Nature and consequences of induced chromosome damage in mammals.

There are marked qualitative and quantitative differences in the patterns of chromosomal damage observed after irradiation of spermatogonia, spermatozoa and oocytes of mice. These differences often result from reduced or zero transmission of particular classes of abberration arising in pre-meiotic germ cells. Probably this is the reason why the level of X-chromosomal and autosomal monosomy is not increased after spermatogonial irradiation. Similarly, the reduced transmission of certain d-se deficiencies may help to explain their low F(1) frequency after pre-meiotic as compared with later irradiation. Spermatozoal irradiation has revealed no Robertsonian translocations, but has produced some types of reciprocal translocations which apparently are not transmitted to the F(1) after spermatogonial treatment because they prevent maturation of the male pre-meiotic germ cell. Thus they cause sterility in males, but not in females. They include X-autosome and Y-autosome translocations, those giving a metacentric or sub-metacentric chromosome (with reciprocal product present) and those in which one break-point is in or near the centromeric heterochromatin while the other is more distally placed. This last group (which grades into male sub-fertile conditions) gives a preponderance of chain configurations (often with one separate univalent) in heterozygotes of both sexes at meiosis and a high incidence of somatic marker chromosomes. Nondisjunction associated with the univalent generates tertiary trisomics, which are usually male-sterile also and may show phenotypic abnormalities. Sterile males with complete separation of X and Y chromosomes have also been reported after mutagenic treatment of meiotic and post-meiotic germ cells. Such separation seems to prevent a primary spermatocyte from forming a secondary one. The usual derivation (in mouse and man) of tertiary trisomics from mothers rather than from fathers may be due to a similar block, together with a general tendency for male heterozygotes for the parental balanced translocation to be sterile or sub-fertile. Mature oocytes tend to resemble spermatoza in the types of aberration produced by irradiation, which include the male-sterile translocation, but more data are needed. Many of the aberrations described contribute to the human cytogenetic load and can be studied in the mouse from this point of view.

Cytogenetic effects of protracted gamma exposures from conception of male mice.

In order to gain an overall picture of the genetic effects of an increased level of background radiation it is necessary to study the results of protracted exposures to embryonic and immature germ-cell stages as well as to stages found in the mature organism. For this purpose, litters produced by female mice, kept in a 10 or 20 rad/day 60 Co gamma-irradiation field, were kept in the same fields from conception until about 60 days later, having absorbed doses of 526 and 1078 rad respectively. Tests on exposed female offspring showed them to be sterile. 8 weeks after removal from the gamma field, mean testis masses of males in the 20 rad/day series were only half normal but those receiving 10 rad/day were little affected. Frequencies of translocations in spermatocytes at diakinesis/metaphase I were only slightly increased in the exposed series, differences not being significant. Estimated rates of translocation induction were around 5 x 10(-6) per rad, about one-third of those found after protracted gamma-irradiation of stem-cell spermatogonia in the adult. Embryonic lethality in progeny of other similarly irradiated males(absorbed doses of 560 and 1040 rad), mated 2 months after removal from the radiation fields, was also increased slightly, but not significantly. Results are compared with others on the induction of chromosome aberrations and gene mutations, mainly by acute irradiation, in prenatal and neonatal male mice. It is concluded that early male germ-cell stages generally show a reduced genetic radiosensitivity after both acute and chronic exposures.

The effects of radiation dose-rate and quality on the induction of dominant lethals in mouse spermatids.

Hybrid male mice were given 3 Gy (300 rad) doses of X- or gamma-irradiation at dose-rates of either 0.6 or 0.002 Gy/min for each radiation. Germ-cells treated as spermatids were tested for dominant lethality. Effects on spermatogonia were evaluated by studying testis-weight, sperm-count and sperm abnormalities. The rate of induction of dominant lethal mutations was 2.1 times as high after acute X-irradiation as after protracted gamma-irradiation. Most of this difference resulted from the change in radiation quality, since the relative effectiveness of X- versus gamma-irradiation was 1.9 at low and 1.6 at high dose rates. For each radiation, however, fewer dominant lethals were induced at low dose-rates than at high (low/high ratios of 0.8 and 0.9 respectively) although differences did not reach a significant level. There were no statistically significant effects of dose rate on testis-weight or sperm-count in the X-ray series, but there were significantly less severe effects on both with protraction of the gamma-irradiation. Evidence for effects of radiation quality on these characters was conflicting. Frequencies of abnormal spermatozoa were markedly increased 7 weeks after irradiation but there were no consistent effects of radiation intensity or quality.

Spermatogenic effects of male-fertile translocations in the mouse.

Four male-fertile translocations, T(2;4)13H, T(2.8)26H, T(7;18)50H and T(1;13)70H were crossed to the inbred strains CBA/H and C57BL/6J. F1 heterozygotes were compared with wild-type litter-mates for signs of spermatogenic impairment, in view of previous reports that the C57BL strain had this effect in the T(14;15)6Ca translocation. There was a general tendency for body-weights to be slightly reduced in translocation carriers vs. wild-type. Mean testis weights were significantly reduced on the C57BL background with all four translocations as compared to wild-type, but also significantly increased in T26H on CBA. Sperm counts were also reduced on the C57BL background in T13H, T50H and T70H (significantly so in the last two) but were significantly increased in T13H on a CBA background. Only in T50H did the frequency of sperm-head abnormalities show any marked change in the translocation heterozygotes, being approximately doubled with both CBA and C57BL backgrounds although still remaining at a low level. It was concluded that the deleterious effects of C57BL strains on spermatogenesis in translocation heterozygotes were not confined to T6Ca but were probably widespread. Some inconclusive evidence suggested that this might be because some genetic factors associated with C57BL tended to reduce chiasma frequencies in translocation heterozygotes.

Effects of post-irradiation interval on translocation frequency in male mice.

Hybrid male mice were given 5 Gy + 5 Gy acute X-rays 24 h apart, with cytological examination of testes 16-19, 39-42 and 64-66 weeks later. Mean testis weights were significantly lower in the youngest group than in the other two. However, translocation frequencies in spermatocytes of the youngest group (mean of 0.57 per cell) were significantly higher than in either of the other two groups, which gave similar values averaging 0.36 translocations per cell. There was highly significant heterogeneity in translocation yields within the youngest group. The decline in translocation yield with time after irradiation is in line with that reported by Léonard and Deknudt (1970) in inbred strain C57BL males. Analysis of all available data suggests that high translocation yields are found during late stages in the process of germ-cell repopulation of the testis after high radiation doses and may be connected with changing frequencies of radiosensitive and radioresistant stem cell populations as repopulation proceeds.

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.

An in vivo method for the detection of somatic mutations at the cellular level in mice.

This new method for detection of somatic mutations is based on the fact that recessive mutations at the dilute (d) and leaden (ln) loci change the shape of pigment-cells in the hair follicles from their normal highly dendritic appearance (nucleofugal) to a rounded-up almost non-dendritic form (nucleopetal). Gene action is autonomous and individual mutant melanocytes can be recognised in whole mounts of dorsal skin made after the post-natal onset of melanogenesis. Foetal heterozygotes for d and ln were treated with X-rays (0-200 rad) or procarbazine (0-300 mg/kg body mass by maternal i.p. injection) 17 days after detection of a vaginal plug; whole mounts of dorsal skin (fixed 3 days after birth) were microscopically scanned for mutant melanocytes in the hair follicles.About half a million follicular melanocytes were present in the 2 mounts made per mouse. Mutant cells were mainly in the form of small intrafollicular clones; the few mount containing large interfollicular clones were excluded from the analysis. For both treatments, dose-response relationships showed good fits to both a quadratic and a power-law curve. Equations for the latter were: For X-rays, y = 3.2 x 10(-5) + 3.12 x 10(-9) D2.07; for procarbazine, y = 3.6 x 10(-5) + 0.4 x 10(-10) D2.60. However, neither of these differed significantly from a square-law relationship. The estimated mutation rate at the 100 rad X-ray level of 4.7 x 10(-7)/rad/locus was in good agreement with that obtained by Russell and Major's (1957) pioneer studies of somatic mutation in mice, by looking for mutant patches in the coat ("spot test"). Possible ways in which the present method might be improved and extended are discussed.

Effects of X-irradiation at different times during development on the yield of somatic mutations in melanocytes of the mouse.

The effect of 2.0 Gy X-irradiation at different times during foetal and early post-natal development on the resultant somatic mutation frequency was investigated by scoring for changes in follicular melanocyte morphology (nucleofugal vs. nucleopetal) in mice heterozygous for the recessive coat colour mutations dilute (d) and leaden (ln). Two peaks were observed following X-irradiation on days 12.5 and 17.5 post coitus (p.c.). The biomodal character of the mutation frequency with time of X-irradiation may be related to changes in the dynamics of the melanocyte population with foetal age. Nonetheless, the results validate the treatment time used in the pilot study (Searle and Stephenson, 1982) as the most sensitive to the induction of somatic mutations within the follicular melanocyte population.

Cytogenetic effects of protracted exposures to alpha-particles from plutonium-239 and to gamma-rays from cobalt-60 compared in male mice.

Adult C3H X 101 hybrid male mice were injected intravenously with 4 muCi of 239Pu citrate per kg body weight and examined for evidence of cytogenetic damage to the testis after exposures of 21, 28 and 34 weeks, with average doses from alpha-particles estimated as 13, 18 and 18 rad respectively (mean dose rate 0.00006 rad/min). Results were compared with those obtained when equivalent males were exposed continuously and concurrently to 1128 rad 60Co gamma-irradiation over 28 weeks (0.004 rad/min). The following estimates of the relative effectiveness of the alpha- and gamma-radiation were made: 24 for reciprocal translocations and for chromosome fragments, 22 for dominant lethal mutations acting after implantation. These values (with mean of 23) are based on average testis doses, with no correction for probable non-homogeneity of alpha dose distribution. In the mice exposed to gamma-irradiation there were significant reductions in testis mass and epididymal sperm-count. Although corresponding differences from control were not significant in the alpha series, consideration of results from a previous experiment by the same authors [2] allowed the relative effectiveness of the alpha- and gamma-irradiation for testis mass reduction to be estimated as roughly 10-15. Existing data on translocation induction in mouse spermatogonia by low dose-rates of gamma-rays (down to 0.003 rad/min) were analysed. They suggested that minimum rates of induction at very low intensities were not less than 1 X 10(-5) translocations per rad. A comparison of the frequencies of induction of fragments and of sperm-head abnormalities obtained after chronic gamma-ray exposures in the present experiment with those found by other workers after acute X-ray exposures suggested that there were no marked dose-rate effects with these types of mutational effect. Finally, the special problems associated with cytogenetic studies on alpha-emitters are discussed.

A search for radiosensitive mouse mutants by use of the micronucleus technique.

In order to identify radiosensitive mutations in mice, 26 genetically well defined mutations in 26 different combinations of homozygous, hemizygous or heterozygous conditions, together with normal mice and mutagen-sensitive MS/Ae mice were analysed for the induction of micronuclei by X-rays in bone-marrow cells. For each mutant two doses of 0.5 and 1.0 Gy, two sampling times of 18 and 27 h after irradiation and unirradiated controls were studied. Using our criteria, homozygous contrasted allele of steel (Slcon), scabby (scb), viable dominant spotting (Wv), quaking (qk), fidget (fi) and postaxial hemimelia (px), heterozygous lurcher (Lc), hemizygous gyro (Gy), the compounds Slcon/grizzle-belly (SlgbH) and Wv/rump-white (Rw) and MS/Ae mice, were regarded as radiosensitive, with Slcon/Slcon the highest in rank order. Homozygous wabbler-lethal (wl) and wasted (wst) showed hyposensitivity which for the latter may be connected with enhanced cell killing.

Cytogenetic characterization of radiosensitive mouse mutants.

In order to develop mouse models for human mutagen-sensitive syndromes, we carried out cytogenetic characterization of several mouse mutants and MS/Ae mice showing enhanced radiosensitivities. The applied cytogenetic techniques include chromosomal analysis of in vitro cell cultures and lymphocyte cultures as well as in vivo UDS in hepatocytes, induction of micronuclei in polychromatic erythrocytes and translocation induction in spermatogonial stem cells. Among the mutations studied, namely the contrasted allele of steel (Slcon), viable dominant spotting (Wc), wasted (wst), varitint-waddler (Va) and dystonia musculorum (dt) as well as MS/Ae mice, various iso-, hyper- or hypo-sensitive conditions were recorded. Only Va and dt appear to be associated with some deficiency in DNA repair.