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.

Separation of specific stages of spermatids from vitamin A-synchronized rat testes for assessment of nucleoprotein changes during spermiogenesis.

Studies of the precise steps of spermiogenesis at which dramatic changes occur in the nuclear proteins have been limited by the inability to obtain sufficient quantities of these cells in narrowly defined developmental stages, especially those between steps 1 and 12. This limitation can now be overcome by vitamin A-induced synchronization of rat testes into a few stages of the seminiferous epithelial cycle. Cell suspensions from stage-synchronized rat testes were separated by centrifugal elutriation, and selected fractions were further purified on Percoll gradients. Fractions enriched in spermatids in steps 1-3, 7-8, 9-10, and 11-12 were obtained. Analysis of the basic nucleoproteins from these cells by PAGE revealed the following changes. Between steps 3 and 7, histone (H) 2A variants, H2A.1, H2A.2, and TH2A, became post-translationally modified; and during steps 9-11, H1t became modified. H4, which was monoacetylated in steps 1-3, showed maximal levels of hyperacetylation in steps 11-12. The histones were the major basic nuclear proteins in spermatids through step 12. The low levels of transition proteins 1 and 2 observed in a fraction enriched in steps 11-12 could be largely accounted for by contamination from step 13-15 spermatids. All results were consistent with those obtained from normal, unsynchronized rats. The technique of vitamin A synchronization is therefore useful in more precisely defining biochemical changes during spermiogenesis.

Embryonic effects transmitted by male mice irradiated with 512 MeV/u 56Fe nuclei.

High-energy, high-charge nuclei may contribute substantially to the yearly equivalent dose in space flight from galactic cosmic radiation (GCR) at solar minimum. The largest single heavy-ion component is 56Fe. We used the mouse embryo chimera assay to test 512 MeV/u 56Fe nuclei for effects on the rate of proliferation of embryonic cells transmitted by sperm from irradiated mice. Male CD1 mice were acutely irradiated with 0.01, 0.05 or 0.1 Gy (LET, 184 keV/micron; fluence, 3.5 x 10(4)-3.3 x 10(5) nuclei/cm2; average dose rate, 0.02 Gy/min) at the Lawrence Berkeley Laboratory BEVATRON/BEVALAC Facility in Berkeley, CA. Irradiated males were bred weekly for 7 weeks to nonirradiated females and their four-cell embryos were paired with control embryos, forming aggregation chimeras. After 30-35 h of culture, chimeras were dissociated to obtain "proliferation ratios" (number of cells contributed by the embryo from the irradiated male/total number of cells in the chimera). Significant dose-dependent decreases in proliferation ratios were obtained across all three dose groups for postirradiation week 2 (P < 0.05 to P < 0.003). The 0.01- and 0.05-Gy dose groups also produced significant decreases in proliferation ratios for postirradiation week 1 (P < 0.05 to P < 0.01) and the 0.05-Gy dose group produced significant decreases in proliferation ratios for postirradiation week 6 (P < 0.05). Postirradiation weeks 1, 2 and 6 correspond to irradiation of epididymal sperm, testicular spermatids and spermatogonia, respectively. We calculate that only about 5% of sperm in the 0.1-Gy, 2.5% in the 0.05-Gy and 0.5% in the 0.01-Gy dose groups sustained direct hits from 56Fe nuclei. However, up to 47% of sperm during postirradiation weeks 1 and 2 transmitted proliferation ratios that were at or below one standard deviation from control mean proliferation ratios. Morphometry on sectioned testes showed a significant log-linear dose response for cell killing of type B spermatogonia, which are the most radiosensitive stage of spermatogenesis and which would have been tested as mature sperm during postirradiation week 6. We conclude that amplification from secondary radiation produced in the mouse and/or from diffusible chemical products arising from hit sperm and adjacent cells contributed to the high incidence of transmitted effects on proliferation of embryonic cells.

Spermatogenesis in retinol-deficient rats maintained on retinoic acid.

Rats maintained on a diet deficient in retinol and retinoic acid were given a diet containing retinoic acid for 21-29 days after the start of weight loss. The testes of four of these rats were studied. Spermatogonia of all types were observed, though in lower numbers than in controls, and their mitotic activity was normal. Normal preleptotene spermatocytes were encountered, but no normal spermatocytes in further stages of development were seen. Pale cells that appeared to be in prophase were observed. It was concluded that, in retinol-deficient rats maintained on retinoic acid, the spermatogonial population is qualitatively normal, but quantitatively subnormal, while spermatocyte development is qualitatively and quantitatively abnormal. No evidence of spermatogonial arrest or any other form of synchronization was found in testes of these rats, but when the remaining rats were injected with retinol, the seminiferous epithelium did show stage synchronization at 36 and 128 days after the injection.

Stage-synchronized seminiferous epithelium in rats after manipulation of retinol levels.

Optimal conditions for obtaining stage-synchronization of the seminiferous epithelium were investigated. In this study, 147 rats were subjected to protocols in which vitamin A deficiency was induced by feeding a diet without retinol (R-ol) or retinoic acid (RA), followed by maintenance on a diet containing RA and supplementation of R-ol by injection and diet. An acceptable degree of stage synchronization and recovery of the seminiferous epithelium was observed in 90 (61%) of the 147 rats. The effects on synchrony of variations in the protocol, including the degree of deficiency before RA maintenance, the dose and duration of RA maintenance, and the manner of injection of R-ol, were tested. Initiation of maintenance on RA when a medium degree of deficiency was achieved (4-12 g of weight loss, 3-6 days without growth) resulted in a more reliable (80% of the rats) induction of synchrony than did initiation of maintenance on RA at either a less (70% synchronized rats) or more severe (50-60% synchronized rats) deficiency. Maintenance on food containing 10 mg/kg RA gave better and more reliable synchrony (70%) than maintenance on food containing 5 mg/kg RA (less than 40%). Although the duration of this maintenance did not influence the degree of synchrony, the reliability was lower when maintenance was continued for a month or more (54%). During the interval from 33 to 128 days after resupplementation, the degree of synchronization decreased, as did the predictability of the stages, while the restoration of spermatogenesis increased. Linear regression, performed on the location of the median point of synchronization, indicated that spermatogenesis progressed at a rate of 12.4 days per cycle. The median stage of synchronization, predicted by this regression line, differed by an average of 8% of the cycle from the actual location in individual rats. Extrapolation of the regression line indicated that spermatogenesis was reinitiated in mid-to-late stage VII.

Pathological effects of the radiation protector WR-151327 in mice.

The systemic effects of the radiation protective agent, S-3-(3-methylaminopropylamino) propylphosphorothioic acid (WR-151327), were studied in unirradiated B6CF1 male mice. Fifty mice were injected intraperitoneally with 540 mg/kg WR-151327, and groups of five mice were sacrificed at 14-day intervals up to and including 140 days post-treatment. Ten mice served as sham-injected controls. A necropsy was performed and gross morphological abnormalities were noted. Tissues (brain, eyes, harderian gland, salivary glands, sternal bone marrow, thyroid, lung, thymus, esophagus, trachea, skeletal muscle, heart, liver, kidney, adrenal gland, spleen, small intestine, pancreas, and testes) were fixed in 10% formalin, embedded in paraffin, and sectioned. Slides were routinely stained with hematoxylin and eosin while Alizarin red stain was used to test specifically for the presence of calcium salts. Histopathological effects of WR-151327 were restricted to the testes, salivary gland, and pancreas. The caudal pole of the testes was observed to undergo progressive changes from coagulation necrosis to dystrophic calcification. The cells of the submandibular salivary gland showed mainly hyperchromatic nuclei while the pancreas showed enlarged islets of Langerhans.

Symplastic spermatids (sys): a recessive insertional mutation in mice causing a defect in spermatogenesis.

A line of transgenic mice that carries an insertional mutation in a gene essential for spermatogenesis is described. Males homozygous for the transgenic insert are sterile, while female homozygotes and both male and female heterozygotes exhibit normal fertility. Developing spermatids in homozygous males form prominent abnormal multinucleated syncytia (symplasts) and do not complete maturation. In addition, abnormal cytoplasmic vacuolation is commonly seen in Sertoli cells. One flank of the transgenic integration site within the genome has been cloned and used to show linkage between homozygosity for the transgene and the mutant phenotype. The flank maps to mouse chromosome 14 approximately 4 centimorgans proximal to the gene encoding esterase-10 (Es-10). As no other gene that is known to be essential for spermatogenesis has been mapped to this region of the genome and as the mutant phenotype is unique, the transgenic insert appears to affect a previously unidentified gene. We have named the mutation "symplastic spermatids" (sys).

A method for quantifying synchrony in testes of rats treated with vitamin A deprivation and readministration.

Using a variation of a previously published method for manipulating vitamin A levels, we obtained synchronized rat testes and determined the frequency of stages of the seminiferous epithelium in each rat. In this study, we have demonstrated a method for quantitative analysis of the synchrony. The degree of synchronization was expressed as a fraction of the cycle of the seminiferous epithelium, and thus in terms not influenced by the different durations of the stages of this cycle. The median stage about which the tubules were synchronized was calculated. This method may be used to compare the effects of different synchronizing treatments, which may be subtle, and to study various aspects of spermatogenesis in the synchronized testes. For example, the duration of the cycle of the seminiferous epithelium in synchronized testes is estimated to be 12.5 days.

Probability of self-renewing divisions of spermatogonial stem cells in colonies, formed after fission neutron irradiation.

Repopulating spermatogenic colonies, found in the seminiferous epithelium after irradiation with fast-fission neutrons, were studied to determine the chance that a stem cell Asingle (As) spermatogonium would complete a self-renewing division (P). Mathematical formulas originally derived for such studies in haemopoietic colonies were employed, and a method specifically aimed at spermatogenic colonies was developed. The results showed that during the first division after irradiation, P is close to 1.0. P decreases in later generations, but remains 0.7 or higher up to the 4th or 5th divisions. The mean value for P was over 0.8, which is higher than the value of 0.6-0.7 found for stem cells in haemopoietic colonies.

Low levels of chromosomal mutations in germ cells derived from doxorubicin-treated stem spermatogonia in the mouse.

The mutagenic effects of doxorubicin (Adriamycin, ADR) on mouse spermatogonial stem cells were examined by analysis of spermatocyte chromosomes and of dominant lethality transmitted through the spermatozoa. The effects of ADR on mutations, cytotoxicity, and sperm head abnormalities were compared with those of radiation. The cytotoxic effect of 6 Gy of gamma-radiation on stem spermatogonia was equivalent to about 4-5 mg ADR/kg. Chromosomal translocations were observed in 0.6% of the spermatocytes of mice treated with ADR (2-6 mg/kg). In contrast, 6 Gy of radiation induced translocations in 11.1% of spermatocytes. No increase in dominant lethality was observed after treatment with ADR at doses up to 6 mg/kg, while the frequency after 6 Gy of radiation was 3.6%. Based on these results, ADR would be expected to be only a weak inducer of balanced chromosomal rearrangements. Because ADR at 4.5 mg/kg was much weaker than 6 Gy of gamma-radiation at inducing chromosomal translocations, but just as effective at inducing sperm head abnormalities, the level of sperm head abnormalities is not indicative of balanced chromosomal rearrangements induced in stem spermatogonia by cytotoxic agents.

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.

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).

Response to fission neutron irradiation of spermatogonial stem cells in different stages of the cycle of the seminiferous epithelium.

Mice were irradiated with 1 Gy of fission neutrons. At intervals up to 15 days after irradiation undifferentiated spermatogonia were counted in whole mounts of seminiferous tubules in up to eight stages of the epithelial cycle. From Day 6 onward lower numbers of spermatogonia were found in the areas which were in stages IV-VII during irradiation than in those which were in stages IX-II. Minimal numbers in the former area were two to six times lower than those in the latter one. Areas which were in stages III or VIII gave intermediate values. It is concluded that the epithelial cycle can be divided into two parts with a different response to irradiation, that begin or end in stages III and VIII. Part III-VIII and part VIII-III comprise 45 and 55% of the epithelial cycle, respectively. In part VIII-III control levels were found again at Day 15, while in part III-VIII spermatogonial numbers were still very low. In controls it was found that part VIII-III corresponds to a period of high proliferative activity of the stem cells, while in part III-VIII the proliferative activity is very low. This may affect their radiosensitivity and/or their proliferative behavior after irradiation, resulting in different spermatogonial numbers in the two parts of the epithelial cycle. Unlike in normal epithelium, after irradiation giant cells, odd-numbered clones (not containing 2" cells), and clones of Apr and Aal , in which the composing cells clump together, were observed.