O4-Alkyldeoxythymidines have been extensively studied for their ability to cause mutations and to induce cancer. Since these adducts can change DNA conformation, they may also have a more immediate effect of altering DNA-protein interactions. To address this issue, the effects of these adducts on restriction enzyme activity were examined. Oligodeoxyribonucleosides containing O4-ethyldeoxythymidine (O4-EtdT) or O4-methyldeoxythymidine (O4-MedT) at a unique site within the sequence 5'-GAATGGATCCTAATGAGATC-3' were constructed by automated DNA synthesis. This sequence contains the recognition site for various restriction enzymes. These oligomers were annealed to various complementary strands and digested with restriction enzymes: BamHI or BstI (GGATCC); Sau3A, NdeII, or MboI (GATC); DpnI (GmATC); and BstYI, MflI, or XhoII (PuGATCPy). Analysis of the digests demonstrated that the presence of either O4-EtdT or O4-MedT abolished the ability of XhoII, MboI, MflI, or NdeII to cut at the restriction site. DpnI failed to cut any of the oligomers. BamHI, Sau3A, BstI, and BstYI exhibited alterations in cutting specificity depending upon the oligomers used. These results demonstrated that O4-alkyldeoxythymidine adducts alter DNA-restriction enzyme interactions in a protein- and sequence-dependent manner. Because of the importance of natural methylation in genetic regulation, it is possible that aberrant methylation in the form of DNA adducts could also alter protein-DNA interactions in cells exposed to DNA-modifying agents.