Abstract
Tryptophan fluorescence is extensively used for label-free protein characterization. Here, we show that by analyzing how the average tryptophan fluorescence intensity varies with excitation modulation, kinetics of tryptophan dark transient states can be determined in a simple, robust and reliable manner. Thereby, highly environment-, protein conformation- and interaction-sensitive information can be recorded, inaccessible via traditional protein fluorescence readouts. For verification, tryptophan transient state kinetics were determined under different environmental conditions, and compared to literature data. Conformational changes in a spider silk protein were monitored via the triplet state kinetics of its tryptophan residues, reflecting their exposure to an air-saturated aqueous solution. Moreover, tryptophan fluorescence anti-bunching was discovered, reflecting local pH and buffer conditions, previously observed only by ultrasensitive measurements in highly fluorescent photo-acids. Taken together, the presented approach, broadly applicable under biologically relevant conditions, has the potential to become a standard biophysical approach for protein conformation, interaction and microenvironment studies.
Highlights
Tryptophan (Trp) auto-fluorescence is widely used for label-free structural and dynamic studies of proteins[1], and Room Temperature Phosphorescence (RTP) from the Trp triplet state can provide valuable complementary information[2,3,4,5,6,7]
To investigate how transient state monitoring (TRAST) spectroscopy compares to RTP and Flash Photolysis (FP) for determining dark state transitions in Trp, TRAST curves of Trp in buffer solution were recorded under different excitation irradiances, under air-saturated and deoxygenated conditions (Fig. 2)
Transient state transitions of Trp in aqueous solution were determined by TRAST measurements
Summary
Tryptophan (Trp) auto-fluorescence is widely used for label-free structural and dynamic studies of proteins[1], and Room Temperature Phosphorescence (RTP) from the Trp triplet state can provide valuable complementary information[2,3,4,5,6,7]. With relaxed requirements on sample preparation, detection quantum yield and time-resolution of the instrument, as well as on fluorescence brightness of the molecules studied, TRAST is broadly applicable, and has been demonstrated both for solution measurements[25,26] and live cell studies[27,28]. This far, the studies have been based on fluorescence from added fluorophores. The presented approach offers a robust alternative to RTP, FP and traditional protein auto-fluorescence readouts for label-free micro-environmental monitoring, as well as for structural and dynamic studies of proteins, and is applicable under a broad range of biologically relevant conditions
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