Fluorophore-mediated Photooxidation of the Guanine Heterocycle.

Abstract

Fluorescent dyes are routinely used to visualize DNA or RNA in various experiments, and some dyes also act as photosensitizers capable of catalyzing oxidation reactions. The present studies explored whether the common labeling dyes fluorescein, rhodamine, BODIPY, or cyanine3 (Cy3) can function as photosensitizers to oxidize nucleic acid polymers. Photoirradiation of each dye in the presence of the guanine (G) heterocycle, which is the most sensitive toward oxidation, identified slow rates of nucleobase oxidation in the nucleoside and DNA contexts. For all four fluorophores studied, the only product detected was spiroiminodihydantoin (Sp) suggesting the dyes functioned as Type II photosensitizers and generate singlet oxygen (1O2). The nucleoside reactions were then conducted in D2O solutions, known to increase the lifetime of 1O2, which resulted in a ~6-fold increase in the Sp yield, further supporting the classification of these dyes as Type II photosensitizers. Lastly, we inspected the pattern of G reactivity with the dyes upon photoirradiation in the context of a parallel-stranded G-quadruplex. The G nucleotides in the two exterior G-tetrads were found to be oxidation prone, providing the third line of evidence that the dyes are Type II photooxidants. The present work found that the common dyes fluorescein, rhodamine, BODIPY, or Cy3 can drive G oxidation but with a slow rate and low overall yield. This will likely not impact many experiments using dyes to study nucleic acids except for those that have long exposures with high-intensity lights, such as sequencing-by-synthesis experiments using fluorescence as the readout.