Effect on growth but not on chromosomes of the mammalian cells after treatment with three organophosphorus insecticides

A core in vitro genotoxicity battery comprising the Ames test plus the in vitro micronucleus test is sufficient to detect rodent carcinogens and in vivo genotoxins

In vitro genotoxicity testing needs to include tests in both bacterial and mammalian cells, and be able to detect gene mutations, chromosomal damage and aneuploidy. This may be achieved by a combination of the Ames test (detects gene mutations) and the in vitro micronucleus test (MNvit), since the latter detects both chromosomal aberrations and aneuploidy. In this paper we therefore present an analysis of an existing database of rodent carcinogens and a new database of in vivo genotoxins in terms of the in vitro genotoxicity tests needed to detect their in vivo activity. Published in vitro data from at least one test system (most were from the Ames test) were available for 557 carcinogens and 405 in vivo genotoxins. Because there are fewer publications on the MNvit than for other mammalian cell tests, and because the concordance between the MNvit and the in vitro chromosomal aberration (CAvit) test is so high for clastogenic activity, positive results in the CAvit test were taken as indicative of a positive result in the MNvit where there were no, or only inadequate data for the latter. Also, because Hprt and Tk loci both detect gene-mutation activity, a positive Hprt test was taken as indicative of a mouse-lymphoma Tk assay (MLA)-positive, where there were no data for the latter. Almost all of the 962 rodent carcinogens and in vivo genotoxins were detected by an in vitro battery comprising Ames+MNvit. An additional 11 carcinogens and six in vivo genotoxins would apparently be detected by the MLA, but many of these had not been tested in the MNvit or CAvit tests. Only four chemicals emerge as potentially being more readily detected in MLA than in Ames+MNvit--benzyl acetate, toluene, morphine and thiabendazole--and none of these are convincing cases to argue for the inclusion of the MLA in addition to Ames+MNvit. Thus, there is no convincing evidence that any genotoxic rodent carcinogens or in vivo genotoxins would remain undetected in an in vitro test battery consisting of Ames+MNvit.

Genetic toxicity of malathion: a review

Mammalian in vivo and in vitro studies of technical or commercial grade malathion and its metabolite malaoxon show a pattern of induction of chromosome damage, as measured by chromosome aberrations, sister chromatid exchanges, and micronuclei. Experiments with purified (> 99%) malathion gave weak or negative results. In contrast to the cytogenetic effects of technical grade malathion, responses in gene mutation assays were generally negative except for malaoxon, which was positive for mammalian gene mutations in both tested instances. This result also could be a consequence of chromosome level changes, however. Dermal exposure, a common human route, caused cytogenetic damage in test animals at doses near those producing positive results by intraperitoneal injection. Workers who apply technical grade malathion and other pesticides have higher levels of chromosomal damage than unexposed individuals. Because of the inactivity of malathion mixtures in gene mutation assays, malathion has been thought to be of little genotoxic concern. However, the pattern of chromosome damage in animals and mammalian cells in culture (including human) indicates that technical grade malathion and its components have not been adequately studied for genotoxic potential in humans.

Mutagenic evaluation of the organophosphorus insecticides methyl parathion and triazophos in Drosophila melanogaster

The possible genotoxic effects of the organophosphorus insecticides methyl parathion and triazophos were evaluated by their ability to induce gene and chromosome mutations in male germ cells of Drosophila melanogaster. Sex-linked recessive lethal (SLRL), total and partial sex-chromosome losses (SCL), and non-disjunction (ND) assays were conducted. The routes of administration included adult feeding, injection, and larval feeding. Methyl parathion was unable to induce point mutations or chromosome mutations, although a small increase in the frequency of non-disjunction was detected after larval treatment. Triazophos induced point mutations when assayed in the SLRL test and induced a weak increase in the non-disjunction frequency, but gave negative results in the SCL test.

Cytogeneticity of quinalphos and methyl parathion in human peripheral lymphocytes

1. Four different concentrations of quinalphos and methyl parathion were tested on human peripheral lymphocytes over different time periods, for the analysis of chromosomal aberrations and sister chromatid exchanges (SCEs). 2. A significant increase in chromosomal aberrations was observed when cells were treated with quinalphos for 48 and 72 h and a significant increase in SCEs was observed at all the concentrations and over all the time periods. 3. Methyl-parathion did not induce chromosomal aberrations but it did induce SCEs significantly over all time periods.

Preparation for human study of pesticide applicators: sister chromatid exchanges and chromosome aberrations in cultured human lymphocytes exposed to selected fumigants

In preparation for a human study of worker exposure to grain fumigants and pesticides, we decided to screen commonly used fumigants for genotoxic effects in vitro. This research strategy was employed to test the possibility that structurally simple chemicals might have similar genotoxic properties in vivo and in vitro. As a first step, we designed our in vitro protocol to mimic to the extent possible, a single in vivo exposure of lymphocytes to fumigants. Go lymphocytes were treated with different doses of carbon tetrachloride, carbon disulfide, methyl bromide, chloropicrin, and melathion with and without addition of rat liver homogenate for 1/2 hour, washed free of toxicant, and stimulated with PHA. After culture, the prepared slides were studied for chromosome aberrations and SCEs. Malathion, methyl bromide, and chloropicrin significantly induced SCEs without S-9. Carbon disulfide alone required S-9 for significant SCE induction. Chromosome aberrations were significantly increased by malathion and methyl bromide. Carbon tetrachloride failed to induce SCEs or chromosome aberrations with or without S-9. We concluded from these preliminary studies and other comparable work that the fumigants studied here may be less likely to express genotoxicity in terms of SCEs or chromosome aberrations than ethylene oxide or phosphine given a single short-term in vivo exposure. The final design of our human study was altered to focus on seasonal worker exposure rather than on a single exposure event.

Altered colony-forming activities of bone marrow hematopoietic stem cells in mice following short-term in vivo exposure to parathion

This paper describes a study of hematopoiesis in parathion-treated mice. Adult mice (48 C57B1/6) were given a daily dose of parathion (4 mg/kg p.o.) or corn oil vehicle (5 ml/kg p.o.) for 14 days. During the pesticide and the examination period, treated animals showed no signs of poisoning and had normal body weights. On days 2, 5, 7, 9, 12 and 14 following parathion or corn oil, femoral marrow cells were assayed in vitro for granulocyte/monocyte (CFU-gm), erythroid (CFU-e and BFU-e), megakaryocyte (CFU-meg), stromal (CFU-str) and multipotential (CFU-mix) hematopoietic stem cells. Leukocyte counts were elevated on days 2 and 5, while platelet counts were not increased until day 12. No change was observed in either hematocrits or numbers of marrow cells. BFU-e were reduced (23% of control) by day 7, then increased to 137% of control by day 14. CFU-e were reduced (41% of control) on day 9, then increased to 71% of control by day 14. CFU-mix were 130% of control (day 2), then declined to control values by day 5. On days 12 and 14, CFU-mix colonies decreased to 40% of control. CFU-str were reduced at all time points examined. CFU-gm were 123%, 136% and 130% of control on days 7, 12 and 14, respectively, while CFU-meg were increased (145% of control) on day 7. The data suggest that parathion alters the cloning potential of bone marrow precursor stem cells.

Cytogenetic effects of paraoxon and methyl-parathion on cultured human lymphocytes: SCE, clastogenic activity and cell cycle delay

Paraoxon and methyl-parathion (Wofatox), frequently used organophosphate pesticides, were tested for cytogenetic effects in lymphocytes of persons with different phenotypes of paraoxonase activity. Sister chromatid exchanges (SCE), chromosome breaks, and cell cycle traverse were studied in ten individuals. Paraoxon showed no significant effects whereas methyl-parathion showed a dose-dependent increase in the SCE and a definite delay in the cell cycle as assessed by fluorescence plus Giemsa technique. No significant clastogenic effects and no difference in response were observed among individuals with different phenotypes of paraoxonase.

Effect of malathion on nucleic acid synthesis in phytohemagglutinin-stimulated human lymphocytes

The effect of malathion, an organophosphorus insecticide, on DNA and RNA synthesis was investigated by measuring the rate of incorporation of 3H thymidine and 3H uridine, respectively, into human lymphocytes stimulated by phytohemagglutinin (PHA). Increasing concentrations of malathion, from 10 to 70 micrograms/ml, were added to human lymphocyte cultures at different times in relation to PHA introduction. The lowest applied dose of malathion (10 micrograms/ml) in most cases led to increased incorporation of both 3H thymidine and 3H uridine. Higher concentrations of malathion (30, 50, 70 micrograms/ml) caused a time- and dose-dependent decrease of radioisotope incorporation.

Effect of malathion on the genetic material of human lymphocytes stimulated by phytohemagglutinin (PHA)

This paper gives the results of studies on the effects of malathion on human lymphocytes stimulated by PHA, including cell survival, chromosomal aberration and nucleic acid content. Increasing malathion doses (10-70 micrograms/ml) were introduced into cultures of human lymphotyes at different times relative to the time of PHA addition. At a concentration of 10 micrograms/ml, malathion induced an increase in the RNA and DNA fractions in lymphocyte cultures. Higher malathion concentrations (50 and 70 micrograms/ml), especially the dose of 70 micrograms/ml, induced both a significant decrease in the content of RNA and DNA and reduced survival of cultured cells. The insecticide damaged the chromosome structure, but no correlation was revealed between the dose and the level of chromosome aberrations.