Y-family DNA polymerases lack some of the mechanisms that replicative DNA polymerases employ to ensure fidelity, resulting in higher error rates during replication of undamaged DNA templates and the ability to bypass certain aberrant bases, such as those produced by exposure to carcinogens, including benzo
O6-Methylguanine (O6-meG), which is produced in DNA following exposure to methylating agents, instructs human RNA polymerase II to mis-insert bases opposite the lesion during transcription. In this study, we examined the effect of O6-meG on transcription in human cells and investigated the subsequent effects on protein function following translation of the resulting mRNA. In HEK293 cells, O6-meG induced incorporation of uridine or cytidine in nascent RNA opposite the adduct. In cells containing active O6-alkylguanine-DNA alkyltransferase (AGT), which repairs O6-meG, 3% misincorporation of uridine was observed opposite the lesion. In cells where AGT function was compromised by addition of the AGT inhibitor O6-benzylguanine, ∼58% of the transcripts contained a uridine misincorporation opposite the lesion. Furthermore, the altered mRNA induced changes to protein function as demonstrated through recovery of functional red fluorescent protein (RFP) from DNA coding for a non-fluorescent variant of RFP. These data show that O6-meG is highly mutagenic at the level of transcription in human cells, leading to an altered protein load, especially when AGT is inhibited.
DNA substrates containing O6-n-butylguanine, O6-iso-butylguanine, O6-n-propylguanine and O6-iso-propylguanine were prepared by reaction of calf thymus DNA with the appropriate N-alkyl-N-nitrosourea. These substrates were used to test the ability of O6-alkylguanine-DNA alkyltransferases from Escherichia coli and rat liver to remove such alkyl groups from the O6-position of guanine. It was found that all of these adducts were removed by the alkyltransferases, but the branched alkyl chain iso-butyl- and iso-propyl adducts were removed very slowly. Also, when tested with a DNA substrate containing both O6-n-propylguanine and O6-iso-propylguanine, the alkyltransferases removed almost all of the n-propyl-adduct before the iso-propyl-adduct was attacked. Both alkyltransferases showed a decreasing rate of reaction as the size of the alkyl group increased, but there was a significant difference between the rat liver and E. coli alkyltransferase in the relative rates. The rat liver alkyltransferase repaired O6-methylguanine more slowly than the E. coli protein, but was considerably more rapid than the bacterial equivalent when acting on n-propyl- and n-butyl-adducts. The relative rates of repair were methyl much greater than ethyl greater than n-propyl greater than n-butyl greater than iso-propyl, iso-butyl for the E. coli alkyl-transferase and methyl greater than ethyl, n-propyl greater than n-butyl greater than iso-propyl, iso-butyl greater than 2-hydroxyethyl for the rat liver protein. These results indicate that differential rates of repair may contribute to the relative risks of carcinogenesis and mutagenesis by exposure to alkylating agents of different size and that rates of repair may be species specific and must be determined from specific measurements rather than extrapolated from data on other organisms.
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