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.     

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.     

Nondisjunction and chromosome breakage in mouse oocytes after various X-ray doses

Summary The effect of varying X-ray doses (0.05–0.80 Gy) on preovulatory mouse oocytes was studied by measuring nondisjunction during the first meiotic division, as well as structural chromosome anomalies in ovulated oocytes at metaphase stage II. The incidence of nondisjunction (0.1% hyperploid oocytes) found in oocytes from nonirradiated NMRI-Han female mice was in accordance with the results previously obtained with the same strain. Significantly (P<0.05) more hyperploid oocytes (0.9%) were ovulated following irradiation with 0.8 Gy. There was no statistically significant increase of nondisjunction after low doses. Structural chromosome anomalies occurred, however, even after an irradiation dose as low as 0.05 Gy. The dose response for structural chromosome anomalies is altogether different from that of radiation-induced hyperpoidy. We consider that irradiation of mature oocytes might well be less hazardous with regard to its potency for increasing nondisjunction during the first meiotic division when compared with the effect of chemical mutagens.     

Chromosome anomalies in mouse oocytes after irradiation.

We investigated the cytogenetic effects of X-rays on unfertilized mouse oocytes. NMRI females received an irradiation with 0,22.2,66.6,200, and 600 R during the preovulatory phase 3 hrs after HCG (human chorionic gonadotrophin). This is a stage during oogenesis in which the oocytes pass from late dictyotene to diakinesis. Chromosome analysis was performed after ovulation at metaphase II. From these experiments we can draw the following conclusions: 1) X-rays induced during the preovulatory phase a high number of chromosome anomalies. Among these, structural anomalies prevail. 7 out of 144 ovulated oocytes in matched controls carried such an abnormality, whereas after irradiation we observed with 22.2, 66.6, 200, and 600 R, 11 out of 72, 34 out of 108, 89 out of 102, and 122 out of 124, respectively. 2) Irradiation seems also to affect the chromosome segregation during the 1. meiotic division, as we observed after 22.2, 66.6, and 200 R a total of 6 oocytes out of 204 with a supernummary chromosome. In controls, however, no hyperploidy was found in 143 ova. This increase, however, was not significant. 3) Chromosome anomalies, e.g. breaks and deletions that go back to a one-break event increased linearly with increasing dose. Exchanges, however, going back to two-break events fittest best to the linear-quadratic dose-response model. 4) The dose of 600 R seems to represents a kind of borderline in this experiment, because nearly all (122 out 124) carried at least one structural chromosome anomaly. It is also this dose after which the highest frequency of reciprocal translocations was observed in a hump-shaped slope in spermatocytes after irradiation of spermatogonia (Preston and Brewen, 1973). With an increasing dosage up to 1200 R the frequency of translocations decrease again. The elimination of cells, crossing this borderline, might be due to genetic or non-genetic effects. 5) The frequency of radiation-induced translocations per oocyte agrees with the frequency of translocations in human lymphocytes (Dolphin and Lloyd, 1974) after in vitro irradiation. 6) Significant, lower frequencies of structural chromosome anomalies were observed irradiating earlier stages of mouse oogenesis. These stages are dictyotene from females at the age of 3, or 6 weeks and prophase I-stages in female embryos on the 17th day of gestation. This result may be due to a lower sensitivity of these stages or to modifying events during the interval between irradiation and preparations.     

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.     

Chromosome aberrations in metaphase II oocytes of Chinese hamster (Cricetulus griseus). I. The sensitivity of the pre-ovulatory phase to triaziquone

In previous investigations with triaziquone, cyclophosphamide, amethopterin and X-rays we showed that the pre-ovulatory stages of mice are sensitive to the induction of numerical and structural chromosome aberrations. In the present investigation, we studied the problem whether or not this sensitivity is restricted to mice. Two doses of triaziquone were injected intraperitoneally to Chinese hamster females at different intervals before ovulation. The ovulated oocytes were collected from the ampulla and analyzed at the metaphase II stage. After treatment with triaziquone, the frequency of both numerical and structural aberrations was significantly increased over the control values. The proportion of induced structural anomalies was higher than that of the numerical ones. Chinese hamsters were less sensitive to the induction of structural and especially numerical anomalies compared with the findings with one strain of mouse.     

Elimination of X-ray-induced chromosomal aberrations in the progeny of female mice

Female NMRI mice were irradiated with various doses of X-rays and induced chromosome aberrations were scored in MII oocytes (Dosage: 0.222, 0.666, 2 and 6 Gy). After irradiation with 2 Gy, early zygotes were examined in the 2-cell stage; additional dominant lethals were counted and surviving embryos were examined after 13.5 days of pregnancy. 87.2% of the MII oocytes showed structural chromosomal aberrations after irradiation with 2 Gy. Surviving embryos, however, failed to show any increase in the aberration rate. This result points to (almost) complete elimination of genetically damaged oocytes and zygotes already before birth. In addition to the structural aberrations, aneuploidies were induced. Most of them, however, were hypoploidies. Hence, the study confirmed the well-known susceptibility of oocytes around the time of fertilization for induced chromosome loss. Induced hyperploidies, however, were very rare. Evidence for induction of meiotic non-disjunction was weak. In surviving embryos, no increase in numerical aberrations, either hypoploid or hyperploid was discovered. The significance of these data for the prediction of chromosomal damage due to to ionizing radiation in humans is discussed. Recent risk estimates of UNSCEAR and other agencies represent very cautious upper levels.     

The response of germ cells of the mouse to the induction of non-disjunction by X-rays

The sensitivity of male and female pre-meiotic germ cells of the mouse to the induction of non-disjunction by low doses of X-rays, has been tested. No enhancement with 5 rad was observed over control of values in dictyate oocytes irradiated from young or aged females. In males, a 3-fold increase in overall chromosome abnormalities (aneuploids, polyploids and mosaics) was found following the treatment of germ cells sampled in the 7th week after irradiation (spermatogonia and early primary spermatocytes) with 100 rad. The increase in aneuploidy alone was not however significant at the 5% level of probability. Primary spermatocytes sampled in week 5 after irradiation were generally insensitive to the induction of chromosome abnormalities.     

Difference in types of radiation-induced structural chromosome aberrations and their incidences between Chinese and Syrian hamster spermatozoa

The effects of ionizing radiations on sperm chromosomes were studied in the Chinese hamster (Crisetulus griseus) and the Syrian (golden) hamster (Mesocrisetus auratus). Testes of mature male Chinese hamsters (CH) were irradiated with X-rays (0.91, 1.82 and 3.63 Gy) and γ-rays (1.10, 2.15, 2.95 and 4.01 Gy) at a single acute dosage, whereas the irradiation was done with lower doses of X-rays (0.45, 0.91 and 1.82 Gy) and γ-rays (0.49, 0.99 and 1.98 Gy) in mature male Syrian hamsters (SH), taking the higher radiosensitivity of this species into consideration. They were mated with normal females within 6 days of exposure. Sperm-derived chromosomes were analyzed in 1125 and 1966 fertilized ova of the CH and the SH, respectively. In both species, there was no great difference in the induction of structural chromosome aberrations between X-irradiated and γ-irradiated spermatozoa. Chromosome-type aberrations were predominantly induced. The incidence of breakage-type aberrations increased linearly, and that of exchange-type aberrations linear-quadratically with increase of dosage. A species-specific difference in chromosomal radiosensitivity of spermatozoa was clear. In spite of the same radiation dosage, the incidence of chromosomally abnormal spermatozoa in the SH was about twice as high as that in the CH (e.g., 27.0% vs. 14.7% at 0.91 Gy of X-rays). The incidences of breakage-type aberrations (69–89%) were far higher than those of exchange-type aberrations (11–31%) in the SH, while the disparity of the two incidences was much smaller in the CH (46–65% vs. 35–54%). Exchange-type aberrations consisted of both chromosome-type and chromatid-type in the SH, while almost all of them were of the chromosome-type in the CH. These results suggest that the DNA-repairing capacity of oocytes is much higher in the CH than in the SH. Moreover, it seems likely that radiation-induced sperm DNA damage is repaired with both pre-replication repair (excision repair) and post-replication repair systems in SH oocytes, whereas the excision repair system operate most exclusively in CH oocytes.     

Effects of x-rays on different meiotic stages of oocytes in the parthenogenetic stick insect carausius morosus Br.

The abdomens of adult females of the parthenogenetic stick insect Carausius morosus were exposed to X-rays up to 4000 R. Adult lifespan, ovariole structure and egg production were affected progressively with increasing doses from 500 to 4000 R. The effect on fecundity was largely dependent on the stage of development of the follicles at the time of irradiation. Growing oocytes, the follicular epithelium of which had still to developep through chromosome duplication, were most sensitive. Oogonia and oocytes of the end-chamber were more sensitive than growing oocytes of the vitellarium. Eggs with two lids were induced by 2000 and 4000 R. Fertility was affected after doses of 91 R or higher. Growing oocytes in first prometaphase and metaphase were about 8 times more sensitive at the LD₅₀ level than growing oocytes in first prophase. Both kinds of growing oocyte were resistant against low doses of X-rays. Dominant lethality was caused by damage not only to the chromosomes but, very likely, also to the yolk and the shell. Radiation of first prophase, prometaphase and metaphase oocytes increased the number of males and gynandromorphs through X-chromosome elimination. The male-to-gynandromorph ratio increased with increasing dose.     

The induction of chromosome aberrations in mouse dictyate oocytes by X-rays and chemical mutagens.

Oocytes were collected from female mice and matured in vitro to Metaphase I during the first or third week after treatment with a dose of 400 rad X-rays, 1.6 mg/kg triethylenemelamine (TEM) or 75 mg/kg isopropylmethanesulphonate (IPMS). In week 1 the mean number of oocytes per female was similar for all treatments but in week 3 irradiated females yielded fewer oocytes than the chemically treated or control females. In week 1 the proportion of oocytes maturing was smaller in irradiated females than in the other groups but in week 3 was similar in all groups.Structural chromosome aberrations, scored in the Metaphase I oocytes, were of the chromatid or isochromatid type and involved gaps, breaks, fragments, intrachanges and interchanges. Aberration frequency did not increase with time after either of the chemical mutagens but after irradiation was higher in the third week than in the first week. The aberration yield from IPMS-treated females was similar at both sampling times, while a lower yield was recorded in week 3 following TEM treatment than in week 1.     

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.     

Factors influencing chromosome condensation and development of cloned rat embryos

Factors influencing premature chromosome condensation (PCC) in transferred rat nuclei have been examined. Chromosome condensation of rat cumulus cell nuclei did not occur when the cell nuclei were injected into enucleated rat oocytes. By contrast, chromosome condensation did occur after transfer to enucleated mouse oocytes or intact rat oocytes. In the first serial NT experiment, rat somatic cell nuclei were injected into enucleated mouse oocytes, and the reconstructed oocytes were activated by strontium chloride. From these reconstructed embryos, karyoplasts containing pronucleus-like vesicles were transferred into pronuclear zygote-derived cytoplasts by a DC pulse. Transfer of a total of 340 serial NT zygotes into recipient females, including 206 two-cell embryos, resulted in only seven implantation sites. In the second serial NT experiment, rat somatic cell nuclei were injected into intact rat oocytes; the recipient metaphase-plate was then aspirated under UV light from the NT oocytes in which PCC of injected nuclei was observed. After activation of the NT oocytes, karyoplasts were introduced into zygote-derived cytoplasts. Transfer of a total of 115 serial NT zygotes, including 37 two-cell embryos, resulted in four implantation sites but no live offspring. These results establish a mean of inducing chromosome condensation in rat oocytes and demonstrate that reconstructed rat zygotes can be prepared by serial NT procedures. Developmental competence of these embryos remains to be clarified.     

Evidence for an increase in X-ray-induced translocation frequency in oocytes of caffeine-treated Drosophila females

0-8 h old Drosophila females carrying a reversed metacentric X chromosome and a suitably marked Y chromosome were treated or not with 0.2% caffeine and irradiated with 2000 R X-rays. In contrast with the reduction found in translocation frequency following 2000 R irradiation of the male mated with 0.2% caffeine-treated females, the frequency of interchanges in oocytes was significantly higher with caffeine as compared with controls.     

Proliferation of type II pneumonocytes after X-irradiation

This paper reports preliminary data on the proliferative response of type II cells in the mouse lung over a five-month period after external thoracic doses of 2, 5, 10 and 12 Gy of X-rays. The DNA labelling index (LI) of control (0 Gy) mice was at all times exceedingly low (0.3-0.4 per cent). The LI after 2 and 5 Gy showed a slight though transient fall below controls during the first week post-irradiation, and thereafter the LIs were similar to the controls for the 5 months of the experiment. The LI after 10 and 12 Gy again showed a significant depression during the first week, but this was followed by a significant increase (P = 0.01) in LI which peaked at 4 weeks after irradiation. The LI returned to control values at 3-4 months and again rose significantly (P = 0.05) at 5 months. The first wave of proliferation corresponds to data showing an increase in surfactant in alveolar fluids within 2-6 weeks of 10-15 Gy of X-rays; and the second wave coincides with the pneumonitic phase and is consistent with a delay before the alveolar epithelial continuity is sufficiently compromised by the low rates of type I cell loss to trigger a compensatory wave of type II cell divisions. This relatively chronic radiation response is discussed and contrasted with the dramatic and immediate hyperplastic responses which many toxic irritants produce in type II epithelial cells.     

Meiotic drive of the aberrant chromosome 1 in the house mouse

Animals with aberrant chromosome 1 carrying one or two large insertions were earlier described in natural populations of Mus musculus. In the present work, inheritance of the aberrant chromosome 1 from the Yakutsk population was investigated. It was shown that 80-85% of the progeny from heterozygous females received chromosome 1 with insertions. From chromosomal analysis of blastocytes and oocytes at the MII stage, it was concluded that the preferential distribution of the aberrant chromosome into oocytes during the first and especially, the second meiotic divisions is relevant to the segregation distortion observed. The mechanism of this powerful meiotic drive is discussed.     

The effects of spermatozoal irradiation with X-rays on chromosome abnormalities and on development of mouse zygotes after delayed fertilization

The chromosome complements of zygotes derived from oocytes aged post ovulation and fertilized in vivo with X-ray-irradiated sperm were studied. Ovulation was induced by an injection of luteinizing hormone-releasing hormone (LHRH) at pro-estrus and fertilization was achieved by artificial insemination at 13 h and 24 h after LHRH in order to obtain embryos from unaged and aged (12 h post-ovulation) oocytes respectively. Post-ovulatory aging prior to fertilization did not significantly affect the percentage of zygotes with irradiation-induced chromosome abnormalities. However, post-ovulatory aging had a negative effect on the morphology of male as well as female pronuclear chromosomes of the first cleavage metaphase. When fertilized with control spermatozoa this effect was apparent in both the male and the female pronucleus. When unaged oocytes were fertilized with X-irradiated spermatozoa chromosome morphology was also adversely affected in both pronuclei. In zygotes from aged oocytes, there was an extra negative effect of X-rays on the male pronuclear chromosomes only. After fertilization with X-irradiated sperm 27% of zygotes from aged oocytes were arrested at interphase compared to 7% from unaged oocytes. We suggest that post-ovulatory aging and X-rays affect the male and female pronuclear chromatin structure after fertilization. These chromatin alterations could interact with DNA lesions induced in the spermatozoa prior to fertilization, such that development to first cleavage can be blocked.     

X-ray- and chemically induced germ-line mutation causing phenotypical anomalies in mice

A large and significant increase of phenotypical anomalies was observed in the progeny of ICR parent mice treated before mating with X-rays, urethane, 7,12-dimethylbenz[a]anthracene, ethylnitrosourea (ENU), and 4-nitroquinoline 1-oxide, but the increase was not significant with furylfuramide. Major types of induced anomalies were cleft palate, dwarf, open eyelid, tail anomalies, and exencephalus. Dwarf, open eyelid and tail anomalies were predominant types of viable anomalies and were inherited as if they were dominant mutations with varying expressivity or penetrance. Incidence of prenatal anomalies increased with treated doses of X-rays, urethan, or ENU for both spermatozoa and spermatogonia. Spermatogonia were less sensitive to X-rays and urethane than spermatozoa, while ENU induced a very high incidence of prenatal anomalies by the spermatogonial treatment. In contrast to the previous works with X-rays, there was a clear, almost linear increase of anomalies in the dose range from 0 to 216 rad after spermatogonial exposure. For treatment of oocytes, there was also a clear increase with doses of X-rays and urethane. Doubling doses of X-rays for prenatal anomalies were 12 rad for spermatozoa, 27 rad for spermatogonia, and 19 rad for mature oocytes. These values are similar to those for ordinary mouse mutations. However, the mean rate of prenatal anomalies per rad (1.2 X 10(-4), 6.6 X 10(-5) and 9.1 X 10(-5) for spermatozoa, spermatogonia and mature oocytes, respectively) and that for 1 micrograms/g of ENU (3.4 X 10(-4) for spermatogonia) were 4-40 times higher than that of ordinary mutation in mice, because overall phenotypical abnormalities were scored in this study. Information obtained from the work on phenotypical anomalies is valuable to assess genetic risk of radiation and chemicals, because a majority of human genetic diseases show this kind of irregular and uncertain inheritance and most of the induced anomalies are similar to those found in humans.     

Cryotops versus open-pulled straws (OPS) as carriers for the cryopreservation of bovine oocytes: effects on spindle and chromosome configuration and embryo development

Two experiments were designed to assess the effectiveness of cryopreserving bovine MII oocytes using cryotops as the carrier system for vitrification. In the first experiment, we examined the developmental competence of oocytes after: (i) vitrification in open-pulled straws (OPS method); or (ii) vitrification in <0.1 μl medium droplet on the surface of a specially constructed fine polypropylene strip attached to a plastic handle (Cryotop method). In the second experiment, warmed oocytes that had been vitrified in OPS or cryotops were fixed to analyze spindle and chromosome configuration. In all experiments both cow and calf oocytes were used. Significantly different fertilization rates were observed between the vitrification groups: 31.5% and 20.2% for the cow and calf oocytes vitrified in OPS, respectively, versus 46.1% and 46.4% for the oocytes vitrified using cryotops. After in vitro fertilization, 3.8% of the calf oocytes and 5.3% of the cow oocytes developed to the blastocyst stage. All blastocysts from vitrified oocytes resulted from the Cryotop method. A significantly lower percentage of the OPS-vitrified calf oocytes showed a normal spindle configuration (37.8%) compared to control fresh oocytes (69.9%), while normal spindle and chromosome configurations were observed in a significantly higher proportion of the cryotop-vitrified calf oocytes (60.2%). For the cow oocytes, 60.6% in the OPS group and 60.3% in the Cryotop group exhibited a normal morphology after warming. These findings suggest the cryotop system is a more efficient carrier for vitrification than OPS for the cryopreservation of bovine oocytes.     

Discrimination between the effects of X-ray irradiation of the mouse oocyte and uterus on the induction of dominant lethals and congenital anomalies

In order to test whether irradiation of the postimplantation maternal environment had any effect on the apparent induction of dominant lethals or congenital anomalies by radiation, preimplantation embryos were surgically transferred between females which had been irradiated before conception or left untreated. A high proportion of preimplantation embryos, collected from females that had been irradiated 15-21 days prior to conception with 3.6 Gy X-rays, were either arrested or developmentally retarded compared with those collected from untreated females. The transfer experiments indicate that irradiation of the uterus has no significant effect on the frequency of subsequent postimplantation mortality or on mean fetal weight. However, it remains unclear whether irradiation of the uterus contributes to the induction of congenital anomalies.