Translocations in mouse spermatogonia after exposure to unequally fractionated doses of x-rays

Gene trap: knockout on the fast lane

Gene trapping is a powerful tool to ablate gene function and to analyze in vivo promoter activity of the trapped gene in parallel. The gene trap strategy is not as commonly used as the conventional gene-targeting strategy, although it offers appealing options. Nowadays, a wide collection of embryonic stem cell clones, with a huge variety of trapped genes, have been identified and are available through the members of the International Gene Trap Consortium (IGTC). This chapter focuses on BLAST searches for the appropriate stem cell clones, the confirmation of vector insertion by RT-PCR or X-Gal staining, and the characterization of the exact insertion site to develop a PCR-based genotyping strategy. Furthermore, protocols to follow the activity of the commonly used beta-galactosidase reporter are given.

Delayed manifestation and transmission bias of de novo chromosome mutations: their relevance for radiation health effect

The origin and transmission of de novo chromosome mutations were reviewed on the basis of our chromosome studies in retinoblastoma patients and male infertility. In a series of 264 sporadic retinoblastoma families, gross chromosome rearrangements involving the RB1 locus were identified in 23 cases (8.7%), of which 16 were non-mosaic and 7 were mosaic mutations. The newly formed chromosome mutations, whether they were non-mosaic or mosaic, had a strong bias towards paternally derived chromosome, indicating that they shared a common mechanism where a pre-mutational event or instability is carried over to zygote by sperm and manifested as gross chromosome mutation at the early stages of development. The de novo chromosome mutations are preferentially transmitted through female carriers. This transmission bias is consistent with the finding of higher frequencies of translocation carriers in infertile men (7.69% versus 0.27% in general populations) in whom meiotic progression is severely suppressed, possibly through activation of meiotic checkpoints. Such a meiotic surveillance mechanism may minimize the spreading of newly-arisen chromosome mutations in populations. A quantitative model of meiotic surveillance mechanism is proposed and successfully applied to the published data on ;humped' dose-response curves for radiation-induced spermatogonial reciprocal translocations in several mammalian species.

Enhanced specific-locus mutation response of 101/H male mice to single, acute X-irradiation

The specific-locus mutation yield from 101/H mice following single, acute 6 Gy spermatogonial X-irradiation was significantly higher than both a concurrent C3H/HeH x 101/H F1 hybrid control and historical data obtained with mice of equivalent genotype. There is therefore discord with the reduced translocation response to single X-ray doses previously identified in this strain. By contrast, the mutation yield following a 24-h interval 3 + 3 Gy fractionated X-ray dose was not significantly different from that of its concurrent hybrid control, nor from results obtained by others with mice of the equivalent or different genotypes. Here there is no discord with the translocation response obtained with a 1 + 5 Gy 24-h interval fractionated regime. Appraisal of comparable specific-locus and translocation data indicates that the differing results obtained with the two genetic end-points are not without precedence. This, together with the observation that the responses for cytologically visible deletions and specific-locus mutations are similar, suggests that the latter two events predominantly derive from one-hit events, with translocations deriving from two-hit events and that the probabilities of induction of each type of lesion vary according to the organisation of the nucleus in different phases of the cell cycle.

The radiosensitivity of spermatogonial stem cells in C3H/101 F1 hybrid mice

The radiosensitivity of spermatogonial stem cells of C3H/HeH x 101/H F1 hybrid mice was determined by counting undifferentiated spermatogonia at 10 days after X-irradiation. During the spermatogenic cycle, differences in radiosensitivity were found, which were correlated with the proliferative activity of the spermatogonial stem cells. In stage VIIirr, during quiescence, the spermatogonial stem cells were most radiosensitive with a D0 of 1.4 Gy. In stages XIirr-Virr, when the cells were proliferatively active, the D0 was about 2.6 Gy. Based on the D0 values for sensitive and resistant spermatogonia and on the D0 for the total population, a ratio of 45:55% of sensitive to resistant spermatogonial stem cells was estimated for cell killing. When the present data were compared with data on translocation induction obtained in mice of the same genotype, a close fit was obtained when the translocation yield (Y; in % abnormal cells) after a radiation dose D was described by Y = e tau D, with tau = 1 for the sensitive and tau = 0.1 for the resistant spermatogonial stem cells, with a maximal e tau D of 100.

Enhanced spermatogonial stem cell killing and reduced translocation yield from X-irradiated 101/H mice

The spermatogonial stem cells of 101/H mice have been found to be more sensitive to killing by acute X-ray doses than those of the "standard" C3H/HeH X 101/H F1 hybrid. Duration of the sterile period was longer throughout the 0.5-8.0-Gy dose range tested and "recovered" testis weights, taken after recovery of fertility, were more severely reduced. The shapes of the sterile period dose-response curves were similar, but with the 101/H mice the plateau occurred at 3-5 Gy, rather than at 6 Gy. An equivalent observation was made with the testis weight data. The translocation dose-response curve was bell-shaped, as previously found with the hybrid, but yields were lower at all but the lowest doses. Notably, peak yields occurred at 3-5 Gy, rather than at 6 Gy. The altered stem cell killing and genetic responses may be explained either by a higher proportion of radiosensitive cells in the heterogeneous stem cell population or by a higher ratio of cell killing to recoverable chromosome damage which might imply a reduced repair capacity. The latter finds some support in other data. The pattern of genetic response obtained when an X-ray dose was given in two fractions at various intervals was similar in 101/H and the hybrid mice, suggesting that their kinetics of stem cell repopulation following depletion differ little.

Relation between number of hemopoietic stem cells in newborn mice and their radiosensitivity

Fractionation of a radiation exposure causes greater damage in newborn mice than a single application since it induces radioresistant foetal hemopoietic stem cells to differentiate prematurely to more radiosensitive adult ones. In the present investigation, it was studied whether other agents that give rise to extensive stem cell destruction also lead to such a change in radiosensitivity. Indeed, treatment with cytostatic drugs which reduces the number of spleen colony forming units (CFU-s) and total cells also diminished the D0 value of the surviving cells 3 days later. Adriamycin was most effective in causing damage to hemopoietic stem cells and in inducing micronuclei in bone marrow; it also had the most marked action on the D0 of the surviving stem cells.

Evidence for the re-establishment of a heterogeneity in radiosensitivity among spermatogonial stem cells repopulating the mouse testis following depletion by X-rays

Earlier studies have shown that the spermatogonial stem cells of the mouse testis recovering from previous radiation or chemical mutagen exposure give subnormal yields of genetic damage with subsequent X-irradiation. This response has been investigated further: (a) with a high, 9-Gy X-ray dose given 4, 12 or 21 days after a 1-Gy conditioning dose (Expt. 1), and (b) with a 1 + 7-Gy, 24-h fractionation regime given 4 or 14 days after a 1-Gy conditioning dose (Expt. 2). In Expt. 1 the 1 + 9-Gy, 4-day interval regime gave a very low response, lower than obtained previously with an equivalent 1 + 5-Gy treatment. This suggests that a heterogeneity in radiosensitivity, such as exists in unirradiated stem cell populations and absent 24-48 h after radiation depletion, is quickly re-established among the stem cells repopulating the testis. By contrast, the 1 + 7-Gy, 24-h fractionation when given 4 days after the 1-Gy conditioning dose (Expt. 2) gave a very high yield of genetic damage, almost as high as that given by the fractionated (1 + 7 Gy) dose applied to previously unirradiated stem cells. This suggests that the newly established heterogeneity is removed by the second 1-Gy conditioning dose. With longer intervals between treatments, genetic yields consistent with additivity were obtained in Expt. 1; less clear results were obtained Expt. 2. Comparison with earlier data generally suggested that the duration of the repopulating period is dose-dependent. In a third experiment evidence was obtained that genetic damage induced by X-irradiation can be reduced by a subsequent treatment with triethylenemelamine (TEM) during the repopulating phase. This confirmed an earlier finding. Such an interaction could not be demonstrated with two X-ray treatments. An explanation for the X-ray/TEM interaction is offered.

X-ray-induced reciprocal translocations in stem-cell spermatogonia of the rhesus monkey: dose and fractionation responses

Rhesus monkeys received total body or local testes X-irradiation with unfractionated (50, 300, 400, 800 and 850 rad) or fractionated (200 + 200 rad with 24-h interval) exposures. At different times after irradiation, chromosomal analysis was made of C-banded dividing spermatocytes. The observed frequencies of translocation configurations confirmed earlier results about the low induction rate of reciprocal translocations in stem-cell spermatogonia of the rhesus monkey. The absence of any translocation induction at doses of 400 rad and higher indicates an extreme insensitivity of surviving radiation-resistant stem cells for the induction of this type of genetic damage. The frequency of translocations following a fractionated exposure to 400 rad, which is above the peak yield for single exposures, was clearly higher than that obtained when the same dose was applied as a single exposure (0.71 versus 0%), but significantly lower than expected on the basis of additivity of the two fractions (0.71% versus 1.98%).

Absence of correlation between the chromosomal radiosensitivity of peripheral blood lymphocytes and stem-cell spermatogonia in mammals

To evaluate the reliability of quantitative extrapolation of radiation-induced chromosomal damage from somatic cells to germ cells, data on the effects of several biological and physical factors on the chromosomal radiosensitivity of blood lymphocytes and stem-cell spermatogonia have been collected from the literature. The results show that most of the factors considered, such as chromosomal constitution, age, genetic constitution, species, sampling time and dose fractionation, had differential effects on the induction of chromosomal aberrations in both systems. These differential effects can easily be explained in terms of the biological differences between in-vitro-stimulated peripheral blood lymphocytes and stem-cell spermatogonia. It is concluded that only direct experiments on germ cells of higher primates and man can be used for a quantitative estimation of human genetic radiation risks arising from structural chromosomal aberrations.

An analytical approach to the induction of translocations in the spermatogonia of the mouse

An analysis of a series of data providing a comprehensive impression of the effect of radiation on the induction of translocations in the spermatogonia of the mouse is presented. It is assumed that the spermatogonial stem-cell population is made up of a sensitive and resistant compartment, that the same type of basic lesion can lead to either translocation induction or cell inactivation, and that the basic lesion has a linear-quadratic dose relationship. The same set of parameter values is used to provide a quantitative description of the acute dose--response relationship and the effects of dose-rate and short-term, 24-h and long-term fractionation. The unusual effect of 24-h fractionation can be explained by proposing that the first dose blocks the progression of sensitive cells into the resistant compartment whilst the progression of the resistant cells into the sensitive compartment is unaffected. The analysis indicates that (1) the majority of the spermatogonial stem cells in the mouse are in the sensitive compartment; (2) that the yield of translocations is proportional to accumulated dose for chronic radiation schedules; (3) the biology of spermatogenesis should be taken into account when extrapolations are made from one animal species to another.

The in vitro radiosensitivity of hemopoietic stem cells from control and preirradiated infant mice

The radiosensitivity of hemopoietic stem cells isolated from infant mice (6 or 9 days of life), of infant preirradiated mice (exposed to 126 rad on day 6 and assayed at day 9 of life) and of adult C57/Bl mice was assayed on the basis of their capacity to form spleen colonies and to incorporate iododeoxyuridine after transplantation into heavily irradiated hosts. Stem cells of infant non-irradiated mice have a DO of 115 rad compared to 72 rad for adult mice whereas the DO of preirradiated infant mice has diminished to 80 rad. No significant difference was seen between spleen and bone marrow cells or between total cells and cells not sensitive to 3H-thymidine. It is postulated that this sensitization of stem cells caused by a preirradiation is responsible for the greater mortality of infant mice after fractionated exposure compared to a single one.

Cytogenetic effects of fractionated or unfractionated X-ray exposures to mouse spermatogonia

The induction of chromosomal aberrations in mouse spermatogonia was studied, after single (50 and 100 rad) and fractionated doses (50 / 50 rad spaced 24 h apart), a short time after irradiation, by analysis of mitotic stages. From 17 to 21 h after the second fraction of the dose, the recorded frequencies of chromosomal deletions and exchanges were fully additive when compared with single "control" doses. Thus there was no suggestion of any sensitization effect of the first exposure. Possible reasons for this are discussed.

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 + 975 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.

Translocation yield from mouse spermatogonial stem cells following unequal-sized x-ray fractionations: evidence of radiation-induced loss of heterogeneity

Previous work has shown that a high yield of genetic damage can be recovered from stem spermatogonia exposed to a high (900 R) X-ray dose, despite extensive cell killing, when this follows 24 h after a smaller (100 R) radiation exposure. This differs from the response of the normal stem-cell population and has been interpreted to mean that the more radio-resistant cells surviving the first exposure become sensitive both to radiation-induced killing and genetic damage after this time interval and, as a consequence, lose the heterogeneity in radio-sensitivity that typifies a normal stem-cell population. Similar results have now been obtained with doses of 600 and 800 R given in fractions of 100 + 500 R and 100 + 700 R 24 h apart. Yields of translocations among spermatocytes were higher than obtained with the single doses and responses consistent with the fractions acting additively were obtained when the fractions were given in reverse order. Further analyses of the data provided support for the concept that 24 h after a radiation exposure there is a loss of heterogeneity in radio-sensitivity in the surviving stem-cell population.

Failure of X-rays to mutate class II histocompatibility loci in Balb/c mouse spermatogonia

Adult Balb/c Kh male mice were irradiated (pelvic region, 250 kVcp X-rays, 60 rad per min) and three months later were mated to untreated C57BL/6 Kh females. Their B6C F1 progeny were screened for mutations at the Class II histocompatibility loci, i.e. those that carry similar alleles in the parental lines and are therefore homozygous in the F1 progeny. The treatment groups were: single doses of 0, 350, 500, 650 and 800 rad; split doses 1 day apart, totalling 500, 650 and 800 rad; split doses averaging 52 days apart, totalling 650 and 800 rad. Thirty-six mutants were identified in 13,614 progeny. Twelve of them occurred in five clusters of two or three, presumably owing to five gonadal mosaics among 940 parents. Irradiation did not increase the spermatogonial mutation rate. The only effect of exposure appeared to be a decrease in the mutation rate of the 1-day split dose-groups compared to those with the same total doses in a single exposure or in two fractions, 52 days apart.

X-Ray-induced translocations in spermatoginia. II. Fractionation in mice

The dose-response curve for reciprocal translocations induced by X-rays in spermatogonial stem cells, and observed in primary spermatocytes of mice, is "hump-shaped", with a maximum yield at about 600 R. To test the hypothesis that the decrease in yield with increasing dose above 600 R is a consequence of the different sensitivities of cells in different stages of the cell cycle to both cell killing and chromosome aberration induction, several fractionation experiments were carried out. A total dose of 2800 R was given in repeated doses of 400 R, separated by 8-week intervals. The yield of translocations is that expected for additivity; for example, the yield at 1600 R is approximately equal to that for four separate 400-R doses. When a total dose (500 R) which gives a translocation yield on the ascending part of the dose-response curve is given as two equal fractions separated by intervals of 30, 90, or 150 min, the translocation yield decreases with increasing interval. However, when a total dose (1000 R) which would give a translocation yield on the descending part of the dose-response curve is given in two equal fractions separated by intervals of from 30 min to 6 weeks, the response is different; the translocation yield increases with intervals up to 18 h, then decreases with intervals up to 4 weeks, and finally increases again to a yield equal to additivity with an interval of 6 weeks. These changes in translocation yield with changes in interval between the two doses are explained in terms of the differential sensitivity of cells to killing and aberration induction in the different phases of the cell cycle, and by assuming that the cells surviving the first dose and repopulating the testis have different cycle characteristics from normal cells.

Dose-response data for X-ray induced translocations in spermatogonia of Rhesus monkeys

The yields of translocations in spermatocytes after irradiation of spermatogonia of Rhesus monkeys with doses of 100, 200 or 300 rad X-rays were low, and consistent with a humped dose-response curve with a peak at about 200 rad. Such a curve would agree well with earlier results on the marmoset and man, but the yields at any dose in the Rhesus monkey were lower.

Translocation yield from the mouse spermatogonial stem cell following fractionated X-ray treatments: Influence of unequal fraction size and of increasing fractionation interval

(1) The genetic response of the mouse spermatogonial stem cell to a high dose of X-rays given in two unequal fractions 24 h apart can be dependent upon the order in which the two fractions are given. When 1000 R was administered as 100 R followed by 900 R the recovered translocation yield (22%) was similar to that which can be obtained by extrapolation from lower doses and also to that of a 500 + 500 R 24 h fractionation. By contrast, when the 900 R preceded the 100 R the response was much lower (7.4%), yet still greater than that produced by a single 1000 R treatment (4.5%). The same order of effectiveness was observed for length of sterile period. (2) The sub-additive translocation yields previously obtained with 800 R treatments given in fractions of 500 R and 300 R at intervals of 3-12 days were found to be maintained with intervals up to at least 15 days but additivity was regained by the end of the third week. Sterile period data indicated that with these intervals the germinal epithelium had recovered sufficiently from the first fraction for spermatogenesis to restart before the second fraction was given. (3) It is concluded from the two experiments that (a) 24 h after a radiation exposure the surviving stem cells are more sensitive than formerly both to killing and genetic damage, (b) at this time they are no longer heterogeneous in their radiosensitivities, so that increasing yields of genetic damage may be obtained with increasing dose i.e. there is no fall in yield at higher doses, (c) the change in sensitivity could be a consequence of a synchronization to a sensitive stage in a cell cycle, or to a transitional phase preparatory to entering a different cell cycle. (d) to achieve rapid repopulation of the germinal epithelium the surviving stem cells are stimulated to enter a shorter cell cycle and this is the cause of the sub-additive translocation yields with fractionation intervals of 3-15 days, (e) the recommencement of spermatogenesis is associated with the reestablishment of the heterogeneity in radiosensitivity among the stem cells. At this time additive translocation yields can again be recovered.