Room temperature phosphorescence from tryptophan and halogenated tryptophan analogs in amorphous sucrose

Tryptophan phosphorescence lifetime and quantum yield are sensitive to the local environment. The phosphorescence from tryptophan analogs, however, has not been studied. We report here data on the room temperature phosphorescence of tryptophan, 4-, 5- and 6-fluoro-DL-tryptophan (4-F-trp, 5-F-trp and 6-F-trp) and 5-bromo-DL-tryptophan (5-Br-trp) embedded in glassy powders of freeze-dried sucrose. In aqueous solution, the absorption of the analogs was either blue-shifted (4-F-trp), red-shifted (5-F-trp and 5-Br-trp) or not shifted (6-F-trp) with respect to tryptophan. The phosphorescence emission spectra of all analogs were red-shifted compared to trp (442 nm) with maxima at 446 nm (5-F-trp), 451 nm (6-F-trp), 452 nm (5-Br-trp) and 469 nm (4-F-trp). The 5-F-trp and 6-F-trp analogs had emission intensities similar to tryptophan (relative quantum yields of 0.68 and 0.91, respectively, compared to tryptophan), while the intensities of the 4-F and 5-Br analogs were lower (relative quantum yields of 0.039 and 0.022, respectively). All analogs exhibited complex decay behavior requiring several exponentials for an adequate fit; the average lifetimes were all lower than that of trp (1039 ms). The average lifetimes of the fluorinated analogs (5-F, 721 ms; 6-F, 482 ms and 4-F, 35 ms) scaled approximately with the relative quantum yields while that of 5-Br (0.53 ms) was significantly lower. Analysis of the individual lifetimes suggested that the fluorinated analogs differ in their sensitivity to environmental interactions, with 5-F- and 6-F-trp quenched 1.5-2-fold and 4-F-trp about 23-fold more efficiently than tryptophan. The red-shifted 5-F-tryptophan analog, which has been incorporated into proteins, may provide an alternative phosphorescence probe for selective phosphorescence detection of a specific protein in a complex mixture.