A FLIM Microscopy Based on Acceptor-Detected Förster Resonance Energy Transfer

Delgadillo, Roberto F.; Carnes, Katie A.; Zaleta-Rivera, Kathia; Olmos, Omar; Parkhurst, Lawrence J.

doi:10.1021/acs.analchem.0c04492

Cited by 3 publications

(2 citation statements)

References 47 publications

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“…In contrast, the acceptor rise time is spectroscopically separated from photophysical heterogeneity, providing a higher signal-to-noise readout for FRET determination. Essentially, the rise time directly isolates the FRET process, which leads to a higher signal-to-noise ratio than indirect methods 25 . Collectively, these advantages are reflected in the improved performance of smART FRET.…”

mentioning

confidence: 99%

Single-molecule acceptor rise time (smART) FRET for nanoscale distance sensitivity

Guo

Chen

Manna

et al. 2023

Preprint

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The structure, dynamics, and binding of individual biomolecules have been extensively investigated using single-molecule Förster resonance energy transfer (smFRET) as a ′spectroscopic ruler.′ The FRET efficiency between a fluorophore pair is used to measure distances in the several nanometer range. Existing approaches to detect closer distances come at the expense of sensitivity to longer distances. Here, we introduce single-molecule acceptor rise-time (smART) FRET that spans closer and longer distances. The acceptor rise time encodes the FRET rate, which scales polynomially with distance and thus has a steep dependence that expands the working range by 50%. High precision and accuracy is achieved through the spectroscopic separation between the rise time and the photophysical fluctuations that obfuscate other FRET readouts. Using the nanoscale sensitivity, we resolved the architectures of DNA bound to the single-stranded binding protein from E. coli, demonstrating the ability of smART FRET to elucidate the complex behaviors of biomolecules.

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confidence: 99%

Single-molecule acceptor rise time (smART) FRET for nanoscale distance sensitivity

Guo

Chen

Manna

et al. 2023

Preprint

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“…However, formalin used to treat the samples should largely limit its application in living cells . Relatively, a fluorescent probe has been widely used in vitro and vivo with respect to its merits such as noninvasion, high selectivity, and high resolution. − Thereinto, aggregation-induced emission (AIE) active fluorophores exhibit unparalleled advantages and have been successfully used in nonsubstrate fluorescent probes. − Meanwhile, terbinafine is one of the most common inhibitors of SQLE . According to the crystal data (PDB: 6C6N) of the inhibitor/SQLE complex, the key recognition structure of the inhibitor is the hydrophobic side chain .…”

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confidence: 99%

Off–On Squalene Epoxidase-Specific Fluorescent Probe for Fast Imaging in Living Cells

Zang¹,

Wang²,

Su³

et al. 2021

Anal. Chem.

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SQLE (squalene epoxidase) is a cell membranebound enzyme. It is a target of fungicides and may become a new target for cancer therapy. Therefore, monitoring the content and distribution of the key enzyme in living cells is very challenging. To achieve this goal, tetraphenyl ethylene-Ter (TPE-Ter) was first designed as a new fluorescent probe to SQLE based on its active cavity. Spectral experiments discovered that SQLE/TPE-Ter shows stronger emission with fast response time and low interference from other analytes. Molecular dynamics simulation clearly confirmed the complex structure of SQLE/TPE-Ter, and the key residues contribute to restriction of TPE-Ter single-molecular motion in the cavity. TPE-Ter-specific response to SQLE is successfully demonstrated in living cells such as LO2, HepG2, and fungi. Imaging of TPE-Ter-treated fungi indicates that it can be used to rapidly assess antifungal drug susceptibility (30 min at least). The present work provides a powerful tool to detect content and distribution of SQLE in living cells.

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Efficient detection ofl-aspartic acid andl-glutamic acid by self-assembled fluorescent microparticles with AIE and FRET activities

Liu

Chai

et al. 2023

Org. Biomol. Chem.

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A FLIM Microscopy Based on Acceptor-Detected Förster Resonance Energy Transfer

Cited by 3 publications

References 47 publications

Single-molecule acceptor rise time (smART) FRET for nanoscale distance sensitivity

Single-molecule acceptor rise time (smART) FRET for nanoscale distance sensitivity

Off–On Squalene Epoxidase-Specific Fluorescent Probe for Fast Imaging in Living Cells

Efficient detection ofl-aspartic acid andl-glutamic acid by self-assembled fluorescent microparticles with AIE and FRET activities

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