Repair of gamma-irradiation-induced DNA single-strand breaks in human bone marrow cells: effects of a second irradiation

Radiation-Induced DNA Damage in Uveal Melanoma Is Influenced by Dose Delivery and Chromosome 3 Status

Purpose

The purpose of this study was to analyze the extent of DNA breaks in primary uveal melanoma (UM) with regard to radiotherapy dose delivery (single-dose versus fractionated) and monosomy 3 status.

Methods

A total of 54 patients with UM were included. Stereotactic radiotherapy (SRT) was performed in 23 patients, with 8 undergoing single-dose SRT (sdSRT) treatment and 15 receiving fractionated SRT (fSRT). DNA breaks in the enucleated or endoresected tumors were visualized by a TUNEL assay and quantified by measuring the TUNEL-positive area. Protein expression was analyzed by immunohistochemistry. Co-detection of chromosome 3 with proteins was performed by immuno-fluorescent in situ hybridization.

Results

The amount of DNA breaks in the total irradiated group was increased by 2.7-fold (P < 0.001) compared to non-irradiated tissue. Tumors treated with fSRT were affected more severely, showing 2.1-fold more DNA damage (P = 0.007) compared to the cases after single (high) dose irradiation (sdSRT). Monosomy 3 tumors showed less DNA breaks compared to disomy 3 samples (P = 0.004). The presence of metastases after radiotherapy correlated with monosomy 3 and less DNA breaks compared to patients with non-metastatic cancer in the combined group with fSRT and sdSRT (P < 0.05).

Conclusions

Fractionated irradiation led to more DNA damage than single-dose treatment in primary UM. As tumors with monosomy 3 showed less DNA breaks than those with disomy 3, this may indicate that they are less radiosensitive, which may influence the efficacy of irradiation.

Fourier transform IR spectroscopic appraisal of radiation damage in Micrococcus luteus

Fourier transform IR spectroscopy (FTIR) is used to analyze cells of Micrococcus luteus, the type species of the highly heterogeneous genus Micrococcus that belongs to the Micrococcaceae family. The cells of M. luteus, which is a Gram-positive and yellow-pigmented bacterium, are submitted to increasing doses of gamma radiation. Irradiation leads to the generation of reactive oxygen species that induce biochemical changes as shown in spectral profiles. Beyond a dose of 0.70 kGy, significant differences between samples are observed, particularly in the 1485-900 cm(-1) region, which contains information about membrane lipids, cell wall polysaccharides, and nucleic acids. After a dose of 16.50 kGy, M. luteus is reincubated for times ranging from 1 to 24 h. Postirradiation reincubated bacteria are found far from the control and irradiated cells (mainly in the 985-900 cm(-1) range), suggesting that a biomolecular rearrangement occurs as soon as reincubation begins in the growth medium. Thus, FTIR spectroscopy appears to be a very useful technique for the rapid visualization of the alterations induced by both the radiation and mutagenic response during reincubation. The use of mathematical methods gives good insight into the biomolecular compounds involved in these two mechanisms. In view of these preliminary results, we hypothesize that it can be successfully applied to any type of tissue and that it may be a future interesting tool for evaluating the effects of radiation in humans.

Detection of DNA single-strand breaks and glutathione in mononuclear blood cells of radiotherapy technicians

We wanted to investigate the effects of gamma radiation on DNA single-strand breaks (SSB) and glutathione (GSH) levels in mononuclear blood cells (MNC) of radiotherapy technicians. DNA SSB in MNC of radiotherapy technicians who use (60)Co-gamma source in their works were detected by alkaline filter elution and compared to control subjects. In addition, GSH levels were measured using the enzymatic method in MNC. Blood samples were collected from radiotherapy technicians on Monday and Friday. DNA SSB levels were found to be significantly higher in smoking controls compared to non-smoking controls. Significant increases of 36% and 49% in DNA SSB were detected from Monday to Friday for non-smoking and smoking radiotherapy technicians, respectively. GSH levels were found to be decreased significantly from Monday to Friday. Gamma-radiation resulted in increased DNA SSB levels of MNC in radiotherapy technicians throughout the working week and these breaks have been observed to be repaired at the weekend. Smoking habit caused an additional increase in the SSBs observed in radiotherapy technicians.

Kinetics of excision repair of UV-induced DNA damage, measured using the comet assay

The kinetics of UV- (254 nm) irradiation-induced DNA single-strand breaks (SSBs), generated during the excision repair of UV-induced DNA damage, in leukemic lymphocytes and in normal blood mononuclear cells (MNCs) were studied using the alkaline comet assay. The cells were isolated by density gradient centrifugation from peripheral blood of patients with chronic lymphocytic leukemia (CLL) and from healthy study subjects. The cytotoxicity of UV irradiation was determined in vitro in peripheral blood mononuclear lymphocytes from 36 CLL patients and from eight healthy donors using the incorporation of radioactive leucine in 4-day cultures. A remarkable difference in excision repair capability was observed between normal and leukemic lymphocytes. In contrast to normal lymphocytes, there was always a subpopulation of CLL cells that did not complete the repair of UV-induced DNA damage during the 24-h repair period. Furthermore, differences were also recorded between UV-sensitive and UV-resistant CLL cases. The differences in DNA migration between the maximum increase (59-77 microm) and that at 24 h after irradiation (21-66 microm) was statistically significant in two of three patients exhibiting UV-resistance. Correspondingly, only in one of three patients exhibiting UV-sensitivity was the difference in DNA migration statistically significant (maximum increase: 44-107 microm, vs. 24 h after: 42-100 microm). Our results confirm an abnormal pattern of the CLL cell response to UV irradiation. Furthermore, we identified defective processing of UV-induced DNA damage in CLL versus normal lymphocytes, particularly in UV-sensitive cases.

Increased DNA single-strand break joining activity in UV-irradiated CD34+ versus CD34- bone marrow cells

The kinetics of UV-irradiation-induced (254 nm) DNA single-strand breaks (SSBs) were studied in single human hematopoietic cells using alkaline comet assay. Three cell populations were investigated: (i) Bone marrow mononuclear cells (BMMNCs) isolated by density gradient centrifugation, (ii) CD34- cells, and (iii) CD34+ cells. The two latter populations were purified from BMMNCs by negative and positive selection, respectively, using anti-CD34 immunobeads. SSBs were induced faster by 10 and 50 J/m2 than by 2 J/m2 and those caused by 2 J/m2 were joined faster that those caused by 10 or 50 J/m2. During the first 1.5 h after irradiation with a dose of 10 J/m2, CD34+ cells joined SSBs faster than did BMMNCs. The superior joining capacity of CD34+ cells was further substantiated with a higher UV dose. The comet lengths, indicating the extent of DNA repair, among 8/8 study subjects were shorter in CD34+ than in CD34- cells when assessed 24 h after a dose of 50 J/m2. Overall, the comet lengths at 24 h after irradiation were: CD34+ cells; 39+/-12 *m, and CD34- cells; 65+/-18 *m (8 subjects, 50 cells measured from each donor, mean+/-S.D.; p=0.0087, Mann-Whitney U-test). These results strongly suggest that nucleotide excision repair, the major mechanism responsible for the repair of UV-irradiation-induced DNA lesions in mammalian cells, is increased in CD34+ cells compared with CD34- cells and with BMMNCs. These results may have implications in stem cell purging, clinical chemotherapy and carcinogenesis.

Single cell gel electrophoresis assay: methodology and applications

The single cell gel electrophoresis or Comet assay is a sensitive, reliable, and rapid method for DNA double- and single-strand breaks, alkali-labile sites and delayed repair site detection, in eukaryotic individual cells. Given its overall characteristics, this method has been widely used over the past few years in several different areas. In this paper we review the studies published to date about the principles, the basic methodology with currently used variations. We also explore the applications of this assay in: genotoxicology, clinical area, DNA repair studies, environmental biomonitoring and human monitoring.

Modeling radioprotective mechanisms in the dose effect relation at low doses and low dose rates of ionizing radiation

A new model (Random Coincidence Model--Radiation Adapted (RCM-RA)) is proposed which explains a possible pseudo threshold for stochastic radiation effects. It describes the formation of cancer in the case of multistep fixation of lesions in the critical regions of tumor associated genes such as proto-oncogenes or tumor-suppressor genes. The RCM-RA contains two different possibilities of DNA damage to complementary nucleotides. The damage may be caused either by radiation or by natural processes such as cellular radicals or thermal damage or by chemical cytotoxins. The model is based on the premise that radiation initially is bionegative, damaging organisms at their different levels of organization. The radiation, however, also induces various cellular radioprotective mechanisms which decrease the damage by natural processes. Considering both effects together, the theory explains apparent thresholds in the dose-response relation for radiation carcinogenesis without contradiction to the classical assumption that radiation is predominantly bionegative at doses typically found in occupational exposures.

Repair of gamma-irradiation-induced DNA single-strand breaks in human bone marrow cells: analysis of unfractionated and CD34+ cells using single-cell gel electrophoresis

Human bone marrow mononuclear cells (BMMNCs) were separated by density gradient centrifugation, and a subpopulation of progenitor cells was further isolated using anti-CD34-coated magnetic beads. The cells were irradiated with gamma-rays (0.93-5.43 Gy) from a 137Cs source. The extent of DNA damage, i.e., single-strand breaks (SSBs) and alkali-labile lesions of individual cells, was investigated using the alkaline single-cell gel electrophoresis technique. The irradiation resulted in a dose-dependent increase in DNA migration, reflecting the number of detectable DNA lesions. An approximately similar extent of SSB formation was observed in BMMNCs and CD34 + cells. Damage was repaired when the cells were incubated at 37 degrees C: a fast initial repair phase was followed by a slower rejoining of SSBs in both BMMNC and CD34 + cell populations. A significantly longer time was required to repair the lesions caused by 5.43 Gy than those caused by 0.93 Gy. In the present work we report, for the first time, the induction and repair of DNA SSBs at the level of single human bone marrow cells when exposed to ionizing radiation at clinically relevant doses. These data, together with our previous results with human blood granulocytes and lymphocytes, indicate an approximately similar extent of formation and repair of gamma-irradiation-induced DNA SSBs in immature and mature human hematopoietic cells.