N. de Vogel

Ctrogenetic effects of mutagens/carcinogens after activation in a microsomal system in vitro I. Induction of chromosome aberrations and sister chromatid exchanges by diethylnitrosamine (DEN) and dimethylnitrosamine (DMN) in CHO cells in the presence of rat-liver microsomes

A rat-liver microsomal system in vitro has been used to activate two indirectly acting carcinogens, DMN and DEN. On activation, both compounds were extremely potent in inducing chromosomal aberrations as well as sister chromatid exchanges in Chinese hamster cells. The implications of these findings and the potential utility of this technique to detect mutagens/carcinogens are discussed.

A micronucleus method for detection of meiotic micronuclei in male germ cells of mammals

A new rapid micronucleus method is presented for the detection of chromosomal damage induced in spermatocyte stages of mammals. Analysis of micronuclei is done in early spermatids that have been isolated from testis tubules in a special testis isolation medium supplemented with enzymes (collagenase, trypsin and DNAase).

The induction of chromosomal damage in rat hepatocytes and lymphocytes I. Time-dependent changes of the clastogenic effects of diethylnitrosamine, dimethylnitrosamine and ethyl methanesulfonate

Male Wistar rats received a single injection of diethylnitrosamine (DEN), dimethylnitrosamine (DMN) or ethyl methanesulfonate (EMS). After a number of time intervals (up to 56 days) liver cells were assayed for the presence of possible preclastogenic damage by performing partial hepatectomy and subsequent analysis of chromosomal damage (micronucleus formation) in isolated hepatocytes. Peripheral blood lymphocytes from the same animals were collected, stimulated to proliferate and assayed for the frequency of sister-chromatid exchanges (SCEs). Whereas all agents significantly increased frequencies of SCEs in lymphocytes up to at least 28 days (EMS) or 56 days (DMN, DEN) after injection, only the latter 2 compounds gave rise to significantly increased incidences of micronucleated hepatocytes. DMN-induced preclastogenic damage in hepatocytes was lost between 28 and 56 days after injection. After DEN, this type of damage was persistent over the entire experimental period (56 days). When rats treated with DEN did not undergo partial hepatectomy, the frequencies of micronuclei at different time intervals after treatment were at control level. This result, together with those from hepatectomized DEN-treated rats, suggests that it is the persistent character of the preclastogenic damage that is responsible for the occurrence of micronucleated hepatocytes at later time intervals after treatment with DEN, rather than the stability of micronuclei which might eventually have been formed soon after injection.

Antimutagenicity of eugenol in the rodent bone marrow micronucleus test

The antimutagenic effect of eugenol on the mutagenicity of cyclophosphamide (CP), mitomycin C (MMC), ethyl methanesulfonate (EMS) and benzo[a]pyrene (B[a]P) was assessed in the rodent bone marrow micronucleus test using male Swiss mice. Oral administration of eugenol (0.4% in the diet) for 15 days was found to decrease significantly the frequency of micronucleated polychromatic erythrocytes (MPEs) elevated by CP. No effect was found on the frequency of MPEs elevated by MMC, EMS and B[a]P. The results provide some support for antimutagenic potency of eugenol in vivo.

Differential persistence of chromosomal damage induced in resting rat-liver cells by X-rays and 4.2-MeV neutrons

Rats were exposed to 400 rad X-rays or 100 rad 4.2-MeV neutrons and subjected to partial hepatectomy at 1 day, 1 week, 1 month or 3 months after irradiation. 2 or 3 days later the remaining liver was perfused and isolated hepatocytes were screened for micronuclei in the cytoplasm. Frequencies of micronucleated hepatocytes following X-irradiation decreased with increasing time intervals after irradiation, the frequency at 3 months being not significantly different from the control value. Following neutron irradiation, frequencies of micronuclei remained constant at all time intervals tested. In the case of X-irradiation, the progressive decrease in frequencies of micronuclei may be explained by 2 mechanisms operating simultaneously: (i) slow long-term repair of chromosomal damage and (ii) mitotic selection against cells carrying substantial amounts of chromosomal damage. Both mechanisms do not seem to operate in the case of neutron irradiation. For both types of radiation, the dose-effect relationship was linear in the ascending part of the dose-effect curves. The dose-effect curve plateaud at 400 rad X-rays and 50 rad neutrons. The RBE value for 4.2 MeV neutrons in the ascending part of the dose-effect curves was about 4.

A correlative study on the genetic damage induced by chemical mutagens in bone marrow and spermatogonia of mice.: III. 1,3-Bis (2-chloroethyl)-3-nitrosourea (BCNU)

Cytogenetic damage induced by various concentrations of BCNU was evaluated by determining the frequencies of (a) micronuclei in polychromatic erythrocytes of bone marrow, (b) chromatid aberrations in bone marrow, (c) chromatid aberrations in spermatogonia, and (d) reciprocal translocations induced in spermatogonia and scored in spermatocytes. The order of sensitivity for the four parameters tested was: micronuclei greater than chromatid aberrations in bone marrow greater than aberrations in spermatogonia greater than translocations in spermatocytes, a situation similar to that found in an earlier study with CNU-ethanol. When the effect of concentration of the chemical was taken into consideration there was no correlation among the four parameters tested, so that information on induced frequencies of one parameter does not have predictive value for the frequencies of the others. A comparison of the results obtained with the bifunctional BCNU and the mono-functional CNU-ethanol at equal concentrations indicated that BCNU had a similar or a lesser clastogenic effect than did CNU-ethanol. In an experiment in vitro the situation was different in that BCNU was more effective than CNU-ethanol.

The induction of sex-chromosomal nondisjunction and diploid spermatids following x-irradiation of pre-spermatid stages in the northern vole Microtus oeconomus.

Chromosome nondisjunction seems to be one of the most important mutagenic effects occurring in man and makes an enormous contribution to human foetal wastage. As yet, little or no information is available on which environmental factors are important in inducing nondisjunction and accordingly we have investigated the effect of X-irradiation on inducing nondisjunction in male germ cells of an experimental mammal, the Northern vole-Microtus oeconomus. Using a staining technique based upon the presence of heterochromatin we have scored the number of sex chromosomes in early spermatids in both irradiated and unirradiated animals. A significant increase in nondisjunction, following treatment, was found with all doses between 25 and 200 R. However, variations in nondisjunction induction at various time intervals following irradiation suggest variations in cell stage sensitivity. More surprising was the large induction of diploid gametes which also demonstrated a significant induction with all irradiation doses. From the distribution of sex chromosomes we conclude that both nondisjunction and diploid gamete induction occur at both meiotic divisions. At present it is not possible to conclude whether the radiation response is linear and to define the cell-stage sensitivity with precision. The reasons for this appear to be variations in sensitivity between animals and also that there is a clear overlap between the duration of the early spermatid stage analyzed (4 days) and the interval between sampling times.

Changes in erythropoiesis due to radiation or chemotherapy as studied by flow cytometric determination of peripheral blood reticulocytes

SummaryFlow cytometric determination of time dependent changes of numbers of reticulocytes in peripheral blood were investigated as a parameter for changes in erythropoiesis induced by radiation- or chemotherapy. Rats irradiated or treated with drugs (such as e.g. cyclo-phosphamide 100 mg/kg, vincristin 0.2 mg/kg, or mitomycin C 1.0 mg/kg) showed clear changes in erythropoietic activity. Reticulocyte numbers decreased rapidly until day 3–4 after treatment; this period was followed by a gradual increase and normal control values were seen at day 8–11. Radiation effects of doses as low 0.5 Gy could be detected in such a way.Similar studies were performed with patients with ovarian tumors treated with cis-platinum, a drug that may cause non-immune haemolysis. During prolonged treatment some patients showed increasing numbers of reticulocytes, measured at the first day of each hospitalization period, whereas leucocyte and platelet counts stayed more or less constant. Increasing numbers of reticulocytes generally indicates stimulation of erythropoietic activity of the bone marrow (due to increased blood loss); in this study increasing numbers often preceeded a decrease in hemoglobin values later on.Flow cytometric analysis of reticulocytes is therefore a potentially useful tool to detect changes in erythropoiesis, and considered more sensitive for the early recognition of patients that develop anemia, than hemoglobin measurements only.

Further studies on effects of X-irradiation on prespermatid stages of the Northern vole Microtus oeconomus: Low induction of sex-chromosomal nondisjunction and very high induction of diploid spermatids

Microtus males have been irradiated with X-ray doses of 25, 50, 100 and 200 rad and early spermatids were then analyzed for evidence of induction of sex-chromosomal nondisjunction and diploid spermatids at 1, 4, 6, 7, 9 and 12 days after treatment. In contrast to earlier findings, there was no induction of nondisjunction above control levels. A possible explanation for the differences in results of old and new experiments might be that genetic changes have taken place in the Microtus colony that was initiated with animals trapped in the wild, but which has now become highly inbred. In the present experiment, diploid spermatids were frequently induced. The dose--effect relationships at the different time intervals were linear, but the slopes were different, indicating stage-specific differences in sensitivity. The average doubling dose is of the order of 12 rad with a range of 5-30 rad for the individual time intervals. When diploid spermatozoa in man are also inducible by such low doses of X-rays, the consequence would be an increase of triploid abortions which would constitute an undesirable form of personal or family hardship.

The response of spermatogonia and spermatocytes of the Northern vole Microtus oeconomus to the induction of sex-chromosome nondisjunction, diploidy and chromosome breakage by X-rays and fast fission neutrons

Microtus males were exposed to different doses of 250 kV X-rays or fast fission neutrons of 1 MeV mean energy. Early (= round) spermatids were analyzed for the presence of extra sex chromosomes, diploidy and micronuclei at different time intervals corresponding with treated differentiating spermatogonia and spermatocytes. Induction of nondisjunction of sex chromosomes could not be detected. In contrast, induction of diploids by both types of radiation was statistically significant at all sampling times. Dose-effect relationships for most of the sampling times were linear and sometimes linear-quadratic concave upward or downward. There were pronounced stage-specific differences in sensitivity as reflected by differences in doubling doses that ranged from 4 to 22 cGy for X-rays and from 0.4 to 4 cGy for neutrons. Spermatocytes at pachytene were the most sensitive cells and proliferating spermatogonia the least sensitive ones. The relative biological effectiveness (RBE) of neutrons depended on the cell stage treated and fluctuated between 1.4 and 9.2. Evidence for radiation-induced chromosomal breakage events was obtained via detection of micronuclei. Induction of micronuclei by X-rays or neutrons was statistically significant at all spermatocyte stages tested. There was no effect in spermatogonia. With a few exceptions dose-effect relationships were linear. Differences in stage sensitivity were clearly present as evidenced by doubling dose which ranged from 5 to 29 cGy for X-rays and from 1 to 3 cGy for neutrons. RBE values varied from 5.2 to 12.7. Maximum sensitivity was detected in spermatocytes at diakinesis, MI and MII. Resting primary spermatocytes (G1 and S phase) were somewhat less sensitive and actively proliferating spermatogonia were the least sensitive cells. The pattern of stage sensitivity for induction of diploids was distinctly different from that for induction of chromosomal breakage.