Time-resolved luminescence resonance energy transfer imaging of protein–protein interactions in living cells

Rajapakse, Harsha E.; Gahlaut, Nivriti; Mohandessi, Shabnam; Yu, Dan; Turner, Jerrold R.; Miller, Leon K.

doi:10.1073/pnas.1002025107

Cited by 133 publications

(117 citation statements)

References 48 publications

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“…However, a wider applicability to cell measurements has to date been limited due to the lack of suitable bright and photo-stable lanthanide complexes and difficulties to specifically attach these probes to proteins or subcellular structures. 12 In addition, LRET measurements require a modulated, high intensity UV excitation source and a time-gated detection rarely offered by standard microscopes.…”

Section: Introductionmentioning

confidence: 99%

Förster Resonance Energy Transfer beyond 10 nm: Exploiting the Triplet State Kinetics of Organic Fluorophores

et al. 2011

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Inter-or intramolecular distances of biomolecules can be studied by Förster resonance energy transfer (FRET). For most FRET methods, the observable range of distances is limited to 1-10 nm and the labeling efficiency has to be controlled carefully to obtain accurate distance determinations, especially for intensity-based methods. In this study, we exploit the triplet state of the acceptor fluorophore as a FRET readout using fluorescence correlation spectroscopy and transient state monitoring. The influence of donor fluorescence leaking into the acceptor channel is minimized by a novel suppression algorithm for spectral bleedthrough, thereby tolerating a high excess (up to 100 fold) of donor-only labeled samples. The suppression algorithm and the high sensitivity of the triplet state to small changes in the fluorophore excitation rate make it possible to extend the observable range of FRET efficiencies by up to 50 % in the presence of large donor-only populations. Given this increased range of FRET efficiencies, its compatibility with organic fluorophores and the low requirements on the labeling efficiency and instrumentation, we foresee that this approach will be attractive for in-vitro and in-vivo FRET-based spectroscopy and imaging.

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Section: Introductionmentioning

confidence: 99%

Förster Resonance Energy Transfer beyond 10 nm: Exploiting the Triplet State Kinetics of Organic Fluorophores

et al. 2011

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“…These experiments constitute a rare example of a timeresolved intracellular FRET experiment, using a lanthanide complexes as the donor 35 , and serve to highlight the potential for future experiments of this type, wherein the lanthanide complex is targeted to a particular organelle to report a biochemical event. …”

Section: Journal Name [Year] [Vol] 00-00mentioning

confidence: 99%

“…6,7 This approach has been developed for a number of fluorescent organic dyes commonly used in cell biology to visualise selected organelles, notably the MitoTracker TM and LysoTracker TM family of stains that reveal the mitochondria and lysosomes selectively. 35 The MitoTracker stains are based upon substituted benzylic chlorides that irreversibly alkylate Cys residues in abundant mitochondrial proteins (e.g. heat shock protein-60, VDAC-1, aldolase-A) 8a and probably also attack mitochondrial DNA, via alkylation at guanine N-7.…”

Section: Introductionmentioning

confidence: 99%

EuroTracker dyes: highly emissive europium complexes as alternative organelle stains for live cell imaging

Lamarque²,

et al. 2014

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Nine very bright europium(III) complexes with different macrocyclic ligands have been prepared that exhibit excellent cell uptake behaviour and distinctive sub-cellular localisation profiles, allowing the use of fluorescence microscopy and time-gated spectral imaging to track their fate in cellulo. Their use as cellular imaging stains is described for the selective illumination of mitochondria, lysosomes or the endoplasmic reticulum of various mammalian cell types.

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“…LRET using LLCs has been applied in a number of applications, including monitoring protein-protein interactions in cells [356], monitoring orthogonal ligand-dependent protein-peptide binding events [352], high-throughput screening of potential drug candidates [357], and numerous in vitro bioassays [347,353,[358][359][360][361]. Kupstat et al, for example, developed a homogeneous time-resolved immunoassay for prostate-specific antigen (PSA) that was sensitive and quantitative, and could be incorporated into a point-of-care testing (POCT) device [360].…”

Section: Luminescent Lanthanide Complexes and Doped Nano-/microparticlesmentioning

confidence: 99%

Materials for FRET Analysis: Beyond Traditional Dye–Dye Combinations

Sapsford

Wildt

Mariani

et al. 2013

FRET – Förster Resonance Energy Transfer

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The intrinsic sensitivity (r 6 dependence) of F€ orster (or fluorescence) resonance energy transfer (FRET) to nanoscale changes in the donor/acceptor separation distance has made FRET an invaluable biophysical tool in a variety of applications, ranging from studying the structure and conformation of proteins and nucleic acids to examining biomolecular interactions, including its use in in vitro and in vivo bioassays [1][2][3][4][5][6][7]. While the myriad of FRET configurations and techniques currently in use are covered throughout this book, here we focus primarily on the materials utilized as donor or acceptor probes in FRET rather than the process itself [3,5,8,9]. Our 2006 review paper on this topic serves as the foundation for this updated chapter [3]. The materials were divided into three main categories: organic materials that include "traditional" dye fluorophores, dark quenchers, polymers, and carbon nanomaterials (NMs); inorganic materials such as metal chelates, metal, and semiconductor nanocrystals; and fluorophores of biological origin such as fluorescent proteins (FPs), amino acids, and fluorescence generated from enzymatic bioluminescence (BL) and chemiluminescence (CL). These materials may function as FRET donors and/or acceptors, depending upon experimental design. Many of the new materials developed and/or new donor-acceptor probe combinations used address some of the inherent complications of more traditional FRET materials, including photobleaching, spectral cross talk, and direct excitation of the acceptor species, and examples of these will be highlighted and discussed throughout the chapter. Since the vast majority of FRET applications are biological in nature, they routinely involve some type of biomolecule labeling strategy, which ultimately plays a significant and fundamental role in the success and interpretation of the resulting FRET. Therefore, we begin the chapter with a brief discussion of the bioconjugation techniques commonly utilized for FRET and points to consider, followed by sections highlighting the current and emerging materials that are used, or have the potential to be used, in FRET applications.

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Time-resolved luminescence resonance energy transfer imaging of protein–protein interactions in living cells

Cited by 133 publications

References 48 publications

Förster Resonance Energy Transfer beyond 10 nm: Exploiting the Triplet State Kinetics of Organic Fluorophores

Förster Resonance Energy Transfer beyond 10 nm: Exploiting the Triplet State Kinetics of Organic Fluorophores

EuroTracker dyes: highly emissive europium complexes as alternative organelle stains for live cell imaging

Materials for FRET Analysis: Beyond Traditional Dye–Dye Combinations

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