Abstract
Histones react with various aldehyde-containing DNA modifications to form reversible but long-lived DNA-histone cross-links. The investigation of their biochemical effects and repair mechanisms has been impeded due to their reversibility and the lack of methods for synthesizing stable and structure-defined DNA-histone cross-links. Herein, we present a visible-light-driven strategy to install an aminooxyhomolysine on a histone at a defined position. Using this method, we synthesized a hydrolytically stable and site-specific 3'-DNA-histone cross-link derived from an abasic DNA lesion. Such an adduct can be efficiently repaired by proteolysis coupled with nuclease excision. This work provides a strategy that can be readily expanded to synthesize DNA-histone cross-links derived from other aldehyde-containing DNA modifications.