Human cell extracts perform an aberrant form of DNA synthesis on methylated plasmids [1], which represents processing of O6-methylguanine (O6-meG). Here, we show that extracts of colorectal carcinoma cells with defects in the mismatch repair proteins that normally correct replication errors do not carry out this synthesis. hMSH2-defective LoVo cell extracts (hMSH for human MutS homologue) performed O6-meG-dependent DNA synthesis only after the addition of the purified hMutS alpha mismatch recognition complex. Processing of O6-meG by mismatch correction requires PCNA and therefore probably DNA polymerase delta and/or epsilon. Mismatch repair-defective cells withstand O6-meG in their DNA [2], making them tolerant to methylating agents. Methylation-tolerant HeLaMR clones, with a mutator phenotype and a defect in either mismatch recognition or correction in vitro, also performed little O6-meG-dependent DNA synthesis. Assays of pairwise combinations of tolerant and colorectal carcinoma cell extracts identified hMLH1 as the missing mismatch repair function in a group of tolerant clones. The absence of processing by extracts of methylation-tolerant cells provides the first biochemical evidence that lethality of DNA O6-meG derives from its interaction with mismatch repair.
To study the effects of methylation damage on DNA replication in vitro, the plasmid pSVori containing the SV40 origin of replication was reacted with N-methyl-N-nitrosourea and used as a substrate for SV40 T antigen dependent replication by HeLa cell extracts. The plasmid was methylated with a range of N-methyl-N-nitrosourea concentrations that introduced an average of 0.3-2.5 O6-methylguanine and equal amounts of 3-methyladenine lesions per DNA molecule. When methylated plasmid was incubated with extract of Mex-HeLaMR cells under conditions favoring DNA replication, an impairment of replication was observed as the accumulation of incompletely replicated form II plasmid molecules. These extracts simultaneously performed a T antigen independent, DpnI-sensitive DNA repair synthesis that increased with increasing DNA damage. Subtraction of this repair DNA synthesis revealed that methylation inhibited overall replication. At low levels of methylation (< or = 1 O6-methylguanine and < or = 1 3-methyladenine lesion per plasmid), inhibition was transient, while more extensive damage resulted in apparently irreversible inhibition of replication. Removal of O6-methylguanine by pretreatment of the methylated plasmid with purified human O6-methylguanine-DNA methyltransferase restored replication to almost normal levels. When the methylated plasmid was replicated by extracts of Mex+ HeLaS3 cells proficient in the repair of O6-methylguanine, a lower level of inhibition and less repair DNA synthesis was observed. The inhibition of DNA synthesis and the stimulation of repair DNA synthesis are thus both largely due to the presence of O6-methylguanine in DNA.(ABSTRACT TRUNCATED AT 250 WORDS)
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