Two fluorescent adenosine analogs, 4-amino-6-methyl-8-(2-deoxy-β--ribofuranosyl)-7(8H)-pteridone (6MAP) and 4-amino-2,6-dimethyl-8-(2′-deoxy-β--ribofuranosyl)-7(8H)-pteridone (DMAP), have been synthesized as phosphoramidites. These probes are site-selectively incorporated into oligonucleotides using automated DNA synthesis. Relative quantum yields are 0.39 for 6MAP and 0.48 for DMAP as monomers and range from >0.01 to 0.11 in oligonucleotides. Excitation maxima are 310 (6MAP) and 330 nm (DMAP) and the emission maximum for each is 430 nm. Fluorescence decay curves of each are monoexponential exhibiting lifetimes of 3.8 and 4.8 ns for 6MAP and DMAP, respectively. When these probes are incorporated into oligonucleotides they display quenching of fluorescence intensity, increases in the complexity of decay curves, and decreases in mean lifetimes. Because these changes are apparently mediated by interactions with neighboring bases, spectral changes that occur as probe-containing oligonucleotides meet and react with other molecules provide a means of monitoring these interactions in real time. These probes are minimally disruptive to DNA structure as evidenced by melting temperatures of probe-containing oligonucleotides that are very similar to those of controls. Digestion of probe-containing oligonucleotides with P1 nuclease confirms probe stability as fluorescence levels are restored to those expected for each monomer. These adenosine analog probes are capable of providing information on DNA structure as it responds to binding or catalysis through interaction with other molecules.