Similar dose-related chromosome non-disjunction in young and old female mice after X-irradiation

Shortened estrous cycle length, increased FSH levels, FSH variance, oocyte spindle aberrations, and early declining fertility in aging senescence-accelerated mouse prone-8 (SAMP8) mice: concomitant characteristics of human midlife female reproductive aging

Women experience a series of specific transitions in their reproductive function with age. Shortening of the menstrual cycle begins in the mid to late 30s and is regarded as the first sign of reproductive aging. Other early changes include elevation and increased variance of serum FSH levels, increased incidences of oocyte spindle aberrations and aneuploidy, and declining fertility. The goal of this study was to investigate whether the mouse strain senescence-accelerated mouse-prone-8 (SAMP8) is a suitable model for the study of these midlife reproductive aging characteristics. Midlife SAMP8 mice aged 6.5-7.85 months (midlife SAMP8) exhibited shortened estrous cycles compared with SAMP8 mice aged 2-3 months (young SAMP8, P = .0040). Midlife SAMP8 mice had high FSH levels compared with young SAMP8 mice, and mice with a single day of high FSH exhibited statistically elevated FSH throughout the cycle, ranging from 1.8- to 3.6-fold elevation on the days of proestrus, estrus, metestrus, and diestrus (P < .05). Midlife SAMP8 mice displayed more variance in FSH than young SAMP8 mice (P = .01). Midlife SAMP8 ovulated fewer oocytes (P = .0155). SAMP8 oocytes stained with fluorescently labeled antitubulin antibodies and scored in fluorescence microscopy exhibited increased incidence of meiotic spindle aberrations with age, from 2/126 (1.59%) in young SAMP8 to 38/139 (27.3%) in midlife SAMP8 (17.2-fold increase, P < .0001). Finally, SAMP8 exhibited declining fertility from 8.9 pups/litter in young SAMP8 to 3.5 pups/litter in midlife SAMP8 mice (P < .0001). The age at which these changes occur is younger than for most mouse strains, and their simultaneous occurrence within a single strain has not been described previously. We propose that SAMP8 mice are a model of midlife human female reproductive aging.

Effect of x-rays on chromosome 21 nondisjunction

In a series of 156 females and 149 males with a Down syndrome (DS) child, a case-control study was performed to evaluate the effect of abdominal-pelvic exposure to diagnostic x-rays prior to conception on nondisjunction (ND). Cytogenetic analysis using QFQ banding allowed unequivocal identification of ND parents as cases. Partners of ND parents were treated as control group. Odds ratio for the association of x-rays exposure and ND occurrence (stratified for sex and age) was 1.85 (borderline to significance: with a 95% confidence interval 1-3.44). Such an association appeared highly significant in older fathers and borderline to significant in younger mothers, when age groups were analyzed separately. By comparing mean parental ages at birth of the propositus, the prevalence of exposure to x-rays appeared moderately associated with aging in control parents of both sexes. Furthermore, the mean age of unexposed ND parents of paternally derived SD cases was the same as the referent population's, suggesting that age is not a risk factor for ND in the male, except for being associated with increasing exposure risk. Conversely, risk attributable to x-rays exposure in the female appears to be progressively diluted with increasing age, by strongly age-dependent high risk, presumably due to biologic factors that are not affected by environmental exposure.

Cytogenetic and genetic studies of radiation-induced chromosome damage in mouse oocytes. I. Numerical and structural chromosome anomalies in metaphase II oocytes, pre- and post-implantation embryos

The incidences of X-ray induced numerical and structural chromosome anomalies were screened in a range of developmental stages from metaphase II oocytes through to post-implantation embryos. Following 1 Gy of acute X-rays to immediately preovulatory stage oocytes, the rate of hyperploidy (chromosome gain) was found to be elevated over levels in unirradiated controls, at metaphase II, in 1-cell and 3.5 day pre-implantation embryos but not in 8.5 day post-implantation foetuses. In the latter, however, the frequency of mosiacism was significantly increased. A similar response of an increase in mosaicism but not in hyperploidy in 8.5 day post-implantation embryos was also found after irradiation of dictyate stage oocytes with 4 Gy of acute X-rays. Significantly elevated frequencies of structural chromosome anomalies were present in metaphase II oocytes and pre-implantation embryonic stages, but could not be detected in block-stained chromosome preparations from 8.5 day post-implantation foetuses. However, analysis of chromosome preparations after G-banding showed that almost 14% of 14.5 day foetuses carried a chromosome rearrangement after 1 Gy of X-rays to immediately preovulatory stage oocytes. Overall, our data indicate that the presence of radiation-induced chromosome gains are incompatible with embryonic survival but that a proportion of embryos with structural chromosome damage develop past mid-gestation. These latter embryos are therefore potentially capable of contributing to the genetic burden of the next generation.

Aneuploidies and micronuclei in the germ cells of male mice of advanced age

The objective of this research was to determine whether the frequencies of chromosomally defective germ cells increased with age in male laboratory mice. Two types of chromosomal abnormalities were characterized: (1) testicular spermatid aneuploidy (TSA) as measured by a new method of multi-color fluorescence in situ hybridization (FISH) with DNA probes specific for mouse chromosomes X, Y and 8, and (2) spermatid micronucleus (SMN) analyses using anti-kinetochore antibodies. B6C3F1 mice (aged 22.5 to 30.5 months, heavier than controls but otherwise in good health) showed significant approximately 2.0 fold increases in the aneuploidy phenotypes X-X-8, Y-Y-8, 8-8-X and 8-8-Y with the greatest effects appearing in animals aged greater than 28 months. No age effect was observed, however, in X-Y-8 hyperhaploidy. Major age-related increases were seen in Y-Y-8 and X-X-8 hyperhaploidies suggesting that advanced paternal age is associated primarily with meiosis II rather than meiosis I disjunction errors. A approximately 5 fold increase was also found in the frequency of micronucleated spermatids in aged mice when compared with young controls. All micronuclei detected in the aged animals lacked kinetochore labeling, suggesting that they either did not contain intact chromosomes or the chromosomes lacked detectable kinetochores. The findings of the TSA and SMN assays are consistent with meiotic or premeiotic effects of advanced age on germ cell chromosomes, but there were differences in the age dependencies of aneuploidy and micronuclei. In summary, advanced paternal age may be a risk factor for chromosomal abnormalities (both aneuploidy and structural abnormalities) in male germ cells.

Risk calculations for hereditary effects of ionizing radiation in humans

A prediction of the extent to which an additional dose of ionizing radiation increases the natural germ cell mutation rate, and how much such an increase will affect the health status of future human populations is part of the service that human geneticists are expected to offer to human society. However, more detailed scrutiny of the difficulties involved reveals an extremely complex set of problems. A large number of questions arises before such a prediction can be given with confidence; many such questions cannot be answered at our present state of knowledge. However, such predictions have recently been attempted. The 1988 report of the United Nations Scientific Committee for the Effects of Atomic Radiation and the fifth report of the Committee on Biological Effects of Ionizing Radiation of the US National Research Council have presented a discussion of the human genetics problems involved. Empirical data from studies on children of highly radiation-exposed parents, e.g. parents exposed to the atomic bombs of Hiroshima and Nagasaki, or parents belonging to populations living on soil with high background radiation, have been mentioned in this context. Whereas precise predictions are impossible as yet because of deficiencies in our knowledge of medical genetics at various levels, the bulk of the existing evidence points to only small effects of low or moderate radiation doses, effects that will probably be buried in the "background noise" of changing patterns of human morbidity and mortality.

The influence of maternal age on radiation-induced chromosome aberrations in mouse oocytes

The relative sensitivities of dictyate oocytes from young and old female mice to radiation-induced chromosome damage were examined in 2 separate experiments. Firstly, females were given either 2 or 4 Gy of X-rays and metaphase I stage oocytes collected 16.5 days later. Analysis of these cells showed dose-related increases in chromosome aberrations in both age groups. The response was significantly greater in oocytes of older females. In the second experiment, females were given 4 Gy of X-rays and metaphase I stage oocytes collected 3.5 days later. Again, a significantly larger frequency of aberrations was present in cells from older animals. Overall, these 2 experiments provide unambiguous evidence that the radiosensitivity of mouse dictyate oocytes increases with advancing maternal age.

The effect of low-dose X-irradiation on numerical and structural chromosome anomaly induction in mouse immature oocytes

The ability of low doses of X-rays to induce numerical and structural chromosome anomalies in immature oocytes was examined in two experiments. In the first, 10-11-day-old females were given 0.1 or 0.2 Gy of X-rays and sampled at intervals up to 32 weeks later. In the second, 4-5-week-old females were given 0.1 Gy of X-rays and sampled up to 36 weeks post-irradiation. Chromosome anomalies were assessed in metaphase II oocytes. In the first experiment, there was evidence of dose-related increases in both hyperhaploidy (n + 1) and structural chromosome anomalies. In the second experiment, only the frequency of structural chromosome anomalies was found to increase consistently after irradiation. There was no indication that radiation-induced depletion of the oocyte population was associated with an early onset of the maternal age effect on nondisjunction.

Gamma-ray-induced numerical and structural chromosome anomalies in mouse immature oocytes

Young female mice were given 1, 2 or 3 Gy of chronic gamma-irradiation. Metaphase II oocytes from these mice were sampled 8 weeks after the end of the treatment and screened for numerical and structural chromosome anomalies. The proportions of hyperhaploid (n + 1) metaphase II oocytes increased after 1 and 2 Gy (significantly after the latter) but remained at the control level after 3 Gy of gamma-rays. Structural chromosome anomalies were significantly increased above control levels at all doses and also showed an increase with dose to 2 Gy and a decline at 3 Gy. The cause of this unusual dose-response pattern for induced chromosome damage is uncertain. These results show that significant chromosome damage can be induced by irradiation of immature oocytes, a cell stage previously suggested to be resistant to induced genetic damage.

Immunofluorescent staining of kinetochores in micronuclei: a new assay for the detection of aneuploidy

The immunofluorescent staining of kinetochores in micronuclei with antikinetochore antibodies was used to develop an in vitro assay for aneuploidy-inducing agents. The results show that about 80% of micronuclei induced by either colchicine or chloral hydrate contained kinetochores; only 9% of X-ray-induced micronuclei reacted positively to the antibody. These findings indicate that the in vitro micronucleus assay coupled with immunofluorescent staining of kinetochores can be a useful method for assessing the ability of chemicals to induce aneuploidy and/or chromosome aberrations.

Analysis of structural and numerical chromosomal anomalies at the first, second, and third mitosis after irradiation of one-cell mouse embryos with X-rays or neutrons

One-cell mouse embryos were irradiated with X-rays or neutrons. Analysis of the first, second, and third postradiation mitoses revealed that the yields of structural aberrations increased linearly after exposure to both radiation qualities. For X-rays the aberration frequency decreased from the first to the third mitosis, whereas after neutrons it decreased from the first to the second mitosis but then increased in the third mitosis. RBEs of 4.7, 4.8, and 7.4 were calculated for the corresponding mitoses. It was clearly demonstrated that new aberrations were produced after the first postradiation mitosis and expressed during the second and third mitosis. Chromosome loss also increased with increasing radiation dose at the second mitosis. An RBE of 2 was calculated for this effect. Comparing the presented data with previous investigations on embryonic and fetal death after prenatal irradiation, it was concluded that the high radiosensitivity of the one-cell embryo is due to the induction of structural as well as of numerical chromosome aberrations.

The genotoxic effect of beta-propiolactone on mammalian oocytes

beta-Propiolactone (beta PL) has been tested on preimplantation mouse embryos for possible genotoxic effects. Tests were performed at different stages of meiosis (late prophase I, diakinesis/metaphase I, anaphase I, telophase I/prophase II and metaphase II) by injecting females at various times after the induction of superovulation. Male and female derived chromosome complements from first-cleavage embryos were analysed before syngamy for cytogenetic abnormalities. A higher proportion of diploid oocytes, produced by the non-extrusion of the first or second polar body, was found after fertilization when the compound was administered immediately before metaphase I or II. No obvious effect was detected at any other time of beta PL exposure. Based on these results, several possible modes of action for beta PL are postulated.

Meiotic non-disjunction induced by fission neutrons relative to X-rays observed in mouse secondary spermatocytes. II. Dose-effect relationships after treatment of pachytene cells

(C57B1/Cne X C3H/Cne)F1 male mice were irradiated with single acute doses of 0.4 MeV neutrons (from 0.11 to 0.72 Gy) or 250 kV X-rays (from 0.25 to 3 Gy) and sacrificed 5 days later. Chromosome preparations of secondary spermatocytes, irradiated at the stage of pachytene, were analysed and the incidence of hyper-haploidies and chromosome fragments was recorded. Data on numerical aberrations were fitted by highly significant linear relationships for both types of radiation. A relative biological effectiveness (RBE) value of 5.65 was estimated by the ratio between the slopes of the two regression lines. The same linear fitting was applied to frequencies of cells with fragments, even if in this case other types of functions could not be excluded. An RBE value was estimated in the same way as for numerical aberrations and yielded a comparable figure of 5.23. A significant correlation was also found between the incidence of numerical and structural aberrations, which points to the chromosome itself as the prevalent target for radiation-induced non-disjunction (ND). In addition, the highly significant linearity of the dose-effect relationship observed for the induction of aneuploidies suggests, as the simplest hypothesis, a single-hit mechanism of radiation action, possibly through pre-non-disjunctional damage to the centromeric region, rather than an indirect induction of segregational difficulties after primarily induced chromatid interchanges.

X-ray-induced chromosome aberrations in immediately preovulatory oocytes

The effects of relatively small doses of X-rays (up to 100 cGy) to immediately preovulatory mouse oocytes have been examined by screening chromosome aberrations at metaphase I. Dose-related responses for the induction of aberrations were found. These were mainly of the quadratic or power-law types, and therefore similar in nature to the dose-responses described elsewhere for dictyate oocytes. The frequencies of the various categories of structural aberration have been compared to the previously determined rates of radiation-induced non-disjunction in immediately preovulatory oocytes in order to examine the potential involvement of structural chromosome aberrations in radiation-induced non-disjunction.

The influence of mating status and age on the induction of chromosome aberrations and dominant lethals in irradiated female mice

Young and old hybrid female mice were given 0.5 Gy or 2 Gy acute x-irradiation, followed by (i) in utero examination for dominant lethal mutations, or (ii) examination of metaphase I oocytes for chromosome aberrations 2-3 weeks after the irradiation. Some of the old females had been mated when young to males of a specific locus stock. Others were left unmated until after the irradiation when they, and the young females, were mated to the same specific locus stock and allowed to have 1 (if given 2 Gy) or 2 (if given 0.5 Gy) litters before the dominant lethal test. In both the 0.5-Gy and 2-Gy series, mean sizes of first litters in the old late-mated group were markedly lower than in the old early-mated or young groups, the differences being significant at the 2-Gy level. The intrauterine examinations showed that this difference was largely the result of a reduced ovulation rate in the old late-mated females. Preimplantation loss tended to be higher in all the old females than in the young ones, but differences between the groups in postimplantation lethality were less pronounced. In the chromosome studies, only about half as many oocytes were recovered from the ovaries of old females than from young ones. At both the 0.5-Gy and 2-Gy dose levels interchange frequencies were non-significantly higher in old than in young females (with no clear-cut effect of mating status), while the overall frequency of aberrations (interchanges + fragments) was significantly higher in oocytes of old than young females after 2 Gy X-rays (35.5% against 12.5%). No specific locus mutations were found in 5616 offspring of unirradiated females.

Tests for heritable genetic damage and for evidence of gonadal exposure in mammals

Tests for the induction of genetic damage in mammalian germ cells provide the data needed for human genetic risk assessment and are used as standards for judging the ability of shorter-term tests to predict genetic hazard. In this review, 15 mammalian germ-cell tests and their variants are described. These tests are of two general types: (a) those designed to detect certain classes of genetic damage (gene mutations, chromosome breakage and/or rearrangement, and chromosome mis-segregation), regardless of whether or not the endpoint scored has any significance to human health, and (b) those designed to detect phenotypes that have human health implications, while the nature of the genetic damage is not usually known. Exposure to a mutagenic agent presents no genetic hazard if the chemical or its metabolites fail to reach the reproductive cells. Tests for gonadal exposure are, therefore, important, as preliminaries or components of studies on germ-cell mutagenicity. Seven of these tests and their variants are briefly described in the second part of the paper.

Dose-related chromosome non-disjunction in female mice after X-irradiation of dictyate oocytes

The chromosome non-disjunction inducing effect of relatively large doses (100-600 cGy) of X-rays to various dictyate oocyte stages has been examined by chromosomal analysis of 1-cell embryos recovered from female mice 3.5-23.5 days after irradiation. Numerical chromosome anomalies, as a result of non-disjunction, occurred in significantly larger proportions of embryos from irradiated females compared to unirradiated controls. Moreover, non-disjunction was induced by X-irradiation in dose-related fashions which could be described by either quadratic or dose-squared curves. The different oocyte maturation stages sampled showed significantly different responses to X-irradiation. The most mature stage, sampled 3.5 days after treatment, was less responsive to the non-disjunction inducing effect of X-rays compared to other, younger maturation stages. Chromosome structural anomalies were also found significantly more frequently after X-irradiation of dictyate oocytes. Structural anomalies were induced in dose-related fashions in all oocyte maturation stages and could be described by either quadratic or dose-squared curves. A smaller proportion of embryos from females sampled at the shortest interval after irradiation contained structural anomalies compared to those from females sampled at the longer intervals. No evidence was obtained for a significant effect of X-irradiation on the frequency of triploid embryos.

Testing of 3 chemical compounds for aneuploidy induction in the female mouse

The 3 chemicals, 6 mercaptopurine (6-MCP), phenylalanine and para-fluorophenylalanine (pFPA) have been tested on mouse oocytes of the Swiss strain for possible aneuploidy-inducing effects. Tests were made at the dictyate stage in young and aged females and at the preovulatory (diakinesis/MI) stage in aged females only. Metaphase II chromosome complements were analysed for aneuploidy resulting from segregational errors arising at the first meiotic division. No evidence of non-disjunction was found either in treated or control groups up to the age of 40 weeks tested. The need to select for gametogenic stage and strain when using a mouse model system for aneuploidy testing, is considered.

Experimental approaches for the detection of chromosomal malsegregation occurring in the germline of mammals

Existing and newly proposed methods to detect the induction of heritable aneuploidy are summarized, and their favorable and unfavorable features discussed. Among the tests involving direct chromosomal examination, those involving study of pronuclear chromosomes at first cleavage are judged to be the most universally informative and reliable, provided tertiary trisomy can be ruled out. Measurement of postmidterm (fetal) death is proposed as a trisomy prescreen that can be readily combined with a dominant-lethal test. Among the genetic procedures for identifying the results of malsegregation events, direct detection of aneuploids has a number of advantages over complementation methods, in which only a fraction of the products of aneuploid gametes is detectable. Direct detection of aneuploids must, however, be restricted to sex chromosomes if postnatal animals are examined. A genetic marker system to detect autosomal trisomies in fetuses is proposed. An examination of experimental parameters that might maximize induction of malsegregation leads to the recommendation to include preleptotene among exposed germ-cell stages.

Meiosis in the foetal mouse ovary. II. Oocyte development and age-related aneuploidy. Does a production line exist?

A systematic search for chromosome pairing defects in foetal mouse oocytes has been carried out in two different strains (Swiss and CBA/Ca) over days 15-19 of gestation and on day 1 post-partum. The aim was to seek direct cytological evidence for a "production line" of oocyte development, or the occurrence of pairing anomalies at meiotic prophase that might lead, in the adult female, to nondisjunction at anaphase I. No evidence for either was found. The data argue against the "production line" hypothesis as the basis for maternal age-related increases in aneuploidy in the mouse. Attempts to analyse chiasmata in oocytes at diplotene were unsuccessful.