Synaptonemal complex damage as a measure of chemical mutagen effects on mammalian germ cells

Interdisciplinary Approach to Assessing the Health Risk of Air Toxic Chemicals: An Overview

To assist the regulatory branch of the Environmental Protection Agency in addressing the risk assessment of air toxics, the Health Effects Research Laboratory initiated a comprehensive inhalation toxicology program to provide key health effects data missing from the current data base. A priority ranking of chemicals based on the potential for substantial human exposure and the need for health effects data was developed to identify candidate chemicals for toxicological research. The major goal of the program is to evaluate the concentration-response from acute, intermittent and subchronic inhalation exposures to developmental, genetic, hepatic, immunologic, neurologic, pulmonary and reproductive toxicity in a manner that provides data for the regulatory health assessment of air toxic chemicals. Extrapolation and dosimetry research is also conducted to improve the basis for human risk assessment. Determination of biological endpoints to be examined will be decided on a compound-by-compound basis, depending on the physical, chemical and structural characteristics of the chemical and evaluation of the existing health data base. Although the main emphasis is on inhalation as the primary route of exposure, some of the laboratories will compare inhalation to other routes, such as oral, to better understand the influence of route of exposure and hence the potential applicability of existing health data. Acute and intermittent exposures will be done for all compounds. Upon evaluation of the acute results, a decision will be made as to whether subchronic studies are needed. Endpoints that show unusual sensitivity may be investigated in greater detail. The total length of exposure will vary from 1 to 21 days. The daily length of exposure will range from 1 to 8 hr. If adverse effects are observed at ambient levels, the time to recovery after exposure will be investigated.

Radiobiology and reproduction-what can we learn from Mammalian females?

Ionizing radiation damages DNA and induces mutations as well as chromosomal reorganizations. Although radiotherapy increases survival among cancer patients, this treatment does not come without secondary effects, among which the most problematic is gonadal dysfunction, especially in women. Even more, if radio-induced DNA damage occurs in germ cells during spermatogenesis and/or oogenesis, they can produce chromosomal reorganizations associated with meiosis malfunction, abortions, as well as hereditary effects. However, most of our current knowledge of ionizing radiation genotoxic effects is derived from in vitro studies performed in somatic cells and there are only some experimental data that shed light on how germ cells work when affected by DNA alterations produced by ionizing radiation. In addition, these few data are often related to mammalian males, making it difficult to extrapolate the results to females. Here, we review the current knowledge of radiobiology and reproduction, paying attention to mammalian females. In order to do that, we will navigate across the female meiotic/reproductive cycle/life taking into account the radiation-induced genotoxic effects analysis and animal models used, published in recent decades.

Effects of Acute and Chronic Cyclophosphamide Treatment on Meiotic Progression and the Induction of DNA Double-Strand Breaks in Rat Spermatocytes1

Male rats treated with cyclophosphamide, an alkylating agent commonly used clinically in both acute and chronic regimens, present with damaged male germ cells and abnormal progeny outcome. The extent and type of damage induced by cyclophosphamide largely depend on the germ cell type exposed to the drug and its ability to respond to insult. In the present study, the response of pachytene spermatocytes to damage was evaluated by assessing their ability to undergo meiotic G2/MI transition following exposure to acute or chronic cyclophosphamide. Male rats were given an acute high dose (70 mg/kg, once) or chronic low doses (6 mg/kg, daily for 5-6 wk) of cyclophosphamide. Pachytene spermatocytes were isolated, cultured, and induced to undergo G2/MI transition with okadaic acid. To determine the effect of DNA damage on meiotic progression, induction of DNA double-strand breaks was detected after each treatment regimen by the formation of foci of phosphorylated histone H2AX. The transition from G2 to MI was impaired after acute cyclophosphamide treatment; this impairment in the progression of pachytene spermatocytes was correlated with extensive DNA double-strand breaks. In contrast, despite the presence of significant levels of DNA damage, meiotic progression was not impaired in spermatocytes after chronic cyclophosphamide exposure. We suggest that the cell cycle impairment induced after acute cyclophosphamide treatment could be mediated by a G2/M checkpoint activated in response to DNA damage. The absence of impairment after chronic treatment raises concern about the functionality of defense mechanisms in male germ cells after repeated exposure to low doses of genotoxic agents.

The effects of oral administration with 17 alpha-methyltestosterone on chromosomal synapsis in Oreochromis niloticus (Pisces, Cichlidae)

The pattern of chromosomal synapsis after treatment with 17 alpha-methyltestosterone (MT), a testosterone analogue routinely used for the reversal of phenotypic sex in aquaculture, was investigated using the Nile tilapia (Oreochromis niloticus) as a model teleost species. Progeny-tested, monosex diploid (2n = 44) individuals were orally administered with diets containing 50 mg/kg MT for 30 days after first feeding (XX(MT) neomales and XY(MT) males) and compared to controls (XY males). The formation and structure of the synaptonemal complex (SC) and the nature of chromosomal synapsis were investigated in control and treated groups by computer-assisted image analysis of transmission electron microscope (TEM) microphotographs taken from SC spreads. Nuclei at the pachytene stage were first observed in XX(MT) neomales, indicating an earlier commitment of genetically female spermatocytes to enter the first meiotic prophase. Administration of MT did not result in obvious SC lesions, breakage, asynapsis or formation of multivalents in genotypic females (XX(MT) neomales). Administration of MT resulted in a significant increase in the SC lengths in XY(MT) males, although it did not significantly alter the pattern of synapsis (SC structure and number and morphology of bivalents) in comparison to XY controls. The significance of the effects and the putative mode(s) of action of MT on chromosomal synapsis in teleosts is discussed.

X-ray-induced synaptonemal complex damage during meiotic prophase in female fetuses of Rattus norvegicus

The different types of damage (synaptic anomalies, chromosome reorganizations and nucleolar fragmentation) observed in oocytes from female rat fetuses irradiated at 14, 16 and 18 days of gestation (d.g.), respectively, indicates the existence of a special sensitivity at the different stages of prophase to X-rays. At the highest dose (5 Gy), we observed a decrease in some of the synaptonemal complex indicators of chromosomal damage, probably reflecting a selection against cells with the highest degree of chromosome anomalies.

Cyclophosphamide-induced aberrations of chromosome pairing in pachytene oocytes

The aim of this study was to characterise damage to synaptonemal complexes in oocytes following cyclophosphamide exposure. Pregnant mice were treated with three different doses of cyclophosphamide (10, 30 and 50 mg/kg body weight) at day 13 of gestation, when oogonia and very early meiotic cells in the female fetuses are found. Primary oocytes were analysed by light- and electron microscopy at gestational day 17 to reveal effects of the alkylating agent on the chromosomal pairing behaviour. Our pachytene analysis demonstrated that the fraction of cells with lesions of synaptonemal complexes, partial asynapsis and desynaptic bivalents were significantly increased over the levels in the control group. The frequency of alterations was similar at doses of 30 and 50 mg/kg. In addition, a significant increase in frequency of univalents over the base level became evident, showing the highest incidence on a dose of 50 mg/kg.

Mutagenicity of anticancer drugs in mammalian germ cells

The evidence for mammalian germ cell mutagenicity induced by anticancer drugs is summarized. Primary attention is paid to the three major mouse germ cell mutagenicity tests- the dominant lethal, heritable translocation, and morphological specific locus tests- from which most germ cell mutagenicity data historically have been obtained. Of the 21 anticancer drugs reviewed, 16 have been tested in one or more of these three tests; with all 16 tested in the most common germ cell test, the male dominant lethal test, and 9 of the 16 also tested in the female dominant lethal test. The patterns of germ cell stage specificity for most of the anticancer drugs are similar, and generally resemble the patterns seen with other types of chemicals; however, some of the patterns are unique. For example, 2 of the 8 chemicals shown to induce dominant lethal mutations in female oocytes, do not induce dominant lethal mutations in male germ cells (adriamycin and platinol). Ten of the 16 chemicals tested in the dominant lethal test were positive in post-meiotic stages (spermatids through mature sperm), and seven also induced reciprocal translocations and/or specific locus mutations in post-meiotic stages. This propensity to induce mutations in post-meiotic stages has been observed with most mutagens. However, 5 of the anticancer drugs also induced dominant lethal mutations in spermatocytes (meiotic prophase cells) and one of them, 6-mercaptopurine, uniquely induced dominant lethal mutations exclusively in preleptotene spermatocytes. Finally, three of the anticancer drugs (melphalan, mitomycin C, procarbazine) are members of a very select group of chemicals shown to induce specific locus mutations in spermatogonial stem cells of mice. The implications for human risk are discussed.

Cyclophosphamide: review of its mutagenicity for an assessment of potential germ cell risks

Cyclophosphamide (CP) is used to treat a wide range of neoplastic diseases as well as some non-malignant ones such as rheumatoid arthritis. It is also used as an immunosuppressive agent prior to organ transplantation. CP is, however, a known carcinogen in humans and produces secondary tumors. There is little absorption either orally or intravenously and 10% of the drug is excreted unchanged. CP is activated by hepatic mixed function oxidases and metabolites are delivered to neoplastic cells via the bloodstream. Phosphoramide mustard is thought to be the major anti-neoplastic metabolite of CP while acrolein, which is highly toxic and is produced in equimolar amounts, is thought to be responsible for most of the toxic side effects. DNA adducts have been formed after CP treatment in a variety of in vitro systems as well as in rats and mice using 3H-labeled CP. 32P-postlabeling techniques have also been used in mice. However, monitoring of adducts in humans has not yet been carried out. CP has also been shown to induce unscheduled DNA synthesis in a human cell line. CP has produced mutations in base-pair substituting strains of Salmonella tryphimurium in the presence of metabolic activation, but it has been shown to be negative in the E. coli chromotest. It has also been shown to be positive in Saccharomyces cerevisiae in D7 strain for many endpoints but negative in D62.M for aneuploidy/malsegregation. It has produced positive responses in Drosophila melanogaster for various endpoints and in Anopheles stephensi. In somatic cells, CP has been shown to produce gene mutations, chromosome aberrations, micronuclei and sister chromatid exchanges in a variety of cultured cells in the presence of metabolic activation as well as sister chromatid exchanges without metabolic activation. It has also produced chromosome damage and micronuclei in rats, mice and Chinese hamsters, and gene mutations in the mouse spot test and in the transgenic lacZ construct of Muta Mouse. Increases in chromosome damage and gene mutations have been found in the peripheral blood lymphocytes of nurses, pharmacists and female workers occupationally exposured to CP during its production or distribution. Chromosome aberrations, sister chromatid exchanges and gene mutations have been observed in somatic cells of patients treated therapeutically with CP. In general, there is a maximum dose and an optimum time for the detection of genetic effects because the toxicity associated with high doses of CP will affect cell division. In germ cells, CP has been shown to induce genetic damage in mice, rats and hamsters although the vast majority of such studies have used male mice.(ABSTRACT TRUNCATED AT 400 WORDS)

Cyclophosphamide-induced synaptonemal complex damage during meiotic prophase of female Rattus norvegicus

The reproductive system can be especially sensitive to the toxic, carcinogenic or mutagenic effects of alkylating agents. However, since studies of such effects on germ cells are complex, their analysis has been frequently overlooked. In humans, occupational or therapeutic exposure to cyclophosphamide has been associated with male (azoospermia) and female (ovarian failure) sterility or infertility. In this work, we have studied the effect of cyclophosphamide on the formation of the synaptonemal complexes in female rat fetuses. Our results indicate that cyclophosphamide administered at 16 days of gestation, when most germ cells are in a proliferative stage in the female rat, significantly increases the frequency of synaptonemal complex and nucleolar fragmentation in a dose-dependent way.

Culture of pachytene spermatocytes for analysis of meiosis

An impediment to the investigation of mammalian spermatogenic meiosis has been the lack of an appropriate system for experimental manipulation of meiotic prophase cells. We report here the use of a simple system for the short-term culture of pachytene spermatocytes. We have assayed parameters of cell function pertinent to meiotic prophase, namely chromosome pairing and synapsis. During the culture period of 24-48 hr, cells maintained typical pachytene morphology, chromatin condensation patterns, and chromosome pairing, as assessed by light and electron microscopy. Uridine incorporation, monitored by autoradiography, reflected the chromosomal distribution found in vivo in that the autosomal chromosomes were transcriptionally active, while the sex chromosomes were not. Thus features of chromosome pairing and sex chromatin inactivation are maintained in these cultures. We have conducted experiments to demonstrate that cultured pachytene spermatocytes can be useful for the analysis of agents, some of which may be suspected mutagens, that might affect chromosome structure and function during meiosis. Treatment of cells with actinomycin D revealed a differential effect on chromatin condensation in the autosomes versus the sex chromosomes. Camptothecin, a topoisomerase inhibitor, induced desynapsis of paired chromosomes. Okadaic acid, a phosphatase inhibitor, induced premature metaphase-I condensation of pachytene chromosomes. This last experiment suggests that these cultured cells may be useful for analysis of meiotic cell cycle controls. Taken together, these results demonstrate a culture system that can be useful for analysis of meiotic events as well as in screening for potential mutagenic agents that might affect meiotic chromosome structure and function.

Synaptonemal complex damage in fetal mouse oocytes induced by ionizing irradiation

Fetal female mice were exposed to ionizing irradiation of 2 Gy in a single dose at days 14, 16, and 17 of gestation. Synaptonemal complexes of primary oocytes were analyzed on day 17. It has been demonstrated that electron beam irradiation of early oocytes on day 14 with 2 Gy is accompanied by a duplication of atretic cells. A significant increase in fragmentations of the synaptonemal complexes over the base level became evident when mice were exposed to irradiation on days 16 and 17 of gestation. Frequencies of multivalent formation and univalents were not increased over the levels in the control group. Reduction of fertility and malsegregation of chromosomes may be a reflection of the consequences of the observed nuclear lesions.

Synaptonemal complex studies in male mice treated with cyproterone acetate or with testosterone

Male mice were injected either with cyproterone acetate (CyAc) or with testosterone enanthate (TE) separately or in combination with estradiol benzoate (E2B) from the neonatal period on or during adulthood. Neonatally treated animals were killed on d28 or d60, whereas all treated adults were killed on d60. Synaptonemal complexes (SCs) were analyzed under the electron microscope. Various SC anomalies were recorded. The frequency of SC alterations was higher in neonatally treated mice injected with E2B alone or in combination with CyAc (range 9.6-23.7%) than in those injected separately with TE or CyAc (range 2-3.9%). In treated neonates, combination of CyAc and E2B treatment increased the prevalence of synaptic impairments (range 11-23.5%). However, whenever TE was added to E2B treatment a significant reduction of these impairments was observed (range 11-2.4 and 23.7-9.7% respectively). In treated adult mice the prevalence of SC anomalies was low (range 2.4-3.1%) whatever hormone was injected. Furthermore, the combination of estradiol with CyAc had no increasing effect on the induction of synaptic alterations. In E2B-treated animals, those injected during the neonatal period were more susceptible than those treated in adulthood. In mice injected separately with TE or CyAc such a difference of sensitivity between neonates and adults was not noticeable. This work demonstrates that testosterone deficiency is partly responsible for E2B-induced SC alterations. However, inhibition of testosterone action at the level of testicular target cells, such as that resulting from administration of cyproterone acetate, is less harmful to the synaptic process of meiosis.

Synaptonemal complex alterations in X-irradiated and in oestrogen-treated mice: a comparative study

Synaptonemal complexes (SCs) were analysed in male NMRI mice either X-irradiated or treated with oestradiol benzoate (E2B). Animals 30 days old underwent a single X-ray exposure of either 5, 7.5 or 10 Gy and were killed at different times after exposure, i.e., 24 h, 1, 4, 12 and 16 weeks. E2B was injected daily to adult mice from day 30 to day 60 or up to day 90 of age. Oestradiol was also administered during the neonatal period and animals were examined on days 28, 60 and 90 of age. Different SC alterations were found in X-irradiated and in E2B-treated mice. SC lesions were rare in oestrogen-treated adult mice. Among SC anomalies, asynapsis and fragmentation of SC were common lesions. However, the former was more frequent in E2B-treated mice, whereas the latter was more frequent in X-irradiated mice. Quadri- or multi-valents, bridges between bivalents, rings and loops were exclusively encountered in the latter, whereas heterotelomeric associations seemed to be specific in E2B-treated animals. The mechanisms of the different SC lesions are discussed.

The effect of tequila in the synaptonemal complex structure of mouse spermatocytes

The effect of tequila in the synaptonemal complex (SC) of mouse spermatocytes was determined. We tested 3 dosages (2.1, 4.2 and 8.4 g/kg) administered in a single intraperitoneal inoculation. The frequency of SC alterations was established in pachytenic nuclei 5 days after the administration using a silver impregnation technique. Three types of alterations were observed (desynapses, breaks and multiaxials) and the rate of each alteration was compared with that obtained with appropriate controls, including cyclophosphamide (CP) (150 mg/kg). The results showed a significant increase induced by tequila only in the frequency of desynapses. This damage began at the second highest dose (4.2 g/kg). The other SC alterations were in the control range. CP, however, induced a significant increase in all 3 types of SC alterations.

Evidence that methanol inhalation does not induce chromosome damage in mice

Mice were exposed by inhalation to 800 or 4000 ppm methanol for 5 days, and cytogenetic effects were analyzed in blood erythrocytes, lung cells, and testicular germ cells. The results were uniformly negative; no increased frequencies of micronuclei in blood cells, of sister-chromatid exchanges, chromosome aberrations, or micronuclei in lung cells, or of synaptonemal complex damage in spermatocytes were found. From the standpoint of risk assessment, these experimental studies do not reveal any evidence of a cytogenetic hazard associated with inhalation of methanol.

Synaptonemal complex damage as a measure of genotoxicity at meiosis

Synaptonemal complex aberrations can provide a sensitive measure of chemical-specific alterations to meiotic chromosomes. Mitomycin C, cyclophosphamide, amsacrine, ellipticine, colchicine, vinblastine sulfate, and cis-platin exposures in mice have been shown to cause various patterns of synaptonemal complex structural damage and synaptic irregularity. These effects are suggestive of abnormal homologue pairing/synapsis/recombination effects which, theoretically, could be implicated in mechanisms leading to aneuploidy and other potentially heritable chromosomal disorders.

Synaptonemal complex damage induced by clastogenic and anti-mitotic chemicals: implications for non-disjunction and aneuploidy

Mice were treated with mitomycin C, cyclophosphamide, amsacrine, colchicine, or vinblastine sulfate, and meiotic prophase cells analyzed for synaptonemal complex (SC) damage. All test agents caused synaptonemal complex breakage and synapsis irregularities, although propensities for inducing specific types of damage at S-phase or prophase stages varied among the chemicals. The data indicate that SC analysis can reveal chemical-specific alterations to meiotic homologue pairing/synapsis which have not generally been recognized, and which theoretically may be implicated in non-disjunction.

Synaptonemal complex damage in relation to meiotic chromosome aberrations after exposure of male mice to cyclophosphamide

The genetic implications of induced synaptonemal complex (SC) damage are not known. However, on theoretical grounds, such aberrations could be involved in mechanisms leading to potentially heritable defects. Cyclophosphamide (CP), a chemical reported to cause structural and numerical chromosomal aberrations in the mouse, was used to determine if SC damage observed in meiotic prophase is related to subsequent metaphase chromosomal aberrations. Male mice were injected i.p. with CP. In some instances, mice were also injected simultaneously with tritiated thymidine to label DNA so that cells could be tracked autoradiographically through spermatogenesis. Prophase, primary metaphase (M1), and secondary metaphase (M2) samples were sequentially harvested at appropriate times from the same individual, and nuclei were examined for aberrations. Correlation coefficients between SC and metaphase chromosome aberrations were calculated. The inclusion of tritium labeling increased the number and significance of positive correlations. Positive correlations were found between (1) dose-dependent total SC damage and damage to M1, and to a lesser extent, M2 chromosomes; (2) SC breaks/fragments and M1 chains/rings as well as isochromatid breaks/fragments; (3) SC asynapsis and M1 chromatid breaks/fragments; (4) SC multi-axial configurations and M1 chains/rings as well as isochromatid and chromatid breaks/fragments; and (5) SC multi-axial configurations and M2 hyperploidy. These correlations do not define mechanistic or causal relationships between SC and chromosomal damage. However, taken together with the observation that induced SC damage is many times greater than ensuing metaphase chromosome damage, they substantiate SC analysis as a highly sensitive indicator of potentially heritable effects of this (and presumably other) genotoxic agents.

In vitro analysis of germ cell genotoxicity in testis explant cultures: spermatid micronucleus assays

Explant cultures of testes from the frog Xenopus laevis have been employed to evaluate the application of testis culture to the routine screening of potential germ cell genotoxicants. Testis explants were incubated with varied concentrations of 3 model mutagens (9,10-dimethyl-1,2-benzanthracene, cyclophosphamide, adriamycin) and solvent controls. Round spermatids were isolated from testes cultured 2-30 days after exposure to each mutagen. The spermatids were then stained with Hoechst 33258 and spermatid micronuclei were scored with a fluorescence microscope. Acute exposure of testes to each mutagen resulted in a dose-dependent increase in spermatid micronuclei that was stage specific and proportional to the length of the exposure period. The assay sensitively detected clastogenic effects by 10(-7) M adriamycin (4-h exposure period) and 10(-6) M cyclophosphamide and dimethylbenzanthracene (24-h exposure). The results demonstrate the feasibility of in vitro approaches to the routine screening and investigation of genotoxicity in the premeiotic S through meiotic division stages of vertebrate spermatogenesis.

Induction and survival of micronuclei in rat spermatids. Comparison of two meiotic micronucleus techniques using cyclophosphamide

The induction and survival of micronuclei (MN) in rat spermatids was studied by two different methods, the dissection method (DM) and the suspension method (SM). It was observed that MN are induced by cyclophosphamide in the S phase of meiosis, in preleptotene spermatocytes, and in an earlier cell stage, the type B spermatogonia. Both techniques showed that MN survive in spermatids at least 5 days. Advantages of the DM include the use of a DNA-specific fluorochrome for staining of MN, higher MN frequencies observed, and the possibility to gain detailed information of the kinetics of induction of MN. In the SM, slide preparation is simpler than in the DM, and several samples can be prepared simultaneously but the scoring of slides is time consuming. Improvements of the sampling system of the DM are suggested. For evaluation of clastogenic action of chemicals on male germ cells both techniques provide a simple and rapid approach.