Reproductive capacity and dominant lethal mutations in female guinea-pigs and Djungarian hamsters following X-rays or chemical mutagens.

The reproductive capacity and induction of dominant lethal mutations in adult female guinea-pigs and Djungarian hamsters were tested following treatment with 400 rad X-rays, 1.6 mg/kg triethylenemelamine (TEM) or 75 mg/kg isopropylmethanesulphonate (IPMS). A fairly high level of dominant lethals were observed in female guinea-pigs mated at the first oestrus after irradiation (23.4 +/- 6.4%) with a lower yield at 3 months (9.6 +/- 8.2%). Neither of the chemicals caused any significant induction of dominant lethals at either mating time. In the reproductive capacity experiments, the mean litter size of irradiated female guinea-pigs was reduced for about 12 months and this was especially marked in the first 6 months following treatment. Neither of the chemicals caused any significant differences in early litter sizes but there was a noticeable reduction in the litter sizes of TEM-treated females in the 18--24 month interval. With Djungarian hamsters a marked effect of X-rays on reproductive capacity was apparent. After 400 rad a smaller proportion of irradiated females littered in the first 25-day interval than after the other treatments, and no irradiated females produced more than one litter. Neither of the chemicals caused such a drastic reduction in fertility but TEM-treated females produced fewer litters and became sterile at an earlier age than control or IPMS-treated females. With IPMS, the number of litters produced was similar to the controls. Both chemicals caused a significant reduction in litter-size but further work is needed to establish whether this was due to induction of dominant lethals. No translocations were observed in the sons of treated female guinea-pigs or hamsters, but the numbers of animals studied were too small for any conclusions to be drawn.     

Studies on chemically induced dominant lethality. II. Cytogenetic studies of MMS-induced dominant lethality in maturing dictyate mouse oocytes.

Young adult female mice were injected intravenously with either 50- or 100- mg/kg doses of methyl methanesulfonate. The females were superovulated and mated to untreated males at intervals ranging from 0.5 to 14.5 days after treatment. The fertilized ova were collected and cultured to the first cleavage mitosis, at which time the female chromosome complement was analyzed for structural chromosomal damage. Chromatid-type aberrations were observed, but at a much lower frequency than previously reported for treatment of post-meiotic male germ cells. The time after treatment at which chromosomal damage was observed and the frequency of affected cells agree, qualitatively, with existing dominant-lethal data derived from treatment of maturing oocytes. Parallel experiments in which metaphase I oocytes were analyzed indicate a lack of MMS-induced chromosomal damage in the meiotic stages. This observation is consistent with the suggestion that an intervening round of DNA synthesis is necessary for MMS-induced lesions to be translated into chromosomal damage. The low yield of chromosomal damage is consistent with the idea that maturing oocytes, unlike later spermatids and spermatozoa, are capable of performing macromolecular repair of premutational lesions.     

Cytogenetic effects of X-rays and fission neutrons in female mice

The induction by X-rays of chromosomal damage in oocytes was studied, while the genetic consequences of X- and neutron-induced damage in female mice were looked for by testing offspring for dominant lethality and semi-sterility. None out of 386 sons of hybrid females given 300 rad X-rays showed evidence of semi-sterility or translocation heterozygosity, but 9 out of 294 daughters were diagnosed as semi-sterile. At least 3 and probably 4 of these (1.4%) carried reciprocal translocations, 2 of which caused male sterility. Complete or partial loss of the X-chromosome may have been responsible for some of the other sermi-steriles. Examination of oocytes at metaphase-I during the first and third weeks after X-irradiation with 100 or 400 rad revealed both multivalents (some of the ring quadrivalent type) and fragments (mainly double). These were thought to arise mainly from chromatid intercchanges (both symmetrical and asymmetrical) and isochromatid intrachanges respectively. Since neither the proportion of asymmetrical interchanges nor the amount of hidden damage was known it was not thought possible to predict the magnitude of F₁ effects from metaphase-I findings. The aberration frequency in oocytes rose with dose and (at the 400 rad level only) with time after irradiation, reaching a maximum of 10% multivalents and 22% fragments in the third week after 400 rad. The frequency of univalents showed no consistent trend, but chiasma counts decreased in the first week after 400 rad. The increase in levels of chromosomal damage with dose and time after irradiation was reflected in dominant lethal frequencies after the same radiation-conception intervals and doses of 0–400 rad. Induced post-implantation lethality was over twice as high in the third week after 200–400 rad than in the first. Pre-implantation loss also greatly increased in the third week after 300 or 400 rad; this was associated with increased non-fertilization of ova. No evidence for the induction of translocations in oogonia or resting oocytes by fast neutron irradiation was obtained, although there was evidence for X-chromosomal loss after 200 rad to oocytes. The relative biological effectiveness (RBE) for fission neutrons vs. X-rays with respect to dominant lethal induction in oocytes was found to vary with dose, but seamed to be around 1 at lower levels.     

Frequency and nature of specific-locus mutations induced in female mice by radiations and chemicals: a review.

The inducibility of heritable mutations in female mammals has been measured in the mouse specific-locus test (SLT). For radiation-induced mutations, a large body of data has been accumulated that includes information about biological and physical factors that influence mutation yields. However, relatively few SLT studies in females have been conducted with chemicals to date. A single estimate of the spontaneous mutation rate in oocytes, 6/536,207, has been derived as the most appropriate one to subtract from experimental rates. This rate is highly significantly below the spontaneous mutation rate in males. Mutations recovered from females mutagenized at any time after about the 12th day post-conception are induced in non-dividing cells. In adult females, most oocytes are arrested in small follicles; maturation from this stage to ovulation takes several weeks. High-dose-rate radiations are more mutagenic in mature and maturing oocytes than in spermatogonia of the male; on the other hand, no clearly induced mutations have been recovered from irradiated arrested oocytes. Efficient repair processes have been invoked to explain the latter finding as well as the upward-curving dose-effect relation for acute irradiation, and the fact that dose protraction drastically reduces mutation yield from mature and maturing oocytes. The dose-protraction effect is much greater than that found in spermatogonia. Radiation-induced mutation rates in embryonic, fetal, and newborn females are overall lower than those in the mature and maturing oocytes of adults. A dose-protraction effect has also been demonstrated at an early developmental stage when the nuclear morphology of mouse oocytes most resembles that of the human. Of only 5 chemicals so far explored for their effect in oocytes, 2 (ethylnitrosourea, ENU, and triethylenemelamine, TEM), and possibly a third (procarbazine hydrochloride, PRC), are mutagenic--with at least one of these (ENU) mutagenic in arrested as well as maturing oocytes. However, the mutation rate is, in each case, lower than for treated male germ cells. By contrast, ENU-induced mutation yield for the maternal genome of the zygote is an order of magnitude higher than that for the zygote's paternal genome or for spermatogonia. A high proportion of mutants derived from chemical treatment of oocytes (including the oocyte genome in zygotes) are mosaics, probably owing to lesions affecting only 1 strand of the DNA. A characteristic of specific-locus mutations induced in oocytes is that they include a considerably higher percentage of large (multi-locus) lesions (LLs) than do mutations induced in spermatogonia.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intermittent fasting during winter and spring affects body composition and reproduction of a migratory duck

We compared food intake, body mass and body composition of male and female black ducks (Anas rubripes) during winter (January-March). Birds were fed the same complete diet ad libitum on consecutive days each week without fasting (control; nine male; nine female) or with either short fasts (2 day x week(-1); nine male; nine female), or long fasts (4 day x week(-1); eleven male; twelve female). We continued treatments through spring (March-May) to measure the effect of intermittent fasts on body mass and egg production. Daily food intake of fasted birds was up to four times that of unfasted birds. Weekly food intake of males was similar among treatments (364 g x kg(-1) x week(-1)) but fasted females consumed more than unfasted females in January (363 g x kg(-1) x week(-1) vs. 225 g x kg(-1) x week(-1)). Although both sexes lost 10-14% body mass, fasted females lost less mass and lipid than unfasted females during winter. Total body nitrogen was conserved over winter in both sexes even though the heart and spleen lost mass while the reproductive tract and liver gained mass. Intermittent fasting increased liver, intestinal tissue and digesta mass of females but not of males. Fasting delayed egg production in spring but did not affect size, fertility or hatching of the clutch. Females on long fasts were still heavier than controls after laying eggs. Thus black ducks combine flexibility of food intake with plasticity of digestive tract, liver and adipose tissue when food supply is interrupted during winter. Females modulate body mass for survival and defer reproduction when food supply is interrupted in spring.     

Tamoxifen-induced alterations in meiotic maturation and cytogenetic abnormalities in mouse oocytes and 1-cell zygotes

Alterations in the rate of oocyte meiotic maturation (OM) and the timing of the metaphase-anaphase transition may predispose oocytes to premature centromere separation (PCS) and aneuploidy. Tamoxifen has the potential for perturbing the rate of OM since it can function as a calcium antagonist by binding to calmodulin and inhibiting the formation of a calcium-calmodulin complex which is needed for activating calmodulin-dependent cAMP phosphodiesterase and initiating OM. The objective of this study was to test the hypothesis that tamoxifen alters the rate of OM and predisposes oocytes to PCS and aneuploidy. Different does of tamoxifen were administered by oral gavage to female mice preovulation. Metaphase II oocyte and 1-cell zygote chromosomes were C-banded and cytogenetically analysed. Tamoxifen treatment resulted in a modest, but significant (p < 0.05), increase in oocytes with PCS. Similar frequencies of hyperploidy and oocytes with unpaired, single chromatids (SC) were found. Metaphase I, diploid and premature anaphase (PA) oocytes were not detected. Hyperploidy, polyploidy, PCS, PA and SC were not detected in zygotes. These data indicate that the levels of tamoxifen-induced PCS found in mouse oocytes did not predispose zygotes to aneuploidy. Tamoxifen did, however, reduce the proportion of females exhibiting oestrus.     

Heritable translocation test on random-bred mice after prolonged triethylenemelamine treatment.

Heritable translocation and dominant lethal tests were conducted with random-bred Swiss albino male mice. The animals were provided drinking water containing triethylenemelamine (TEM) for 4 weeks, and were then mated for 3 successive weeks for analysis of dominant lethality and production of F1 progeny. Potential translocation carriers among F1 males were selected after two breedings and confirmed by cytogenetic analysis. Translocation heterozygotes were obtained in offspring of the TEM-treated groups, but not in the control groups. In F1 males produced from the first week of mating, the frequencies of translocations were 0, 1.78 6.2 and 10.0% for the control group and groups receiving TEM at 0.0125, 0.025 and 0.050 mg/kg/day, respectively, and in those produced from the third week of mating, the values were 0 and 2.1%, respectively, for the control group and the group receiving TEM at 0.050 mg/kg/day. F1 males from the second week of mating were not studied for the induction of heritable translocations. TEM-induced dominant lethality and heritable translocations were most prominent in the first week of mating after 4 weeks of treatment. In addition, heritable translocations appeared to be a more sensitive endpoint than dominant lethal mutations for the measurement of mutagenic effects of TEM.     

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.     

Radiation-induced chromosome aberrations in guinea-pig growing oocytes, and their relation to follicular atresia

The female guinea-pig has been shown to represent a good model to investigate the genetic hazard of ionizing radiation in humans. The sensitivity of the guinea-pig oocytes to radiation-induced chromosome aberrations was, therefore, studied at different stages of oocyte and follicular growth. The sensitivity of oocytes enclosed in small follicles (15 weeks before ovulation) was found to be low and comparable to that of immature oocytes present at birth. The sensitivity of growing oocytes remained low and almost constant until 3 weeks before ovulation, from which time it began to increase. The most dramatic increase of sensitivity occurred during the last week preceding ovulation: about 90% of oocytes X-irradiated with 4Gy, 2 days before ovulation showed one or more chromatid interchanges, as compared to 20% for those irradiated with the same dose 1 week earlier. A comparison of our results with those found by others in the mouse shows that considerable differences of sensitivity exist between oocytes of these two species irradiated at similar stages of development. The possible reasons for these differences are discussed.     

Chemical induction of presumed dominant-lethal mutations in postcopulation germ cells of mice. I. Relative sensitivity between pre- and postcopulation germ cells to isopropyl methanesulfonate

Females from ($\text{C}\text{3}\text{H}\text{×}\text{IOI}\text{)}\text{F}{}_1$ and a mixed stock were injected intraperitoneally with either 25 or 50 mg/kg isopropyl methanesulfonate (IMS) or Hanks' solution 4.5 h after the midpoint of the dark period during which mating occurred. It was determined that at the time of treatment the great majority of oocytes were undergoing second meiotic division. For comparison, the same doses of IMS were given to females treated within 3.5 days prior to mating (predominantly dictyate oocytes) or to males treated within 4.5 days prior to mating (sperm in vas and epididymis). The frequencies of presumed dominant lethals induced by 50 mg/kg IMS in sperm treated in vas and epididymis, dictyate oocytes, and germ cells in mated females are 22%, 19%, and 79%, respectively, for (C3H × IOI)F₁ and 26%, 30%, and 76% for the other stock. Clearly, in both stocks, effects in mated females, when both female and male germ cells were treated, are relatively much higher than the added effects on dictyate oocytes and spermatozoa. This is also true for the 25 mg/kg dose.     

Comparison of single/multiple-dose protocols using triethylenemelamine and procarbazine hydrochloride for the mouse bone marrow micronucleus test

Treatment of mice with a single dose of either 4.8 mg/kg of triethylenemelamine (TEM) or 348 mg/kg of procarbazine hydrochloride (PC) induced higher frequencies of micronucleated polychromatic erythrocytes (MPE) after 48 h than after 24 h. The same observation was made when animals were treated with 1.6 or 8 mg/kg of TEM or 116 or 580 mg/kg of PC for 2 consecutive days (double-dose protocol). Surprisingly, the third dose of either 1.6 or 8 mg/kg of TEM caused lower MPE frequencies at the 72-h than at the 48-h sampling time. The observation that lower MPE frequencies after 72 h were also accompanied by reduced bone marrow toxicity might have reflected a drug-related adaptive reaction of the animals, for example the induction of detoxifying enzymes. Mean MPE frequencies as well as bone marrow toxicity were also slightly decreased after the third dose of either 116 or 580 mg/kg of PC, but statistical analysis showed no differences between the 48-h and the 72-h sampling times as regards the MPE frequencies and bone marrow toxicity. In addition to the high mean MPE frequency observed after 2 doses of 116 mg/kg of PC at the 48-h sampling time, a late increase in micronucleus induction was also seen after triple dosing at the 96-h sampling time. The present experiments with TEM and PC showed similar sensitivity for the multiple-dose assays when compared with the single-dose micronucleus test. In the case of the triple-dose assay, bone marrow toxicity proved to be a critical factor for appropriate dose selection. The computerized image analysis system was a convenient and time-saving tool for the automatic scoring of large quantities of cells for micronuclei as well as for the evaluation of bone marrow depression from the entire cell population analyzed for micronuclei.     

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.     

Comparison of fecundity and longevity of Anoplophora malasiaca (Coleoptera: Cerambycidae) adults fed on three different host‐plants

Oocyte development, age at first reproduction, ovipositing activity and longevity were compared among three groups of Anoplophora malasiaca (Coleoptera: Cerambycidae) female adults that were grown on an artificial diet and provided with mandarin orange (MO), blueberry (BB) and willow (WI) branches after adult emergence. The female adults that were fed with MO began to lay eggs earlier, produced more eggs and lived longer than those that were fed with BB or WI. None of the female adults that were fed with BB laid eggs. The BB‐fed female adults developed the lowest number of oocytes after one and three weeks of feeding. The female adults that were fed with WI and MO for one week developed similar numbers of oocytes. However, after three weeks the MO‐fed female adults developed significantly more oocytes than WI‐fed females. When female adults were first fed with MO for one week and then supplied with BB, subsequent ovarian development was strongly suppressed and the number of immature oocytes decreased. The results suggested that some immature oocytes degenerated. From these results it was concluded that MO was the most suitable adult host‐plant, followed by WI and BB. It is possible that adults that emerge from BB trees may shift their host‐plant during the adult stage in the field.     

Comparative investigations with Trypaflavin in metaphase-II oocytes and in dominant lethal assay

Summary Pregnant C3H mice were orally treated with 50 mg Trypaflavin/kg on day 7, 11, 14, or 15 post conception. The embryos were thus treated in utero with the test compound. At the age of 10 weeks, the dominant lethal assay was performed with F₁ females. Dominant lethal mutations were induced only in those mice treated in utero on day 7 of the prenatal stage.Female C3H mice were chronically treated with Trypaflavin (50x2 mg/kg/day; dissolved in drinking water). These mice were caged with untreated males. The percentage of preimplantation egg loss and the yield of dead implants per female was increased.Female NMRI mice were chronically treated with Trypaflavin (50x2 mg/kg/day by stomach tube). In metaphases II of unfertilized oocytes, the yield of all observed aberration types (aneuploidies, gaps, satellite associations, breaks and fragments, deletions, and interchanges) was increased weakly.The investigation of metaphase-II chromosomes was supported by the EC Contract No. 175-77-1 ENV D.     

Effects of thioglycolic acid on in vivo oocytes maturation in mice

Background

Thioglycolic acid (TGA) is widely used in the hairdressing industry, which mostly caters to women. Recently, TGA has been reported to impair several organs, especially reproductive ones such as testes and ovaries. The reproductive toxicity of TGA on females has become an issue that cannot be neglected.

Methodology/Principal Findings

In the present work, superovulated female mice were percutaneously treated with different doses of TGA (37.81, 75.62, and 151.25 mg/kg). The mice were sacrificed to collect ovulated oocytes, whose numbers were counted and compared. Immunofluorescence-stained oocytes were observed under a confocal microscope to investigate the effects of TGA on spindle morphology, distribution of cortical granules (CGs), and parthenogenetic activation. The number of ovulated oocytes was decreased by TGA. The ovulated oocytes in the 151.25 mg/kg TGA group were significantly less than in the control and in the 37.81 mg/kg TGA groups. The ovulated oocytes in the 75.62 mg/kg TGA group were less than in the 37.81 mg/kg dose group. Abnormal spindle configuration in vivo was also induced by TGA. The spindle areas in the 75.62 and 151.25 mg/kg TGA groups were significantly larger than in the control and 37.81 mg/kg TGA groups. The parthenogenetic activation of ovulated oocytes in vitro was inhibited as well. The percentage of activated oocytes in the 75.62 and 151.25 mg/kg TGA groups was significantly lower than in the control and 37.81 mg/kg TGA groups. The percentage in the 151.25 mg/kg TGA group was also less than in the 75.62 mg/kg group. CG distribution was not affected by TGA.

Conclusion

Mice were percutaneously treated with TGA. Consequently, the number of ovulated oocytes decreased, abnormal spindle configurations were induced, and the parthenogenetic activation of ovulated oocytes was inhibited. CG distribution was not affected.     

Mouse oocytes gradually develop the capacity for activation during the metaphase II arrest

Metaphase II (M II) mouse oocytes were subjected to a parthenogenetic stimulus (8% ethanol) or fertilized in vitro at various times following the extrusion of the first polar body. The oocytes progressively develop the ability for full activation. Their responsiveness to activation stimuli not only increases, but also changes qualitatively with time. Newly arrested oocytes do not respond at all; then, when the ability to undergo meiotic anaphase II first develops, the response is defective: following extrusion of the second polar body (II PB), the oocyte does not enter interphase but arrests again at metaphase (M III-arrest). Finally, oocytes gain the ability for full activation including the entry to interphase. Depending on the type of activating stimulus, oocytes exhibit the capacity for full activation at different ages. The oocyte arrest in M III is similar to M II and can be released by subsequent activation. Such oocytes undergo anaphase III, extrude a third polar body (III PB), and form an aneuploid female pronuclei.     

Terahertz radiation influence on number and development dynamics of offspring F1 of fruit fly females under stress

Virgin fruit fly females were stressed by placement into a confined space without food for 2.5 hours. Some flies were subjected to terahertz radiation (0.1–2.2 THz) for the last 30 min. Then females were copulated with males. Offspring F1 from oocytes which were mature or immature at exposure (oviposition in 1–2 or 9–10 days after irradiation) was studied. Stress induces a rejection of the offspring maturation dynamics to imago from external control (offspring of flies which was maintained in standard conditions). In offsping from mature oocytes of irradiated flies the dynamics of male maturation to imago was different from internal control (offspring of stressed unirradiated flies). The number of imago males decreased. The dynamics of female maturation to imago coincides with laboratory control. In offsping from immature oocytes of irradiated flies the dynamics of female and male maturation and the number of flies were not significantly different from the internal control. It was concluded that only mature oocytes are sensitive to THz radiation influence.     

The relationship between radiation-induced and transposon-induced genetic damage during Drosophila oogenesis

The combined effect of X-irradiation and transposon mobility on the frequencies of X-linked recessive lethals and dominant lethals was investigated in female hybrids in the P-M system of hybrid dysgenesis. X-linked lethals were measured in G2 hybrid dysgenic females whose X chromosome was derived from the M X P cross. To test for additivity or synergism, the mutation rate in irradiated dysgenic females was compared to that of unirradiated females as well as to irradiated nondysgenic hybrid females derived from M X M crosses. Eggs collected for 2 days after irradiation, were represented by the more radiation-sensitive A and B oocytes (about 75%) and the least sensitive C oocytes (about 25%). The production of X-linked lethal events in X-irradiated dysgenic females was 8.1%, as compared to 4.5% in dysgenic controls and 3.4% in irradiated, nondysgenic controls, demonstrating an additive effect of radiation and dysgenesis-induced genetic damage. The effect of irradiation on sterility of dysgenic hybrid females was a negative one, resulting in 20% less sterility than expected from an additive effect. The combined effect of radiation and dysgenesis on dominant lethality tested in A, B and C oocytes of the same hybrid females was synergistic. Egg broods collected for 3.5 days after irradiation showed that significantly more damage was induced in the presence of ionizing radiation in dysgenic females than in their nondysgenic counterparts. This effect was most obvious in B and C oocytes. The synergism observed may be related to the inability of cells to repair the increased number of chromosome breaks induced both by radiation and transposon mobility.     

Unique effects of spindle inhibitors on mammalian oocyte meiosis

The effects of Nocodazole, reported to be a rapidly reversible inhibitor of microtubules in somatic cells (1), and Colcemid, a classic microtubule inhibitor, were studied for their effects on mouse and cow oocyte in vitro meiotic resumption. When present throughout the maturation period to Metaphase II/Polar Body I, both compounds predictably inhibited progression at Metaphase I (MI). An unexpected effect was seen on mouse germinal vesicle breakdown (GVB) with both inhibitors, but not in cow oocytes tested with Nocodazole. Recovery from Nocodazole was notably retarded in mouse oocytes even with brief exposure times. Addition of 1 microgram/ml of Nocodazole 10 min after commencement of mouse and cow oocyte incubation was sufficient time to allow normal GVB, while inhibition at MI still took place suggesting that the critical events of GVB occur very quickly in vitro.     

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.