Effects of 8-methoxypsoralen and ultraviolet light A on EGF receptor (HER-1) expression

Activation of psoralens by ultraviolet light irradiation at 308-400 nm (UVA) is used in the photochemical treatment of psoriasis. While the major effect of this activation is the formation of DNA adducts, it was recently demonstrated that psoralens can also bind to specific saturable high affinity cellular receptors, and that this is associated with inhibition of epidermal growth factor (EGF)-receptor binding. In view of these findings, we have examined whether 8-methoxy-psoralen (8-MOP) itself, or in combination with UVA, influences expression of the human EGF-receptor gene ("HER-1") in a human keratinocyte cell line. We have found that 8 MOP alone, and to a lesser extent UVA, induce a striking increase in cellular levels of HER-1 RNA. The combination of 8-MOP with UVA produces less induction of HER-1 RNA than that obtained with 8-MOP alone. We suggest, therefore, that this effect of 8-MOP is not due to DNA damage, but may reflect a separate effect of this compound on receptor-mediated signal transduction.     

Retinyl palmitate is non-genotoxic in Chinese hamster ovary cells in the dark or after pre-irradiation or simultaneous irradiation with UV light

Retinyl palmitate (RP), an ingredient of cosmetic and medical skin-care preparations, has been reported to be photo-genotoxic/photo-clastogenic in mouse lymphoma cells (Tk locus) as well as in human Jurkat T-cells, as measured by use of the comet assay. Given that these results were obtained under exploratory conditions, we re-investigated the photo-genotoxicity of RP following a protocol consistent with current recommendations for photo-genotoxicity testing of drugs and chemicals. We tested RP in Chinese hamster ovary (CHO) cells in the dark (standard chromosome aberration test), under pre-irradiation (UVA irradiation of cells and subsequent treatment with RP) or simultaneous irradiation (irradiation of cells and RP together, standard photo-genotoxicity protocol) conditions. UVA irradiation was applied at 350 and 700 mJ/cm2 with the high UV dose targeted to produce a small increase in the incidence of structural chromosome aberrations (CA) in cells not treated with RP. RP was tested up to and above its limit of solubility in the culture medium (20-40 μg/mL). There was no overt cytotoxicity under dark or different irradiation conditions. Treatment of cells with RP in the dark, as well as treatment under pre- or simultaneous irradiation conditions failed to produce biologically significant increases in the incidence of CA, whereas the positive control substances 4-nitroquinolone and 8-methoxypsoralene produced significantly positive effects in the dark or under simultaneous irradiation, respectively. Overall, our results failed to confirm the reported positive photo-genotoxic effects, and suggest that they may have been due to the test conditions, i.e. high irradiation doses, high cytotoxicity or re-irradiation of photo-products. In conclusion, our data suggest that, under standard conditions for testing photo-genotoxicity, RP had no in vitro genotoxic or photo-genotoxic potential and is therefore unlikely to pose a local or systemic genotoxic or photo-genotoxic risk.     

A strong genotoxic effect in mouse skin of a single painting of coal tar in hairless mice and in MutaMouse

The dorsal skin of C3H/Tif/hr hairless mice was painted with coal tar, pharmacological grade. Epidermal cells and hepatocytes were isolated after 4, 24, 48 and 96 h and DNA strand breaks were determined as tail moment by the alkaline comet assay. The tail moment of epidermal cells was significantly greater at the time points 4, 24, 48 and 96 h after exposure compared to the controls, with the most DNA strand breaks at 24 h. The DNA strand breaks in epidermal cells increased linearly with the dose of coal tar. In hepatocytes, no difference in DNA strand breaks was found between exposed animals and controls. DNA adducts were determined by the 32P-postlabeling assay. For epidermal cells, the mean DNA adduct level was 12-fold greater in coal tar painted mice after 24 h than in controls. Again, a linear dose/response relationship was seen 24 h after painting. For liver DNA, the mean DNA adduct level was 3-fold greater than for controls. The mutation frequency in epidermal and liver cells was examined in lambdalacZ transgenic mice (MutaMouse). Thirty-two days after painting, the mutation frequency in epidermal cells was 16-fold greater in coal tar treated mice compared to controls. No effect was detected in hepatocytes. We found that a single painting of coal tar resulted in strong genotoxic effects in the murine epidermis, evidenced by induction of DNA strand breaks and DNA adducts in hairless mice and lambdalacZ mutations in the MutaMouse. This demonstrates that it is possible to detect genotoxic effects of mixtures with high sensitivity in mouse skin by these end-points.     

Mutagenicity of 8-methoxypsoralen and long-wave ultraviolet irradiation in diploid human skin fibroblasts: an improved risk estimate in photochemotherapy

Cell killing and the induction of mutation were studied in dividing and non-dividing human skin fibroblasts as a result of treatment by 8-methoxypsoralen (8-MOP) and long-wave UV irradiation (UVA). The cytotoxic effect was highly dependent upon the duration of the UVA exposure. The frequency of mutations increased linearly with the UVA dose at concentrations of 10 and 0.25 microliter 8-MOP/ml, the latter representing the concentration in the skin during PUVA treatment. The number of mutations induced per unit dose (= per microgram 8-MOP/ml per joule UVA/m2) was calculated: for dividing cells this value was 3.3 X 10(-8) per cell and for non-dividing cells 0.6 X 10.8(-8) per cell. On the basis of these values the expected number of induced mutants in the human skin per session of photochemotherapy is 1.2 X 10(-5), and per 30 years of maintenance therapy 1.3 X 10(-2) per cell. A comparison was made between this frequency and the frequency to be expected from spontaneous mutation. In addition the significance of absence in patients of SCE induction by photochemotherapy is discussed.     

PUVA (8-methoxy-psoralen plus ultraviolet A) induces the formation of 8-hydroxy-2'-deoxyguanosine and DNA fragmentation in calf thymus DNA and human epidermoid carcinoma cells.

The objective of this study is to investigate if 8-methoxy-psoralen (8-MOP) plus ultraviolet A (UVA) radiation (PUVA) induces oxidative DNA damage. When calf thymus DNA was incubated with 8-MOP and irradiated with UVA (335-400 nm), the level of 8-hydroxy-2'-deoxyguanosine (8-OHdG) was substantially increased by approximately 6-fold. Formation of 8-OHdG proportionally correlated with both UVA fluence and 8-MOP concentrations. Human epidermoid carcinoma cells were incubated with 10 microg 8-MOP per milliliter, followed by irradiation of 25 kJ/m2 UVA. The level of 8-OHdG increased by nearly 3-fold in PUVA-treated cells compared to 8-MOP and UVA controls. The formation of 8-OHdG correlated with DNA fragmentation as determined by spectrofluorometry. To investigate the reactive oxygen species (ROS) involved in PUVA-induced oxidative DNA damage, less or more specific ROS quenchers were added to DNA solution prior to PUVA treatment. The results showed that only sodium azide and genistein significantly quenched PUVA-induced 8-OHdG, whereas catalase, superoxide dismutase, and mannitol exhibited no effect. The quencher study with cultured cells indicated that N-acetyl-cysteine and genistein protected oxidative DNA damage as well as DNA fragmentation by PUVA treatment. Our studies show that PUVA treatment is able to induce the formation of 8-OHdG in purified DNA and cultured cells and suggest that singlet oxygen is the principle reactive oxygen species involved in oxidative DNA damage by PUVA treatment.     

Psoralen activity and binding sites in melanotic and amelanotic human melanoma cells

The biological activity and specific binding sites of 8-methoxypsoralen (8-MOP) are assayed using two human melanoma cell lines, melanotic SK-Mel 28 and amelanotic C32TG. Long-term (72 hr) treatment with 8-MOP at a concentration of 10(-4)M results in an increase in melanogenesis and a decrease in proliferation, similar in both cell lines. Daily exposure of these cells to ultraviolet A (UVA) irradiation (1.28 mJ/cm(2)) does not enhance the response to the compound. Daily pulse application (30 min daily) of 8-MOP does not promote any response. However, in combination with UVA, 8-MOP pulse treatment becomes as effective as the long-term treatment. A decrease in cell proliferation in the constant presence of 8-MOP is not coupled with apoptosis, since no increase in the number of apoptotic nuclei was observed after the treatment. The flow cytometry indicates that 8-MOP arrests the cells at the G0/G1 phase, irrespective of the presence or absence of UVA light. In view of the lack of epidermal growth factor (EGF) receptors in both cell lines, it is not likely that such an arrest is associated with the down-regulation of EGF receptors by 8-MOP. It is noted that this compound elicits a biphasic cell response, since cell proliferation increases after the first 24-hr treatment, whereas it decreases in the subsequent 48 hr and thereafter. Competition binding assays using 3H-8-MOP disclosed: 1) the specific binding of the compound in both cell lines occurs in the presence or absence of UVA light, and 2) a higher binding rate at low concentrations of the compound is in SK-Mel 28 (72%) rather than C32TG (58%) cells. The competition assays in the presence of UVA suggest a possible occurrence of covalent bindings between psoralen and receptor, as DNA covalent binding accounted to only 3-5% of the total binding in both cell lines.     

Mutagenicity of 8-methoxypsoralen and long-wave ultraviolet irradiation in V-79 Chinese hamster cells : A first approach to a risk estimate in photochemotheraphy

The effect of 8-methoxypsoralen (8-MOP) and long-wave ultraviolet irradiation (UVA) on cell killing and mutation induction was studied in V-79 Chinese hamster cells. No effect was observed after treatment with 8-MOP alone (50 μg/ml, 4 h), UVA alone (9000 J/m²), or 8-MOP metabolized by rat-livermicrosomes. Combined treatment with 8-MOP and UVA induced both cell killing and mutation. This was also observed under conditions approaching patient treatment with PUVA photochemotherapy with respect to the concentration of 8-MOP in the skin and the amount of UVA received by the epidermal cells. A simple relation proved to apply for mutation induction under different treatment conditions: 5.5 × 10⁻⁸ per J/m² per μg 8-MOP/ml. On this basis the mutation induction in dividing cells per session of PUVA-photochemotherapy amounts to 12.4 × 10⁻⁵, which is probably an over-estimation.     

Effect of vinblastine sulfate on gamma-radiation-induced DNA single-strand breaks in murine tissues

The effect of vinblastine sulfate on gamma-radiation-induced DNA strand breaks in different tissues of tumour bearing mice, was studied by single-cell gel electrophoresis. Intraperitonial administration of different doses (0.25-2.0mg/kg body weight) of vinblastine sulfate 30 min prior to 4 Gy gamma-radiation exposure showed a dose-dependent decrease in the yield of DNA strand breaks in murine fibrosarcoma, blood leukocytes and bone marrow cells. The dose-dependent protection of cellular DNA against radiation-induced strand breaks as evidenced from comet tail length, tail moment and percent DNA in the tail, was more pronounced in bone marrow cells than in the cells of the tumor fibrosarcoma. In fibrosarcoma cells, the decrease in comet tail length, tail moment and percent DNA in the tail was detected at lower doses of vinblastine sulfate administration and these parameters were not significantly altered at higher doses, from that of the control irradiated. From this study, it appears that in addition to anticancer activity, vinblastine sulfate could offer protection to the normal tissues against gamma-radiation-induced DNA strand breaks.     

Molecular aspects of extracorporeal photochemotherapy

8-methoxypsoralen (8-MOP), activated upon exposure to long-wavelength ultraviolet radiation, is used therapeutically to treat the diseased blood cells of cutaneous T-cell lymphoma patients. The factors responsible for the efficacy of this therapy are reviewed. Primary among these are the plasma level of 8-MOP at the time of irradiation and the effective dose of UVA. 8-MOP plasma levels determined in a series of six patients demonstrated that the drug is absorbed at a highly variable rate (122 ng/ml +/- 67). A new liquid form of 8-MOP is absorbed with a modest increase in plasma levels (170 ng/ml) but with no improvement in the variability (+/- 163). An examination of the dose-response relationship between 8-MOP concentration and UVA dose indicated that properties such as 8-MOP photoadduct formation and PHA response are proportional to the combined doses of these two factors. A new molecular target for 8-MOP photomodification, cell membrane DNA, is described.     

Genotoxic effects and DNA photoadducts induced in Chinese hamster V79 cells by 5-methoxypsoralen and 8-methoxypsoralen

The induction of lethal effects and 6-thioguanine-resistant (6-TGr) mutants were studied in Chinese hamster V79 cells after treatment with the two bifunctional furocoumarins 5- and 8-methoxypsoralens (5-MOP, 8-MOP) in the presence of 365-nm radiation (UVA). The in vivo DNA-photobinding capacity of these two compounds was measured and in parallel the cross-linking capacities of 5-MOP and 8-MOP were determined using the alkaline elution technique. The results show that 5-MOP plus UVA was about 2.5 times more effective than 8-MOP plus UVA for inhibiting cell survival and for inducing the same frequency of 6-TGr mutants (10(-4]. The total number of photoinduced lesions by 5-MOP plus UVA was about 6 times higher than that induced by 8-MOP plus UVA. However, the cross-linking capacities of 5-MOP and 8-MOP were found to be within the same range at equal doses of UVA. At equal number of DNA photoadducts produced, the lesions induced by 5-MOP appeared to be less genetically active than those induced by 8-MOP. The apparently weaker genotoxicity of 5-MOP-induced lesions is likely to be due to the induction of a lower proportion of cross-links by 5-MOP at a given number of photoadducts.     

Effects of ultraviolet light on melanocyte differentiation: studies with mouse neural crest cells and neural crest-derived cell lines

To evaluate the etiologic role of ultraviolet (UV) radiation in acquired dermal melanocytosis (ADM), we investigated the effects of UVA and UVB irradiation on the development and differentiation of melanocytes in primary cultures of mouse neural crest cells (NCC) by counting the numbers of cells positive for KIT (the receptor for stem cell factor) and for the L-3,4-dihydroxyphenylalanine (DOPA) oxidase reaction. No significant differences were found in the number of KIT- or DOPA-positive cells between the UV-irradiated cultures and the non-irradiated cultures. We then examined the effects of UV light on KIT-positive cell lines derived from mouse NCC cultures. Irradiation with UVA but not with UVB inhibited the tyrosinase activity in a tyrosinase-positive cell line (NCCmelan5). Tyrosinase activity in the cells was markedly enhanced by treatment with alpha-melanocyte-stimulating hormone (alpha-MSH), but that stimulation was inhibited by UVA or by UVB irradiation. Irradiation with UVA or UVB did not induce tyrosinase activity in a tyrosinase-negative cell line (NCCmelb4). Levels of KIT expression in NCCmelan5 cells and in NCCmelb4 cells were significantly decreased after UV irradiation. Phosphorylation levels of extracellular signal-regulated kinase 1/2 in cells stimulated with stem cell factor were also diminished after UV irradiation. These results suggest that UV irradiation does not stimulate but rather suppresses mouse NCC. Thus if UV irradiation is a causative factor for ADM lesions, it would not act directly on dermal melanocytes but may act in indirect manners, for instance, via the overproduction of melanogenic cytokines such as alpha-MSH and/or endothelin-1.     

Does toxoplasmosis cause DNA damage? An evaluation in isogenic mice under normal diet or dietary restriction

Toxoplasmosis is an anthropozoonotic widespread disease, caused by the coccidian protozoan parasite Toxoplasma gondii. Since there are no data regarding the genotoxicity of the parasite in vivo, this study was designed to evaluate the genotoxic potential of the toxoplasmosis on isogenic mice with normal diet or under dietary restriction and submitted to a treatment with sulfonamide (375 microg/kg per day). DNA damage was assessed in peripheral blood, liver and brain cells using the comet assay (tail moment). The results for leucocytes showed increases in the mean tail moment in mice under dietary restriction; in infected mice under normal diet; in infected, sulfonamide-treated mice under normal diet; in infected mice under dietary restriction and in infected sulfonamide-treated mice under dietary restriction. In liver and brain cells, no statistically significant difference was observed for the tail moment. These results indicated that dietary restriction and T. gondii were able to induce DNA damage in peripheral blood cells, as detected by the comet assay.     

Assessment of genotoxic effects of chloropyriphos and acephate by the comet assay in mice leucocytes

Two organophosphorus (OP) pesticides (chloropyriphos and acephate) and cyclophosphamide (CP) (positive control) were tested for their ability to induce in vivo genotoxic effect in leucocytes of Swiss albino mice using the single cell gel electrophoresis assay or comet assay. The mice were administered orally with doses ranging from 0.28 to 8.96 mg/kg body weight (b. wt.) of chloropyriphos and 12.25 to 392.00 mg/kg b.wt. of acephate. The assay was performed on whole blood at 24, 48, 72 and 96 h. A significant increase in mean comet tail length indicating DNA damage was observed at 24h post-treatment (P<0.05) with both pesticides in comparison to control. The damage was dose related. The mean comet tail length revealed a clear dose dependent increase. From 48 h post-treatment, a gradual decrease in mean tail length was noted. By 96 h of post-treatment the mean comet tail length reached control levels indicating repair of the damaged DNA. From the study it can be concluded that the comet assay is a sensitive assay for the detection of genotoxicity caused by pesticides.     

Inhibition of antiskin allograft immunity induced by infusions with photoinactivated effector T lymphocytes (PET cells)

Induction of tolerance for skin allotransplantation requires selective suppression of the host response to foreign histocompatibility antigens. This report describes a new approach which employs pre-treatment with 8-methoxypsoralen (8-MOP) and ultraviolet A light (UVA) to render the effector cells of graft rejection immunogenic for the syngeneic recipient. Eight days after BALB/c mice received CBA/j skin grafts, their splenocytes were treated with 100 ng/ml 8-MOP and 1 J/cm2 UVA prior to reinfusion into naive BALB/c recipients. Recipient mice were tested for tolerance to alloantigens in mixed leukocyte culture (MLC), cytotoxicity (CTL), delayed-type hypersensitivity assays (DTH), and challenge with a fresh CBA/j graft. Splenocytes from BALB/c recipients of photoinactivated splenocytes containing the effector cells of CBA/j alloantigen rejection proliferated poorly in MLC and generated lower cytotoxic T-cell responses to CBA/j alloantigens in comparison with sensitized and naive controls and suppressed the MLC and CTL response to alloantigen from sensitized and naive BALB/c mice. In vivo, the DTH response was specifically suppressed to the relevant alloantigen in comparison with controls. BALB/c mice treated in this fashion retained a CBA/j skin graft for up to 42 days post-transplantation without visual evidence of rejection. These results showed that reinfusion of photoinactivated effector cells resulted in an immunosuppressive host response which specifically inhibited in vitro and in vivo responses that correlate with allograft rejection and permitted prolonged retention of histoincompatible skin grafts.     

Interaction of hyperbaric oxygen, nitric oxide, and heme oxygenase on DNA strand breaks in vivo

Hyperbaric oxygen (HBO), e.g. pure oxygen breathing at supra-atmospheric pressures, represents a well-suited model for investigating oxidative stress-induced DNA damage as well as protective mechanisms. While the induction of heme oxygenase-1 (HO-1) seems to be crucial for this protection against this DNA damage, the role of nitric oxide (NO) remains unclear. HO-1 expression is a major regulator of the inducible NO synthase (iNOS), and therefore we investigated the effect of the interaction between HBO, NO, and HO-1 on DNA damage. Prior to exposure to HBO (3 h at 3 bar ambient pressure) rats randomly received vehicle (HBO alone, 1 mL 0.9% saline, n=8), the NO donor molsidomine (SIN-10, 40 mg/kg, n=8) or the HO-1 blocker tin-mesopophyrin (Sn-MP, 50 micromol/kg, n=8). Additional groups received SIN-10 without exposure to HBO, i.e. breathing air under normobaric conditions for 3h (SIN-10 alone, 40 mg/kg, n=6), vehicle without HBO (negative controls, n=6), and ethylmethanesulfonate without HBO (EMS, 200 mg/kg) (positive controls n=4). Immediately after the 3 h HBO or air breathing period blood was analysed for DNA strand breaks (tail moment in the alkaline comet assay) and nitrite+nitrate (chemoluminescence). Whereas the tail moment was ten-fold higher after EMS than in the negative controls, there was no effect of HBO nor SIN-10 alone. Together with HBO, pretreatment with SIN-10 doubled the tail moment, and Sn-MP increased it by 50%. In contrast to Sn-MP or HBO alone, SIN-10 resulted in a five-fold increase of nitrite+nitrate concentrations. We conclude that both HO-1 blockade and excess NO release promote DNA damage during HBO exposure in vivo. The effect of HO-1 inhibition is probably independent of the regulatory function of HO-1 for iNOS.     

Gender differences in UV-induced inflammation and immunosuppression in mice reveal male unresponsiveness to UVA radiation

Immunosuppression attributed mainly to the UVB (290-320 nm) waveband is a prerequisite for skin cancer development in mice and humans. The contribution of UVA (320-400 nm) is controversial, but in mice UVA irradiation has been found to antagonise immunosuppression by UVB. In other studies of photoimmune regulation, protection mediated via oestrogen receptor-β signalling was identified as a normal endogenous defence in mice, and was shown to depend on UVA irradiation. A gender bias in photoimmune responsiveness was thus suggested, and is tested in this study by comparing the UV-induced inflammatory and immune responses in male and female hairless mice. We report that male mice, which show greater skin thickness than females, developed a less intense but slower resolving sunburn inflammatory oedema, correlated with reduced epidermal expression of pro-inflammatory IL-6 than females following solar simulated UV (SSUV, 290-400 nm) exposure. On the other hand, the contact hypersensitivity reaction (CHS) was more severely suppressed by SSUV in males, correlated with increased epidermal expression of immunosuppressive IL-10. Exposure to the UVB waveband alone, or to cis-urocanic acid, suppressed CHS equally in males and females. However, whereas UVA irradiation induced immunoprotection against either UVB or cis-urocanic acid in females, this protection was significantly reduced or abrogated in males. The results indicate that males are compromised by a relative unresponsiveness to the photoimmune protective effects of UVA, alone or as a component of SSUV. This could explain the known gender bias in skin cancer development in both mice and humans.     

Mutagenic effects photoinduced in normal human lymphoblasts by a monofunctional pyridopsoralen in comparison to 8-methoxypsoralen

The photobiological effects induced by the monofuctional 7-methylpyrido[3,4-c]psoralen (MePyPs) in comparison to the bifunctional furocoumarin 8-methoxypsoralen (8-MOP) have been studied in a human lymphoblast cell line TK6. We report that, in human lymphoblasts, the cytotoxic effect of MePyPs plus UVA (365 nm) is much higher than that of 8-MOP plus 365-nm irradiation. The dose-modifying factor at the 37% survival level between the 2 compounds equals 120. Mutation induction by photoactivated MePyPs and 8-MOP has been studied in 2 genetic loci, hypoxanthine phosphoribosyl transferase (HPRT) and Na+/K+ ATPase. For equal UVA doses, the mutagenic effectiveness of MePyPs was higher than that of 8-MOP. However at equal survival levels, the mononfuctional psoralen MePyPs was less efficient than the bifunctional 8-MOP. In other words, compared to 8-MOP, the monofunctional agent MePyPs is more cytotoxic than mutagenic. This higher phototoxic and mutagenic efficiency of MePyPs in comparison to 8-MOP is likely to be related to the chemical nature of MePyPs-induced lesions which may be responsible for a reduced recognition and/or accessibility of the repair enzymes to damaged DNA.     

Genetic effects of specific DNA lesions in mammalian cells

Accurate dosimetry for chemical mutagens is extremely difficult, and precise manipulation of the frequency of a particular lesion is ordinarily impossible. With 8-MOP plus UVA, however, both are possible because 8-MOP, when photoactivated by one photon of UVA, forms monoadducts whilst crosslinks are formed only if a second photon of light photoactivates the monoadducts. If 8-MOP molecules that are unreacted after a UVA exposure are removed from cells by washing, the effect of a subsequent UVA irradiation can be attributed only to the conversion of monoadducts to DNA interstrand crosslinks. Using this experimental procedure and L5178Y mouse lymphoma cells, we have shown that DNA interstrand crosslinks are at least 10-fold more effective at causing both sister-chromatid exchanges and chromosomal aberrations than are monoadducts. In contrast, crosslinks are no more effective than monoadducts in mutation induction. These experiments identify directly for the first time that a particular chemically induced lesion, DNA interstrand crosslinks, can, like thymine dimers, cause chromosomal aberrations and sister-chromatid exchanges. The results also show that sister-chromatid exchanges can be induced independently of mutations.     

Effect of ATM heterozygosity on heritable DNA damage in mice following paternal F0 germline irradiation

The ataxia telangiectasia mutated (ATM) gene product maintains genome integrity and initiates cellular DNA repair pathways following exposures to genotoxic agents. ATM also plays a significant role in meiotic recombination during spermatogenesis. Fertilization with sperm carrying damaged DNA could lead to adverse effects in offspring including developmental defects or increased cancer susceptibility. Currently, there is little information regarding the effect of ATM heterozygosity on germline DNA repair and heritable effects of paternal germline-ionizing irradiation. We used neutral pH comet assays to evaluate spermatozoa 45 days after acute whole-body irradiation of male mice (0.1Gy, attenuated (137)Cs gamma rays) to determine the effect of ATM heterozygosity on delayed DNA damage effects of Type A/B spermatogonial irradiation. Using the neutral pH sperm comet assay, significant irradiation-related differences were found in comet tail length, percent tail DNA and tail extent moment, but there were no observed differences in effect between wild-type and ATM +/- mice. However, evaluation of spermatozoa from third generation descendants of irradiated male mice for heritable chromatin effects revealed significant differences in DNA electrophoretic mobility in the F(3) descendants that were based upon the irradiated F(0) sire's genotype. In this study, radiation-induced chromatin alterations to Type A/B spermatogonia, detected in mature sperm 45 days post-irradiation, led to chromatin effects in mature sperm three generations later. The early cellular response to and repair of DNA damage is critical and appears to be affected by ATM zygosity. Our results indicate that there is potential for heritable genetic or epigenetic changes following Type A/B spermatogonial irradiation and that ATM heterozygosity increases this effect.