Particle-based phasor-FLIM-FRET resolves protein-protein interactions inside single viral particles

Abstract

AbstractFluorescence lifetime imaging microscopy (FLIM) is a popular modality to create additional contrast in fluorescence images. By carefully analyzing pixel-based nanosecond lifetime patterns, FLIM allows studying complex molecular populations. At the single molecule or single particle level, however, image series often suffer from low signal intensities per pixel, rendering it difficult to quantitatively disentangle different lifetime species, such as during FRET analysis in the presence of a significant donor-only fraction. To address this problem, we combined particle localization with phasor-based FLIM analysis. Using simulations, we first showed that an average of ∼300 photons, spread over the different pixels encompassing single fluorescing particles and without background, is enough to determine a correct phasor signature (standard deviation <5% for a 4 ns lifetime). For immobilized single- or double-labeled dsDNA molecules, we next validated that particle-based phasor-FLIM-FRET readily allows estimating fluorescence lifetimes and FRET from single molecules. Thirdly, we applied particle-based phasor-FLIM-FRET to investigate protein-protein interactions in sub diffraction HIV-1 viral particles. To do this, we first quantitatively compared the fluorescence brightness, lifetime and photostability of different popular fluorescent protein-based FRET probes when genetically fused to the HIV-1 integrase enzyme (IN) in viral particles, and conclude that eGFP, mTurquoise2 and mScarlet perform best. Finally, for viral particles co-expressing FRET-donor/acceptor labeled IN, we determined the absolute FRET efficiency of IN oligomers. Available in a convenient open-source graphical user interface, we believe that particle-based phasor-FLIM-FRET is a promising tool to provide detailed insights in samples suffering from low overall signal intensities.Why it mattersPhasor-FLIM is an extraordinarily popular tool for fluorescence lifetime imaging analysis. However, it remains susceptible for low signal intensities, operational challenges and therefore required informed users and a clear analysis understanding. In this work we developed a convenient all-graphical workflow for quantitative phasor-FLIM in heterogenous and low-signal samples and applied it to quantifying absolute FRET efficiencies from protein-protein interactions inside single viral particles. Moreover, containing a well-illustrated theoretical introduction to time-domain phasor-FLIM, our paper helps novice users to correctly implement phasor-FLIM in standard microscopy practice.