Difference in the response of two hybrid stocks of mice to X-ray induction of chromosome aberrations in spermatogonial stem cells

Ionizing radiation induces balanced reciprocal translocations in spermatogonial stem cells of mice. From cells carrying these rearrangements, which can be scored cytologically in the diakinesis-metaphase I stage, balanced normal, balanced translocated and unbalanced (duplication/deficiency) sperm can be produced. The relationship between expected (calculated from cytological data) and observed frequencies of embryonic lethality (presumably as a result of unbalanced sperm fertilizing the egg) following exposure of spermatogonial stem cells to X-rays was studied in two hybrid stocks. A marked difference in the incidence of induced embryonic lethality was found between the two stocks. Similarly, a difference in the cytological frequencies of translocations was also found, although smaller than that observed for embryonic lethality. Thus, it appears that the difference between the two stocks in the frequencies of embryonic lethality may be attributable both to processes occurring prior to metaphase I and to a difference in the rate of transmission of unbalanced chromosome constitutions.     

The induction by X-rays of chromosome aberrations in male Guinea-pigs and golden hamsters. IV. Dose response for spermatogonia treated with fractionated doses.

The effect of dose fractionation on the induction of translocations by 400 and 600 rad X-rays in spermatogonia of guinea-pigs and hamsters was investigated cytologically. Three types of fractionation were used, dividing the dose into (a) two equal fractions 24 h apart, (b) two equal fractions 8 weeks apart, and (c) eight or twelve equal fractions of 50 rad, at intervals of one week. The two species responded similarly throughout, but gave lower translocation yields than the mouse. The effects of the first and third types of fractionation were similar to those described previously in the mouse, and suggested that a first radiation dose modifies the spermatogonial population so that its sensitivity to a dose 24 h later is altered, and that repeated radiation doses result in development of resistance to translocation induction. After 8-week fractionation the results suggested that in guinea-pigs and hamsters the spermatogonial population had not returned to normal by 8 weeks after the first dose, whereas in the mouse normal sensitivity had returned by this time. The results, reported previously, of single doses of X-rays suggest that the spermatogonial population consists of fractionated doses in the mouse suggest that the sensitive and resistant types represent different phases of the same cell type rather than two distinct types of cell. In the guinea-pig and hamster this question remains open.     

Radiation-induced translocations in spermatogonial stem cells of Macaca fascicularis and Macaca mulatta

3 adult monkeys, one Macaca fascicularis and two Macaca mulatta, were whole-body irradiated with 1 Gy gamma-rays (60 Co). Reciprocal translocations induced in spermatogonial stem cells were scored as translocation multivalents in primary spermatocytes from 7.5 to 27.5 months after exposure. The translocation yields ranged from 4.1% at the earliest to 1.8% at the latest sampling interval. No significant differences were observed in the responses of the individual animals. A decline in the translocation frequencies with time after treatment was found in all 3 animals. The present data are different from those reported for testicular X-irradiation of the rhesus monkey Macaca mulatta (van Buul, 1980; Lyon et al., 1976) in that the translocation yields are higher. They are consistent with the results reported for testicular gamma-irradiation of the crab-eating monkey Macaca fascicularis (Matsuda et al., 1984, 1985). In view of the present results it appears unlikely that a species difference exists within the genus Macaca in the sensitivity of spermatogonial stem cells to the induction of translocations by ionizing radiation.     

Expanded simple tandem repeat (ESTR) mutation induction in the male germline: lessons learned from lab mice

Expanded simple tandem repeat (ESTR) DNA loci that are unstable in the germline have provided the most sensitive tool ever developed for investigating low-dose heritable mutation induction in laboratory mice. Ionizing radiation exposures have shown that ESTR mutations occur mainly in pre-meiotic spermatogonia and stem cells. The average spermatogonial doubling dose is 0.62-0.69 Gy for low LET, and 0.18-0.34 Gy for high LET radiation. Chemical alkylating agents also cause significant ESTR mutation induction in pre-meiotic spermatogonia and stem cells, but are much less effective per unit dose than radiation. ESTR mutation induction efficiency is maximal at low doses of radiation or chemical mutagens, and may decrease at higher dose ranges. DNA repair deficient mice (SCID and PARP-1) with elevated levels of single and double-strand DNA breaks have spontaneously elevated ESTR mutation frequencies, and surprisingly do not show additional ESTR mutation induction following irradiation. In contrast, ESTR mutation induction in p53 knock-outs is indistinguishable from that of wild-type mice. Studies of sentinel mice exposed in situ to ambient air pollution showed elevated ESTR mutation frequencies in males exposed to high levels of particulate matter. These studies highlight the application of the ESTR assay for assessing environmental hazards under real-world conditions. All ESTR studies to date have shown untargeted mutations that occur at much higher frequencies than predicted. The mechanism of this untargeted mutation induction is unknown, and must be elucidated before we can fully understand the biological significance of ESTR mutations, or use these markers for formal risk assessment. Future studies should focus on the mechanism of ESTR mutation induction, refining dose responses, and developing ESTR markers for other animal species.     

Transmitted mutational events induced in mouse germ cells following acrylamide or glycidamide exposure

An increase in the germ line mutation rate in humans will result in an increase in the incidence of genetically determined diseases in subsequent generations. Thus, it is important to identify those agents that are mutagenic in mammalian germ cells. Acrylamide is water soluble, absorbed and distributed in the body, chemically reactive with nucleophilic sites, and there are known sources of human exposure. Here we review all seven published studies that assessed the effectiveness of acrylamide or its active metabolite, glycidamide, in inducing transmitted reciprocal translocations or gene mutations in the mouse. Major conclusions were (a) acrylamide is mutagenic in spermatozoa and spermatid stages of the male germ line; (b) in these spermatogenic stages acrylamide is mainly or exclusively a clastogen; (c) per unit dose, i.p. exposure is more effective than dermal exposure; and (d) per unit dose, glycidamide is more effective than acrylamide. Since stem cell spermatogonia persist and may accumulate mutations throughout the reproductive life of males, assessment of induced mutations in this germ cell stage is critical for the assessment of genetic risk associated with exposure to a mutagen. The two specific-locus mutation experiments which studied the stem cell spermatogonial stage yielded conflicting results. This discrepancy should be resolved. Finally, it is noted that no experiments have studied the mutagenic potential of acrylamide to increase the frequency of transmitted mutational events following exposure in the female germ line.     

Transmitted mutational events induced in mouse germ cells following acrylamide or glycidamide exposure

An increase in the germ line mutation rate in humans will result in an increase in the incidence of genetically determined diseases in subsequent generations. Thus, it is important to identify those agents that are mutagenic in mammalian germ cells. Acrylamide is water soluble, absorbed and distributed in the body, chemically reactive with nucleophilic sites, and there are known sources of human exposure. Here we review all seven published studies that assessed the effectiveness of acrylamide or its active metabolite, glycidamide, in inducing transmitted reciprocal translocations or gene mutations in the mouse. Major conclusions were (a) acrylamide is mutagenic in spermatozoa and spermatid stages of the male germ line; (b) in these spermatogenic stages acrylamide is mainly or exclusively a clastogen; (c) per unit dose, i.p. exposure is more effective than dermal exposure; and (d) per unit dose, glycidamide is more effective than acrylamide. Since stem cell spermatogonia persist and may accumulate mutations throughout the reproductive life of males, assessment of induced mutations in this germ cell stage is critical for the assessment of genetic risk associated with exposure to a mutagen. The two specific-locus mutation experiments which studied the stem cell spermatogonial stage yielded conflicting results. This discrepancy should be resolved. Finally, it is noted that no experiments have studied the mutagenic potential of acrylamide to increase the frequency of transmitted mutational events following exposure in the female germ line.     

Serial analysis of chromosomal aberrations and proliferation kinetics of mouse spermatogonia after single or fractionated X-ray exposures

Dose-fractionation studies on translocation induction in stem-cell spermatogonia of mice, as measured by spermatocyte analysis many cell generations after irradiation, revealed that a small conditioning dose of X-rays sensitizes the stem cells to the induction of translocations by a second dose 24 h later (Van Buul and Léonard, 1974, 1980). To find out whether such sensitization effects also occur at other spermatogonial stages, a comparison was made of the effects of single (50, 100 and 150 rad) and fractionated (100 + 50 rad, with 24 h in between) doses of X-rays on the induction of chromosomal aberrations in spermatogonia by analysing spermatogonial metaphases shortly after irradiation at multiple sampling times (0–48 h; every 4 h). In addition, the kinetics of spermatogonial proliferation was studied by using, in vivo, a BrdU chromosome-labelling procedure. The recorded frequencies of chromosomal aberrations did not indicate any sensitization effect of dose fractionation. It is concluded that the sensitization effects, as observed for chromosomal aberrations in male premeiotic germ cells, are characteristic for the stem-cell spermatogonia and do not occur in the more differentiated spermatogonia.     

Increased frequency of chromosome translocations associated with diagnostic x-ray examinations

Informative studies of cancer risks associated with medical radiation are difficult to conduct owing to low radiation doses, poor recall of diagnostic X rays, and long intervals before cancers occur. Chromosome aberrations have been associated with increased cancer risk and translocations are a known radiation biomarker. Seventy-nine U.S. radiologic technologists were selected for blood collection, and translocations were enumerated by whole chromosome painting. We developed a dose score to the red bone marrow for medical radiation exposure from X-ray examinations reported by the technologists that they received as patients. Using Poisson regression, we analyzed translocations in relation to the dose scores. Each dose score unit approximated 1 mGy. The estimated mean cumulative red bone marrow radiation dose score was 42 (range 1-265). After adjustment for age, occupational radiation, and radiotherapy for benign conditions, translocation frequencies significantly increased with increasing red bone marrow dose score with an estimate of 0.007 translocations per 100 CEs per score unit (95% CI, 0.002 to 0.013; P = 0.01). Chromosome damage has been linked with elevated cancer risk, and we found that cumulative radiation exposure from medical X-ray examinations was associated with increased numbers of chromosome translocations.     

Inhibition of ADP-ribosylation increases X-ray-induced chromosomal damage in mouse testis and bone-marrow cells in vivo

The effect of 3-aminobenzamide (3AB) treatment on chromosomal radiosensitivity of mouse spermatogonial stem cells and bone-marrow cells was studied using various doses of X-rays. The results show that 3AB increases the induction of reciprocal translocations in slowly cycling spermatogonia as well as the frequency of chromosomal aberrations in actively dividing bone-marrow cells. The experiments indicate that both types of tissue are suitable to study the ability of inhibitors of ADP-ribosylation to modulate chromosome-breaking damage induced by ionizing radiation in vivo.     

Induction of congenital malformations in the offspring of male mice treated with X-rays at pre-meiotic and post-meiotic stages

The induction of congenital malformations among the offspring of male mice treated with X-rays at pre-meiotic and post-meiotic stages has been studied in two experiments. Firstly, animals were exposed to varying doses (108–504 cGy) of X-rays and mated at various time intervals (1–7, 8–14, 15–21 and 64–80 days post-irradiation), so as to sample spermatozoa, spermatids and spermatogonial stem cells. In the second experiment, only treated spermatogonial stem cells were sampled. One group of males was given a single 500-cGy dose, a second group a fractionated dose (500 + 500 cGy, 24 h apart) and a third group was left unexposed.In the first experiment, induced post-implantation dominant lethality increased with dose, and was highest in week 3, in line with the known greater radiosensitivity of the early spermatid stage. Preimplantation loss also increased with dose and was highest in week 3. There was no clear induction of either pre-implantation or post-implantation loss at spermatogonial stem cell stages.There was a clear induction of congenital malformations at post-meiotic stages, the overall incidence being 2.0 ± 0.32% in the irradiated series and 0.24 ± 0.17% among the controls. The induction was statistically significant at each dose. At the two highest doses the early spermatids (15–21 days) appeared more sensitive than spermatozoa, and at this stage the incidence of malformations increased with dose. The data from Expt. 1 on the induction of malformations by irradiation of spermatogonial stages were equivocal. In contrast, Expt. 2 showed a statistically significant induction of malformations at both dose levels (2.2 ± 0.46% after 500 cGy and 3.1 ± 0.57% after 500 + 500 cGy). The relative sensitivities of male stem cells, post-neiotic stages and mature oocytes to the induction of congenital malformations were reasonably similar to their sensitivities for specific-locus mutations, except that the expected enhancing effect of the fractionation regime used was not seen.Dwarfism and exencephaly were the two most commonly observed malformations in all series.     

X-ray induced translocations in premeiotic germ cells of monkeys

The induction of reciprocal translocations by various X-ray exposures was studied in spermatogonial stem cells of rhesus monkeys (Macaca mulatta) and stump-tailed macaques (Macaca arctoides) by means of spermatocyte analysis many cell generations after irradiation. The yields of translocations recovered from irradiated stump-tailed macaques were lower than those observed in rhesus monkeys and represent in fact the lowest induction rates per Gy ever recorded for experimental mammals. In the rhesus monkey a humped dose-effect relationship was found with (a) a homogeneous response with (pseudo-)linear kinetics below 1 Gy, (b) much more variability at higher doses, and (c) no induction at all at doses of 4 Gy and above. It is suggested that the post-irradiation proliferation differentiation pattern of surviving rhesus monkey spermatogonial stem cells i mainly responsible for these characteristics of the dose-response curve.     

Distributions of cell populations within alpha-particle range of plutonium deposits in the rat and beagle testis

Plutonium is not uniformly distributed in testicular tissues; thus some cell populations may receive larger or smaller radiation exposures than would be expected if the nuclide were uniformly distributed. The distributions of cell populations within alpha-particle range of Pu deposits in rat and beagle testes were determined. The data were collected from autoradiographs of testicular tissues containing 241Pu. A cell distribution factor (CDF) was determined for each cell population and is defined as the average number of each cell type within alpha-particle range of each observed Pu deposit relative to the number of each cell type that would be expected within alpha-particle range of each Pu deposit, if the deposits were distributed uniformly. In addition, the percentage of the spermatogonial stem cell population within alpha-particle range of Pu deposits was determined. In rats, the CDF for the spermatogonial stem cells is about 2.2. This value is similar to other enhancement and inhomogeneity factors reported for rodents in the literature. In beagles the CDFs to all cells in the seminiferous epithelium were less than the rats. In addition, the percentage of spermatogonial cells within alpha-particle range of Pu concentrations in the interstitial tissues was a factor of about 3 less in the dog than in the rat. The largest CDFs seen in both species were in the interstitial tissues, particularly for Leydig cells. Because the organization of testicular tissues in the beagle is quite different from rodents but more similar to human, the results from this study suggest that extrapolations from rodents to humans may tend to overestimate the potential for radiation exposure to spermatogonial stem cells as well as the fraction of the spermatogonial stem cell population at risk to exposure from internally deposited 239Pu.     

Retrospective biodosimetry among United States radiologic technologists

Measurement of chromosome translocations in peripheral blood lymphocytes has been used to quantify prior exposure to ionizing radiation, including for workers exposed to low, chronic doses. We assessed translocation frequencies in a subset of U.S. radiologic technologists to substantiate ionizing radiation dose estimates developed for 110,418 technologists who worked between 1916 and 1984. From 3,441 cohort members known to have begun working before 1950, we selected a sample of 152, stratified by estimated cumulative dose, over-sampling from higher-dose categories and excluding persons with a prior cancer diagnosis, a personal or family history of chromosomal instability disorders, or a current history of smoking. Estimates of film-badge dose ranged from less than 10 cSv to more than 30 cSv. Blood samples, obtained in 2004, were analyzed by fluorescence in situ hybridization (FISH) whole chromosome painting by simultaneously labeling chromosomes 1, 2 and 4 in red and 3, 5 and 6 in green. Translocations were scored in 1800 well-spread metaphase cells and expressed per 100 cell equivalents (CE) per person. Linear Poisson regression models with allowance for overdispersion were used to assess the relationship between estimated occupational red bone marrow absorbed dose in cGy and translocation frequency, adjusted for age, gender and estimated red bone marrow absorbed dose score from personal diagnostic procedures. We observed 0.09 excess translocations per 100 CE per cGy red bone marrow dose (95% CI: -0.01, 0.2; P = 0.07), which is similar to the expected estimate based on previous cytogenetic studies (0.05 excess translocations per 100 CE per cGy). Despite uncertainty in the estimates of occupational red bone marrow absorbed doses, we found good general agreement between the doses and translocation frequencies, lending support to the credibility of the dose assessment for this large cohort of U.S. radiologic technologists.     

Difference between two hybrid stocks of mice in the incidence of congenital abnormalities following X-ray exposure of stem-cell spermatogonia

Unbalanced (duplication/deficiency) sperm from balanced reciprocal translocations induced in spermatogonial stem cells of mice generally lead to embryonic lethality around the time of implantation. In a recent study (Generoso et al., 1985), it was found that the incidence of X-ray-induced embryonic lethality differed markedly between two hybrid stocks of irradiated male mice. A parallel difference in the frequencies of reciprocal translocations was observed cytologically in the meiocytes of irradiated males. In the present report, which is an adjunct to the study by Generoso et al. (1985), it was determined whether or not similar differences between the two stocks exist for congenital defects resulting from genetic damage to stem-cell spermatogonia. The results indicate not only an association between the frequencies of induced reciprocal translocations and congenital abnormalities, but also a parallel greater frequency of induced malformations in the (C3H × 101)F1 stock versus the (SEC × C57BL)F1 stock of males.     

γ-Ray-induced reciprocal translocations in spermatogonia of the crab-eating monkey (Macaca fascicularis)

The yield of translocations induced by γ-rays in the crab-eating monkey (Macaca fascicularis) spermatogonia were studied by cytological analysis in spermatocytes derived from them. The frequencies of translocations were 0.09% at 0 Gy, 1.9% at 1 Gy, 2.5% at 2 Gy and 1.3% at 3 Gy, showing a humped dose-response curve with a peak yield around 2 Gy. No remarkable inter-seasonal or inter-animal variations in the induction of translocation were observed. The frequencies in the crab-eating monkey were significantly higher than those in the same Macaca genus, the rhesus monkey (Macaca mulatta) (van Buul, 1976, 1980). This inter-species difference in radiosensitivity might be affected by the condition of spermatogonial stem cells at the time of exposure to radiation, depending on the seasonal change in spermatogenetic activity.     

Congenital defects in the offspring of male mice treated with ethylnitrosourea

Daily doses of ENU (25-100 mg/kg) were injected intraperitoneally into ICR strain male mice for 5 days. The males were mated to untreated virgin females of the same strain on days 1-16 and 64-80 after the last dose. Copulations during these periods involve, respectively, treated postmeiotic cells and spermatogonial stem cells. The uterine contents were examined on day 18 of pregnancy for evidence of dominant lethal effects. The fetuses were examined for external and skeletal abnormalities. ENU treatment of either postmeiotic cells or spermatogonial stem cells caused dose-dependent significant increases in the incidence of abnormal fetuses over the control level. The induction rate per live fetus per unit dose in mg/kg by treating spermatogonial stem cells was estimated to be 1.0 X 10(-4), which is 3-fold lower than the rate previously estimated for the same endpoint at the same germ cell stage with MNU. Cleft palate was the most frequent external abnormality in the ENU-treated and the control series. Malformed vertebrae was the most frequent skeletal abnormality in the treated series. Rib fusion was the only skeletal malformation seen in the control series. Dominant lethals were clearly induced when germ cells were treated as postmeiotic cells.     

Translocations induced by fast neutrons and X-rays in Delia antiqua

Summary A comparison was made using X-rays and fast neutrons for the induction of translocations in Delia antiqua. Using the same radiation dose, no difference in efficiency between the two radiation types could be observed. However, with fast neutrons many multiple translocations were induced, including a quadruple translocation involving 4 out of 5 autosomes. One male linked translocation was also induced.The reciprocal translocations were assigned into two classes: symmetrical and asymmetrical, and ten of the latter were chosen for inbreeding to produce homozygotes. Asymmetrical exchanges were chosen so that translocation homozygotes could be differentiated cytologically from the normal karyotype. In seven different translocations, homozygous larvae were observed, but often at a low frequency. In four of these lines, viable adult homozygotes were observed. Subsequent random sib-crossing failed to produce a homozygous line.     

The induction of reciprocal translocations in rhesus monkey stem-cell spermatogonia: effects of low doses and low dose rates

The induction of reciprocal translocation in rhesus monkey spermatogonial stem cells was studied following exposure to low doses of acute X rays (0.25 Gy, 300 mGy/min) or to low-dose-rate X rays (1 Gy, 2 mGy/min) and gamma rays (1 Gy, 0.2 mGy/min). The results obtained at 0.25 Gy of X rays fitted exactly the linear extrapolation down from the 0.5 and 1.0 Gy points obtained earlier. Extension of X-ray exposure reduced the yield of translocations similar to that in the mouse by about 50%. The reduction to 40% of translocation rate after chronic gamma exposure was clearly less than the value of about 80% reported for the mouse over the same range of dose rates. Differential cell killing with ensuing differential elimination of aberration-carrying cells is the most likely explanation for the differences between mouse and monkey.     

The characterization and transmissibility of chromosome aberrations induced in peripheral blood lymphocytes by in vitro alpha-particle radiation

Peripheral blood lymphocytes were irradiated in vitro with (213)Bi alpha particles at doses of 0, 10, 20, 50, 100, 200 and 500 mGy. Chromosome analysis was performed on 47-h cultures using single-color fluorescence in situ hybridization (FISH) to paint chromosomes 1, 3 and 5. The whole genome was analyzed for unstable aberrations to derive aberration frequencies and determine cell stability. The dose response for dicentrics was 33.60 +/- 0.47 x 10(-2) per Gy. A more detailed analysis revealed that the majority of aberrations scored as dicentrics were part of complex/multiple aberrations, with the proportion of cells containing complexes increasing with dose. Cells containing aberrations involving painted chromosomes (FISH aberrations) were further classified according to cell stability and complexity. The majority of cells with FISH aberrations were unstable. The proportion of aberrant FISH cells with complex/multiple aberrations ranged from 56% at 10 mGy to 89% at 500 mGy. A linear dose response for genomic frequencies of translocations in stable cells fitted the data from 0 to 200 mGy with a dose response of 7.90 +/- 0.98 x 10(-2) per Gy, thus indicating that they are likely to be observed in peripheral blood lymphocytes from individuals with past or chronic exposure to high-LET radiation. Comparisons with the dose response for low-LET radiation suggest an RBE of 13.6 for dicentrics in all cells and 3.2 for translocations in stable cells. Since stochastic effects of radiation are attributable to genetic changes in viable cells, translocations in stable cells may be a better measure when considering the comparative risks of different qualities of radiation.     

X-ray induced translocations in spermatogonia. I. Dose and fractionation responses in mice

The frequency of recirprocal translocations, inducedm by X-irradiation of mouse spermatogonial cells and observed at diakinesis-metaphase I in primary spermatocytes, was measured over a dose range of 0–1200 R. The resulting dose-response curve gave a best fit to the model Y = bD+CD² over the range of 0–500 R. Above 600 R, howeverm, the yeild of translocations decreased with increasing dose, leadiong to a “humped” dose-response curve over the whole dose range studied, as has been observed by several worker previously.The significance of the nonlinear dose-response curve over the lower dose range is discussed in terms of the known fractionation and dose-rate effects for reciprocal translocations induced in spermatogonia.A dose of 800 R was split into two 400-R fractions separated by 8 weeks, or one of 1200 R into three equal parts, each separated by an 8-week interval. The resulting yield of translocations was the same as the sum of two, or three, separate 400-dose doses, but was much higher than a single dose of 800 R or 1200 R.It is suggested that these results, namely the shape of the dose-response curve and the “reverse” fractionation effect, can be explained in terms of resistant and sensitive stem-cell populations, but that any one cell can be in either population, depending upon the stage of the cell cycle in which it is at the time of irradiation.