The (6-4) photoproduct of thymine-thymine induces targeted substitution mutations in mammalian cells

SOS mutagenesis results from up-regulation of translesion synthesis

Irradiation of DNA with ultraviolet light generates a variety of photolesions. Among them, are cyclobutane pyrimidine dimers (CPD) and (6-4) photoproducts blocking lesions that interfere with DNA replication if left unrepaired. In addition to efficient pre-replicative excision repair mechanisms, cells have evolved damage tolerance pathways enabling them to replicate lesion-containing DNA molecules either by directly replicating through the damaged base (translesion synthesis, TLS) or by employing the locally undamaged complementary strand thus avoiding the lesion (damage avoidance pathways, DA). Using double-stranded vectors with a single T(6-4)T UV lesion and a strand segregation analysis (SSA), we have measured the relative utilization of the two tolerance pathways (TLS and DA) in Escherichia coli. During the SOS response the error-prone TLS pathway is strongly stimulated ( approximately 20-fold) at the expense of the error-free DA pathways. Thus, up-regulation of TLS may turn out to be a general property of the SOS response; a similar conclusion was previously reached with the frameshift-inducing N-2-acetylaminofluorene adduct. Therefore, as far as its contribution to damaged DNA replication is concerned, the SOS response appears to be an induced mutator state rather than a survival strategy. Depending on the base inserted opposite the lesion, TLS can be error-free or mutagenic. In a wild-type strain, both forms of TLS are increased to a similar extent during the SOS response. In contrast, in a DeltaumuDC strain induction of TLS is totally abolished, demonstrating that the UmuDC proteins usually thought to be specifically involved in mutagenesis facilitate the recovery of both error-free and mutagenic replication intermediates in vivo.

Benzimidazolium triflate-activated synthesis of (6-4) photoproduct-containing oligonucleotides and its application

In the solid-phase synthesis of oligonucleotides containing the pyrimidine(6-4)pyrimidone photoproduct using a dinucleotide building block, considerable amounts of by-products were found as the chain length increased. The by-products were the major product when a 49mer was synthesized on a 40 nmol scale. It was assumed that these by-products were formed by the coupling of phosphoramidites with the N3 imino function of the 5' component of the (6-4) photoproduct. We examined imidazolium triflate and benzimidazolium triflate to find an alternative activator for DNA synthesis. Imidazolium triflate prevented by-product formation to some extent, but the coupling yields were low. Benzimidazolium triflate was comparable to tetrazole in coupling efficiency and reduced by-product formation to a great extent, without modification of the synthesizer program. The obtained 49mer was used to detect proteins that recognize UV-damaged DNA in HeLa cell extracts. Two major protein-DNA complexes were found when a 49mer duplex was used as probe, while a 30mer duplex failed to detect one of them. This application showed the usefulness of long chain 'damaged' oligonucleotides in biochemical studies.

Chemical synthesis of oligonucleotides containing the (6-4) photoproduct at the thymine-cytosine site and its repair by (6-4) photolyase

A phosphoramidite building block of the T(6-4)C photoproduct was synthesized. One of the differences from T(6-4)T was formation of cytosine hydrates by UV irradiation, and the other was acylation of the amino function with the capping reagent. The capping step was omitted to improve the yield of the desired oligonucleotides. Characterization of the (6-4) photolyase using one of the oligonucleotides revealed that this enzyme restores the pyrimidines in T(6-4)C to their original structures.