymatic activities that play a key role in the repair of DSB.PURPOSE Sodium butyrate is known to inhibit histone deacetylase enzymes and to enhance the frequencies of X-ray-induced dicentrics and rings in human lymphocytes. In this study an investigation was made of the mechanisms underlying this enhancement by assessing the effect of sodium butyrate on the extent of X-ray-induced DNA damage and its repair in human peripheral blood lymphocytes. METHODS AND MATERIALS Unstimulated G0 lymphocytes were pretreated for 24h with sodium butyrate at a final concentration of 5 mM, irradiated with different doses of X-rays and then analysed for different endpoints either immediately or after different repair periods. The frequencies of DNA strand breaks were determined biochemically using nucleoid sedimentation, alkaline elution and immunochemical analysis as well as cytogenetically using the premature chromosome condensation (PCC) technique. RESULTS The results show that sodium butyrate pretreatment does not lead to a significant increase of DNA double- or single-strand breaks nor to an increase of alkali labile base damage in G0 lymphocytes. Moreover, sodium butyrate treatment had no effect on the initial frequency of chromosome breaks. However, PCC analysis clearly showed that the presence of sodium butyrate post-irradiation severely inhibited DNA double-strand break (DSB) repair, which most likely accounts for the increase in X-ray-induced chromosome aberrations. CONCLUSIONS Sodium butyrate treatment leading to changes in histone acetylation and increased accessibility of chromatin had no effect on the initial levels of X-ray-induced DNA damage. However, sodium butyrate may affect either the chromatin configuration or the enzymatic activities that play a key role in the repair of DSB.