Methyl methanesulfonate-induced hprt mutation spectra in the Chinese hamster cell line CHO9 and its xrcc1-deficient derivative EM-C11.

The Chinese hamster cell mutant EM-C11, which is hypersensitive to the cell killing effects of alkylating agents compared to its parental line CHO9, has been used to study the impact of base excision repair on the mutagenic effects of DNA methylation damage. This cell line has a defect in the xrcc1 gene. XRCC1 can interact with DNA polymerase-beta, thereby suppressing strand displacement, and DNA ligase III, both of which have been implicated in base excision repair. XRCC1 may, therefore, allow efficient ligation of single-strand breaks generated during base excision repair. Both EM-C11 and CHO9 cells were treated with methyl methanesulfonate (MMS), a DNA-methylating agent reacting predominantly with nitrogen atoms generating adducts which are substrates for the base excision repair pathway. EM-C11 cells are much more sensitive to the cytotoxic effects of MMS than CHO9: for EM-C11, the dose of MMS inducing 10% survival is 6-fold lower than that for CHO9. In contrast, mutation induction at the hprt locus following MMS is similar in EM-C11 and CHO9. Molecular analysis of hprt gene mutations showed that although the largest class of hprt mutations, both in EM-C11 and CHO9 cells, consisted of GC > AT transitions, most likely caused by O6-methylguanine, the size of this class was smaller in EM-C11. The fraction of deletion mutants in EM-C11, however, was twice as large as that found in CHO9 cells. These results suggest that reduced ligation efficiency of single-strand breaks generated during base excision repair, as result of a defect in XRCC1, may lead to the formation of deletions.

Effect of nucleotide excision repair on hprt gene mutations in rodent cells exposed to DNA ethylating agents.

The role of the nucleotide excision repair (NER) pathway in removal of DNA ethylation damage was investigated by means of hprt mutational spectra analysis in the NER-deficient Chinese hamster ovary cell line UV5, which lacks ERCC2/XPD, and in its parental cell line AA8. Both cell lines were exposed to ethyl methanesulfonate (EMS) or N-ethyl-N-nitrosourea (ENU). EMS gave a similar dose-dependent increase in hprt mutants in UV5 compared with AA8. In both cell lines EMS-induced mutations in the hprt coding region consisted almost exclusively of GC-->AT transitions, probably due to the direct miscoding lesion O6-ethylguanine. ENU, an agent that in addition to O6-ethylguanine also induces other O-alkylation products, was significantly more mutagenic in UV5 than in AA8. Mutational spectra analysis showed that the proportions of ENU-induced GC-->AT, AT-->TA and AT-->GC base pair changes were similar for both cell lines. ENU-induced DNA lesions that may be involved in GC-->AT transitions are O6-ethylguanine and O2-ethylcytosine, the latter being a chemically stable DNA lesion of which the miscoding properties and repair characteristics are largely unknown. ENU-induced AT-->TA transversions are probably caused by O2-ethylthymine, which mispairs with thymine. In AA8 thymines in ENU-induced AT-->TA transversions were exclusively located in the non-transcribed strand of the hprt gene, whereas in UV5 30% of these thymines were found in the transcribed strand. Together, these results indicate that O6-ethylguanine is a poor substrate for NER in rodent cells and that O2-ethylpyrimidines are preferentially removed from the transcribed strand of the hprt gene by NER.

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.

Molecular analysis of ethyl methanesulfonate-induced mutations at the hprt gene in the ethyl methanesulfonate-sensitive Chinese hamster cell line EM-C11 and its parental line CHO9.

The Chinese hamster cell line EM-C11 has been shown to be 5 times more sensitive than its parental line CHO9, but not hypermutable, after treatment with ethyl methanesulfonate. Ethyl methanesulfonate-induced mutational spectra were determined at the hprt locus to investigate whether the same adducts are responsible for mutation induction in both cell lines. The mutational spectra for EM-C11 and CHO9 show an important difference. GC-->AT transitions were found in both cell lines at similar frequencies; however, the spectrum of CHO9 contains a class of AT-->GC transitions, which seems to be replaced by a group of deletions in EM-C11. Since the ethyl methanesulfonate-induced mutation frequency for both lines is the same at equal exposure, it is hypothesized that the lesions leading to AT-->GC transitions in CHO9 are responsible for the deletions in EM-C11. This phenomenon might be explained if the responsible adduct(s) in CHO9 is bypassed resulting in replication errors, while blocking DNA synthesis in EM-C11 causing the observed increase in cell death. In surviving EM-C11 cells, DNA strand exchanges might have occurred at the position of stalled replication forks, leading to gross molecular changes. The adduct probably responsible for the AT-->GC transitions in CHO9 and the deletions in EM-C11 is 3-ethyladenine.

Asynchrony between pronuclear development and protein synthetic changes in zygotes of the mouse derived from oocytes aged postovulation in vivo and fertilized in vivo.

The pattern of proteins synthesized by one-cell embryos derived from unaged oocytes and oocytes aged postovulation in vivo was analyzed by means of 35S-methionine labeling and gel electrophoresis. The oocytes were obtained after ovulation induction by an injection of luteinizing hormone-releasing hormone (LHRH) at proestrus or after a superovulation procedure. The analysis was performed in unfertilized aged and unaged secondary oocytes and in zygotes derived from them. The patterns of proteins synthesized by secondary oocytes from all experimental groups were very similar: The oocytes showed a predominant synthesis of 35 kDa proteins. Zygotes from aged as well as unaged LHRH-induced oocytes also showed a predominant synthesis of one group of polypeptides with a relative molecular weight of about 35 kDa. The proteins of the 35 kDa protein complex migrated in an upper (u), middle (m), or lower (l) band in 10% polyacrylamide sodium dodecyl sulfate (SDS) gels. The u- and m-band 35 kDa proteins were shown to be synthesized by secondary oocytes. Early pronuclear zygotes from unaged LHRH-induced oocytes synthesized u- and m- but no l-band 35 kDa proteins. In contrast, part (38%, n = 47) of the early pronuclear zygotes from aged LHRH-induced oocytes did synthesize the l-band 35 kDa proteins. Late pronuclear zygotes (LPZ) from aged as well as unaged oocytes synthesized predominantly the l-band 35 kDa proteins. However, although only 5.8% (n = 51) of LPZ from unaged oocytes synthesize m- and l-band 35 kDa proteins, these bands of proteins are present in 25% (n = 24) of the LPZ from aged oocytes.(ABSTRACT TRUNCATED AT 250 WORDS)