Roberto Ranaldi

Reproductive toxicity of 1,3-butadiene in the mouse: cytogenetic analysis of chromosome aberrations in first-cleavage embryos and flow cytometric evaluation of spermatogonial cell killing.

Reproductive effects of 1,3 butadiene inhalation have been evaluated in male mice by reduction of post-meiotic germ cells, alteration of sperm chromatin structure and transmission of chromosome aberrations to one-cell embryos. Animals were exposed for 5 consecutive days for 6 h per day to butadiene concentrations of 130, 500 or 1300 ppm. The testicular fraction of post-meiotic germ cells was measured by flow cytometric analysis on the basis of their DNA content. Round spermatids were discriminated from mature, elongated spermatids by their different degree of chromatin condensation. Butadiene-induced cytotoxic effects on differentiating spermatogonia were shown by a concentration-dependent decrease of round spermatids occurring 21 days after chemical exposure, confirmed by a similar decrease of elongated spermatids measured in testes sampled 7 days later. Statistically significant effects were seen already at 130 ppm. An incomplete repopulation of the elongated spermatid compartment observed 35 days after exposure to 1300 ppm suggested that, at the highest concentration tested, butadiene toxicity extended to stem cells. Alterations of sperm chromatin were revealed by its increased sensitivity to acidic denaturation in situ. The percentage of abnormal sperm was significantly increased after butadiene exposure of differentiating spermatogonia and spermatocytes. This suggested the induction of persistent effects interfering with chromatin remodelling during spermiogenesis. Chromosome-type structural aberrations were significantly elevated in first-cleavage embryos conceived by males mated during the first and second week after the end of exposure. The lowest effective tested concentration was 500 ppm, the same reported for dominant lethal induction under identical exposure conditions. As in the dominant lethal assay, the effect of this dose was confined to exposed sperm, while both sperm and late spermatids were affected by the inhalation of 1300 ppm. A quantitative comparison between the effects induced by intraperitoneal injections of diepoxybutane or butadiene inhalations suggested that other reactive intermediates, in addition to diepoxybutane, might contribute to mediate butadiene-induced reproductive toxicity.

Kinetics of γ-H2AX induction and removal in bone marrow and testicular cells of mice after X-ray irradiation

Male germ cells have been shown to differ in their DNA damage response (DDR) with respect to somatic cells. In addition, DDR pathways are modulated along spermatogenesis, accompanying profound chromatin modifications. Histone H2AX phosphorylation is a fundamental step of DDR. Few data are available on the long-term kinetics of phosphorylated H2AX (γ-H2AX) after in vivo irradiation. We have investigated, by microscopic and flow cytometric immunochemistry, γ-H2AX induction and removal in testicular cells of irradiated mice, in comparison with bone marrow cells. In unirradiated testicular cells, much higher levels of γ-H2AX were measured by flow cytometry with respect to bone marrow cells. Irradiation induced a redistribution of γ-H2AX into discrete foci detectable by microscopy. In irradiated bone marrow, the percentage of labelled cells peaked at 1 h and rapidly declined, in agreement with data on in vitro cell lines. In contrast, spermatocytes and round spermatids showed persistent labelling until 48 h. During this time, in spermatids, topological changes were observed in γ-H2AX foci from a pattern of many uncountable dots to a pattern of few large spots. Observations of testicular sections confirmed this trend in the reduction of foci number in spite of substantially invariable percentages of labelled cells in the analysed timeframe. To assess whether γ-H2AX persistence in testicular cells was due to unrepaired DNA breaks, we performed comet assay and immunofluorescence analysis of Mdc1, a marker of DDR different from γ-H2AX. Comet assay showed that most breaks were repaired within 2 h. Forty-eight hours after irradiation, contrary to γ-H2AX foci that remained detectable in 80% of initially labelled cells, Mdc1 foci were observed in only 20-30% of cells. These data suggest that, at long times after irradiation, mechanisms additional to impairment of DNA break repair may account for the long persistence of γ-H2AX foci in male germ cells.

Mechanisms and risk of chemically induced aneuploidy in mammalian germ cells.

Aneuploidy is a pathological condition that affects 35% of human spontaneous abortions and 0.3% of livebirths. In spite of the increasing knowledge about molecular mechanisms of meiosis and chromosome segregation, maternal age remains the only ascertained aetiological factor. Genetically modified mouse models have been produced that show increased incidence of aneuploid gametes or abnormalities in meiotic recombination and synapsis. They suggest that genetic polymorphisms might also be involved in the aetiology of human germ cell aneuploidy. Experimental studies in the mouse have identified chemicals that can induce aneuploidy in male and female germ cells. Compounds affecting spindle assembly/dynamics are potent aneugens for oocytes and less so also for spermatocytes. They are active at acute doses during a short time interval preceding the metaphase-to-anaphase transition. Topoisomerase inhibitors are also meiotic aneugens which act on the recombination process; for the first time, the production of viable aneuploid mouse progeny was shown after paternal treatment with etoposide. A comparison between in vitro and in vivo effects of suspect aneugens demonstrates that there are biological mechanisms protecting mammalian oocytes from acute exposures to exogenous chemicals. Endocrine disruptors are a novel group of compounds that might affect chromosome segregation at meiosis. Data on bisphenol-A suggest that such chemicals could be active at low chronic exposure levels, but this hypothesis needs to be confirmed by further experiments. Experiments on cultured mouse oocytes treated with inhibitors of biochemical reactions involved in the regulation of chromosome segregation point to possible new mechanisms of action of environmental aneugens.

Induction and transmission of chromosome aberrations in mouse oocytes after treatment with butadiene diepoxide

A study was conducted on the genotoxicity of butadiene diepoxide (DEB) in mouse oocytes. Superovulated female mice were injected intraperitoneally with DEB and mated with untreated males. Oocyte exposure occurred approximately 1.5 days before ovulation. DEB doses ranged between 26 and 52 mg/kg. Chromosome aberrations were scored in C‐banded metaphases of one‐cell embryos. The percentage of mated females, the average number of zygotes harvested per female, the frequencies of unfertilized oocytes and developmentally delayed zygotes did not reveal any overt sign of chemical toxicity which hindered the propensity of animals to mate or affected the ovulation, fertilization, or cell cycle progression of treated oocytes. A dose‐dependent induction of chromosome aberrations was observed which was best fitted by a linear quadratic equation. Half of all the aberrations transmitted by DEB‐treated oocytes were chromatid‐type breaks or exchanges. Among chromosome‐type aberrations, double fragments far exceeded chromosome exchanges. This spectrum of structural aberrations differed markedly from what was previously observed in one‐cell embryos conceived by DEB‐treated sperm, where 97% were chromosome‐type aberrations and 40% were dicentrics or translocations. This difference suggests that chromosome damage in one‐cell embryos can be fixed by different mutagenic pathways influenced by the targeted gamete and its specific chromatin configuration. After exposure to the same dose, oocytes transmitted to one‐cell embryos between 4 and 8 times fewer aberrations than DEB‐treated sperm. While the rate of aberration induction suggests that female germ cells may be less at risk than mature sperm,especially at low‐dose levels, the higher threshold for reproductive toxicity observed in female than in male mice may justify inclusion of data on female germ cell mutagenicity in the genetic risk assessment of butadiene exposure. Environ. Mol. Mutagen. 30:403–409, 1997

X-Ray Induced DNA Damage and Repair in Germ Cells of PARP1 −/− Male Mice

Poly(ADP-ribose)polymerase-1 (PARP1) is a nuclear protein implicated in DNA repair, recombination, replication, and chromatin remodeling. The aim of this study was to evaluate possible differences between PARP1−/− and wild-type mice regarding induction and repair of DNA lesions in irradiated male germ cells. Comet assay was applied to detect DNA damage in testicular cells immediately, and two hours after 4 Gy X-ray irradiation. A similar level of spontaneous and radiation-induced DNA damage was observed in PARP1−/− and wild-type mice. Conversely, two hours after irradiation, a significant level of residual damage was observed in PARP1−/− cells only. This finding was particularly evident in round spermatids. To evaluate if PARP1 had also a role in the dynamics of H2AX phosphorylation in round spermatids, in which γ-H2AX foci had been shown to persist after completion of DNA repair, we carried out a parallel analysis of γ-H2AX foci at 0.5, 2, and 48 h after irradiation in wild-type and PARP1−/− mice. No evidence was obtained of an effect of PARP1 depletion on H2AX phosphorylation induction and removal. Our results suggest that, in round spermatids, under the tested experimental conditions, PARP1 has a role in radiation-induced DNA damage repair rather than in long-term chromatin modifications signaled by phosphorylated H2AX.

In vivo repair of DNA damage induced by X-rays in the early stages of mouse fertilization, and the influence of maternal PARP1 ablation.

The early pronucleus stage of the mouse zygote has been characterised in vitro as radiosensitive, due to a high rate of induction of chromosome-type chromosome abnormalities (CA). We have investigated the repair of irradiation induced double strand DNA breaks in vivo by γH2AX foci and first cleavage metaphase analysis. Breaks were induced in sperm and in the early zygote stages comprising sperm chromatin remodelling and early pronucleus expansion. Moreover, the role of PARP1 in the formation and repair of spontaneous and radiation-induced double strand breaks in the zygote was evaluated by comparing observations in C57BL/6J and PARP1 genetically ablated females. The results confirmed in vivo that the rate of chromosome aberration induction by X-rays was approximately 3-fold higher in the zygote than in mouse lymphocytes. This finding was related to a diminished efficiency of double strand break signalling, as shown by a lower rate of γH2AX radiation-induced foci compared to that measured in most other somatic cell types. The spontaneous frequency of CA in PARP1 depleted zygotes was slightly but significantly higher than in wild type zygotes. Also, these zygotes showed some impairment of the radiation-induced DNA Damage Response when exposed closer to the start of S-phase, revealed by a higher number of γH2AX foci and a longer cell cycle delay. The rate of chromosome aberrations, however, was not elevated over that of wild type zygotes, possibly thanks to backup repair pathways and/or selection mechanisms against damaged cells. When comparing with the literature data on irradiation induced CA in mouse zygotes in vitro, the levels of induction were strikingly similar as was the frequency of misrepair of double strand breaks (γH2AX foci). This result can be reassuring for in vitro human gamete and embryo handling, because it shows that culture conditions do not significantly affect double strand DNA break repair.

Genotoxic effects of butadiene in mouse lung cells detected by an ex vivo micronucleus test.

Lung fibroblasts from BD-exposed mice have been analysed for the occurrence of micronuclei. Primary cultures set up 24h after the end of exposure were treated with cytochalasin B and micronuclei scored in binucleate cells. A three-fold statistically significant increase of micronucleated cells was detected after exposure to 500ppm, the lowest tested concentration. A linear dose effect relationship was observed between 500 and 1300ppm. Immunofluorescent staining of kinetochore proteins was applied to distinguish between acentric micronuclei produced by chromosome breaks and micronuclei containing a centromeric region, most likely induced by chromosome loss. A statistically significant increase of both types of MN in 1300ppm-exposed females and a significant increase in centromeric MN in 500ppm-exposed males were detected. These data demonstrate that an intermediate of BD metabolism with a potential for clastogenic and aneugenic effects is active in lung cells after inhalation exposure. These effects can play a role in the initiation and promotion of BD-induced lung tumours.