The interactive effect of alcohol and folic acid on genome stability in human WIL2-NS cells measured using the cytokinesis-block micronucleus cytome assay

Chromosomal mutations are commonly found in cancer cells, and can be caused by several factors including dietary insufficiency and exposure to environmental and life-style genotoxins. Folate (vitamin B9), one of the essential micronutrients, is required for DNA repair and synthesis and to maintain genome stability. Since excessive alcohol (ethanol) consumption may alter folate status and low folate might alter susceptibility to alcohol toxicity, a study was performed to investigate the individual and interactive impacts of folic acid (FA) and ethanol on genome stability in vitro. The experiments were performed using WIL2-NS cells cross-tested at three FA (20, 200 and 2000 nM) and four ethanol concentrations (0, 0.09, 0.36 and 1.34%, v/v) over a two-week culture time. Chromosomal damage and cytotoxicity were measured using the cytokinesis-block micronucleus cytome assay. The present study showed dose-related genotoxic effects of both decreasing folic acid concentration and increased ethanol on day 15 resulting in significant induction of micronuclei, nuclear buds and nucleoplasmic bridges which are biomarkers of chromosome breakage or loss, gene amplification and chromosomal rearrangement, respectively. Increased ethanol and FA deficiency interacted to further significantly increase micronuclei and nucleoplasmic bridges. However there was no evidence showing alcohol's ability to cleave FA. The findings from this study suggest a protective effect of FA against alcohol-induced DNA damage and that FA deficiency in the physiological range has a stronger impact on genome stability than exposure to cytotoxic doses of ethanol achievable in binge drinking.     

Cytokinesis-block micronucleus assay evolves into a "cytome" assay of chromosomal instability, mitotic dysfunction and cell death

The cytokinesis-block micronucleus (CBMN) assay was originally developed as an ideal system for measuring micronuclei (MNi) however it can also be used to measure nucleoplasmic bridges (NPBs), nuclear buds (NBUDs), cell death (necrosis or apoptosis) and nuclear division rate. Current evidence suggests that (a) NPBs originate from dicentric chromosomes in which the centromeres have been pulled to the opposite poles of the cell at anaphase and are therefore indicative of DNA mis-repair, chromosome rearrangement or telomere end-fusions, (b) NPBs may break to form MNi, (c) the nuclear budding process is the mechanism by which cells remove amplified and/or excess DNA and is therefore a marker of gene amplification and/or altered gene dosage, (d) cell cycle checkpoint defects result in micronucleus formation and (e) hypomethylation of DNA, induced nutritionally or by inhibition of DNA methyl transferase can lead to micronucleus formation either via chromosome loss or chromosome breakage. The strong correlation between micronucleus formation, nuclear budding and NPBs (r = 0.75–0.77, P < 0.001) induced by either folic acid deficiency or exposure to ionising radiation is supportive of the hypothesis that folic acid deficiency and/or ionising radiation cause genomic instability and gene amplification by the initiation of breakage–fusion–bridge cycles. In its comprehensive mode, the CBMN assay measures all cells including necrotic and apoptotic cells as well as number of nuclei per cell to provide a measure of cytotoxicity and mitotic activity. The CBMN assay has in fact evolved into a “cytome” method for measuring comprehensively chromosomal instability phenotype and altered cellular viability caused by genetic defects and/or nutrional deficiencies and/or exogenous genotoxins thus opening up an exciting future for the use of this methodology in the emerging fields of nutrigenomics and toxicogenomics and their combinations.     

The role of folic acid and Vitamin B12 in genomic stability of human cells

Folic acid plays a critical role in the prevention of chromosome breakage and hypomethylation of DNA. This activity is compromised when Vitamin B12 (B12) concentration is low because methionine synthase activity is reduced, lowering the concentration of S-adenosyl methionine (SAM) which in turn may diminish DNA methylation and cause folate to become unavailable for the conversion of dUMP to dTMP. The most plausible explanation for the chromosome-breaking effect of low folate is excessive uracil misincorporation into DNA, a mutagenic lesion that leads to strand breaks in DNA during repair. Both in vitro and in vivo studies with human cells clearly show that folate deficiency causes expression of chromosomal fragile sites, chromosome breaks, excessive uracil in DNA, micronucleus formation and DNA hypomethylation. In vivo studies show that Vitamin B12 deficiency and elevated plasma homocysteine are significantly correlated with increased micronucleus formation. In vitro experiments indicate that genomic instability in human cells is minimised when folic acid concentration in culture medium is >227nmol/l. Intervention studies in humans show: (a) that DNA hypomethylation, chromosome breaks, uracil misincorporation and micronucleus formation are minimised when red cell folate concentration is >700nmol/l folate; and (b) micronucleus formation is minimised when plasma concentration of Vitamin B12 is >300pmol/l and plasma homocysteine is <7.5micromol/l. These concentrations are achievable at intake levels in excess of current RDIs i.e. more than 200-400microgram folic acid per day and more than 2microgram Vitamin B12 per day. A placebo-controlled study with a dose-response suggests that based on the micronucleus index in lymphocytes, an RDI level of 700microgram/day for folic acid and 7microgram/day for Vitamin B12 would be appropriate for genomic stability in young adults. Dietary intakes above the current RDI may be particularly important in those with extreme defects in the absorption and metabolism of these Vitamins, for which ageing is a contributing factor.     

Enhanced sensitivity of lymphoblastoid cells from individuals carrying the mutation for the fragile X syndrome to the clastogenic effects of FUdR

Individuals known to carry the mutation for the fragile X syndrome can sometimes be identified cytogenetically by the presence of a fragile site on the X chromosome at q27.3. The frequency of cells bearing this fragile site is known to be enhanced by culturing the cells in folic acid deficient medium and/or by introducing folic acid metabolism inhibitors such as FUdR. In this study FUdR induction of chromosomal aberrations other than the fragile X was investigated. Lymphoblastoid cells from an obligate carrier, a mentally retarded male and a control were cultured in folic acid deficient medium in the presence of FUdR and harvested at various times after culture initiation. The frequency of chromosome and chromatid breaks was found to be higher in cells from the individuals carrying the mutation for the fragile X syndrome. The frequency of micronuclei, an indirect index of chromosome breakage, was also more elevated in cells from these individuals than in cells from the control. These findings are of potential importance to carrier detection of this common genetic disorder.     

Enhancement of radiation-induced DNA double-strand breaks and micronuclei in human colon carcinoma cells by N-methylformamide

The differentiation-inducing agent N-methylformamide (NMF) enhances the sensitivity of some cell lines to ionizing radiation. To elucidate the mechanism of NMF-mediated radiosensitization, we examined the effects of this agent on gamma-ray-induced DNA double-strand breaks and micronuclei in two cell lines, clone A (human colon carcinoma) and HCA-1 (murine hepatocarcinoma). Both cell lines form a better differentiated phenotype upon exposure to NMF, yet only clone A is radiosensitized. The neutral (pH 9.6) elution assay was used to evaluate the effects of this maturational agent on radiation-induced double-strand breaks in these cell lines. Exposure of HCA-1 cells to NMF had no effect on the level of DNA double-strand breaks induced by gamma rays. In clone A cells, however, exposure to NMF enhanced the initial formation of gamma-ray-induced double-strand breaks at each dose tested. The repair of double-strand breaks in both cell lines was not influenced by NMF. As a measure of chromosome fragmentation after irradiation, we evaluated micronuclei using the cytokinesis block method. Exposure to NMF had no effect on radiation-induced micronuclei formation in HCA-1 cells yet significantly enhanced the frequency of micronuclei induced by radiation in clone A cells. In clone A cells, the increases in radiation-induced double-strand breaks and micronuclei as a function of NMF exposure time reached maximums by approximately 72 h. These data suggest that NMF-mediated radiosensitization is the result of an increase in the initial level of radiation-induced DNA double-strand breaks.     

Lack of spontaneous and radiation-induced chromosome breakage at interstitial telomeric sites in murine scid cells

Interstitial telomeric sites (ITSs) in chromosomes from DNA repair-proficient mammalian cells are sensitive to both spontaneous and radiation-induced chromosome breakage. Exact mechanisms of this chromosome breakage sensitivity are not known. To investigate factors that predispose ITSs to chromosome breakage we used murine scid cells. These cells lack functional DNA-PKcs, an enzyme involved in the repair of DNA double-strand breaks. Interestingly, our results revealed lack of both spontaneous and radiation-induced chromosome breakage at ITSs found in scid chromosomes. Therefore, it is possible that increased sensitivity of ITSs to chromosome breakage is associated with the functional DNA double-strand break repair machinery. To investigate if this is the case we used scid cells in which DNA-PKcs deficiency was corrected. Our results revealed complete disappearance of ITSs in scid cells with functional DNA-PKcs, presumably through chromosome breakage at ITSs, but their unchanged frequency in positive and negative control cells. Therefore, our results indicate that the functional DNA double-strand break machinery is required for elevated sensitivity of ITSs to chromosome breakage. Interestingly, we observed significant differences in mitotic chromosome condensation between scid cells and their counterparts with restored DNA-PKcs activity suggesting that lack of functional DNA-PKcs may cause a defect in chromatin organization. Increased condensation of mitotic chromosomes in the scid background was also confirmed in vivo. Therefore, our results indicate a previously unanticipated role of DNA-PKcs in chromatin organisation, which could contribute to the lack of ITS sensitivity to chromosome breakage in murine scid cells.     

Induction of chromosomal damage by restriction endonuclease in CHO cells porated with streptolysin O.

A procedure is described for the poration of living CHO cells with the bacterial cytotoxin streptolysin O (SLO) which allows the introduction into cells of the restriction endonuclease Pvu II to mimic and model the effects of ionising radiation in causing chromosomal damage. The dependence of this clastogenic effect of Pvu II on SLO concentration was measured by assaying the formation of micronuclei in cytokinesis-blocked binucleate cells. The optimum concentration was found to be 0.045 U/ml. Using the micronucleus assay, the time-course of expression of chromosome damage was investigated and found to show a biphasic kinetic with time. Using a sampling time of 30 h, a dose-effect curve for micronucleus induction by Pvu II was generated. Using this optimized SLO treatment protocol, the frequency of metaphase chromosome damage was subsequently investigated and found to be also linearly related to Pvu II concentration and total aberrations were approximately double the frequency of micronuclei. The induction and repair kinetics of DNA double-strand breaks were investigated in CHO cells treated with SLO and Pvu II using the neutral filter elution technique at pH 9.6. The data presented show that SLO can be used as an alternative method for porating cells to allow the introduction of restriction endonucleases into cells.     

Lack of specificity of chromosome breaks resulting from radiation-induced genomic instability in Chinese hamster cells

In V79 Chinese hamster cells, radiation-induced genomic instability results in a persistently increased frequency of micronuclei, dicentric chromosomes and apoptosis and in decreased colony-forming ability. These manifestations of radiation-induced genomic instability may be attributed to an increased rate of chromosome breakage events many generations after irradiation. This chromosomal instability does not seem to be a property which has been inflicted on individual chromosomes at the time of irradiation. Rather, it appears to be secondary to an increased level of non-specific clastogenic factors in the progeny of most if not all irradiated cells. This conclusion is drawn from the observations presented here, that all the chromosomes in surviving V79 cells are involved in the formation of dicentric chromosome aberrations 1 or 2 weeks after irradiation with about equal probability if corrections are made for chromosome length. Received: 5 March 1998 / Accepted in revised form: 1 July 1998     

Antiatherogenic and radioprotective role of folic acid in whole body γ-irradiated mice

Free radical mediated oxidative damage is one of the prime factors for atherogenic changes in humans. We have shown that the folic acid administration reduced the risk of the atherogenic factors induced by γ -radiation. Folic acid administration prevented the radiation induced increase in the plasma lipoprotein lipase activity and also prevented the radiation-induced increase in the hepatic cholesterol and triglycerides levels. These results indicate the role of folic acid as an antiatherogenic agent. Further, we also report the radioprotective property of folic acid as demonstrated by reduction in the radiation induced membrane damage as measured by lipid peroxidation products and DNA damage, which was measured by alkaline comet assay.     

Lack of dependance of transcription-induced cytosine deaminations on protein synthesis

We have validated the analysis of nucleoplasmic bridges (NPBs) and nuclear buds as biomarkers of genomic instability within the cytokinesis-block micronucleus assay in long-term lymphocyte cultures. Lymphocytes from 20 subjects were cultured in medium containing 12-120 nM folic acid for 9 days. Binucleate cells were scored for micronuclei (MN), NPBs and nuclear budding on day nine after 24h incubation in the presence of the cytokinesis inhibitor cytochalasin-B. Folic acid concentration was correlated significantly (P<0.0001) and negatively (r=-0.63 to -0.74) with all these markers of chromosome damage. Chromosome damage was minimised at 60-120 nM folic acid, which is greater than the concentration of folate normally observed in plasma (<30 nM). Current evidence suggests that (a) NPBs originate from dicentric chromosomes in which the centromeres have been pulled to the opposite poles of the cell at anaphase and are therefore, indicative of chromosome rearrangement and (b) that the nuclear budding process is the mechanism by which cells remove amplified DNA and is therefore a marker of gene amplification. The strong correlation between micronucleus formation, nuclear budding and NPBs (r=0.75-0.77, P<0.001) is supportive of the hypothesis that folic acid deficiency causes genomic instability and gene amplification by the initiation of breakage-fusion-bridge (BFB) cycles. These results also suggest that the CBMN assay may be a useful model for the study of the BFB cycle which may be one of the key mechanisms for the hypermutability phenotype required for the rapid evolution of cancer cells.     

Studying the mechanism of sperm DNA damage caused by folate deficiency

Sperm DNA injury is one of the common causes of male infertility. Folic acid deficiency would increase the methylation level of the important genes, including those involved in DNA double‐strand break (DSB) repair pathway. In the early stages, we analysed the correlation between seminal plasma folic acid concentration and semen parameters in 157 infertility patients and 91 sperm donor volunteers, and found that there was a significant negative correlation between seminal folic acid concentration and sperm DNA Fragmentation Index (DFI; r = −0.495, p < 0.01). Then through reduced representation bisulphite sequencing, global DNA methylation of sperm of patients in the low folic acid group and the high folic acid group was analysed, it was found that the methylation level in Rad54 promoter region increased in the folic acid deficiency group compared with the normal folic acid group. Meanwhile, the results of animal model and spermatocyte line (GC‐2) also found that folic acid deficiency can increase the methylation level in Rad54 promoter region, increased sperm DFI in mice, increased the expression of γ‐H2AX, that is, DNA injury marker protein, and increased sensitivity of GC‐2 to external damage and stimulation. The study indicates that the expression of Rad54 is downregulated by folic acid deficiency via DNA methylation. This may be one of the mechanisms of sperm DNA damage caused by folate deficiency.     

Chromosome nondisjunction and loss induced by protons and X rays in primary human fibroblasts: role of centromeres in aneuploidy

To study the origin of micronuclei induced in human primary fibroblasts by low-energy protons (7.7 and 28.5 keV/microm) and X rays, we have developed a combined antikinetochore-antibody (CREST) and FISH staining with pancentromeric probes. This technique allowed us to analyze the integrity of the kinetochore and centromeric DNA structures and to assess their role in induced aneuploidy. The effect of LET on radiation-induced chromosome nondisjunction was studied in binucleated cells with centromeric-specific DNA probes for chromosomes 7 and 11. Our results indicate that, though more than 90% of radiation-induced micronuclei were CREST(-)/FISH(-), 28.5 keV/microm protons and X rays were also able to induce statistically significant increases in the number of micronuclei that were CREST(-)/FISH(+) and CREST(+)/FISH(+), respectively. One interpretation of these results could be that the protons induced chromosome loss by kinetochore detachment or by breakage in the centromeric DNA region, whereas X rays induced aneuploidy through a non-DNA damage mechanism. Nondisjunction appears to be a far more important mechanism leading to radiation-induced aneuploidy. Irrespective of the higher frequency of micronuclei induced by 28.5 keV/microm protons, the frequency of chromosome loss was markedly higher for X rays than for 28.5 keV/microm protons, strengthening the hypothesis that non-DNA targets, such as components of the mitotic spindle apparatus, may be involved in aberrations in chromosome segregation after X irradiation.     

Radioprotective potential of histamine on rat small intestine and uterus

The aim of this study was to improve knowledge about histamine radioprotective potential investigating its effect on reducing ionising radiation-induced injury and genotoxic damage on the rat small intestine and uterus. Forty 10-week-old male and 40 female Sprague-Dawley rats were divided into 4 groups. Histamine and histamine-5Gy groups received a daily subcutaneous histamine injection (0.1 mg/kg) starting 24 h before irradiation. Histamine-5Gy and untreated-5Gy groups were irradiated with a dose of whole-body Cesium-137 irradiation. Three days after irradiation animals were sacrificed and tissues were removed, fixed, and stained with haematoxylin and eosin, and histological characteristics were evaluated. Proliferation, apoptosis and oxidative DNA markers were studied by immunohistochemistry, while micronucleus assay was performed to evaluate chromosomal damage. Histamine treatment reduced radiation-induced mucosal atrophy, oedema and vascular damage produced by ionising radiation, increasing the number of crypts per circumference (239±12 vs 160±10; P<0.01). This effect was associated with a reduction of radiation-induced intestinal crypts apoptosis. Additionally, histamine decreased the frequency of micronuclei formation and also significantly attenuated 8-OHdG immunoreactivity, a marker of DNA oxidative damage. Furthermore, radiation induced flattening of the endometrial surface, depletion of deep glands and reduced mitosis, effects that were completely blocked by histamine treatment. The expression of a proliferation marker in uterine luminal and glandular cells was markedly stimulated in histamine treated and irradiated rats.The obtained evidences indicate that histamine is a potential candidate as a safe radio-protective agent that might increase the therapeutic index of radiotherapy for intra-abdominal and pelvic cancers. However, its efficacy needs to be carefully investigated in prospective clinical trials.Key words: histamine, ionising radiation, radio-protectors, small intestine, uterus.     

The effect of mitotic inhibitors on DNA strand size and radiation-associated break repair in Down syndrome fibroblasts

The effect of mitotic inhibitors on formation and repair of DNA breaks was studied in cultured fibroblasts from patients with Down syndrome in order to investigate the hypothesis that the karyotyping procedure itself may play a role in the increased chromosome breakage seen in these cells after gamma radiation exposure. Using the nondenaturing elution and alkaline elution techniques to examine fibroblasts from Down syndrome patients and from controls, no specific abnormalities in Down syndrome cells could be detected after exposure to mitotic inhibitors, including rate and extent of elution of DNA from filters as well as repair of radiation-induced DNA breaks. In both normal and Down syndrome cell strains, however, exposure to mitotic inhibitors was associated with a decrease in cellular DNA strand size, suggesting the presence of drug-induced DNA strand breaks. The mechanism of increased chromosome sensitivity of Down syndrome cells to gamma radiation remains unknown.     

Kinetochore analysis of micronuclei allows insights into the actions of colcemid and mitomycin C

We have induced micronuclei in two strains of diploid human fibroblasts with a known aneugen, colcemid, and a known clastogen, mitomycin C. Using immunofluorescence to detect the presence of kinetochores in micronuclei, we were able to demonstrate a 26.8-fold increase in fluorescence-positive micronuclei (aneuploidy) in colcemid-treated cells. However, colcemid also induced an increase in kinetochore-negative micronuclei. Our findings support previous reports that suggest colcemid may induce chromosome breakage in addition to its major aneugenic effect. The frequency of kinetochore-negative micronuclei (chromosome breakage) in mitomycin C-treated cells rose an average of 7.9-fold in the two test strains, a clear reflection of its clastogenic action. However, a 4-fold increase in the kinetochore-positive fraction was seen. We conclude that the fibroblast micronucleus assay, coupled with kinetochore immunofluorescence, provides a useful screening approach for genotoxic agents. The delineation of the precise mechanism by which an agent perturbs the rates of chromosomal breakage or lag may require more detailed analysis.     

Association of ionizing radiation-induced foci of NBS1 with chromosomal instability and breast cancer susceptibility

NBS1, a protein essential for DNA double-strand break repair, relocalizes into subnuclear structures upon induction of DNA damage by ionizing radiation, forming ionizing radiation-induced foci. We compared radiation-induced NBS1 foci in peripheral blood lymphocytes (PBLs) from 46 sporadic breast cancer patients and 30 healthy cancer-free volunteers. The number of persistent radiation-induced NBS1 foci per nucleus at 24 h after irradiation for patients with invasive cancer was significantly higher than for normal healthy volunteers. The frequency of spontaneous chromosome aberration increased as the number of persistent radiation-induced NBS1 foci increased, indicating that the number of persistent radiation-induced NBS1 foci might be associated with chromosome instability. There was also an inverse correlation between the number of radiation-induced NBS1 foci and the activity of DNA-dependent protein kinase (DNA-PK), which plays an important role in the nonhomologous end-joining (NHEJ) pathway, another mechanism of DNA DSB repair, indicating a close interrelationship between homologous recombination (HR) and NHEJ in DNA DSB repair. In conclusion, the number of persistent radiation-induced NBS1 foci is associated with chromosomal instability and risk of sporadic breast cancer and hence might be used to select individuals for whom a detailed examination is necessary because of their increased susceptibility to breast cancer, although refinement of the techniques for technical simplicity and accuracy will be required for clinical use.     

Frequency of micronuclei in root-tips of Tradescantia clone 02: Effects of diurnal temperature difference and Co gamma radiation

Frequency of micronuclei in root-tip cells was used to asses the influence and/or interaction of a large Diurnal Temperature Difference (DTD) on irradiated and non-irradiated Tradescantia Clone 02. Hydroponically grown plants were subjected to four different treatment combinations: no radiation/normal DTD (7.2°C), no radiation/large DTD (23.5°C), radiation (60R)/normal DTD, radiation/large DTD. An analysis of variance of Feulgen positive micronuclei arising from chromosome fragments in root-tip cells revealed that a 5-day chronic exposure to a large DTD without radiation does not significantly increase the frequency of cells with micronuclei (freq. = 0.53%). An accute 60 R radiation exposure, as expected, did significantly increase the frequency (freq. = 3.23%). None of the treatment interactions significantly altered micronuclei production. These data lend support to the contention that the mutation-induction mechanism of large DTD's, as expressed by variant color sectoring in stamen hair cells of this clone, is not mediated by chromosome breakage. Exposure to a large DTD, therefore, may be a method for inducing mutations in stamen hairs without concomitant chromosome breakage, and may also provide a good cytological means for analyzing somatic crossing over, which has been postulated as a possible mechanism for the expression of spontaneous mutations at the D⁺ locus. The frequency of micronuclei in irradiated tissue remained constant throughout the 5-day course of the experiments and several explanations for this occurrence are proposed.     

Impaired DNA double strand break repair in cells from Nijmegen breakage syndrome patients

Nijmegen breakage syndrome, caused by mutations in the NBS1 gene, is an autosomal recessive chromosomal instability disorder characterized by cancer predisposition. Cells isolated from Nijmegen breakage syndrome patients display increased levels of spontaneous chromosome aberrations and sensitivity to ionizing radiation. Here, we have investigated DNA double strand break repair pathways of homologous recombination, including single strand annealing, and non-homologous end-joining in Nijmegen breakage syndrome patient cells. We used recently developed GFP-YFP-based plasmid substrates to measure the efficiency of DNA double strand break repair. Both single strand annealing and non-homologous end-joining processes were markedly impaired in NBS1-deficient cells, and repair proficiency was restored upon re-introduction of full length NBS1 cDNA. Despite the observed defects in the repair efficiency, no apparent differences in homologous recombination or non-homologous end-joining effector proteins RAD51, KU70, KU86, or DNA-PK(CS) were observed. Furthermore, comparative analysis of junction sequences of plasmids recovered from NBS1-deficient and NBS1-complemented cells revealed increased dependence on microhomology-mediated end-joining DNA repair process in NBS1-complemented cells.     

Biophysical modeling of radiation induced genetic damage to cells

The paper deals with the new approach for high accurate prediction of ionising radiation induced lesions of the cellular genetic structures. The previous techniques mainly were based on the assumption of the random radiation-induced breakage of the cellular DNA. They did not consider higher-order DNA organisation in the chromatin and in the interphase chromosomes. The paper discusses the new methods of the biophysical modelling of DNA breakage following high LET irradiation which takes into account the information on 3-dimensional structural organisation of DNA in interphase chromosomes. On this basis the influence of DNA organisation in the chromosomes on both dsb clusters induction and on repair were quantitatively studied, that was impossible by the means of previous computational techniques.     

The relationship between colony-forming ability, chromosome aberrations and incidence of micronuclei in V79 Chinese hamster cells exposed to microwave radiation

Cultured V79 Chinese hamster fibroblast cells were exposed to continuous radiation, frequency 7.7 GHz, power density 0.5 mW/cm2 for 15, 30 and 60 min. The effect of microwave radiation on cell survival and on the incidence and frequency of micronuclei and structural chromosome aberrations was investigated. The decrease in the number of irradiated V79 cell colonies was related to the power density applied and to the time of exposure. In comparison with the control samples there was a significantly higher frequency of specific chromosome aberrations such as dicentric and ring chromosomes in irradiated cells. The presence of micronuclei in irradiated cells confirmed the changes that had occurred in chromosome structure. These results suggest that microwave radiation can induce damage in the structure of chromosomal DNA.