Isolation and characterization of a 1-beta-D-arabinofuranosylcytosine-resistant Chinese hamster ovary cell mutant that is also X-ray sensitive and is noncomplementary with ataxia telangiectasia cells.

In order to study the mechanism of induction of mutations and chromosome aberrations by ionizing radiations, it is particularly useful to have available radiation-sensitive mutants. While several X-ray-sensitive rodent cell lines are available, they have been selected rather nonspecifically. It was determined that selection for resistance to the DNA replication/repair inhibitor, 1-beta-D-arabinofuranosylcytosine (ara-C), would permit production of a set of X-ray-sensitive mutant cell lines that would be defective in the resynthesis step of excision or recombination repair. Such mutant cells could also be used for the isolation and characterization of human DNA repair genes. In particular, it was predicted that the repair gene defective in individuals with ataxia telangiectasia (AT) might be amenable to study with ara-C-resistant (X-ray-sensitive) mutants, since additional studies, presented here, have shown that AT cells are resistant to ara-C. In the long term, it is hoped that determining the specific defect in AT might lead to an understanding of the possible role of defective repair in tumor induction and/or progression. The general approach used to isolate ara-C-resistant Chinese hamster ovary cell mutants was to treat cells with ethyl methanesulfonate and select in increasing concentrations of ara-C. Although several mutants were isolated, one in particular, Ara-CR213, has been studied most extensively. It was selected largely because it shows the greatest sensitivity to X-rays. Ara-CR213 cells were hypersensitive to the killing effect of X-rays with an LD10 of 2.5 Gy as compared to the wild-type cells that had an LD10 of 6 Gy. The mutant showed an increased frequency of X-ray-induced chromosomal aberrations in the G1 and G2 stages of the cell cycle compared to wild-type frequencies. There was no increase in sister chromatid exchange levels. All of these observations in Ara-CR213 are very similar to those made with AT cells in our and other laboratories. Even more important, complementation analysis of Ara-CR213 x AT hybrid cells indicated that the gene responsible for X-ray sensitivity of AT is also mutated in Ara-CR213 cells. Thus, Ara-CR213 appears to have a mutant phenotype and probably genotype that is very similar to, if not exactly the same as, those of AT. This makes it quite different from other X-ray-sensitive cells that have been isolated in other laboratories.

Analysis of mouse metaphase II oocytes as an assay for chemically induced aneuploidy.

Our initial objective was to develop an in vivo mammalian, female aneuploid assay that is consistent, time efficient, and that yields a large number of oocytes amenable to objective analyses. Subsequently, we desired to use such an assay for identifying chemicals and dosages that could increase the incidence of aneuploidy in mouse metaphase II oocytes. The experimental protocol involved superovulating CD-1 mice with PMS; HCG was given 48 h later. At the time of HCG injection, different dosages od diethylstilbestrol diphosphate, cadmium chloride, chloral hydrate, or colchicine were injected intraperitoneally. 17 h later, oocytes were collected and fixed prior to C-banding the chromosomes. The procedure required about 3 h to process oocytes from 25 mice and yielded over 100 analyzable metaphase II oocytes. Colchicine was the only compound tested that resulted in a statistically significant (P less than 0.01) increase in hyperploid (N greater than 20) oocytes over controls. The incidence of hyperploid oocytes in the colchicine group was 2/167, 1/182, 21/220, and 38/202, for control, 0.1 mg/kg, 0.2 mg/kg, and 0.3 mg/kg, respectively. This assay appears sensitive for aneuploidy detection but requires further validation.

X-ray stage sensitivity of mouse oocytes and its bearing on dose-response curves.

A detailed cytogenetic study of maturing mouse oocyte radiosensitivity was performed. Oocytes were collected at various intervals ranging from 1.5 days to 28.5 days after irradiation with 50, 100, 200, and 300 R of acute X-rays. The observed sensitivity to chromatid aberration induction varied greatly over this time span. Sensitivity was lowest at the shortest time interval before ovulation and gradually increased up to 9.5 days; it then remained constant until insufficient numbers of oocytes could be collected. The data were analyzed in three ways. First, the data from all time intervals at each dose were pooled; second the data from the least sensitive time intervals, at each dose, were pooled, and third, the data from the period of uniform sensitivity, at each dose, were pooled. Dose-response regression analyses were done on these pooled data and the best fits obtained were to the models Y = a + bD + cD2 and Y = a + cD2 for both deletions and interchanges. This result is interpreted as indicating that the aberrations result from a predominantly two-track process. The cytogenetic data were compared to specific-locus mutation induction data in comparable oocyte stages, and qualitative similarity in dose-response characteristics were observed. This similarity is interpreted to mean that both events result from the same mechanism, and that the large dose-rate effect, observed for both events, is a reflection of the two-track component in the dose-response curves.

Studies on chemically induced dominant lethality. III. Cytogenetic analyses of TEM-effects on maturing dictyate mouse oocytes.

A comparative cytogenetic study was done on metaphase-I oocytes and first cleavage mitoses following treatment of young mature female mice with triethylenemelamine (TEM). The ova were collected at intervals ranging from 12 h to 10.5 days after single intraperitoneal injection of TEM. Very few structural aberrations were seen in the metaphase-I cells after TEM treatment. There was, however, a very clear effect on the female genome when first cleavage mitoses were analyzed. The aberrations seen were principally chromatid deletions and interchanges, and their frequency varied with dose and the time between treatment and mating.

X-ray-induced chromosome aberrations in mouse dictyate oocytes. II. Fractionation and dose rate effects.

Slit-dose experiments were done on maturing dictyate oocytes to determine if the magnitude of the first dose influenced the "rejoining time" of radiation-induced chromosomal lesions. A total dose of 400r was split into various combinations with varying fractionation intervals. The data derived from analyzing interchanges indicate that there is no difference in the rejoining time whether the first dose was 100, 200, or 300r. It thus appears that the radiation dose in the ranges studied does not significantly alter the rate of repair of the chromosomal lesions. This conclusion is contrary to that which has been propounded to explain the nonlinear dose curves obtained for specific locus mutations. Chronic 60Co gamma-ray exposures were given to female mice over an 8-day period. The exposures were delivered during the period of peak sensitivity, i.e., 8-16 days prior to ovulation. The doses given were 117, 240, 348, and 483r. The aberration yields observed were dramatically lower than for comparable doses of acute X rays even when the RBE of gamma rays compared with X rays is taken into account. The large drop in yields at the low dose rates is interpreted as resulting from a large two-track component in the acute curve, and as being independent of effects on repair systems.

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.

X-ray-induced chromosome aberrations in mouse dictyate oocytes. I. Time and dose relationships.

Structural chromosome aberrations were analyzed in superovulated metaphase-I oocytes of the mouse, Mus musculus, at various times after a single acute dose of 200 R of X-rays. The aberrations seen were of the chromatid type, i.e., chromatid interchanges, isochromatid deletions and chromatid deletions. The aberration frequency was low during the interval 24 h to 5 days between irradiation and ovulation; peak frequency was reached when irradiation was given 14 days prior to ovulation. A dose-response study was made 14 days prior to ovulation at doses of 50, 100, 200, 300 and 400 R. A curve of these data indicated that a significant two-track component was present for both interchanges and deletions. Centromere staining revealed that symmetrical and asymmetrical interchanges occurred at approximately equal frequency and also that the asymmetrical equivalent of crossing-over was induced at a measurable frequency.

Studies on chemically induced dominant lethality. I. The cytogenetic basis of MMS-induced dominant lethality in post-meiotic male germ cells.

Young adult male mice were injected intravenously with doses of methyl methanesulfonate(MMS) ranging from 25 to 100 mg/kg body weight. These males were serially mated to superovulated females from day 1 post injection to day 23 post injection. The morning after mating (about 4-6 h post-copulation) the females were sacrificed and ova flushed from the ampulla. The ova were cultured, in the presence of colchicine, for 26 h and metaphase preparations made of the first cleavage division. Chromosome analysis was done and the types, and extent, of chromosome aberrations correlated to previously published dominant lethal data at the same MMS doses and time intervals. The types of aberrations seen were predominantly double fragments (presumably isochromatid deletions), chromatid interchanges, and some chromatid deletions, as well as shattering effect on the male complement at the highest dose and the time of peak sensitivity to dominant lethal induction. When the frequency of cells containing a cytologically visible aberration is compared to the total dominant lethal data an excellent correlation is obtained. Furthermore, the frequency of highly damaged cells, agrees very well with estimated frequencies of preimplantation loss. These data strongly suggest that chromosome aberrations seen at the first cleavage stage are the basis of MMS-induced dominant lethality.