Analysis of morphometric indices in mice for registration of induced mutations in germ cells

The new-born mice of the first generation have been examined for changes in morphometric indices after the influence of fopurine, cyclophosphamide and cadmium chloride on their fathers. It is shown that fopurine and cyclophosphamide, the mutagens for mammals, increase the variability of morphometric indices. The method to calculate the morphometric indices of mice may be used for evaluating genetic risk of the compounds for man.     

Chemical induction of presumed dominant-lethal mutations in postcopulation germ cells of mice. I. Relative sensitivity between pre- and postcopulation germ cells to isopropyl methanesulfonate

Females from ($\text{C}\text{3}\text{H}\text{×}\text{IOI}\text{)}\text{F}{}_1$ and a mixed stock were injected intraperitoneally with either 25 or 50 mg/kg isopropyl methanesulfonate (IMS) or Hanks' solution 4.5 h after the midpoint of the dark period during which mating occurred. It was determined that at the time of treatment the great majority of oocytes were undergoing second meiotic division. For comparison, the same doses of IMS were given to females treated within 3.5 days prior to mating (predominantly dictyate oocytes) or to males treated within 4.5 days prior to mating (sperm in vas and epididymis). The frequencies of presumed dominant lethals induced by 50 mg/kg IMS in sperm treated in vas and epididymis, dictyate oocytes, and germ cells in mated females are 22%, 19%, and 79%, respectively, for (C3H × IOI)F₁ and 26%, 30%, and 76% for the other stock. Clearly, in both stocks, effects in mated females, when both female and male germ cells were treated, are relatively much higher than the added effects on dictyate oocytes and spermatozoa. This is also true for the 25 mg/kg dose.     

Aging of male germ line stem cells in mice

In the present study, we investigated the effect of aging on spermatogonial stem cells (SSCs) and on the testicular somatic environment in ROSA26 mice. First, we examined testis weights at 2 mo, 6 mo, 1 yr, and 2 yr of age. At 1 and 2 yr, bilateral atrophied testes were observed in 50% and 75% of the mice, respectively; the rest of the mice had testis weights similar to those of young mice. Next, we evaluated the number and the activity of aged SSCs using spermatogonial transplantation. Numbers of SSCs in atrophied testes decreased in an age-dependent manner to as low as 1/60 of those in testes of young mice. Numbers of SSCs in nonregressed testes were similar regardless of age. The colony length, which is indicative of the potential of SSCs to regenerate spermatogenesis, was similar with donor cells from atrophied testes of 1-yr-old mice and those from testes of young mice, suggesting that SSCs remaining in 1-yr atrophied testes were functionally intact. Colonies arising from SSCs derived from 2-yr atrophied testes were significantly shorter, however, indicating that both SSC numbers and activity declined with age. Finally, we transplanted donor cells from young animals into 1- and 2-yr atrophied testes. Although the weight of 2-yr testes did not change after transplantation, that of 1-yr testes increased significantly, indicating that 1-yr, but not 2-yr, atrophied testes are permissive for regeneration of spermatogenesis by SSCs from young mouse testes. These results demonstrate that both SSCs and somatic environment in the testis are involved in the aging process.     

Antimutagenic effects on male germ cells of mice

The alkylating agent cyclophosphamide (CPA) and the antioxidant ethoxyquin (EQ) were administered perorally to NMRI mice. The strong clastogenic action of CPA on spermatogonia was diminished by simultaneous doses of EQ. Higher doses of the antioxidant produced greater anticlastogenic action. Furthermore, the action of the mutagen and the antioxidant on the late spermatids and the spermatozoa was observed using the dominant lethal test. The antioxidant had only a weak influence on these postmeiotic stages.     

Mutagenicity of Ascaris chymotrypsin inhibitor in germ cells of mice

Chymotrypsin inhibitor isolated from Ascaris suum (ACHI) was tested for the induction of dominant lethal mutations in male mice. Dominant lethal effects of ACHI for the main stages of germ cell development were analyzed by mating at specific time points after dosing. Two groups of adult BALB/c males received 24 or 40 mg per kilogram body weight (BW) per day intraperitoneal (IP) injection of ACHI in sterile phosphate-buffered saline (PBS) for five consecutive days (subacute exposure). Males from a third group were administered single IP injections of ACHI—60 mg/kg BW (acute exposure). The control group received concurrent injections of PBS for five successive days. After the last dose, each male was mated with two untreated females. For fractionated examination with regard to successive germ cell stages (spermatozoa, spermatids, spermatocytes, spermatogonia), every second week, two other untreated virgin females were placed with each male for mating. The uteri of the females were inspected on the 15th day of gestation, and preimplantation loss and postimplantation loss determined from dominant lethal parameters. Exposure of mice germ cells to ACHI did not impair mating activity of males. Fertility index was reduced (P < 0.05) only for females mated at the third week with males exposed to the highest dose of ACHI. In the females bred to ACHI-treated males, significant (P < 0.05) increase in preimplantation loss was observed at postinjection weeks 1 (reflecting exposure to spermatozoa after single treatment and to spermatozoa or late spermatids after subacute dosing) and 3 (reflecting exposure to mid and early spermatids for acute dosing and to mid and early spermatids or late spermatocytes following acute treatment), regardless of dose and length of exposure to the inhibitor. At the 60-mg/kg-BW group, a significant increase of this parameter was also noted at week 5 (reflecting exposure to early spermatocytes). During mating days 15–21, a significant (P < 0.05) increase in postimplantation loss and dominant lethal effects were observed for all doses of ACHI. Acute ACHI exposure 5 weeks prior to mating resulted in dominant lethal effects in early spermatocytes. These preliminary data suggest that ACHI induces dominant lethal mutations at postmeiotic and meiotic stages of spermatogenesis, but spermatids are the most sensitive cell stage to the effect of ACHI. These results show that ACHI may be one of the factors causing disturbances in spermatogenesis leading to a reduction of host reproductive success.     

Studies on the induction of histocompatibility gene mutations in germ cells of mice by chemical mutagens and/or virus-inducing compounds

This work continues earlier studies concerning the use of histocompatibility mutations in mammalian germ cells as a mutagenicity test system (H test). The rate of spontaneous H mutations was re-examined using a new basis for the classification of H mutants. This procedure led to very high frequencies of suspected spontaneous H mutants: among C57Bl/6 mice, 6% and among C3H mice, 9%. F₂ hybrids of a cross between these strains revealed 1% suspected H mutants. Using the same procedure, the sensitivity of the H test was examined with the mutagens ethylnitrosourea, benzo[a]pyrene, 2-acetylaminofluorene (2-AAF), with the solvent dimethyl sulfoxide (DMSO) and with the antibacterial nitrofurantoin. It was possible to demonstrate the mutagenic potential of all mutagens tested as well as their specific action on the different stages of male germ cell development. We succeeded in demonstrating the mutagenicity of 2-AAF for the first time in germ cells of a mammal. In contrast to the negative result with benzopyrene (BP) in the specific locus test, BP induced H mutants even at the very low dose of 2 mg/kg. DMSO was found to induce H mutations in spermatogonia. This extraordinary result is possibly due to the virus-inducing properties of this compound. Nitrofurantoin which is often used in treating bacterial infections of the urinary tract in humans showed a very stage-specific action on maturing spermatids. The value of the H test for mutagenicity testing is discussed with respect to its sensitivity and economy. The very high spontaneous frequency of suspected H mutants and the ease of inducing incraased mutant frequencies by mutagens and by DMSO suggest the possibility that the majority of the histoincompatibilities found in the H test are due to induced antigenic gene products of endogenous viruses. This, however, does not interfere with the applicability of the H test for mutagenicity testing, but rather seems to augment its sensitivity to alkylating mutagens as well as mutagens which probably cause frameshift mutations.Other tests for mutations and/or inherited tumor proneness using mouse germ cells can easily be combined with the H test, because the test animal does not have to be killed, thus reducing the cost of the test.     

Male differentiation of germ cells induced by embryonic age-specific Sertoli cells in mice

Retinoic acid (RA) is a meiosis-inducing factor. Primordial germ cells (PGCs) in the developing ovary are exposed to RA, resulting in entry into meiosis. In contrast, PGCs in the developing testis enter mitotic arrest to differentiate into prospermatogonia. Sertoli cells express CYP26B1, an RA-metabolizing enzyme, providing a simple explanation for why XY PGCs do not initiate meios/is. However, regulation of entry into mitotic arrest is likely more complex. To investigate the mechanisms that regulate male germ cell differentiation, we cultured XX and XY germ cells at 11.5 and 12.5 days postcoitus (dpc) with an RA receptor inhibitor. Expression of Stra8, a meiosis initiation gene, was suppressed in all groups. However, expression of Dnmt3l, a male-specific gene, during embryogenesis was elevated but only in 12.5-dpc XY germ cells. This suggests that inhibiting RA signaling is not sufficient for male germ cell differentiation but that the male gonadal environment also contributes to this pathway. To define the influence of Sertoli cells on male germ cell differentiation, Sertoli cells at 12.5, 15.5, and 18.5 dpc were aggregated with 11.5 dpc PGCs, respectively. After culture, PGCs aggregated with 12.5 dpc Sertoli cells increased Nanos2 and Dnmt3l expression. Furthermore, these PGCs established male-specific methylation imprints of the H19 differentially methylated domains. In contrast, PGCs aggregated with Sertoli cells at late embryonic ages did not commit to the male pathway. These findings suggest that male germ cell differentiation is induced both by inhibition of RA signaling and by molecule(s) production by embryonic age-specific Sertoli cells.     

Mutagenic evaluation of propranolol in somatic and germ cells of mice

The mutagenic effect of an antihypertensive drug, propranolol, was studied on somatic and germ cells of Swiss albino mice. The induction of a significant increase in the frequency of micronuclei in erythrocytes was observed at higher dose levels, whereas, in germ cells, propranolol failed to induce significant chromosomal aberrations at any dose tested.     

Reciprocal translocations in germ cells of male mice receiving external gamma-irradiation

Data reported in the literature up to 1985 on reciprocal translocation induction in male mouse germ cells by external gamma-ray doses ranging from 0.5 to 6.0 Gy delivered at fixed dose rates were analyzed. On the assumption of a non-threshold linear dose response, zero effect at zero dose, and a center of distribution lying on an approximately straight line, calculations were made of linear regression coefficients. These coefficients (b), as a function of the dose rate (P), were well fitted by two straight lines: b = (3.15 +/- 0.59 log P) X 10(-6) for dose rates from 0.01 to 0.1 mGy/min; and b = (7.52 +/- 3.86 log P) X 10(-6) for dose rates ranging from 0.06 to 1.2 X 10(3) mGy/min. The intersection point of these two lines determined the so-called threshold level of the dose rate, namely, 4.6 X 10(-2) mGy/min, at which the effectiveness of external gamma-irradiation is not expected to exceed 2.36 X 10(-6)/mGy. In addition, experiments were undertaken in which yields were recorded of reciprocal translocations in germ cells of male mice exposed to 0.9 Gy of gamma-radiation at dose rates ranging from 6.14 X 10(-3) to 6.14 X 10(2) mGy/min (6 levels); comparisons were made with data published up to 1985 from similar studies using other fixed doses. To do this, translocation yields were expressed as relative yields (F) and their relationship to the dose rate (P) for the individual fixed doses was represented by an equation of the type: F = alpha + beta log P. For most of the equations, the regression coefficients were in good agreement and a single relationship was obtained to represent them. From the analysis performed it follows that, within the 0.6-6.0 Gy dose range, the pattern of the F vs. P relationship is unaffected by the dose. This supports the initial assumption that for the dose range up to 6.0 Gy the dose response for the reciprocal translocation yield is a non-threshold straight-line relationship.     

X chromosome reactivation initiates in nascent primordial germ cells in mice

During primordial germ cell (PGC) development, epigenetic reprogramming events represented by X chromosome reactivation and erasure of genomic imprinting are known to occur. Although precise timing is not given, X reactivation is thought to take place over a short period of time just before initiation of meiosis. Here, we show that the cessation of Xist expression commences in nascent PGCs, and re-expression of some X-linked genes begins in newly formed PGCs. The X reactivation process was not complete in E14.5 PGCs, indicating that X reactivation in developing PGCs occurs over a prolonged period. These results set the reactivation timing much earlier than previously thought and suggest that X reactivation may involve slow passive steps.     

Induction of specific-locus mutations in male germ cells of the mouse by acrylamide monomer

Acrylamide monomer (AA), injected into male mice at the maximum tolerated dose of 5 x 50 mg/kg (24-h intervals), significantly increased the specific-locus mutation rate in certain poststem-cell stages of spermatogenesis, but not in spermatogonial stem cells. Germ-cell stages in which the treatment induced dominant lethals--namely, exposed spermatozoa and late spermatids (number of surviving offspring only 3% and 27%, respectively, of those in concurrent controls)--jointly yielded the highest frequency of specific-locus mutations. AA thus conforms to Pattern 1 in our earlier classification of chemicals according to the spermatogenic stage at which they elicit maximum response (Russell et al., 1990). No specific-locus mutations were observed among 17,112 offspring derived from exposed spermatogonial stem cells, a result which rules out (at the 5% significance level) an induced mutation rate greater than 2.3 times the historical control rate. A sustained high productivity in matings made for several months following week 3 indicates that there is no significant spermatogonial killing and that cell selection is presumably not the explanation for the negative result. On the basis of genetic and/or cytogenetic evidence, the mutations induced postmeiotically by AA were 'large lesions' (multi-locus), while one of 2 recovered from exposure of differentiating spermatogonia is probably a small lesion. An earlier survey of mammalian mutagenesis results led us to conclude that, regardless of the classification of a chemical according to the stage at which it elicits its maximum response, the nature of mutations is determined by the germ-cell stage in which they are induced (Russell et al., 1990). The AA results on lesion size and on distribution of mutations among the loci fit the general pattern.     

Using embryonic stem cells to introduce mutations into the mouse germ line

It is now possible, through the use of a number of experimental technologies, to transfer genetic information into mouse embryos to stably alter the genetic constitution of mice. This experimental approach, namely the generation of so-termed "transgenic" animals, is affording new insights into a wide variety of biological problems. This review focuses on one system for the generation of transgenic mice, which utilizes tissue culture cell lines of embryonic stem cells, termed ES cells. The remarkable property of ES cells is that they retain the potential to reform an embryo; when they are replaced inside a carrier embryo, they resume normal development and contribute to all the tissues of the live-born chimeric animal. Recent experiments, using a repertoire of gene transfer techniques, have shown that ES cells are amenable to a variety of experimental manipulations in tissue culture. Moreover, it has been demonstrated that these genetically altered cells can be transferred into the germ line of chimeric mice, thus allowing the production of unique strains of animals for study. The applications of the ES cell system are reviewed, with particular emphasis on their use for the generation of random insertional mutations using a retrovirally mediated mutagenesis approach. Finally, the use of ES cells in conjunction with the recently described technique of homologous recombination, or "gene targeting," is discussed. This technology allows the generation of animals carrying extremely precise genetic modifications of endogenous genes.     

Transplantation of male germ line stem cells restores fertility in infertile mice

Azoospermia or oligozoospermia due to disruption of spermatogenesis are common causes of human male infertility. We used the technique of spermatogonial transplantation in two infertile mouse strains, Steel (Sl) and dominant white spotting (W), to determine if stem cells from an infertile male were capable of generating spermatogenesis. Transplantation of germ cells from infertile Sl/Sld mutant male mice to infertile W/Wv or Wv/W54 mutant male mice restored fertility to the recipient mice. Thus, transplantation of spermatogonial stem cells from an infertile donor to a permissive testicular environment can restore fertility and result in progeny with the genetic makeup of the infertile donor male.     

Arsenic trioxide inhibition of the thiophosphamide induction of mutations in mouse germ and somatic cells

After single i. p. injection of arsenic trioxide, at the dosage range of 1/4 to 1/40 LD50 into hybrid mice (CBA X C57B1/6J)F1, no induction of dominant lethals in male germ cells was observed. However, it led to an increase in the number of micronuclei in the erythrocytes of bone marrow. Treatment with the effective dose of thioTEPA, causing an increase in the number of dominant lethals in male germ cells and in the number of micronuclei in the erythrocytes of bone marrow, followed by injection of arsenic trioxide, resulted in inhibition of the mutagenic activity of thioTEPA. This inhibition increased proportionally with the dose of arsenic trioxide.     

Cytotoxic and genotoxic effects of methotrexate in germ cells of male Swiss mice

Methotrexate (MTX) is an anti-metabolite drug widely used in the treatment of neoplastic disorders, rheumatoid arthritis and psoriasis. Developed as an analogue of folic acid, it inhibits purine and pyrimidine synthesis that accounts for its therapeutic efficacy as well as for its toxicities. MTX has narrow therapeutic index and its toxicity has been reported in various organ systems including gastrointestinal, haematologic and central nervous system. The objective of the present study is to investigate the germ cell toxicity induced by MTX in male Swiss mice. MTX was administered intraperitoneally (ip) at the doses of 5, 10, 20 and 40mg/kg to mice (20-25g) weekly once (wk) for 5 and 10 weeks. The animals were sacrificed 1 week after receiving the last treatment of MTX. The germ cell toxicity was evaluated using testes weight (wt), sperm count, sperm head morphology, sperm comet assay, histology, TUNEL and halo assay in testis. MTX treatment significantly reduced the sperm count and increased the occurrence of sperm head abnormalities in a dose dependent manner. It induced the testicular toxicity as evident from the histology of testis. Sperm comet, TUNEL and halo assay in testis also revealed significant DNA damage after MTX treatment. On the basis of the present study, it can be concluded that MTX induced germ cell toxicity in mice.     

Mutagenic profiles of carbazole in the male germ cells of Swiss albino mice

Mutagenic effect of carbazole was evaluated by employing dominant lethal mutation and sperm head abnormality assays in male Swiss albino mice. For the dominant lethal mutation assay, adult male mice were treated for five consecutive days either with 30 or 60 mg/kg body weight (b.w.) of carbazole by single intraperitoneal (i.p.) injection. For the sperm head abnormality assay mice were treated with 50, 100, 150, 200 and 300 mg/kg b.w as a single i.p. injection. Treatment of adult male mice with carbazole resulted in induction of dominant lethal mutation and abnormal sperm heads. The results show that carbazole is mutagenic in male germ cells of mice.     

Gene trap insertional mutagenesis in mice: New vectors and germ Line mutations in two novel genes

Insertional mutagenesis based on gene trap vectors that capture endogenous splice sites is a promising tool for functional genomics. Several groups have proposed large-scale gene trap screens, but questions remain as to the type of vectors and their design. We report a set of plasmid-encoded gene trap vectors and the disruption of two novel genes. Our results include a comparison of the relative gene trapping efficiencies of two different splice acceptor sequences in ES cells and an analysis of the structure of several gene trap insertions.