Spermatogonial stem cell killing in the mouse following single and fractionated x-ray doses, as assessed by length of sterile period

Apoptotic repair of genotoxic tissue damage and the role of p53 gene

The spontaneous mutation rate per replication per genome is nearly invariant in microbes; however, the rate of spontaneous genomic mutations in higher eukaryotes is much higher. Furthermore, the mutation rates per locus per generation among Drosophila, mice and humans are similar, despite the large differences in generation time. A simple explanation for these findings is that mice and humans have a specific antimutagenic mechanism that is lacking in Drosophila. I propose that apoptotic repair-deletion of genotoxic damage-bearing cells-operates in mammalian germ cells and that it works more accurately in humans than in mice because of a slower rate of cell turnover and a longer generation time. It has been a long-standing puzzle that germline mutation frequencies decrease markedly as the dose-rate of radiation is lowered in mice but not in Drosophila. This can be readily explained by p53-dependent apoptotic repair, because the p53 gene is absent from the genome of Drosophila. Fetuses of p53+/+ mice have proficient apoptotic repair capacity for X-ray-induced teratogenic damage, but p53-null fetuses completely lack this capacity. Further, I propose that the primary role of the p53 gene is to guard germ cells and embryos from genotoxic damage. This implies that the tumour suppressor function of the p53 gene results from p53-dependent apoptotic deletion of cells with genotoxic damage. The reasoning behind this proposal is given by reviewing reports that Drosophila larvae are insensitive to tumour formation after irradiation. Finally, I discuss the genetic effects of radiation in humans.

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.

A quantitative study of spermatogonial multiplication and stem cell renewal in the C3H/101 F1 hybrid mouse

In whole mounts of seminiferous tubules of C3H/101 F1 hybrid mice, spermatogonia were counted in various stages of the epithelial cycle. Furthermore, the total number of Sertoli cells per testis was estimated using the disector method. Subsequently, estimates were made of the total numbers of the different spermatogonial cell populations per testis. The results of the cell counts indicate that the undifferentiated spermatogonia are actively proliferating from stage XI until stage IV. Three divisions of the undifferentiated spermatogonia are needed to obtain the number of A1 plus undifferentiated spermatogonia produced each epithelial cycle. Around stage VIII almost two-thirds of the Apr and all of the Aal spermatogonia differentiate into A1 spermatogonia. It was estimated that there are 2.5 x 10(6) differentiating spermatogonia and 3.3 x 10(5) undifferentiated spermatogonia per testis. There are about 35,000 stem cells per testis, constituting about 0.03% of all germ cells in the testis. It is concluded that the undifferentiated spermatogonia, including the stem cells, actively proliferate during about 50% of the epithelial cycle.

Comparative study of spermatogonial survival after x-ray exposure, high LET (HZE) irradiation or spaceflight

Spermatogonial cell loss has been observed in rats flown on Space Lab 3, Cosmos 1887, Cosmos 2044 and in mice following irradiation with X-ray or with high energy (HZE) particle beams. Spermatogonial loss is determined by cell counting in maturation stage 6 seminiferous [correction of seminferous] tubules. With the exception of Iron, laboratory irradiation experiments (with mice) revealed a similar pattern of spermatogonial loss proportional to the radiation dose at levels less than 0.1 Gy. Helium and Argon irradiation resulted in a 5% loss of spermatogonia after only 0.01 Gy exposure. However, significant spermatogonial loss (45%) occured at this radiation level with Iron particle beams. The loss of spermatogonia during each space flight was less than 10% when compared to control (non-flight) animals. This loss, although small, was significant. Although radiation may be a contributing factor in the loss of spermatogonia during space flight, exposure levels, as determined by dosimetry, were not significant to account for the total cell loss observed.

Induction of specific-locus and dominant lethal mutations in male mice by busulfan

The chemotherapeutic agent busulfan was tested for the induction of dominant lethal and specific-locus mutations in male mice. A dose of 5 mg/kg b.w. of busulfan induces dominant lethal mutations in spermatozoa. A dose of 20 mg/kg b.w. induces dominant lethal mutations in spermatozoa and spermatids. A total of 83,196 offspring were scored in the specific-locus experiments. Busulfan-induced specific-locus mutations were recovered in spermatozoa and spermatids, but not in spermatogonia. The sensitivity patterns for the induction of dominant lethal and specific-locus mutations by busulfan in germ cells of male mice are similar but not identical.

The effect of sampling time on radiation-induced translocation yield in spermatogonial stem cells of male mice, differing in chromosomal constitution and sexual activity

We have investigated the frequency of reciprocal translocations in the first differentiating spermatogonia entering the first meiotic division after 2 x 2.5 Gy X-rays, given 24 h apart, as well as the development of this parameter in later stem-cell generations by studying multivalent configurations at the first meiotic division. Diakinesis-metaphase I cells were found for the first time between 30 and 40 days after irradiation. Subsequently, meiotic stages were sampled at 120, 180 and 280 days post irradiation. From day 40 post irradiation on, half of the males were allowed to impregnate females which enabled us to estimate the length of the post-irradiation sterile period, the development of litter size and the possible effect of sexual activity on the development of reciprocal translocation-containing stem cells. Half of the males were karyologically normal, the other half were homozygous for a reciprocal translocation (T/T) that affects testis weight and about halves sperm production. Irrespective of male karyotype, the first meiocytes had an induced translocation frequency of 9.00 +/- 2.56% (n = 8 males), followed by frequencies of 20.70 +/- 4.87% (n = 15) at 180 days and 20.20 +/- 4.30% (n = 20) at 280 days (males with and without mating behavior showing no difference). At 120 days post irradiation, +/+ males had a frequency of 14.59 +/- 2.97% irrespective of sexual activity. T/T males (120 days post irradiation) that had mated showed a frequency of 18.63 +/- 0.85% (n = 4) compared with 13.64 +/- 2.36% (n = 7) for those that had not. The observed rise of multivalent-carrying spermatocytes in time was highly significant. Notwithstanding the differences in testis weight and epididymal sperm count between the karyotypes, fertile matings occurred on average 72 days after irradiation, though with relatively wide margins. For the T/T karyotype, the first litter was statistically smaller than the subsequent litters. At 78 days post irradiation, testis weights were back in the subnormal range for both karyotypes and hardly improved in time. Restoration of fertility thus coincided with the period just prior to the return to subnormal testis weights. The first diakinesis-metaphase I cells precede those that are numerous enough to accomplish 'return to fertility' by about 2 weeks. Thus differentiation of stem-cell spermatogonia already follows a few days after irradiation. A pattern of spermatogonial cell divisions compatible with 'return to fertility' is only established some 2 weeks later.

The relation between induced reciprocal translocations and cell killing of mouse spermatogonial stem cells after combined treatments with hydroxyurea and X-rays

The induction of reciprocal translocations in mouse spermatogonial stem cells, visualised in dividing primary spermatocytes, was studied after combined treatments with hydroxyurea (250 and 500 mg/kg) and X-rays (6, 8 and 9 Gy). The time intervals between the 2 treatments were 16 h (leading to extremely high cell killing) and 48 h (giving rise to less killing than irradiation alone). Comparison of the observed frequencies of translocations with reported data on stem cell killing (de Ruiter-Bootsma and Davids, 1981) show that the ratio between the probabilities that a radiation-induced basic lesion kills a cell or produces a translocation, theoretically calculated by Leenhouts and Chadwick (1981) to be about 10, can indeed be confirmed experimentally.

Induction of specific locus mutations in mouse spermatogonial stem cells by combined chemical X-ray treatments

Data that demonstrate how the biology of spermatogenesis plays an important role in determining the yield of genetic damage from ionizing radiation are briefly reviewed. It is suggested that for valid extrapolations of data from mouse mutation experiments to man detailed knowledge of the spermatogonial stem cell systems in the two species is required. Two new sets of mouse specific mutation data are presented. (1) When a 2 mg/kg dose of triethylenemelamine (TEM) was used as a conditioning dose and followed 24 h later by 6 Gy X-rays, the mutation yield from spermatogonial stem cells was over twice as high (30.20 X 10(-5)/locus/gamete) as that when the X-ray dose was given alone (13.75 X 10(-5)/locus/gamete). No such effect was found when the TEM was given only 3 h prior to the X-irradiation. Since TEM at the dose used is inefficient at inducing specific-locus mutations, an augmentation of the X-ray response is indicated. It has therefore been concluded that the augmented mutation responses obtained with equal 24 h X-ray fractionations at high doses are attributable to mutation induction by the second dose. The responsive cells would be the formerly resistant component of the stem cell population that had survived the TEM treatment and that had been 'triggered' into a radiosensitive phase by the population depletion. (2) When 2 doses of 500 mg/kg hydroxyurea (HU) were given 3 h apart 3 h prior to 6 Gy X-rays to reduce the numbers of stem cells in the S and G2 phases of the cell cycle exposed to the radiation, the mutation responses was greatly enhanced to a level that is the highest yet recorded per unit X-ray dose (7.10 X 10(-5)/locus/gamete/Gy). No such effect was obtained when the intervals between the HU and X-ray treatments were either shorter (less than 0.5 h) or longer (24 h). It was concluded that X-ray-induced specific-locus mutations derive principally from stem cells in the G1 phase of the cell cycle. The reasons why the X-ray-induced mutation-yields from repopulating stem cells (with a short cell cycle and, hence, short G1 phase) are similar to those from undamaged stem cell populations, in contrast to translocation yields, therefore remains unresolved.

Protective effect of hypoxia in the ram testis during single and split-dose X-irradiation

Spermatogonial stem-cell survival in the ram was studied after single (6 Gy) and split-dose (2 x 3 Gy, interval 21-24 h) X-irradiation both under normal and hypoxic conditions. Hypoxia was induced by inflation of an occluder implanted around the testicular artery. The occluders were inflated about 10 min before irradiation and deflated immediately after. Stem-cell survival was measured at 5 or 7 weeks after irradiation by determination of the Repopulation Index (RI) in histological testis sections. The RI-values after fractionated irradiation were only half those after single dose irradiation. Hypoxia had a protective effect on the stem-cell survival. After split-dose irradiation under hypoxic conditions two times more stem cells survived than under normal oxic conditions; the RI-values increased from 34% (oxic) to 68% (hypoxic). This effect of hypoxia was also found after single dose irradiation where the RI-values increased from 68% (oxic) to 84% (hypoxic). The development of the epithelium in repopulated tubules was also studied. Under hypoxia, a significantly higher fraction of tubules with complete epithelium was found after single (38 vs. 4%) as well as after split-dose irradiation (12 vs. 0%).

Genetic effects of combined chemical-X-ray treatments in male mouse germ cells

Several studies have shown that the yield of genetic damage induced by radiation in male mouse germ cells can be modified by chemical treatments. Pre-treatments with radio-protecting agents have given contradictory results but this appears to be largely attributable to the different germ cell stages tested and dependent upon the level of radiation damage induced. Pre-treatments which enhance the yield of genetic damage have been reported although, as yet, no tests have been conducted with radio-sensitizers. Another form of interaction between chemicals and radiation is specifically found with spermatogonial stem cells. Chemicals that kill cells can, by population depletion, substantially and predictably modify the genetic response to subsequent radiation exposure over a period of several days, or even weeks. Enhancement and reduction in the genetic yield can be attained, dependent upon the interval between treatments, with the modification also varying with the type of genetic damage scored. Post-treatment with one chemical has been shown to reduce the genetic response to radiation exposure.

Survival of spermatogonial stem cells in the rat after split dose irradiation during LH-RH analogue treatment

A rat model has been created in which a single injection of an LH-RH analogue depot preparation (Zoladex, ICI 118630) produced a temporary interruption of the pituitary-gonadal axis. This effect applied during irradiation was investigated as a possible mechanism to protect the testis from radiation damage. A local testicular irradiation dose of 6.0 Gy was given either as a single dose or as a fractionated (2 X 3.0 Gy) dose at different time intervals ranging from 8 to 72 h. Stem cell survival was measured 11 weeks after irradiation by means of the repopulation index and the number of haploid cells (spermatids) measured by flow cytometry. Serum gonadotrophins and testosterone concentrations were measured to evaluate hormonal recovery. No significant differences were observed between serum concentrations of follicle-stimulating hormone (FSH), luteinizing hormone (LH) and testosterone and the duration of the fractionation interval. Stem cell survival was higher following fractionated irradiation in comparison with the single dose. For the 8 h interval an increase in recovery ratio was found, amounting to a factor of 5 of the single dose value. The fluctuating pattern of the recovery curves indicated changes in radiosensitivity of stem cells. The combination of hormonal inhibition of spermatogenesis and fractionated irradiation led to a decrease in the absolute numbers of stem cells. However, the stem cell recovery curves were identical to those seen without hormonal inhibition. It was concluded that hormonal pretreatment with Zoladex during split dose irradiation had no protective effect on stem cell survival.

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.

Dose-effect relationship for X-ray-induced translocations in spermatogonia of normal and T70H translocation heterozygous mice

The induction of reciprocal translocations in stem cell spermatogonia was studied in normal mice and T70H translocation heterozygotes using spermatocyte analysis many cell generations after irradiation. Dose-response relationships were constructed employing acute X-ray exposures of 1-10 Gy. The obtained results confirmed our earlier observations that T70H heterozygous mice were overall less sensitive to the induction of translocations compared to normals. The shape of the dose-response curve for T70H heterozygotes was also clearly different from normal mice. No simple correlations between cell killing, measured as testis weight loss, and observed frequencies of chromosomal anomalies could be established. In general, selective elimination of translocation carrying stem cells of T70H heterozygotes seem to be mainly responsible for the differences in induction pattern between the two types of mice.

Dominant cataract and recessive specific locus mutations in offspring of X-irradiated male mice

Male mice were X-irradiated with 3.0 + 3.0 Gy or 5.1 + 5.1 Gy (fractionation interval 24 h). The offspring were screened for dominant cataract and recessive specific locus mutations. In the 3.0 + 3.0-Gy spermatogonial treatment group, 3 dominant cataract mutations were confirmed in 15 551 offspring examined and 29 specific locus mutations were recovered in 18 139 offspring. In the post-spermatogonial treatment group, 1 dominant cataract mutation was obtained in 1120 offspring and 1 recessive specific locus mutation was recovered in 1127 offspring. The induced mutation rate per locus, per gamete, per Gy calculated for recessive specific locus mutations is 2.0 X 10(-5) in post-spermatogonial stages and 3.7 X 10(-5) in spermatogonia. For dominant cataract mutations, assuming 30 loci, the induced mutation rate is 5.0 X 10(-6) in the post-spermatogonial stages and 1.1 X 10(-6) in spermatogonia. In the 5.1 + 5.1-Gy spermatogonial treatment group, 3 dominant cataract mutations were obtained in 11 205 offspring, whereas in 13 201 offspring 27 recessive specific locus mutations were detected in the spermatogonial group. In the post-spermatogonial treatment group no dominant cataract mutation was observed in 425 offspring and 2 recessive specific locus mutations were detected in 445 offspring. The induced mutation rate per locus, gamete and Gy in spermatogonia for recessive specific locus mutations is 2.8 X 10(-5) and for dominant cataract mutations 0.9 X 10(-6). In post-spermatogonial stages, the mutation rate for recessive specific locus alleles is 6.2 X 10(-5). In the concurrent untreated control group, in 11 036 offspring no dominant cataract mutation and in 23 518 offspring no recessive specific locus mutation was observed. Litter size and the number of carriers at weaning have been determined in the confirmation crosses of the obtained dominant cataract mutants as indicators of viability and penetrance effects. Two mutants had a statistically significantly reduced litter size and one mutant had a statistically significantly reduced penetrance.

Long-term infertility and dominant lethal mutations in male mice treated with adriamycin

Sperm production and fertility were studied in male mice treated with adriamycin (ADR) at 6 or 8 mg/kg. Testicular sperm production and epididymal sperm counts were markedly reduced after ADR treatment. Gradual recovery of counts occurred, but sperm counts had not reached control levels even more than 1 year after treatment. Epididymal sperm showed treatment-induced morphological abnormalities throughout the experiment; the frequencies of sperm with detached tails and the frequencies of sperm with morphologically abnormal heads remained elevated about 2-3-fold above control. According to the frequency of vaginal plugs, treated male mice mated at control rates with untreated females during the post-treatment sterile period. However, after some fertility was regained the fertilization rate (calculated as the fraction of eggs, flushed from the oviduct 2 days after mating, that had been fertilized and had cleaved) was markedly reduced and remained depressed for the remainder of the experiment. The fertilization rate reached only 0.29 at 23-32 weeks after 8 mg/kg ADR and 0.76 at 16-23 weeks after 6 mg/kg ADR; both values were significantly below the control value of 0.94. Dominant lethal mutations in the zygotes flushed from the oviduct were measured in culture by the loss of the zygote's ability to develop to a stage characterized by trophectoderm outgrowths and formation of an inner cell mass. The frequencies of dominant lethal mutations detected in vitro were 1.7 or 7.4% after 6 mg/kg, and 32 or 40% after 8 mg/kg ADR; each value was calculated in two different ways, with 3 of these 4 values significantly different from zero. We conclude that even after mice regain fertility following ADR exposure, the level of fertility remains permanently subnormal as evidenced by a lack of fertilization of eggs that is probably due to the decreased quantity and quality of spermatozoa produced. Furthermore, ADR can induce genetic damage in stem spermatogonia, which can be transmitted through fertile spermatozoa. Thus, there may be a genetic risk to the offspring of cancer patients treated with ADR chemotherapy, but at present we are unable to quantitate that risk.

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.

Protection of spermatogonial survival and testicular function by WR-2721 against high and low doses of radiation

The radioprotection of normal cells with WR-2721 at doses of radiation extending down to less than 1 Gy was investigated using testicular cells. Survival of stem spermatogonia after single doses of radiation was measured by counts of repopulating tubules and by sperm head counts, with consistent results obtained for both endpoints. Protection factors (PF) obtained by injection of 400 mg/kg WR-2721 at 15 min prior to irradiation decreased from about 1.4 at radiation doses above 10 Gy to 1.0 at 2 Gy. Similarly, the radioprotection by 300 mg/kg WR-2721 was reduced from a PF of about 1.35 when the drug was given prior to a single high dose of radiation to 1.0-1.1 when the drug was given prior to each of 5 daily fractions of 2 Gy. Thus, less protection of testicular stem cells by WR-2721 was observed at lower doses of radiation. This lowered protection may be explained, at least in part, by a direct cytotoxic effect of WR-2721 on testicular stem cells. Protection of differentiated spermatogonia was observed with 400 mg/kg WR-2721; the PF was 1.4 at 1 Gy and decreased at lower doses. The protection of testicular function by WR-2721, as assayed by the return of fertility and the maximum recovered level of sperm production, was compared to the protection of stem cell survival. At about 8 Gy the PF with 400 mg/kg WR-2721 for both functional endpoints was about 1.5, which was not significantly different from the value of 1.3 obtained using the stem cell assays.

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.

Stem-spermatogonial survival and incidence of reciprocal translocations in the gamma-irradiated boar

To assess the effects of gamma-radiation on stem-cell survival and incidence of reciprocal translocations, boar testes were irradiated with 100, 200, or 400 rad. Stem-cell survival was markedly affected by 100 rad (51% of control) and reduced to 34% of control by 400 rad. Production of differentiating spermatogonia was all but completely interrupted by 200 rad and spermatogonial renewal was incomplete at 12 weeks. From the state of the seminiferous epithelium at 12 weeks, estimates of the percentage of permanent impairment of sperm-producing capacity ranged from 20 +/- 6 (100 rad) to 67 +/- 10 (400 rad). Incidence of translocations peaked at 200 rad and the number occurring at 100 and 400 rad was similar. Kinetics of porcine spermatogonial renewal differs considerably from those of the rodent and, relative to the rodent, this may account for the boar's higher sensitivity to stem-cell killing and lower sensitivity to translocations.

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%).

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.

Modified genetic response to X-irradiation of mouse spermatogonial stem cells surviving treatment with TEM

Earlier studies have shown that the genetic response to X-irradiation of mouse spermatogonial stem-cell populations that are recovering from a previous radiation exposure may differ from that of a normal, unirradiated stem-cell population. Similar modified responses to X-irradiation have now been observed in stem spermatogonia that are recovering from treatment with the chemical mutagen, TEM. (1) In contrast to a normal response to 900 R, high translocation yields were obtained when this dose was administered 24 h after a TEM treatment. (2) A small but non-significant increase above a normal response to 500 R was obtained when this dose followed 24 h after TEM treatment and a normal response to 500 R was obtained from the reverse order treatment (500 R + TEM). (3) When given 4 days after a TEM treatment, the translocation yield from 500 R was only about half that normally obtained. Unexpectedly, a similar low response was obtained from the reverse order treatment which, if verified, would suggest selective cell killing by the TEM. THe chemical administered alone, was almost totally ineffective in producing recoverable translocations in stem spermatogonia. Since it is unlikely that TEM and X-rays should similarly synchronize the cell cycle of surviving stem spermatogonia it is concluded that the modified genetic responses obtained result from a different cause. Depletion of the stem-cell population is suggested as the common mediating factor. This may 'trigger' the radio-resistant, long cycling stem cells into a more active cycle such that, 24--48 h later, survivors may be highly 'synchronized' into either a sensitive cell-cycle stage or transient state preparatory to entering a shorter cell cycle to achieve repopulation. The low translocations yields obtained with longer intervals between treatments may typify the genetic response of the repopulating stem cells.

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.

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.

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.

The induction by X-rays of chromosome aberrations in male Guinea-pigs, rabbits and golden hamsters. III. Dose-response relationship after single doses of X-rays to spermatogonia

The induction by X-rays of translocations in spermatogonia was studied by cytological means in spermatocytes derived from them. In the rabbit and guinea-pig hump shaped dose-response curves were obtained, with a linear relationship at the low doses. The shapes of the curves were similar to those reported for the mouse, except that the maximum occurred at 600-700 rad in the mouse as opposed to 300 rad in the guinea-pig and rabbit. Unlike the guinea-pig and rabbit, the golden hamster showed a hump dose-response curve without a definite peak value and with little decrease in yield at high radiation doses. Over the low dose range 100-300 rad, the slopes of the curves of translocation yield were in the order:mouse (highest), rabbit, guinea-pig and hamster. Data on sterile periods suggested that the amount of spermatogonial killing in the rabbit and guinea-pig was as great or greater than in the mouse, and that in the golden hamster it was most severe. It is suggested that the differing shapes of the dose-response curves can be explained by a lower sensitivity to translocation induction in the test species and, also especially in the golden hamster, a greater sensitivity to cell killing. The possibility of extrapolating from these data to other species is discussed.