Chromosome painting analysis of spontaneous and methyl methanesulfonate-induced trifluorothymidine-resistant L5178Y cell colonies

3'-azido-3'-deoxythymidine induces deletions in L5178Y mouse lymphoma cells

3'-Azido-3'-deoxythymidine (AZT), a nucleoside analogue used for the treatment of acquired immunodeficiency syndrome (AIDS), induced a significant dose-related increase in the thymidine kinase (Tk) mutant frequency (MF) in L5178Y/Tk(+/-) 3.7.2C mouse lymphoma cells. Treatment with 1 mg/ml (3,742 muM) AZT for 24 hr resulted in a MF of 407 x 10(-6) compared to a control MF of 84 x 10(-6). The MFs of the large and small colony mutants resulting from AZT exposure were 142 x 10(-6) and 265 x 10(-6), respectively. One hundred and fifty mutants from the 1 mg/ml (3,742 muM) AZT-treated culture and sixty-nine mutants from independent untreated cultures were isolated and analyzed. LOH analysis using a heteromorphic microsatellite locus located in the Tk gene was performed to determine the presence or absence of the Tk(+) allele. Eight other microsatellite markers spanning the entire mouse chromosome 11 also were examined for heterozygosity to determine the extent of LOH. In addition, Tk gene dosage analysis was conducted using Real-Time PCR in those mutants showing LOH at the Tk locus. The presence of only one Tk allele based on Real-Time PCR indicated that the mutant resulted from deletion while the presence of two alleles was consistent with a recombination event. More mutants from the AZT-treated culture showed Tk LOH than did independent mutants from the untreated cultures (91% vs. 64%) and the induced mutants also showed distinct chromosome 11 LOH patterns. The mutation spectrum of mutants from AZT-treated cells was also significantly different from that of spontaneous mutants. More deletions and fewer intragenic mutations were observed in the mutants from the AZT-treated culture than independent mutants from the untreated control. Our data indicate that AZT primarily induced LOH mutations in L5178Y mouse lymphoma cells and a large number of LOH mutations resulted from deletions.

Genotoxicity screening: the slow march to the future

Genetic toxicology testing in drug discovery and development is slowly moving into the age of high-throughput screening (HTS). This has been helped by the development of new tools, as well as validation studies and data analysis to support their use in hit-to-lead or lead optimisation decisions. This review provides an overview of the current genetic toxicology methodologies and a few HTS methodologies. Comparisons are made between the predictivity of carcinogenesis that can be achieved in screening strategies as well as by the battery of regulatory tests. The importance of false-positive and false-negative calls at different stages in development is considered. There is a good prospect that in genetic toxicology, as in other areas of ADME-Tox, HTS will reduce the growing costs of carrying compounds with undesirable characteristics too far along the drug development process.

Genotoxicity and carcinogenicity studies of soy isoflavones

The potential cancer preventive efficacy of soy isoflavones is being investigated in preclinical and phase 1 clinical studies sponsored by the U.S. National Cancer Institute. Although 90-day oral toxicity studies with PTI G-2535 (an investigational soy isoflavone drug product) in rats and dogs, as well as teratology studies, indicated no signs of toxicity, there remains a mechanistic concern associated with the ability of isoflavones (i.e., genistein) to inhibit topoisomerase, possibly leading to DNA strand breaks. The present report describes results from two in vitro genotoxicity studies, one in vivo genotoxicity study, and a single carcinogenicity study conducted in p53 knockout mice. Bacterial mutagenesis experiments using six tester strains without metabolic activation revealed no evidence that PTI G-2535 was mutagenic. In similar experiments with exogenous metabolic activation there were statistically significant increases in revertants, but less than twofold, in a single (Salmonella typhimurium TA100) tester strain. Mouse lymphoma cell mutagenesis experiments conducted with and without metabolic activation revealed statistically significant increases in mutation frequency at PTI G-2535 concentrations > or = 0.8 and 12 microg/ml, respectively; such increases were dose related and increases in the frequency of both small and large colonies were observed. A statistically significant increase in the frequency of micronucleated polychromatic erythrocytes was also seen 24 hours after treatment in male, but not female, mice who received 500 and 1000 mg/kg body weight PTI G-2535; however,such increases were small, were not dose related, and were not observed 48 hours after treatment. In contrast, dietary genistein had no effect on survival, weight gain, or the incidence or types of tumors that developed in cancer-prone rodents lacking the p53 tumor suppressor gene, p53 knockout mice. The apparent risk/benefit of isoflavone ingestion may ultimately depend on the dose and developmental timing of exposure.

The nature of chromosomal aberrations detected in humans exposed to benzene

Benzene is an established cause of human leukemia that is thought to act by producing chromosomal aberrations and altered in cell differentiation. In several recent studies increased levels of chromosomal aberrations in peripheral blood lymphocytes were correlated with a heightened risk of cancer, especially hematological malignancies. Thus, chromosomal aberrations may be a predictor of future leukemia risk. Previous studies exploring whether benzene exposure induces chromosomal aberrations have yielded mostly positive results. However, it remains unclear whether the chromosomal aberrations induced by benzene occur in a distinct pattern. Here, we thoroughly review the major chromosome studies published to date in benzene-exposed workers, benzene-poisoned and preleukemia patients, and leukemia cases associated with benzene expose. Although three cytogenetic markers (chromosomal aberrations, sister chromatid exchanges, and micronuclei) are commonly examined, our primary focus is on studies of chromosomal aberrations, because only this marker has so far been correlated with increased cancer risk. This review surveys the published literature, analyzes the study results, and discusses the characteristics of effects reported. In most studies of currently exposed workers, increases in chromosomal aberrations were observed. However, due to the relatively small number of affected individuals and variability in the reported aberrations, firm conclusions cannot be made about the involvement of specific chromosomes or chromosome regions. Further, in leukemia cases associated with benzene exposure, there is no evidence of a unique pattern of benzene-induced chromosomal aberrations in humans. Leukemia cases associated with benzene exposure are, however, more likely to contain clonal chromosome aberrations then those arising de novo in the general population.

Spindle poisons induce allelic loss in mouse lymphoma cells through mitotic non-disjunction

Aneuploidy is an important contributor to reproductive failure and tumor development. It arises spontaneously or as a result of exposure to aneugenic agents through non-disjunction. Two spindle poisons, colchicine (COL) and vinblastine (VBL) are mutagenic in the mouse lymphoma assay (MLA), a gene mutation assay that targets the heterozygous thymidine kinase (tk) gene on chromosome 11 in mouse lymphoma L5178Y tk+/- 3.7.2c cells. To investigate the mechanisms of spindle poison mutagenesis, we analyzed the COL- and VBL-induced TK mutants at the molecular and cytogenetic level. Loss of heterozygosity (LOH) analysis employing a microsatellite region within the tk locus revealed that almost all mutants had lost the functional tk allele. To determine the extent of the LOH, we further examined LOH mutants for heterozygosity at nine microsatellite loci spanning the entire chromosome 11. Interestingly, every microsatellite marker showed LOH in all COL- and VBL-induced LOH mutants, suggesting that these mutants were generated by loss of the whole chromosome 11 through mitotic non-disjunction. Chromosome painting analysis supported this hypothesis; there were no mutants showing structural changes such as deletions or translocations involving chromosome 11. In contrast, spontaneous TK mutants followed from point mutations, deletions and recombinational events as well as whole chromosome loss. Our present study indicates that spindle poisons induce mutations through mitotic non-disjunction without structural DNA changes and supports a possible mechanism in which a recessive mutation mediated by aneuploidy may develop tumors.

Induction of forward mutations at the thymidine kinase locus of mouse lymphoma cells: evidence for electrophilic and non-electrophilic mechanisms

A database of 209 chemicals tested for induction of forward mutations at the heterozygous thymidine kinase (TK +/-) locus in L5178Y mouse lymphoma cells was analyzed for structure-activity relationships using the MultiCASE expert system. Consistent with evidence of several contributing biological mechanisms, these studies suggest that such mutations may occur by more than one mechanism. As might be expected, there was evidence for a component involving direct electrophilic attack on the cellular DNA, in a manner previously established as causative in the induction of mutations in Salmonella. In addition, however, there was also strong evidence for another mechanism or mechanisms involving chromosome missegregation, cellular toxicity or an alternate site of action, such as the microtubules.

Mutagenicity and cytotoxicity of reactive oxygen and nitrogen species in the MN-11 murine tumor cell line

There is increasing evidence that endogenously generated reactive oxygen (ROS) and reactive nitrogen (RNS) species at sites of inflammation and in tumors may be genotoxic. We have developed a murine tumor model (MN-11) in which mutations at the hypoxanthine phosphoribosyltransferase (HPRT) locus, arising both in vitro and in vivo, can be detected. In the present report, we describe an in vitro study of the ability of ROS and RNS to induce mutations in our model system. 137Cs radiation and radiomimetic drugs caused a dose-dependent increase in mutant frequency. At D0, radiation induced about 170 mutants per 10(5) viable cells, compared to 50 and 95 for streptonigrin and bleomycin, respectively. H2O2 induced a lower frequency of mutants, 20-30 per 10(5), for enzymatically generated or bolus, respectively. For the following treatments, mutant frequency at 50% survival is shown. Incubation with human granulocytes induced a low frequency of mutants (about 15 per 10(5)). RNS was tested using a series of NO-donating drugs. Spermine/NO. induced cytotoxicity but no mutants while S-nitroso-N-acetylpenicillamine induced a low level, 10 per 10(5). Both release nitrogen monoxide spontaneously, with a t1/2 < 3 h. Glyceryl trinitrate and sodium nitroprusside are two drugs that were slowly metabolized by MN-11 cells (> 12 h). Glyceryl trinitrate induced about 20 per 10(5) while nitroprusside induced 50 per 10(5). Our results indicate that RNS can readily induce mutations detectable in MN-11 cells. At equicytotoxic doses, the induced mutant frequency varied considerably for different drugs, suggesting that different states of nitrogen monoxide (such as NO+ or NO.) may be generated and these may vary in their mutagenic/cytotoxic potential.

Illegitimate recombination leading to allelic loss and unbalanced translocation in p53-mutated human lymphoblastoid cells

Allelic loss and translocation are critical mutational events in human tumorigenesis. Allelic loss, which is usually identified as loss of heterozygosity (LOH), is frequently observed at tumor suppressor loci in various kinds of human tumors. It is generally thought to result from deletion or mitotic recombination between homologous chromosomes. In this report, we demonstrate that illegitimate (nonhomologous) recombination strongly contributes to the generation of allelic loss in p53-mutated cells. Spontaneous and X-ray-induced LOH mutations at the heterozygous thymidine kinase (tk) gene, which is located on the long arm of chromosome 17, from normal (TK6) and p53-mutated (WTK-1) human lymphoblastoid cells were cytogenetically analyzed by chromosome 17 painting. We observed unbalanced translocations in 53% of LOH mutants spontaneously arising from WTK-1 cells but none spontaneously arising from TK6 cells. We postulate that illegitimate recombination was occurring between nonhomologous chromosomes after DNA replication, leading to allelic loss and unbalanced translocations in p53-mutated WTK-1 cells. X-ray irradiation, which induces DNA double-strand breaks (DSBs), enhanced the generation of unbalanced translocation more efficiently in WTK-1 than in TK6 cells. This observation implicates the wild-type p53 protein in the regulation of homologous recombination and recombinational DNA repair of DSBs and suggests a possible mechanism by which loss of p53 function may cause genomic instability.