Dose-effect relationship for X-ray-induced reciprocal translocations in mouse spermatogonia following pretreatment with 3-aminobenzamide

The influence of 3-aminobenzamide (3-AB) pretreatment on the dose-response relationship for radiation-induced reciprocal translocations in mouse spermatogonial stem cells was studied. The results show that at doses of 3-10 Gy of X-rays the frequencies of translocations were higher in 3-AB-pretreated animals as compared to animals that received X-rays only. The 3-AB pretreatment was not effective at dose levels of 1 and 2 Gy. The shape of the dose-effect curve was similar to that obtained without 3-AB pretreatment, i.e., a humped curve, but the initial slope was clearly steeper and the position of the peak was shifted from 7 to 9 Gy. The effects observed can be explained by a 3-AB-mediated sensitization of normally radioresistant stem cells that are at the stage of stimulation to enter the mitotic cycle, thus increasing the population of radiosensitive spermatogonial stem cells.     

Strain differences in the radiosensitivity of mouse spermatogonia

The radiosensitivity of spermatogonia was found to be greater by up to a factor of 2 in C3H mice than in B6D2F1 mice, whether assessed for the highly sensitive spermatogonia (types A2 to In) or the much more resistant clonogenic spermatogonia which repopulate tubules. The latter were similarly resistant in the B6D2F1 hybrid and in the DBA2 parent, but were much more sensitive in the C57BL parent strain. A difference in sensitivity by up to a factor of 2 results in a variation by a factor of 10 or more in the level of survival of clonogenic cells after high doses. This variation is also observed when comparing data in the literature from different authors using various strains of mice. Using the radiosensitizer misonidazole, it was shown that hypoxia did not play a major role in the lesser sensitivity demonstrated in B6D2F1 mice. The variation in sensitivity is similar to the range reported in the literature for reciprocal translocations.     

Studies on the induction of translocations in mouse spermatogonia. IV. Effects of acute gamma-irradiation

The rate of induction of reciprocal translocations by 56–816 R exposures of mouse spermatogonia to acute γ-irradiation (95 R/min) was determined by cytological examination of descendant spermatocytes. The dose-response relationship did not differ significantly from linearity and had a regression coefficient of 1.8·10⁻⁴ per R with respect to translocations per spermatocyte. Further analysis at exposures below 816 R (considered less likely to produce distortion) showed that the quadratic regression of best fit had too small a square-law component to account for the very low frequency of translocations obtained after chronic γ-exposures in a previous experiment. The possibility is discussed that there is some extra factor, besides the diminution of the square-law component, which operates to reduce the yield after protracted exposures.     

Response of mouse spermatogonial stem cells to X-ray induction of heritable reciprocal translocations

Although heritable translocations are an important endpoint for the assessment of genetic risk from radiation, there has been a serious information gap with regard to thier induction in spermatogonical stem cells, the most important cell stage in males for risk considerations. This led to uncertainty in estimating the magnitude of risk per unit exposure. Further, the relationship between the frequency of r eciprocal exchanges scored by cytological analysis of the exposed male's meiocytes and the frequency of those transmitted to first-generation offspring needed to be re-examined. In order to fill in these gaps, two radiation studies, i.e., dose response and dose fractionation, were conducted on spermatogonial stem cells in which heritable and cytologically detected translocations were scored.The present data are by far the most extensive, to date, for heritable translocation induction in spermatogonial stem cells. The linearity of the rising portion of the dose-effect curve and the additivity of effects observed in the fractionation study allow a direct estimation of the number of transmissible translocations expected per unit exposure. Thus,t he expected increase in heritable translocations per rad of acute X-rays in 3.89 × 10^?5 per gamete. The data also show a lack of consistensy between cytologically and genetically scored translocations.     

Induction of translocations in mouse spermatogonia after fractionated exposure to 60Co gamma-rays

Male mice of the Q strain were exposed to 60Co gamma-rays at 2 Gy and 2 X 2 Gy separated by increasing time intervals (from 0 min to 4 min). The chromosome translocations induced in spermatogonia were scored at diakinesis-metaphase I. A significant decrease of the translocation frequency at time intervals higher than 2 min was observed, confirming results obtained with plant materials.     

Evidence of a threshold x-ray dose for sensitizing stem-cell spermatogonia of the mouse to the induction of chromosomal translocations by a second larger one

The effect of different small conditioning doses of X-rays on the production of reciprocal translocations in stem-cell spermatogonia of the mouse (scored in spermatocytes) by a second larger dose have been examined. Fractionation regimes of 25 + 975 R, 50 + 950 R, 75 + 925 R and 100 + 900 R, all with 24 h between the fractions, were applied. The size of the first fraction strongly affected the frequency of induced translocations by the second one, and a kind of threshold dose, somewhere between 75 and 100 R existed for conditioning the spermatogonial population: the translocation yield after 25 + 975 R was 3.3 %, after 50 + 950 R it was 5.0%, and after 75 + 925 R it was 5.1%; whereas 100 + 900 R resulted in 16.1% translocations. It is difficult to explain this observed threshold effect by known biological processes so far held responsible for the conditioning effect.     

Antimutagenic properties of selected radioprotective drug mixtures with regard to X-ray-induced reciprocal translocations in mouse spermatogonia

The radioprotective drugs AET, serotonin, and ATP were tested for antimutagenic activity against induction by 4.0 Gy X-rays of reciprocal translocations in mouse spermatogonia. Single drugs administered in doses of 8, 24 and 360 mg/kg b.wt., respectively, had no effect on translocation yields recorded in diakinesis-metaphase I spermatocytes. Two-drug mixtures afforded insignificant protection. Three-drug mixtures, however, were found to reduce radiation damage considerably, and the extent of protection was dependent in part on the amount of ATP. The best effect was obtained with formulations of serotonin-AET-ATP at the following doses, respectively: 8 + 24 + 360 mg/kg, 16 + 24 + 336 mg/kg, and 16 + 32 + 264 mg/kg. Less effective were the serotonin-AET-ATP formulations: 16 + 32 + 120 mg/kg, and 8 + 24 + 480 mg/kg. Treatment with drugs omitting radiation exposure was observed to raise, though insignificantly, the level of spontaneous translocation frequency.     

Relative biological effectiveness of x-rays and fast neutrons in inducing translocations in mouse spermatogonia

The dose-response relationships for inducing translocations in the spermatogonia of mice were studied, and they were compared for 200 kVp X-rays and 2 MeV fast neutrons. The dose response for fast neutrons was markedly convex; more precisely, the response obtained was linear in the dose range from 24 to 94 rad with a regression coefficient of 11.36·10^?4, but decreased for a further increase in dose up to 267 rad. On the other hand, that for X-rays showed a linear dose-response relationship from 48 to 672 rad with a regression coefficient of 2.69·10^?4. The relative biological effectiveness for inducing translocations in the spermatogonia of mice was compared for the linear parts of the dose response in both types of radiation, and the relative biological effectiveness (RBE) value was 4.22.     

The incidence of sex-chromosome anomalies following irradiation of mouse spermatogonia with single or fractionated doses of x-rays

Attempts to recover XO offspring resulting from 600 R irradiation of spermatogonia proved negative. X-Rays were administered either in a single dose or in 100+ 500 R fractions separated by 24 h, and controls were strictly comparable in all respects. Altogether 14016 offspring were scored, including a small group derived from irradiated mature spermatozoa. The breeding scheme allowed phenotypic detection of paternal or maternal sex-chromosome loss, paternal nondisjunction, and certain translocations. All phenotypically exceptional mice were examined cytologically and through breeding tests. Similar tests of the mothers of presumed O/X^p exceptionals revealed that in 9 of 14 cases there was a pre-existing XO condition, indicating the importance of performing such a test. Two of the 3a X^m/O-appearing mice were probably X^m/O///X^m/X^p mosaics, with the integument predominantly XO and the germinal tissue predominantly X/X.The frequency of paternal sex-chromosome loss was 2.4 · 10^?3 in the controls and 2.0 · 10^?3 in the two irradiated groups, where X^m/O's must therefore be assumed to be of spontaneous origin. Since translocation experiments provide evidence that chromosome breaks are induced by irradiation of spermatogonia, the failure to recover XO's is explained in one of two possible ways. (1) Breakage in spermatogonia does not lead to recoverable single-chromosome loss, either because no sister-chromatid joining occurs, or, if it does, because this leads to cell-division failure. (2) Alternatively, sex chromosome loss does occur, but resulting X/O and O/Y cell progeny is inviable in the testis—a suggestion supported by evidence from natural and artificial mosaics.The results of the present experiment lend further support to our earlier suggestion that most spontaneously occurring X^m/O mice are the result of events occurring after sperm entry into the egg. The spontaneous frequency of paternal sex-chromosome loss has ranged over two orders of magnitude in various reports. On the other hand, the frequencies of spontaneous X^m loss (O/X^p daughters of X/X females/total daughters) and of paternal nondisjunction (2 · X^m/X^p/Y frequency)