Dose-response studies on the spermatogonial stem cells of the rhesus monkey (Macaca mulatta) after X irradiation

Studies of the dose response of the spermatogonial stem cells in the rhesus monkey were performed at intervals of 130 and 160 days after graded doses of X irradiation. The D0 of the spermatogonial stem cells was established using the total numbers of the type A spermatogonia that were present at 130 and 160 days after irradiation and was found to be 1.07 Gy; the 95% confidence interval was 0.90-1.34 Gy.     

The role of the tumor suppressor p53 in spermatogenesis

The p53 protein appeared to be involved in both spermatogonial cell proliferation and radiation response. During normal spermatogenesis in the mouse, spermatogonia do not express p53, as analyzed by immunohistochemistry. However, after a dose of 4 Gy of X-rays, a distinct p53 staining was present in spermatogonia, suggesting that, in contrast to other reports, p53 does have a role in spermatogonia. To determine the possible role of p53 in spermatogonia, histological analysis was performed in testes of both p53 knock out C57BL/6 and FvB mice. The results indicate that p53 is an important factor in normal spermatogonial cell production as well as in the regulation of apoptosis after DNA damage. First, p53 knock out mouse testes contained about 50% higher numbers of A1 spermatogonia, indicating that the production of differentiating type spermatogonia by the undifferentiated spermatogonia is enhanced in these mice. Second, 10 days after a dose of 5 Gy of X-rays, in the p53 knock out testes, increased numbers of giant sized spermatogonial stem cells were found, indicating disturbance of the apoptotic process in these cells. Third, in the p53 knock out testis, the differentiating A2-B spermatogonia are more radioresistant compared to their wild-type controls, indicating that p53 is partly indispensable in the removal of lethally irradiated differentiating type spermatogonia. In accordance with our immunohistochemical data, Western analysis showed that levels of p53 are increased in total adult testis lysates after irradiation. These data show that p53 is important in the regulation of cell production during normal spermatogenesis either by regulation of cell proliferation or, more likely, by regulating the apoptotic process in spermatogonia. Furthermore, after irradiation, p53 is important in the removal of lethally damaged spermatogonia.     

Variation in the sensitivity of the mouse spermatogonial stem cell population to fission neutron irradiation during the cycle of the seminiferous epithelium

Dose-response studies of the radiosensitivity of spermatogonial stem cells in various epithelial stages after irradiation with graded doses of fission neutrons of 1 MeV mean energy were carried out in the Cpb-N mouse. These studies on the stem cell population in stages IX-XI yielded simple exponential lines characterized by an average D0 value of 0.76 +/- 0.02 Gy. In the subsequent epithelial stages XII-III, a significantly lower D0 value of 0.55 +/- 0.02 Gy was found. In contrast to the curves obtained for stem cells in stages IX-III, the curves obtained in stages IV-VIII indicated the presence of a mixture of radioresistant and radiosensitive stem cells. In stage VII, almost no radioresistant stem cells appeared to be present and a D0 value for the radiosensitive stem cells of 0.22 +/- 0.01 Gy was derived. Previously, data were obtained on the size of colonies (in number of spermatogonia) derived from surviving stem cells. Combining these data with data from the newly obtained dose-response curves yielded the number of stem cells, per stage and with the specific radiosensitivities, present in the control epithelium. In stages IX-XI, there are approximately 6 stem cells per 1000 Sertoli cells with a radiosensitivity characterized by a D0 of 0.76 Gy, which corresponds to one-third of the As population in these stages. (The As spermatogonia are presumed to be the stem cells of spermatogenesis.) IN stages XII-III, there are approximately 12 stem cells per 1000 Sertoli cells with a radiosensitivity characterized by a D0 of 0.55 Gy, which roughly equals the number of A single spermatogonia in these stages. These calculations could not be made for stages IV-VIII since no simple exponential lines were obtained for these stages. In view of the pattern of the proliferative activity of the spermatogonial stem cells during the epithelial cycle, it appears that the stem cell population is most radiosensitive during the period when the majority of these cells are in G0 phase, most resistant when the cells are stimulated again into proliferation, and of intermediate sensitivity during active proliferation.     

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.     

The sensitivity of quiescent and proliferating mouse spermatogonial stem cells to X irradiation.

The radiosensitivity of spermatogonial stem cells to X rays was determined in the various stages of the cycle of the seminiferous epithelium of the CBA mouse. The numbers of undifferentiated spermatogonia present 10 days after graded doses of X rays (0.5-8.0 Gy) were taken as a measure of stem cell survival. Dose-response relationships were generated for each stage of the epithelial cycle by counting spermatogonial numbers and also by using the repopulation index method. Spermatogonial stem cells were found to be most sensitive to X rays during quiescence (stages IV-VII) and most resistant during active proliferation (stages IX-II). The D0 for X rays varied from 1.0 Gy for quiescent spermatogonial stem cells to 2.4 Gy for actively proliferating stem cells. In most epithelial stages the dose-response curves showed no shoulder in the low-dose region.     

Germ cell and dose-dependent DNA damage measured by the comet assay in murine spermatozoaa after testicular X-irradiation

The single-cell gel electrophoresis (Comet) assay has been widely used to measure DNA damage in human sperm in a variety of physiological and pathological conditions. We investigated the effects of in vivo radiation, a known genotoxin, on spermatogenic cells of the mouse testis and examined sperm collected from the vas deferens using the neutral Comet assay. Irradiation of differentiating spermatogonia with 0.25-4 Gy X-rays produced a dose-related increase in DNA damage in sperm collected 45 days later. Increases were found when measuring Comet tail length and percentage of tail DNA, but the greatest changes were in tail moment (a product of tail length and tail DNA). Spermatids, spermatocytes, differentiating spermatogonia, and stem cell spermatogonia were also irradiated in vivo with 4 Gy X-rays. DNA damage was indirectly deduced to occur at all stages. The maximum increase was seen in differentiating spermatogonia. DNA damaged cells were, surprisingly, still detected 120 days after stem cell spermatogonia had been irradiated. The distribution of DNA damage among individual sperm cells after irradiation was heterogeneous. This was seen most clearly when changes in the Comet tail length were measured when there were discrete undamaged and damaged populations. After increasing doses of irradiation, an increasing proportion of cells were found in the damaged population. Because a proportion of undamaged sperm cells remains after all but the highest dose, the possibility of normal fertility remains. However, fertilization with a spermatozoa carrying high amounts of DNA damage could lead to effects as diverse as embryonic death and cancer susceptibility in the offspring.     

Nonrandom distribution of mouse spermatogonial stem cells surviving fission neutron irradiation

Colony formation by surviving spermatogonial stem cells was investigated by mapping pieces of whole mounted tubuli at intervals of 6 and 10 days after doses of 0.75 and 1.50 Gy of fission neutron irradiation. Colony sizes, expressed in numbers of spermatogonia per colony, varied greatly. However, the mean colony size found in different animals was relatively constant. The mitotic indices in large and small colonies and in colonies in different epithelial stages did not differ significantly. This finding suggests that size differences in these spermatogenic colonies are not caused by differences in growth rate. Apparently, surviving stem cells start to form colonies at variable times after irradiation. The number of colonies per unit area varied with the epithelial stages. Many more colonies were found in areas that during irradiation were in stages IX-III (IX-IIIirr) than in those that were in stages IV-VII (IV-VIIirr). After a dose of 1.50 Gy, 90% of all colonies were found in areas IX-IIIirr. It is concluded that the previously found difference in repopulation after irradiation between areas VIII-IIIirr and III-VIIIirr can be explained not by differences in colony sizes and/or growth rates of the colonies in these areas but by a difference in the number of surviving stem cells in both areas. In area XII-IIIirr three times more colonies were found after a dose of 0.75 Gy than after a dose of 1.50 Gy. In area IV-VIIirr the numbers of colonies differed by a factor of six after both doses. This finding indicates that spermatogonial stem cells are more sensitive to irradiation in epithelial stages IV-VII than in stages XII-III. In control material, spermatogonia with a nuclear area of 70-110 micron2 are rare. However, especially 6 days after irradiation, single cells of these dimensions are rather common. These cells were found to lie at random over the tubular basement membrane with no preference for areas with colonies. It is concluded that the great majority of these cells were not or do not derive from surviving stem cells. These enlarged cells most likely represent lethally injured cells that will die or become giant cells (nuclear area greater than 110 micron2).     

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

The radiosensitivity of spermatogonial stem cells of C3H/HeH × 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 VIII_irr, during quiescence, the spermatogonial stem cells were most radiosensitive with a D₀ of 1.4 Gy. In stages XI_irr−V_irr, 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^τD, with τ = 1 for the sensitive and τ = 0.1 for the resistant spermatogonial stem cells, with a maximal e^τD of 100.     

Morphology and cell population kinetics of primary spermatogonia in the frog (Rana esculenta) (Amphibia: Anura)

Two morphologically distinct primary spermatogonial cell types were observed in the frog testis and distinguished on the basis of nuclear characteristics. They have been designated the pale and dark types of primary spermatogonia. On the basis of a kinetic analysis, it is proposed that the pale spermatogonia possess the faculty of self-renewal as well as that of forming dark spermatogonia; they are thus bipotential stem cells comparable to the undifferentiated type of mammalian spermatogonia. The dark spermatogonia, in contrast, are committed to a single pathway, i.e. to form secondary sperrnatogonia, and can be defined as differentiated or committed elements of the primary spermatogonial population. The number of stem cell spermatogonia and differentiated spermatogonia vary according to the period of the year, as does the rate of turnover of stem cells, with nearly 60–90% of cells temporarily out of the cell cycle at any given time. It is indicated that the spermatogonial population represents a 'cell renewal system' in a steady state for appreciably long periods of time, however, changing with season in as far as the magnitude of yield of spermatogonial cells is concerned. This implies that an equality should exist between the rate at which stem cells enter cell-cycling and the rate at which daughter cells change their morphological identity.     

Protection from radiation-induced male germ cell loss by sphingosine-1-phosphate

Male germ cells are susceptible to radiation-induced injury, and infertility is a common problem after total-body irradiation. Here we investigated, first, the effects of irradiation on germ cells in mouse testis and, second, the role of sphingosine-1-phosphate (S1P) treatment in radiation-induced male germ cell loss. Irradiation of mouse testes mainly damaged the early developmental stages of spermatogonia. The damage was seen by means of DNA flow cytometry 21 days after irradiation as decreasing numbers of spermatocytes and spermatids with increasing amounts of ionizing radiation (0.1-2.0 Gy). Intratesticular injections of S1P given 1-2 h before irradiation (0.5 Gy) did not protect against short-term germ cell loss as measured by in situ end labeling of DNA fragmentation 16 h after irradiation. However, after 21 days, in the S1P-treated testes, the numbers of primary spermatocytes and spermatogonia at G2 (4C peak as measured by flow cytometry) were higher at all stages of spermatogenesis compared with vehicle-treated testes, indicating protection of early spermatogonia by S1P, whereas the spermatid (1C) populations were similar. In conclusion, S1P appears to protect partially (16%-47%) testicular germ cells against radiation-induced cell death. This warrants further studies aimed at development of therapeutic agents capable of blocking sphingomyelin-induced pathways of germ cell loss.     

Gamma-ray exposure accelerates spermatogenesis of medaka fish,Oryzias latipes

To examine the spermatogenesis (and spermiogenesis) cell population kinetics after gamma-irradiation, the frequency and fate of BrdU-labeled pre-meiotic spermatogenic cells (spermatogonia and pre-leptotene spermatocytes) and spermatogonial stem cells (SSCs) of the medaka fish (Oryzias latipes) were examined immunohistochemically and by BrdU-labeling. After 4.75 Gy of gamma-irradiation, a statistically significant decrease in the frequency of BrdU-labeled cells was detected in the SSCs, but not in pre-meiotic spermatogenic cells. The time necessary for differentiation of surviving pre-meiotic spermatogenic cells without delay of germ cell development was shortened. More than 90% of surviving pre-meiotic spermatogenic cells differentiated into haploid cells within 5 days after irradiation, followed by a temporal spermatozoa exhaust in the testis. Next, spermatogenesis began in the surviving SSCs. However, the outcome was abnormal spermatozoa, indicating that accelerated maturation process led to morphological abnormalities. Moreover, 35% of the morphologically normal spermatozoa were dead at day 6. Based on these results, we suggest a reset system; after irradiation most surviving spermatogenic cells, except for the SSCs, are prematurely eliminated from the testis by spermatogenesis (and spermiogenesis) acceleration, and subsequent spermatogenesis begins with the surviving SSCs, a possible safeguard against male germ cell mutagenesis.     

Quantitative analysis of male germline stem cell differentiation reveals a role for the p53-mTORC1 pathway in spermatogonial maintenance

p53 protects cells from DNA damage by inducing cell-cycle arrest upon encountering genomic stress. Among other pathways, p53 elicits such an effect by inhibiting mammalian target of rapamycin complex 1 (mTORC1), the master regulator of cell proliferation and growth. Although recent studies have indicated roles for both p53 and mTORC1 in stem cell maintenance, it remains unclear whether the p53-mTORC1 pathway is conserved to mediate this process under normal physiological conditions. Spermatogenesis is a classic stem cell-dependent process in which undifferentiated spermatogonia undergo self-renewal and differentiation to maintain the lifelong production of spermatozoa. To better understand this process, we have developed a novel flow cytometry (FACS)-based approach that isolates spermatogonia at consecutive differentiation stages. By using this as a tool, we show that genetic loss of p53 augments mTORC1 activity during early spermatogonial differentiation. Functionally, loss of p53 drives spermatogonia out of the undifferentiated state and causes a consistent expansion of early differentiating spermatogonia until the stage of preleptotene (premeiotic) spermatocyte. The frequency of early meiotic spermatocytes is, however, dramatically decreased. Thus, these data suggest that p53-mTORC1 pathway plays a critical role in maintaining the homeostasis of early spermatogonial differentiation. Moreover, our FACS approach could be a valuable tool in understanding spermatogonial differentiation.     

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.     

Bcl-2 inhibits apoptosis of spermatogonia and growth of spermatogonial stem cells in a cell-intrinsic manner

The growth, differentiation, and death/survival of spermatogonia are precisely regulated for the proper production of spermatozoa. We have previously shown that Bcl-2 ectopically expressed in spermatogonia caused the inhibition of normal spermatogonial apoptosis and the subsequent failure of differentiation in transgenic mice. In addition, the growth of spermatogonial stem cells seemed to be temporally arrested in the transgenic mice. In the present study, we attempted to examine whether the abnormality of spermatogonia described above was caused by Bcl-2 misexpression in the spermatogonia or by an abnormal spermatogenic environment of the transgenic mice. We transplanted testicular cells of transgenic mice to seminiferous tubules of W/Wv mice in which transplanted normal testicular cells can undergo spermatogenesis. We found that the transplanted spermatogonia of the transgenic mice reproduced a series of abnormal changes including temporal growth arrest of spermatogonial stem cells and abnormal accumulation of spermatogonia in tubules, which were also observed in the testes of the transgenic mice. The results indicated that Bcl-2 inhibited apoptosis of spermatogonia and growth of spermatogonial stem cells in a cell-intrinsic manner. We also cultured testicular cells of transgenic mice and found that the spermatogonia of the transgenic mice were better able to survive than were those of wild-type mice but that their differentiation was not affected. The result suggested that failure of differentiation of the accumulated spermatogonia in the transgenic testes is not due to the abnormality of the bcl-2 misexpressing spermatogonia, but may be caused by extrinsic problems including improper interaction of spermatogonia with supporting cells.     

Radioprotective effect of misoprostol on mouse spermatogonial stem cells

The radioprotective effects of misoprostol, a synthetic stable analogue of prostaglandin E1, on spermatogonial stem cells of C3H/HeH x 101/F1 hybrid mice (3H1) were analysed by establishing dose--response relationships for stem cell killing by X-rays in mice that were pretreated with misoprostol. Spermatogonial stem cell killing was studied through determination of the percentage of tubular cross-sections showing repopulation at 10 days after irradiation. In control mice, the D0 values ranged between 1.7 and 3.6 Gy, dependent on the stage of the cycle of the seminiferous epithelium the cells were in. As found previously, proliferating spermatogonial stem cells were much more radioresistant than quiescent stem cells. In the misoprostol-pretreated animals the spermatogonial stem cells were more radioresistant, the D0 values ranging from 3.6 to 5.0 Gy. Both proliferating and quiescent spermatogonial stem cells were protected by misoprostol. As the dose--response curves in control and misoprostol-pretreated mice showed about the same extrapolation number to the y-axis it was concluded that the misoprostol pretreatment did not alter the kinetics of the repopulation process.     

Effects of lithium chloride as a potential radioprotective agent on radiation response of DNA synthesis in mouse germinal cells

Mouse spermatogonial germ cells are highly sensitive to ionizing radiation. Lithium salts are reported to stimulate the postirradiation recovery of hematopoietic marrow cells. We have, therefore, examined whether administered lithium chloride (LiCl) would also be able to protect the mouse germinal cells against radiation injury. Taking DNA synthesis as an endpoint, our results show that the testicular DNA-specific activity in irradiated mice was higher by 61% on average when they had been pretreated with LiCl both 24 h and 1 h prior to γ-irradiation (2.0 Gy). It was also observed that the DNA synthetic activity in the germinal cells fully recovered after LiCl pretreatment at doses of 40 mg per kg body weight prior to total body irradiation of 0.05–0.25 Gy, whereas at doses of 0.5–6.0 Gy, following the same procedure of LiCl pretreatment, only an incomplete recovery was observed. The dose reduction factor for LiCl is 1.84. The current findings indicate that pretreatment with LiCl provides considerable protection against radiation damage in mouse spermatogonia. Received: 18 October 1996 / Accepted in revised form: 3 April 1997     

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.     

Dorsomorphin Promotes Survival and Germline Competence of Zebrafish Spermatogonial Stem Cells in Culture

Zebrafish spermatogonial cell cultures were established from Tg(piwil1:neo);Tg(piwil1:DsRed) transgenic fish using a zebrafish ovarian feeder cell line (OFC3) that was engineered to express zebrafish Lif, Fgf2 and Gdnf. Primary cultures, initiated from testes, were treated with G418 to eliminate the somatic cells and select for the piwil1:neo expressing spermatogonia. Addition of dorsomorphin, a Bmp type I receptor inhibitor, prolonged spermatogonial stem cell (SSC) survival in culture and enhanced germline transmission of the SSCs following transplantation into recipient larvae. In contrast, dorsomorphin inhibited the growth and survival of zebrafish female germline stem cells (FGSCs) in culture. In the presence of dorsomorphin, the spermatogonia continued to express the germ-cell markers dazl, dnd, nanos3, vasa and piwil1 and the spermatogonial markers plzf and sox17 for at least six weeks in culture. Transplantation experiments revealed that 6 week-old spermatogonial cell cultures maintained in the presence of dorsomorphin were able to successfully colonize the gonad in 18% of recipient larvae and produce functional gametes in the resulting adult chimeric fish. Germline transmission was not successful when the spermatogonia were cultured 6 weeks in the absence of dorsomorphin before transplantation. The results indicate that Bmp signaling is detrimental to SSCs but required for the survival of zebrafish FGSCs in culture. Manipulation of Bmp signaling could provide a strategy to optimize culture conditions of germline stem cells from other species.