Investigation of cell death induced by N-methyl-N-nitrosourea in cell lines of human origin and implication of RNA binding protein alterations.

Methylating agents, a widely used class of anticancer drugs, induce DNA methylation adducts, the most biologically significant being O(6)-methylguanine. The efficacy of these drugs depends on the interplay of three DNA repair systems: base excision repair (BER), methyl-directed mismatch repair (MMR) and direct damage reversal by O(6)-methylguanine-DNA methyltransferase (MGMT). An MGMT-inducible, MMR- and BER-proficient HeLa cell line was treated with different concentrations of N-methyl-N-nitrosourea (MNU), a model S(N)1 methylating agent, analogous to widely used methylating cancer chemotherapeutic drugs, under different expression levels of the repair enzyme (MGMT). MNU induced MGMT-dependent apoptotic cell death. In this particular cellular context, the induction of apoptosis was accompanied by modifications of the RNA binding protein poly(A)polymerase and significant down-regulation of the heterogeneous nuclear ribonucleoprotein (hnRNP) C1/C2. These results implicate alterations of the above mentioned RNA binding proteins in S(N)1 methylating agent-induced cell death and apoptosis, providing a possible perspective regarding their use as biomarkers of tumor resistance/sensitivity to chemotherapy.

Monitoring for DNA damage of humans occupationally exposed to methyl bromide.

BACKGROUND: Methyl bromide (MeBr) is a methylating agent, weak mutagen and possible animal carcinogen. A molecular epidemiological study to examine human exposure to, and consequent DNA damage by MeBr was conducted in an area where this agent is used extensively for soil sterilisation in greenhouses. MATERIALS AND METHODS: During the first part of the study, blood samples were collected from 21 persons within 24 hours after use of MeBr for greenhouse sterilisation, as well as from 19 non-exposed subjects. Personal air sampling was also carried out, indicating mean air concentrations for different subjects in the range 11-78 mg/m3. In the second part of the study, an attempt was made to examine professional applicators of MeBr who suffered particularly high exposures (mean exposures, based on personal monitoring 23-165 mg/m3). The levels of N7-methylguanine and O6-methylguanine, two DNA adducts known to be induced by MeBr, were assessed in blood leukocyte DNA. RESULTS: Concerning the first part, two subjects (one exposed and one control) were found to be positive for N7-methylguanine, while none of the blood samples analysed had detectable levels of O6-methylguanine. Among 6 such persons examined during the second part, 2 were found positive for N7-methylguanine while none was positive for O6-methylguanine. CONCLUSION: Within the detection power of this limited study, no significant evidence of induction of DNA damage in blood leukocyte DNA by MeBr was found.

Methyl bromide causes DNA methylation in rats and mice but fails to induce somatic mutations in lambda lacZ transgenic mice.

Following single or multiple oral treatments of rats or lambda lacZ transgenic mice with methyl bromide, methylated DNA adducts (N7- and/or O6-methylguanine) were found at comparable levels in various tissues, including among others the glandular stomach, the forestomach and the liver. Multiple rat treatment resulted in substantial decreases in the repair enzyme O6-alkylguanine-DNA alkyltransferase which were probably due in part to direct interaction of the enzyme with methyl bromide. However, no induction of mutagenesis in the lacZ transgene could be detected in any tissue 14 days after single treatments of up to 50 mg/kg or after multiple treatments of as many as 10 daily treatments of 25 mg/kg MeBr.

Induction of somatic mutations but not methylated DNA adducts in lambdalacZ transgenic mice by dichlorvos.

In order to examine the in vivo genotoxic activity of dichlorvos, lambdalacZ transgenic mice (Muta Mouse) were treated i.p. with single (4.4 or 11 mg/kg) or multiple (5 x 11 mg/kg) doses of this agent and sacrificed 4 h or 14 days post-treatment for DNA adduct measurement or mutant frequency analysis, respectively. Neither methylated DNA adducts nor an increase in mutant frequency were detected in the bone marrow, white blood cells, liver, spleen, lung, brain and sperm cells after the single doses. However, following multiple dosing a statistically significant 3-fold increase in mutant frequency was observed in the liver, while a non-statistically significant increase was observed in the bone marrow. In contrast, dimethylsulphate, a model methylating agent, gave rise to detectable DNA adducts but no increase in mutant frequency following i.p. administration of single (30 mg/kg) or multiple (10 x 6 mg/kg) doses.

DNA damage and mutagenesis induced by procarbazine in lambda lacZ transgenic mice: evidence that bone marrow mutations do not arise primarily through miscoding by O6-methylguanine.

The DNA damaging and mutagenic activities of procarbazine, a methylating drug employed in cancer chemotherapy and suspected of causing therapy-related leukaemia, were investigated in the liver and bone marrow of lambda lacZ transgenic mice (MutaMouse). The drug was administered using two different protocols, a 'high-dose' one involving 5 daily doses of 200 mg/kg, expected to cause depletion of the repair enzyme O6-alkylguanine-DNA alkyltransferase (AGT) and thus favour the selective accumulation of the premutagenic lesion O6-methylguanine (O6-meG) relative to other adducts, and a 'low-dose' one involving 10 daily doses of 20 mg/kg procarbazine. Substantial accumulation of O6-meG was observed in both tissues examined 6 h after the end of the 'high-dose' treatment, with the liver accumulating somewhat higher levels than the bone marrow (28.0 +/- 1.8 fmol/microg DNA and 18.5 +/- 1.1 fmol/microg DNA respectively). However, significant increases in mutant frequency 10 days after the end of treatment were observed only in the bone marrow, reaching a 16-fold increase over background following the 5 x 200 mg/kg treatment. Sequence analysis of the mutations induced after this treatment revealed a mixed spectrum, in which G:C-->A:T transitions (characteristic of O6-meG miscoding) were only a secondary feature: Among 20 mutants analysed, only six such mutations were found, including three at CpG sites, which might have arisen from deamination of 5-methylcytosine. The other mutations observed included 1 A:T-->G:C transition, five transversions (one G:C-->T:A, one double G:C-->C:G, two A:T-->T:A, one A:T-->C:G), five deletions and three insertions. The mechanistic and clinical significance of these findings is discussed.

DNA adducts and the mechanism of carcinogenesis and cytotoxicity of methylating agents of environmental and clinical significance.

DNA adducts are covalent complexes formed between genotoxic carcinogens and DNA bases, and constitute a critical early intermediate on the pathway of chemical carcinogenesis. Their accumulation in different tissues reflects the amount of activated carcinogen reaching DNA, and can therefore serve as an index of the biologically relevant dose reaching the target tissues or cells. Methylating agents are of interest in view of their occurrence in the environment and their use as cytotoxic drugs in cancer chemotherapy. Current evidence indicates that O6-methylguanine plays a particularly important role in the mutagenic, carcinogenic, and cytotoxic activities of methylating agents. O6-Methylguanine is repaired efficiently by the enzyme O6-alkylguanine-DNA alkyltransferase (AGT). Lack of this enzyme results in excessive accumulation of O6-methylguanine and recent evidence suggests that significant quantitative effects on adduct accumulation may be linked to conditions of very low AGT levels. This would be important from the point of view of clinical practice, since modulation of AGT is under investigation as a means of enhancing the therapeutic efficacy of clinical agents acting via the production of O6-methylguanine and related adducts, such as, for example, procarbazine, dacarbazine, and some nitrosoureas. The measurement of O6-methylguanine in human DNA has been employed as a tool to investigate the role of environmental methylating agents in human carcinogenesis. While the nature and origin of the methylating agents responsible for these adducts is currently unknown, recent studies in patas monkeys have shown that N-nitrosodimethylamine, a methylating carcinogen to which human exposure is well documented, is capable of efficiently generating O6-methylguanine in most tissues, including fetal tissues. Furthermore, it has been found that this damage is substantially enhanced by the coadministration of ethyl alcohol which acts by inhibiting the liver first-pass metabolism of the carcinogen, an observation which supports the hypothesis that alcohol consumption may act as a risk factor in human carcinogenesis by augmenting the action of nitrosamines.

Comparative study of mutagenesis by O6-methylguanine in the human Ha-ras oncogene in E. coli and in vitro.

Single residues of O6-methylguanine (O6-meG) were introduced into the first or second position of codon 12 (GGC; positions 12G1 or 12G2, respectively) or the first position of codon 13 (GGT; position 13G1) of the human Ha-ras oncogene in phage M13-based vectors. After transformation of E.coli, higher mutant plaque frequencies (MPF) were observed at 12G1 and 13G1 than at 12G2 if O6-alkylguanine-DNA alkyltransferase (AGT) had been depleted, while similar MPF were observed at all three positions in the presence of active AGT. Taken together, these observations suggest reduced AGT repair at 12G2. Kinetic analysis of in vitro DNA replication in the same sequences using E. coli DNA polymerase I (Klenow fragment) indicated that variation in polymerase fidelity may contribute to the overall sequence specificity of mutagenesis. By constructing vectors which direct methyl-directed mismatch repair to the (+) or the (-) strand and comparing the MPF values in bacteria proficient or deficient in mismatch repair and/or AGT, it was concluded that, while mutS-mediated mismatch repair did not remove O6-meG from O6-meG:C pairs, this repair mechanism can affect O6-meG mutagenesis by repairing G:T pairs generated through AGT-induced demethylation of O6-meG:T replication intermediates.

Mutagenesis by O6 meG residues within codon 12 of the human Ha-ras proto-oncogene in monkey cells.

The first or/and the second guanines of the human Ha-ras codon 12 (normally GGC) were substituted by O6 meG residues and the modified sequence was subsequently introduced into an SV40-based shuttle vector able to replicate in both simian cells and bacteria. After replication in simian COS7 cells (proficient in O6-alkyl-guanine transferase), plasmid DNA was extracted and mutations were screened in E. coli DH5 alpha cells. The vast majority of the mutations induced by O6 meG were G----A transitions. The mutation frequency observed at the second guanine of codon 12 (12G2 position: 3.75% +/- 0.4) was higher than the one observed at the first guanine (12G1 position: 1.09% +/- 0.6). This difference was confirmed by the results obtained when two adjacent O6 meG residues were positioned within codon 12. The higher mutation frequency observed for the 12G2 position could be attributed to differential repair or/and variation in polymerase fidelity. These results are in agreement with animal experiments where alkylating agents gave rise to mutation on G2 position of codon 12.