| Abstract: | Interactions of several acridine dyes with DNA from different species were studied by measuring fluorescence lifetimes in the 2–30-nsec range, using the single-photon counting technique, and by measuring fluorescence quantum yields in the steady state. The results confirm the existence of two principal site classes, one in which the dye fluorescence is quenched by interaction with guanine and another in which fluorescence results from the hydrophobic environment of the A·T base pairs. The emitting sites are found, in some cases, to exhibit fluorescent decay curves which can be resolved into two exponential components corresponding to a short and to a long lifetime. The deviation from one exponential component is particularly clear with rivanol, 9-aminoacridine, and quinacrine, with which one component is two or three times longer than the other. The relative proportion of these two components depends only slightly on the DNA base composition and does not depend on the nature of the acridine derivatives. We postulate that this lifetime heterogeneity corresponds to the two discrete steps in the complex formation elucidated by kinetic studies: the first step corresponds to a semi-intercalated, or “external,” dye with a short fluorescence lifetime and the second step corresponds to a totally intercalated dye with a long lifetime. In this model, we assumed that a transient opening of the site near a semi-intercalated dye induces solvent diffusion which in turn is responsible for its short-lived fluorescence. |
