Quenching of fluorescent nucleobases by neighboring DNA: the "insulator" concept.

Fluorescent nucleosides are widely used as probes of biomolecular structure and mechanism in the context of DNA, but they often exhibit low quantum yields because of quenching by neighboring DNA bases. Here we characterize the quenching by DNA of fluorescent nucleosides that have pyrene (Y), perylene (E), benzopyrene (B), or 2-aminopurine (2AP) as nucleobase replacements, and we investigate the effect of inserting varied nucleosides as potential "insulators" between the fluorescent nucleosides and other nearby DNA bases as a strategy for increasing quantum yields. The data show that the hydrocarbons are quenched by adjacent pyrimidines, with thymine being the strongest quencher. The quantum yield of pyrene is quenched 120-fold by a single adjacent T, that of benzopyrene tenfold, and that of perylene by a factor of 2.5. Quenching of excimer and exciplex dinucleoside labels (Y-Y, Y-E, E-E, etc.) was considerably lessened, but was strongest with neighboring thymine. 2-Aminopurine (2AP) is most strongly quenched (15-fold) by neighboring G. We tested four different insulator candidates for reducing this quenching by measuring the fluorescence of short oligonucleotides containing insulators placed between a fluorescent base and a quenching base. The insulators tested were a C(3) abasic spacer (S), dihydrothymidine nucleoside (DHT), terphenyl nucleoside (TP), and adenine deoxynucleoside (dA). Results showed that the abasic spacer had little effect on quenching, while the other three had substantial effects. DHT and terphenyl enhanced fluorescence of the fluorophores by factors of 5 to 70. Adenine base reduced the quenching of pyrene 40-fold. The results underscore the importance of the nearest neighbors in DNA-quenching mechanisms, and establish simple strategies for enhancing fluorescence in labeled DNAs.

Oligomeric fluorescent labels for DNA.

In an effort to find fluorescent labels that have large Stokes shifts and increased emission intensity, a strategy for fluorescence labeling of DNA was explored in which multiple individual fluorophores are incorporated at adjacent positions at the end of a DNA probe. To encourage close interactions, hydrocarbon and heterocycle fluorophores were substituted at C-1 of deoxyribose, replacing the DNA base. The C-glycosides studied contained the well-known fluorophores terphenyl, pyrene, and terthiophene. For comparison, a commercial fluorescein-dU nucleotide was examined. Oligomeric labels containing up to five fluorophores were tested. Interestingly, all four dyes behaved differently on multiple substitution. Fluorescein displayed strong self-quenching properties, with the quantum yield dropping severalfold with each additional substitution and with a constant, small Stokes shift. In contrast, pyrene showed increases in quantum yield on addition of more than one fluorophore and yielded efficient long-wavelength emission on multiple substitution, with Stokes shifts of >130 nm. Oligomeric terphenyl labels gave a small progressive red shift in absorption and a marked red shift in emission wavelength and showed a strong increase in brightness with more monomers. Finally, terthiophene oligomers showed self-quenching combined with increasing Stokes shifts. Overall, the results suggest that some oligomeric fluorescent labels exhibit properties not available in common fluorescein class (or other commercial) labels, such as large Stokes shifts and increasing brightness with increasing substitution.