Loss of heterozygosity in somatic cells of the mouse. An important step in cancer initiation?

Loss of heterozygosity (LOH) of tumour suppressor genes is a crucial step in the development of sporadic and hereditary cancer. Recently, we and others have developed mouse models in which the frequency and nature of LOH events at an autosomal locus can be elucidated in genetically stable normal somatic cells. In this paper, an overview is presented of recent studies in LOH-detecting mouse models. Molecular mechanisms that lead to LOH and the effects of genetic and environmental variables are discussed. The general finding that LOH of a marker gene occurs frequently in somatic cells of the mouse without deleterious effects on cell viability, suggests that also tumour suppressor genes are lost in similar frequencies. LOH of tumour suppressor genes may thus be an initiating event in cancer development.

Induction of hprt gene mutations in splenic T-lymphocytes from the rat exposed in vivo to DNA methylating agents is correlated with formation of O6-methylguanine in bone marrow and not in the spleen.

The suitability of splenic T-lymphocytes as a substitute tissue for detection of genotoxic effects induced in vivo by chemical agents that are organ-specifically activated was tested in rats exposed to single doses at the potent lung-carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), acetoxymethylmethylnitrosamine (AMMN) or N-methyl-N-nitrosourea (MNU). NNK, AMMN and MNU methylate DNA most likely via the formation of a methanediazohydroxide ion that decomposes to a methyl diazonium ion. For all three agents, an increase in the levels of 06-methylguanine and 7-methylguanine in DNA of rat liver and lung was detected by reverse phase HPLC and electrochemical detection. Treatment with NNK did not result in the formation of O6-methylguanine and 7-methylguanine in DNA of bone marrow and spleen, corresponding with the absence of metabolic activation pathways for this compound in these tissues. For AMMN formation of both 06-methylguanine and 7-methylguanine was detectable in DNA of the spleen, whereas in DNA of bone marrow only very low frequencies of 7-methylguanine were found at a toxic dose. MNU induced O6-methylguanine and 7-methylguanine in both spleen and bone marrow. Using splenic T-lymphocytes from the rat no increase above control levels of the hprt mutant frequencies was found for NNK and AMMN for all exposure levels tested, 32 days after chemical exposure. For MNU a dose-dependent increase in hprt mutant frequency was found at exposure levels of 0.097 mmol/kg up to 0.582 mmol/kg. DNA sequence analysis was performed on PCR products of hprt cDNA from 39 MNU-induced 6-thioguanine-resistant T-lymphocyte clones. Single base pair substitutions were found in 25 of these mutants (64%), GC-->AT transitions being the predominant type of mutation (19 of 25; 76%). These mutations are probably caused by mispairing of 06-methylguanine with thymine during DNA replication. The results indicate that formation of mutagenic lesions in the spleen is not correlated with an enhanced frequency of 6-thioguanine-resistant splenic T-lymphocyte clones from rats, 32 days after exposure in vivo to DNA damaging agents. This suggests that mutation-fixation in T-lymphocytes does not occur in the spleen but at other sites in the body such as bone marrow, after which these mutated cells migrate to the spleen.

Marked differences in the role of O6-alkylguanine in hprt mutagenesis in T-lymphocytes of rats exposed in vivo to ethylmethanesulfonate, N-(2-hydroxyethyl)-N-nitrosourea, or N-ethyl-N-nitrosourea.

The role of DNA alkylation at the O6 position of guanine in the induction of gene mutations in vivo was studied in the hprt gene of rat T-lymphocytes from spleen exposed in vivo to the monofunctional ethylating agents ethylmethanesulfonate (EMS) and N-ethyl-N-nitrosourea (ENU), or the hydroxyethylating agent N-(2-hydroxyethyl)-N-nitrosourea (HOENU). All chemicals showed an exposure-dependent increase in hprt mutant frequency. HOENU and ENU, however, were much more mutagenic than EMS when compared at equimolar levels. DNA sequence analysis was performed on PCR products of hprt cDNA from 40 EMS-, 35 HOENU-, and 46 ENU-induced 6-thioguanine-resistant T-lymphocyte clones. Thirty EMS-induced mutants contained a single base pair substitution with GC to AT transitions being the predominant type of mutation (26 of 30) which are probably caused by mispairing of O6-ethylguanine with T during DNA replication. No strand specificity of mutated G's among GC to AT transitions was observed. Twenty-three HOENU- and 42 ENU-induced mutants contained a single base pair substitution. In contrast to EMS, GC to AT transitions were found at a low frequency, 4 of 23 for HOENU and 5 of 42 for ENU, indicating that O6-hydroxyethylguanine and O6-ethylguanine are less important in HOENU- and ENU-induced mutagenesis in vivo, respectively. Also here no strand bias for mutated G's was observed, although the number of this type of mutation was limited. The most frequently induced base pair alterations by HOENU and ENU were transversions at AT base pairs, 16 of 23 and 28 of 42, respectively, with AT to TA being the predominant type of mutation. In both ENU and HOENU mutational spectra, an extreme strand bias for mutated T's toward the nontranscribed strand was found. The results suggest that DNA damage induced in rat T-lymphocytes in vivo by HOENU and ENU is processed in similar ways.

Mechanisms and biomarkers of genotoxicity. Molecular dosimetry of chemical mutagens.

The relevance of the use of DNA adduct frequencies as a parameter for the extent of mutation induction by monofunctional alkylating agents was investigated in cultured Chinese hamster cells and in rat skin fibroblasts treated in vivo with the test chemicals. The nature of the biologically significant DNA adducts was investigated by DNA sequence analysis of mutations induced at the hypoxanthine-guanine phophoribosyltransferase (hprt) gene. The results show that under conditions where O6-alkylguanine is a persistent DNA lesion more than 50% of the mutations are GC to AT transitions indicating that the frequency of O6-alkylguanine is a good parameter for mutation induction. However, in target cells which are able to remove alkyl groups from the O6 position of guanine, alkylating agents with a low nucleophilic selectivity (e.g. N-ethyl-N-nitrosourea (ENU) and N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG)) exert most of their mutagenic activity most likely via the induction of O2-ethylthymine.

AT base pairs are the main target for mutations at the hprt locus of rat skin fibroblasts exposed in vitro to the monofunctional alkylating agent N-ethyl-N-nitrosourea.

Spectra of N-ethyl-N-nitrosourea (ENU)-induced mutations differ widely among various in vitro and in vivo mutational systems. To investigate possible reasons for these differences, a mutational system is needed in which the same target gene is used for comparison in the same type of cells in vitro and in vivo. In the present study, this was achieved by analysing at the molecular level 35 hprt mutant rat fibroblast clones obtained from cell populations exposed in vitro to ENU and comparing the mutational spectrum with the previously determined spectrum of ENU-induced hprt mutants in the same target cells exposed in vivo. Twenty-eight mutants contained a single base pair alteration in the hprt coding sequence. Most of these changes were found at AT base pairs (19/28), the AT to TA transversion being the most frequent kind of mutation (12/19), which is probably caused by O2-ethylthymine. Transversions at AT base pairs showed all mutated T's to be located in the nontranscribed strand of the hprt gene, suggesting a strand specific fixation of mutations induced by O2-ethylthymine, which appears to be a general feature of ENU- and ENNG-induced hprt mutations in mammalian cells. GC to AT transitions, probably caused by O6-ethylguanine, were detected at a lower frequency (7/28). This in vitro mutational spectrum was very similar to that of the same target cells exposed in vivo to ENU. A comparison of the mutational spectra in AGT-proficient and AGT-deficient rodent cells exposed to ethylating agents showed that in contrast to the situation in AGT-proficient rat fibroblasts, GC to AT base pair changes (and not AT to TA) are the predominant mutations in AGT-deficient hamster cells.

Formation and persistence of DNA adducts in pouch skin fibroblasts and liver tissue of rats exposed in vivo to the monofunctional alkylating agents N-methyl-N-nitrosourea or N-ethyl-N-nitrosourea.

Base substitutions and frameshifts induced by genotoxic agents are considered to result mainly from incomplete repair and incorrect replication of modified nucleotides in DNA. In this study, induction and persistence of O6-alkyl- and 7-alkylguanine adducts were determined by reverse phase HPLC and electrochemical detection in DNA of pouch skin fibroblasts and liver tissue of rats exposed in vivo to the monofunctional alkylating agents N-methyl-N-nitrosourea (MNU) and N-ethyl-N-nitrosourea (ENU). Although an exposure dependent increase in the level of adducts was found for both chemicals, a much lower frequency of both O6-alkylguanine and 7-alkylguanine was detected after ENU treatment than after MNU treatment, indicating that MNU is much more reactive with DNA than ENU. The persistence of O6-alkyl- and 7-alkylguanine was studied for up to 48 h at exposure levels of 60 mg/kg for MNU and 100 mg/kg for ENU. A time-dependent decline in the levels of both adducts was observed, but w6-alkylguanine was more rapidly lost than 7-alkylguanine in both pouch skin fibroblasts and liver. Furthermore, DNA adducts were faster lost from liver than from pouch skin fibroblasts. The loss of O6-alkylguanine adducts is probably mediated by the action of O6-alkylguanine-DNA alkyltransferase (AGT) in the target tissues since AGT activity was detectable in protein extracts of pouch skin fibroblasts and liver from unexposed rats and from exposed rats, 48 h but not 1 h after MNU and ENU treatment. AGT activity recovered faster in liver tissue than in pouch skin fibroblasts, and after ENU exposure an induction of AGT activity was observed in the liver but not in pouch skin fibroblasts. The difference in the level of O6-alkylguanine in DNA of pouch skin fibroblasts introduced upon exposure to MNU and ENU may explain the molecular nature of most base pair changes observed previously in spectra of hprt mutants induced in these cells in vivo. The frequency of O6-methylguanine upon MNU exposure remains relatively high with time and these adducts most likely cause GC to AT transitions. In the case of ENU, O6-ethylguanine was detected at very low frequencies resulting in a low contribution of GC to AT transitions. Rather, the ENU spectrum is dominated by base pair changes at AT base pairs.

Molecular analysis of hprt gene mutations in skin fibroblasts of rats exposed in vivo to N-methyl-N-nitrosourea or N-ethyl-N-nitrosourea.

The granuloma pouch assay in the rat is a model system in which relative frequencies of genetic and (pre-) neoplastic changes induced in vivo by carcinogenic agents can be determined within the same target tissue. The target is granuloma pouch tissue and consists of a population of (transient) proliferating fibroblasts which can be cultured in vitro. hprt gene mutations were studied in granuloma pouch tissue of rats treated with single doses of direct acting alkylating agents N-methyl-N-nitrosourea (MNU) or N-ethyl-N-nitrosourea (ENU). Both agents showed an exposure-dependent increase in the hprt mutant frequency. Thirty-seven MNU (60 mg/kg)- and 43 ENU (100 mg/kg)-induced hprt mutant cell clones were analyzed at the molecular level. Twenty-two MNU-induced and 36 ENU-induced mutants carried a single base pair change in exon sequences of the hprt gene. The predominant base pair alterations induced by MNU were GC to AT transitions (18 of 22), which are probably caused by O6-methylguanine lesions. For most of the GC to AT transitions (16 of 18), the G was located in the nontranscribed strand, suggesting a strand bias in the repair of O6-methylguanine lesions. ENU-induced mutations occurred predominantly at AT base pairs (28 of 36), being mostly AT to TA and AT to CG transversions, and are probably caused by O2-ethylthymidine. Also here, DNA repair processes seem to act with different rates/efficiencies on DNA adducts in the 2 strands of the hprt gene, since all the 24 transversions observed at AT base pairs had the thymidine residue in the nontranscribed strand. GC to AT transitions were only present at a low frequency among ENU-induced mutations, suggesting that O6-ethylguanine lesions were repaired efficiently before mutations were fixed during replication. The mutational spectra of MNU- and ENU-induced hprt mutant clones were different from spontaneously occurring hprt mutant clones. These results indicate that MNU and ENU induce different mutational spectra in vivo and that DNA repair systems remove O6-methylguanine, O2, and/or O4-ethylthymidine much faster from the transcribed strand than the nontranscribed strand of the hprt gene in these rat fibroblasts.