Three-chromophore FRET microscopy to analyze multiprotein interactions in living cells

Galperin, Emilia; Verkhusha, Vladislav V.; Sorkin, Alexander

doi:10.1038/nmeth720

Cited by 175 publications

(179 citation statements)

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“…The use of BiFC allows reconstitution of a fluorescent protein that can be used as a donor or an acceptor. This design would avoid the use of three chromophores for the visualization of ternary complexes (17). Because Cerulean and Venus are a better combination for conventional FRET analysis (7-11) and because Venus-based BiFC allows visualization of protein interactions under physiological conditions and shows higher BiFC efficiency than the YFP-based BiFC system (14), we chose Cerulean and Venus as a donor and an acceptor, respectively, and we used a well characterized Fos-Jun-NFAT system as a model to develop the BiFC-FRET assay.…”

Section: Resultsmentioning

confidence: 99%

“…Contrary to the availability of different fluorescent proteins for FRET-or BiFC-based analysis of individual protein-protein interactions, an easy-to-operate assay for the visualization of ternary complexes in living cells is still lacking. Recently, a threechromophore FRET system has been developed for visualization of ternary complexes (17). Because of the requirement of multiple filters and a complex data process, its application remains very limited.…”

Section: Discussionmentioning

confidence: 99%

“…Unfortunately, demonstration of a ternary complex in cells is a challenging task, and the methods available for visualization and identification of ternary complexes in living cells are extremely limited. Recently, a threechromophore-based FRET system has been developed for visualization of ternary complexes in cells (17). However, this assay has not been widely used because of its sophisticated optical setup and data process.…”

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confidence: 99%

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Visualization of AP-1–NF-κB ternary complexes in living cells by using a BiFC-based FRET

Shyu

Suarez

2008

Proc. Natl. Acad. Sci. U.S.A.

122

100

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Venus ͉ Cerulean ͉ YFP ͉ cross-talk ͉ NFAT P rotein-protein interactions play a pivotal role in mediating signal-transduction pathways and executing cellular functions. Defining how each protein interacts with all possible partners in cells provides insight into cellular roles of individual proteins. This task has become more demanding given that many interacting networks have been generated in the postgenome era (1, 2). Although a number of methods are available for protein interaction study, several fluorescent protein-based methods, such as FRET and bimolecular fluorescence complementation (BiFC), are most widely used because of direct visualization and easy operation (3-5).FRET is an assay that can measure the proximity or distance between a donor and an acceptor. If two fluorophores are fused to a pair of interacting proteins, a fraction of an excited donor fluorophore nonradiatively transfers energy to an acceptor molecule. The efficiency of the energy transfer is defined as the fraction of donor excitation events that results in energy transfer to an acceptor. Hence, FRET efficiency can be used as an indicator of protein-protein interactions (6). Although the most commonly used fluorescent proteins for FRET analysis are CFP and YFP (4-6), development of new fluorescent proteins with improved properties has significantly expanded our choice of selecting appropriate fluorescent proteins for live-cell imaging (4). For example, the YFP mutant Venus and the CFP mutant Cerulean have been developed, and these mutants have shown better properties for live-cell imaging (7-11).We previously used CFP and YFP to develop a BiFC assay and a multicolor BiFC assay for visualization of protein interactions in living cells (12,13). Over the past few years, these assays have been widely used for visualization of protein-protein interactions in living cells and in different model systems (3). Because the YFP-and CFP-based BiFC assays required a preincubation of cells at lower temperature before visualization of BiFC signals because of their sensitivity to higher temperatures, we recently improved the system and demonstrated that several newly developed fluorescent proteins, such as Venus and Cerulean, can be used for BiFC and multicolor BiFC analysis (14). The use of Venus and Cerulean not only allows for BiFC analysis under physiological conditions but also increases the signal output and the specificity (14).Although determination of individual interacting proteins by FRET and BiFC assays provides useful information for function of a pair of interacting proteins, proteins often form multiple protein complexes such as ternary complexes. In particular, many signaling proteins function as ternary complexes. These complexes include membrane-bound receptors, cytoplasmic signaling molecules, and transcriptional regulatory complexes in the nucleus. For example, the formation of ternary complexes of transcriptional regulatory proteins is critical for gene transcription. These complexes include cross-talk between different families...

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Visualization of AP-1–NF-κB ternary complexes in living cells by using a BiFC-based FRET

Shyu

Suarez

2008

Proc. Natl. Acad. Sci. U.S.A.

122

100

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“…The method of sensitized FRET measurements used to examine FRET between CFP and YFP has been described previously (37,38). Briefly, images through YFP, CFP, and FRET filter channels were acquired using a Mariannas TM fluorescence imaging work station consisting of a Zeiss inverted microscope equipped with a cooled charged couple device CoolSnap HQ (Roper, CA), dual filter wheels, and a Xenon 175-watt light source, all controlled by SlideBook software.…”

Section: Methodsmentioning

confidence: 99%

“…Corrected FRET images were presented in a quantitative pseudocolor. The apparent FRET efficiency (E d ) was calculated as described previously (38). All calculations were performed using the FRET statistic module of SlideBook 4.0 or 4.1.…”

Section: Methodsmentioning

confidence: 99%

Enhanced Ubiquitylation and Accelerated Degradation of the Dopamine Transporter Mediated by Protein Kinase C

Miranda

Sorkina

et al. 2005

Journal of Biological Chemistry

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120

133

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Dopamine transporter (DAT) localization in dopaminergic neurons plays an important role in regulating dopamine signaling. However, the mechanisms of DAT trafficking that control DAT localization are still poorly understood. To gain insight into these mechanisms, human DAT was purified in large amounts using a two-step affinity chromatography procedure from untreated HeLa cells or cells treated with phorbol 12-myristate 13-acetate (PMA). Mass spectrometric analysis of purified DAT complexes revealed the presence of several proteins, among which ubiquitin was particularly abundant in the PMA-treated sample. Western blotting of highly purified DAT protein confirmed constitutive ubiquitylation of DAT and a dramatic increase in DAT ubiquitylation in cells treated with PMA. This increase was blocked by pretreatment with the protein kinase C (PKC) inhibitor bis-indolylmaleimide. DAT ubiquitylation by ectopically expressed ubiquitin was demonstrated in cells transiently transfected with yellow fluorescent proteintagged ubiquitin. In addition, fluorescence resonance energy transfer was detected between cyan fluorescent protein-tagged DAT and yellow fluorescent protein-tagged ubiquitin, indicative of DATubiquitin conjugation. Interestingly, the largest fluorescence resonance energy transfer signals were observed in endosomes. Ubiquitylated DAT was detected in the plasma membrane using cell surface biotinylation as well as in intracellular compartments, suggesting that ubiquitylation begins at the plasma membrane and is maintained in endosomes. In both porcine aortic endothelial and HeLa cells, where PKC-dependent DAT ubiquitylation was observed, PKC activation resulted in rapid degradation of DAT (t1 ⁄ 2 ‫؍‬ 1-2 h). Altogether, these data suggest that PKC-induced DAT ubiquitylation may target DAT to lysosomal degradation. The dopamine transporter (DAT)2 is a member of the family of Na ϩ / Cl Ϫ -dependent plasma membrane transporters (SLC6 gene family) that are responsible for rapid clearance of neurotransmitters from the extracellular space. This family also includes norepinephrine, serotonin, ␥-aminobutyric acid, and glycine transporters (1). Members of the SLC6 family share similar predicted topology of a single polypeptide that contains twelve transmembrane segments, a large second extracellular glycosylated loop, and cytoplasmic amino-and carboxyl-terminal tails (2, 3). DAT and several other transporters of this family have been found to be constitutively oligomerized in vitro and in cells (4 -8).The amount of DAT at the plasma membrane and, therefore, dopamine uptake capacity are determined by trafficking of the DAT protein, which is regulated by several signaling cascades including signaling through protein kinase C (PKC). Activation of PKC by 4␣-phorbol 12-myristate 13-acetate (PMA) leads to a reduction in the V max of dopamine transport without a change in the substrate affinity (K m ) as well as in down-regulation of surface DAT protein (9 -15). This downregulation of DAT activity and levels has been shown to be ...

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Basic Microscopic Technique

Isobe

Watanabe

Itoh

2013

Functional Imaging by Controlled Nonlinear Optical Phenomena

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Three-chromophore FRET microscopy to analyze multiprotein interactions in living cells

Cited by 175 publications

References 33 publications

Visualization of AP-1–NF-κB ternary complexes in living cells by using a BiFC-based FRET

Visualization of AP-1–NF-κB ternary complexes in living cells by using a BiFC-based FRET

Enhanced Ubiquitylation and Accelerated Degradation of the Dopamine Transporter Mediated by Protein Kinase C

Basic Microscopic Technique

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