Transient state UV spectroscopy of Tyrosine and Tyrosine-containing protein

Abstract: The aromatic amino acids tryptophan, tyrosine, and phenylalanine have been extensively used for different label-free protein studies. These investigations extract information on protein conformations and interactions from the emitted fluorescence's intensity, wavelength, and/or polarization. Like most fluorescent organic compounds, these amino acids also undergo transitions into dark meta-stable states, including triplet and photo-radical states. These transitions are notably sensitive to the surrounding environment, offering an additional set of parameters that reflect the protein's interactions, folding states, and immediate surroundings. Transient State (TRAST) monitoring has been developed to quantify fluorophore transition dynamics by recording the average fluorescence intensity in response to a modulated excitation. In this work, we performed TRAST experiments to investigate tyrosine autofluorescence and used it to detect conformational changes in calmodulin, a calcium-binding protein containing two tyrosine residues. A photophysical model for tyrosine was established, and it was revealed how tyrosine's dark state transitions changed with excitation intensity, solvent pH, and redox conditions. The TRAST experiments demonstrated that tyrosine's dark state transitions could serve as valuable information sources for label-free analyses of protein conformations and interactions.