A 36-nucleotide oligomer containing a single O2-ethyldeoxythymidine (O2-Et-dT) adduct at a specific site was synthesized. The oligomer, which corresponds to a specific DNA sequence in gene G of bacteriophage phi X174, was used as a template by T7 DNA polymerase to investigate the in vitro mutagenic specificity of O2-Et-dT. At 10 microM dNTP and 5 mM Mg++, the progress of T7 DNA polymerase was interrupted by O2-Et-dT: 80% 3' to O2-Et-dT and 14% after incorporating a nucleotide opposite O2-Et-dT (incorporation-dependent blocked product). DNA synthesis past the lesion was low (6%). Incorporation of a nucleotide opposite O2-Et-dT and subsequent postlesion synthesis were enhanced by increasing the dNTP concentration, with postlesion synthesis reaching 30% at 200 microM. Postlesion synthesis was further increased to 45% by addition of 10 mM dAMP to the polymerization reactions. DNA sequencing revealed that both dA and dT were incorporated opposite O2-Et-dT with dA incorporation impeding the progress of DNA synthesis. dT incorporation was efficiently extended implicating O2-Et-dT in transversion mutagenesis in vivo. These studies provide a basis for understanding the molecular mechanisms by which ethylating agents contribute to cytotoxicity, A.T transversion mutagenesis and activation of the oncogene neu by an A.T----T.A transversion event in rat neuroblastomas.
The O2-position of thymine is a major site of base alkylation by N-nitroso-alkylating agents, and its biological relevance remains obscure. The potential significance of this DNA damage was ascertained by studying in vitro DNA replication properties of O2-ethylthymidine (O2-Et-dT) site-specifically incorporated into a 36-nucleotide template. DNA replication was initiated eight nucleotides away from the O2-Et-dT lesion by Escherichia coli polymerase I (Klenow fragment) using a 17-nucleotide primer. In the presence of 10 microM dNTP and Mg2+, O2-Et-dT blocked DNA replication predominantly (94%) 3' to O2-Et-dT, with the remainder (5%) blocked after incorporation of a nucleotide opposite O2-Et-dT (incorporation-dependent blocked product). Postlesion synthesis was negligible (less than 1%). Nucleotide incorporation opposite O2-Et-dT increased to 23% at 200 microM dNTP. Postlesion synthesis remained negligible (less than 2%). DNA sequencing revealed dA present opposite O2-Et-dT in the incorporation-dependent blocked product. Negligible postlesion synthesis suggests that incorporation of dA opposite O2-Et-dT inhibits in vitro DNA synthesis. The O2-Et-dT.dA base pair may also impede DNA synthesis in vivo, contributing to the cytotoxicity of the ethylating agents. Substitution of Mn2+ for Mg2+ enhanced nucleotide incorporation opposite O2-Et-dT and produced postlesion synthesis (16%) at 10 microM dNTP, which increased to 39% at 200 microM dNTP. DNA sequence analysis showed that while dA was present opposite O2-Et-dT in the incorporation-dependent blocked product, both dA and dT were present opposite this lesion in the postlesion synthesis product.(ABSTRACT TRUNCATED AT 250 WORDS)
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