Facile preparation of model DNA interstrand cross-link repair intermediates using ribonucleotide-containing DNA

Effects of Local Sequence, Reaction Conditions, and Various Additives on the Formation and Stability of Interstrand Cross-Links Derived from the Reaction of an Abasic Site with an Adenine Residue in Duplex DNA

The experiments described here examined the effects of reaction conditions, various additives, and local sequence on the formation and stability interstrand cross-links (ICLs) derived from the reaction of an apurinic/apyrimidinic (AP) site with the exocyclic amino group of an adenine residue on the opposing strand in duplex DNA. Cross-link formation was observed in a range of different buffers, with faster formation rates observed at pH 5. Inclusion of the base excision repair enzyme alkyladenine DNA glycosylase (hAAG) which binds tightly to AP-containing duplexes decreased, but did not completely prevent, formation of the dA-AP ICL. Formation of the dA-AP ICL was not altered by the presence of the biological metal ion Mg²⁺ or the biological thiol, glutathione. Several organocatalysts of imine formation did not enhance the rate of dA-AP ICL formation. Duplex length did not have a large effect on dA-AP yield, so long as the melting temperature of the duplex was not significantly below the reaction temperature (the duplex must remain hybridized for efficient ICL formation). Formation of the dA-AP ICL was examined in over 40 different sequences that varied the neighboring and opposing bases at the cross-linking site. The results indicate that ICL formation can occur in a wide variety of sequence contexts under physiological conditions. Formation of the dA-AP ICL was strongly inhibited by the aldehyde-trapping agents methoxyamine and hydralazine, by NaBH₃CN, by the intercalator ethidium bromide, and by the minor groove-binding agent netropsin. ICL formation was inhibited to some extent in bicarbonate and Tris buffers. The dA-AP ICL showed substantial inherent stability under a variety of conditions and was not a substrate for AP-processing enzymes APE1 or Endo IV. Finally, we characterized cross-link formation in a small (11 bp) stem-loop (hairpin) structure and in DNA-RNA hybrid duplexes.

Preparation of DNA interstrand cross-link repair intermediates induced by abasic sites

DNA interstrand cross-links (ICLs) are extremely deleterious DNA lesions, which can block different DNA transactions. A major step in ICL repair involves strand cleavage activities flanking the cross-linking site, also known as unhooking. The cleavage generates a single-stranded DNA remnant attached to the unbroken strand, often referred to as the unhooked ICL repair intermediates. The unhooked ICLs are substrates for specialized DNA polymerases, leading to the eventual restoration of the duplex DNA structure. Although these repair events have been outlined, the understanding of molecular details of the repair pathways has been hindered by the difficulty of preparing structurally defined ICL repair intermediates. Here, we present a straightforward method to prepare model ICL repair intermediates derived from a ubiquitous type of endogenous DNA modification, abasic (AP) sites. AP-derived ICLs have emerged as an important type of endogenous ICLs. We developed the method based on commercially available materials without the requirement of synthetic chemistry expertise. The method is expected to be accessible to any interested labs in the DNA repair community.

• The method exploits the alkaline lability of ribonucleotides and uses designer oligonucleotides to create ICL repair intermediates with varying lengths of the unhooked strand.

• Strand cleavage at ribonucleotides is achieved using NaOH, which avoids the potential for incomplete digestion during enzymatic workup due to specific substrate structures.

• The method is grounded on the high cross-linking yield between an AP lesion and a nucleotide analog, 2-aminopurine, via reductive amination, developed by Gates and colleagues.