Abstract
Fluorescence lifetime imaging (FLIM) is a quantitative, intensity-independent microscopical method for measurement of diverse biochemical and physical properties in cell biology. It is a highly effective method for measurements of Förster resonance energy transfer (FRET), and for quantification of protein-protein interactions in cells. Time-domain FLIM-FRET measurements of these dynamic interactions are particularly challenging, since the technique requires excellent photon statistics to derive experimental parameters from the complex decay kinetics often observed from fluorophores in living cells. Here we present a new time-domain multi-confocal FLIM instrument with an array of 64 visible beamlets to achieve parallelised excitation and detection with average excitation powers of ~ 1–2 μW per beamlet. We exemplify this instrument with up to 0.5 frames per second time-lapse FLIM measurements of cAMP levels using an Epac-based fluorescent biosensor in live HeLa cells with nanometer spatial and picosecond temporal resolution. We demonstrate the use of time-dependent phasor plots to determine parameterisation for multi-exponential decay fitting to monitor the fractional contribution of the activated conformation of the biosensor. Our parallelised confocal approach avoids having to compromise on speed, noise, accuracy in lifetime measurements and provides powerful means to quantify biochemical dynamics in living cells.
Highlights
Fluorescence lifetime imaging (FLIM) is a quantitative, intensity-independent microscopical method for measurement of diverse biochemical and physical properties in cell biology
Fluorescent biosensors with an optical readout based on Förster resonance energy transfer (FRET) have been used to detect the second messenger cyclic adenosine monophosphate[27,28,29,30,31], which plays a role in many cellular processes including adhesion
A palette of fluorescent biosensors based on exchange protein activated by cAMP (Epac)[1] for detection of intracellular cyclic adenosine monophosphate (cAMP) was recently presented[28], including several constructs with a large dynamic range for FRET optimised for FLIM, with the optimised cyan fluorescent protein, mTurquoise[232–34] as a donor and tandem dark Venus acceptors which minimise the possibility of bleed-through of the acceptor emission into the donor detection channel
Summary
Fluorescence lifetime imaging (FLIM) is a quantitative, intensity-independent microscopical method for measurement of diverse biochemical and physical properties in cell biology. We present a new time-domain multi-confocal FLIM instrument with an array of 64 visible beamlets to achieve parallelised excitation and detection with average excitation powers of ~ 1–2 μW per beamlet We exemplify this instrument with up to 0.5 frames per second time-lapse FLIM measurements of cAMP levels using an Epac-based fluorescent biosensor in live HeLa cells with nanometer spatial and picosecond temporal resolution. Fluorescence lifetime imaging (FLIM) is a well-established, robust technique for quantitative intracellular measurements of protein-protein interactions by Förster resonance energy transfer (FRET)[1,2,3,4], and highly photon efficient FRET measurements are achieved using FLIM with time-correlated single photon counting (TCSPC)[5]. For high frame-rate imaging which retains the benefits of beam scanning time-domain TCSPC FLIM: high signal to noise; excellent photon efficiency; high temporal and spatial accuracy; and optical sectioning capabilities, parallelisation of the excitation and detection is extremely beneficial. A palette of fluorescent biosensors based on Epac[1] for detection of intracellular cAMP was recently presented[28], including several constructs with a large dynamic range for FRET optimised for FLIM, with the optimised cyan fluorescent protein, mTurquoise[2] (mTurq2)[32,33,34] as a donor and tandem dark Venus (tddVenus) acceptors which minimise the possibility of bleed-through of the acceptor emission into the donor detection channel
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