Continuous assay of protein tyrosine phosphatases based on fluorescence resonance energy transfer

An assay method that continuously measures the protein tyrosine phosphatase (PTP)-catalyzed dephosphorylation reaction based on fluorescence resonance energy transfer (FRET) was developed as an improvement of our previously reported discontinuous version [M. Nishikata, K. Suzuki, Y. Yoshimura, Y. Deyama, A. Matsumoto, Biochem. J. 343 (1999) 385-391]. The assay uses oligopeptide substrates that contain (7-methoxycoumarin-4-yl)acetyl (Mca) group as a fluorescence donor and 2,4-dinitrophenyl (DNP) group as a fluorescence acceptor, in addition to a phosphotyrosine residue located between these two groups. In the assay, a PTP solution is added to a buffer solution containing a FRET substrate and chymotrypsin. The PTP-catalyzed dephosphorylation of the substrate and subsequent chymotryptic cleavage of the dephosphorylated substrate results in a disruption of FRET, thereby increasing Mca fluorescence. In this study, we used FRET substrates that are much more susceptible to chymotryptic cleavage after dephosphorylation than the substrate used in our discontinuous assay, thus enabling the continuous assay without significant PTP inactivation by chymotrypsin. The rate of fluorescence increase strictly reflected the rate of dephosphorylation at appropriate chymotrypsin concentrations. Since the continuous assay allows the measurement of initial rate of dephosphorylation reaction, kinetic parameters for the dephosphorylation reactions of FRET substrates by Yersinia, T-cell and LAR PTPs were determined. The continuous assay was compatible with the measurement of very low PTP activity in a crude enzyme preparation and was comparable in sensitivity to assays that use radiolabeled substrates.     

RecQ helicase-catalyzed DNA unwinding detected by fluorescence resonance energy transfer

A fluorometric assay was used to study the DNA unwinding kinetics induced by Escherichiacoli RecQ helicase.This assay was based on fluorescence resonance energy transfer and carried out onstopped-flow,in which DNA unwinding was monitored by fluorescence emission enhancement of fluoresceinresulting from helicase-catalyzed DNA unwinding.By this method,we determined the DNA unwinding rateof RecQ at different enzyme concentrations.We also studied the dependences of DNA unwinding magnitudeand rate on magnesium ion concentration.We showed that this method could be used to determine thepolarity of DNA unwinding.This assay should greatly facilitate further study of the mechanism for RecQ-catalyzed DNA unwinding.     

Real-time monitoring of RNA helicase activity using fluorescence resonance energy transfer in vitro

We have developed a continuous fluorescence assay based on fluorescence resonance energy transfer (FRET) for the monitoring of RNA helicase activity in vitro. The assay is tested using the hepatitis C virus (HCV) NS3 helicase as a model. We prepared a double-stranded RNA (dsRNA) substrate with a 5′ fluorophore-labeled strand hybridized to a 3′ quencher-labeled strand. When the dsRNA is unwound by helicase, the fluorescence of the fluorophore is emitted following the separation of the strands. Unlike in conventional gel-based assays, this new assay eliminates the complex and time-consuming steps, and can be used to simply measure the real-time kinetics in a single helicase reaction. Our results demonstrate that Alexa Fluor 488 and BHQ1 are an effective fluorophore-quencher pair, and this assay is suitable for the quantitative measurement of the RNA helicase activity of HCV NS3. Moreover, we found that several extracts of marine organisms exhibited different inhibitory effects on the RNA and DNA helicase activities of HCV NS3. We propose that this assay will be useful for monitoring the detailed kinetics of RNA unwinding mechanisms and screening RNA helicase inhibitors at high throughput.     

Comparative analysis of fluorescence resonance energy transfer (FRET) and proximity ligation assay (PLA)

Both fluorescence resonance energy transfer (FRET) and proximity ligation assay (PLA) are techniques used in the investigation of protein interactions but the latter has not been evaluated in a systematic way, prompting us to compare their performance quantitatively. Proteins were labeled with oligonucleotide- or fluorophore-conjugated antibodies and their proximity was analyzed by flow cytometry in order to obtain statistically robust data. Both intermolecular and intramolecular PLA signals reached saturation at high expression levels. At the same time, the FRET efficiency was independent of, while the FRET signal exhibited a strict linear correlation with the expression levels of proteins. When the density of oligonucleotide- and fluorophore-conjugated antibodies was systematically changed by competition with unlabeled antibodies the FRET signal was linearly proportional to the amount of bound fluorophore-tagged antibodies, whereas the PLA signal was again saturated. The saturation phenomenon in PLA could not be eliminated by decreasing the duration of the rolling circle amplification reaction. Our data imply that PLA is a semiquantitative measure of protein colocalizations due to non-linear effects in the reaction and that caution should be exercised when interpreting PLA data in a quantitative way.     

Protein biosensors based on the principle of fluorescence resonance energy transfer for monitoring cellular dynamics

Genetically-coded, fluorescence resonance energy transfer (FRET) biosensors are widely used to study molecular events from single cells to whole organisms. They are unique among biosensors because of their spontaneous fluorescence and targeting specificity to both organelles and tissues. In this review, we discuss the theoretical basis of FRET with a focus on key parameters responsible for designing FRET biosensors that have the highest sensitivity. Next, we discuss recent applications that are grouped into four common biosensor design patterns—intermolecular FRET, intramolecular FRET, FRET from substrate cleavage and FRET using multiple colour fluorescent proteins. Lastly, we discuss recent progress in creating fluorescent proteins suitable for FRET purposes. Together these advances in the development of FRET biosensors are beginning to unravel the interconnected and intricate signalling processes as they are occurring in living cells and organisms.     

Fluorescence resonance energy transfer in single enzyme molecules with a quantum dot as donor

H(+)-ATPsynthases couple a transmembrane proton transport with ATP synthesis and ATP hydrolysis. Previously, the relative subunit movement during this process has been measured by fluorescence resonance energy transfer (FRET) between two organic fluorophores covalently bound to different subunits. To improve the photophysical stability, a luminescent CdSe/ZnS nanocrystal (quantum dot) was bound to the enzyme and an organic fluorophore, Alexa568, was used as fluorescence acceptor. Single-molecule spectroscopy with the membrane integrated labeled H(+)-ATPsynthase was carried out. Single-pair FRET indicates three different conformations of the enzyme. During ATP hydrolysis relative intramolecular subunit movements are observed in real time.     

Multiplexed DNA detection using a gold nanorod‐based fluorescence resonance energy transfer technique

A fluorescence resonance energy transfer method for multiplex detection DNA based on gold nanorods had been successfully constructed. This method is simple, easy to operate, good selectivity, no requirement to label the probe molecule and can analyze simultaneously multiple targets of DNA in one sample. The limit of detection for the 18‐mer, 27‐mer and 30‐mer targets is 0.72, 1.0 and 0.43 nM at a signal‐to‐noise ratio of 3. The recoveries of three targets were 96.57–98.07%, 99.12–100.04% and 97.29–99.93%, respectively. The results show that the method can be used to analyze a clinical sample or a biological sample; it also can be used to develop new probes for rapid, sensitive and highly selective multiplex detection of analytes in real samples. Copyright © 2015 John Wiley & Sons, Ltd.     

The co-translational folding and interactions of nascent protein chains: a new approach using fluorescence resonance energy transfer

During protein biosynthesis, a nascent protein is exposed to multiple environments and proteins both inside and outside the ribosome that influence nascent chain folding and trafficking. Fluorescence resonance energy transfer between two dyes incorporated into a single nascent chain using aminoacyl-tRNA analogs can directly and selectively monitor changes in nascent chain conformation. This approach recently revealed the existence and functional ramifications of ribosome-mediated folding of nascent membrane proteins inside the ribosome and can be extended to characterize the effects of chaperones and other proteins and ligands on nascent protein folding, interactions, assembly, and avoidance of misfolding and degradation.     

生物学中荧光共振能量转移的研究应用进展

荧光共振能量转移（FRET）可用于对生物大分子之间的距离进行定性、定量检测,所采用的材料、方法在近年都有了很大的发展,在核酸、蛋白质、细胞器结构功能检测、免疫测定、配体－受体相互作用测定等方面都有巧妙而有效的应用,应用前景十分广阔。     

利用荧光共振能量转移检测外源信号分子对拟南芥ATP水平的影响

本研究使用ATP特异性荧光共振能量转移(Fluorescence resonance energy transfer,FRET)为基础的荧光蛋白传感器(Ateam1.03-nD/nA),分析了4种外源信号分子(细胞外ATP、Ca²⁺、H₂O₂和NO)对拟南芥(Arabidopsis thaliana(L.)Heynh.)幼苗叶绿体和细胞质中ATP水平的影响。结果显示,细胞质ATP水平整体高于叶绿体,在4种不同浓度的信号分子处理下,叶绿体Ateam1.03-nD/nA的FRET比值仅在1.2 ~ 1.8波动;细胞质Ateam1.03-nD/nA 的FRET比值仅在2.2 ～ 3.0之间波动,未产生显著变化。结果表明在以上外源信号分子的作用下,植物细胞质和叶绿体ATP均维持在较为稳定的水平。     

The effects of peptides with estrogen‐like activity on cell proliferation and energy metabolism in human derived vascular smooth muscle cells

Hormone replacement therapy (HRT) for post‐menopausal symptoms in diabetes is associated with increased risk of coronary heart disease and stroke. Therefore, there is a need for new HRT with no adverse effects on diabetic post‐menopausal women. We developed peptides as potential estrogen mimetic compounds and now we evaluated the effects of the most efficacious peptide; hexapeptide estrogen‐mimetic peptide 1 (EMP‐1) (VSWFFE) in comparison to estrogen (E₂) and peptides with weak activity A44 (KAWFFE) and A45 (KRAFFE) on modulation of cell proliferation of vascular smooth muscle cells (VSMC) growing in normal (ng) or high glucose (hg) concentrations. In ng EMP‐1‐like E₂ inhibited cell proliferation at high concentration, and stimulated at low concentration. EMP‐1 did not affect E₂ stimulation of DNA, but inhibited E₂ inhibition of cell proliferation at high concentration. All effects by the combination of EMP‐1 and E₂ were abolished at hg. A44‐stimulated cell proliferation at all concentrations and A45 had no effect. When A44 was co‐incubated with E₂ at both concentrations, DNA synthesis was stimulated, but abolished at hg. A45 abolished E₂ stimulation and inhibition of cell proliferation at both glucose concentrations. All peptides tested except A45‐stimulated CK‐specific activity at both glucose concentrations. In hg A44 stimulation of DNA was unaffected as well as its inhibition by EMP‐1. EMP‐1 and A44 similar to E₂‐stimulated MAPK activity in ng or hg, suggesting similar mechanism of action. The results presented here suggest that EMP‐1 provided it acts similarly in vivo can replace E₂ for treatment of post‐menopausal women in hyperglycemia due to diabetes. J. Cell. Biochem. 110: 1142–1146, 2010. Published 2010 Wiley‐Liss, Inc.     

Single-nucleotide polymorphism analysis using fluorescence resonance energy transfer between DNA-labeling fluorophore,fluorescein isothiocyanate,and DNA intercalator,POPO-3, on bacterial magnetic particles

To develop an analytical system for single-nucleotide polymorphisms (SNPs), the fluorescence resonance energy transfer (FRET) technique was employed on a bacterial magnetic particle (BMP) surface. A combination of fluorescein isothiocyanate (FITC; excitation 490 nm/emission 520 nm) labeled at the 5' end of DNA and an intercalating compound (POPO-3, excitation 534 nm/emission 570 nm) was used to avoid the interference from light scattering caused by nanoparticles. After hybridization between target DNA immobilized onto BMPs and FITC-labeled probes, fluorescence from POPO-3, which was excited by the energy from the FITC, was detected. The major homozygous (ALDH2*1), heterozygous (ALDH2*1/*2), and minor homozygous (ALDH2*2) genotypes in the blood samples were discriminated by this method. The assay described herein allows for a simple and rapid SNP analysis using a fully automated system.     

Microtubule affinity regulating kinase activity in living neurons was examined by a genetically encoded fluorescence resonance energy transfer/fluorescence lifetime imaging-based biosensor: inhibitors with therapeutic potential

Protein kinases of the microtubule affinity regulating kinase (MARK)/Par-1 family play important roles in the establishment of cellular polarity, cell cycle control, and intracellular signal transduction. Disturbance of their function is linked to cancer and brain diseases, e.g. lissencephaly and Alzheimer disease. To understand the biological role of MARK family kinases, we searched for specific inhibitors and a biosensor for MARK activity. A screen of the ChemBioNet library containing ~18,000 substances yielded several compounds with inhibitory activity in the low micromolar range and capable of inhibiting MARK activity in cultured cells and primary neurons, as judged by MARK-dependent phosphorylation of microtubule-associated proteins and its consequences for microtubule integrity. Four of the compounds share a 9-oxo-9H-acridin-10-yl structure as a basis that will serve as a lead for optimization of inhibition efficiency. To test these inhibitors, we developed a cellular biosensor for MARK activity based on a MARK target sequence attached to the 14-3-3 scaffold protein and linked to enhanced cyan or teal and yellow fluorescent protein as FRET donor and acceptor pairs. Transfection of the teal/yellow fluorescent protein sensor into neurons and imaging by fluorescence lifetime imaging revealed that MARK was particularly active in the axons and growth cones of differentiating neurons.     

The localization of the local anesthetic tetracaine in phospholipid vesicles: A fluorescence quenching and resonance energy transfer study

Fluorescence quenching and resonance energy transfer have been used to determine the localization of the local anesthetic tetracaine in vesicles composed of 1,2-dimyristoyl-sn-glycero-3-phosphatidylcholine (DMPC) as a function of both temperature and ionic strength. The fluorescence behaviour of tetracaine in vesicles can be attributed to its different partition coefficients in acid and basic solution, in gel phase and fluid phase vesicles, respectively. Using both steady-state and time-resolved fluorescence measurements we show that a saturable binding rather than a partitioning model holds for the interaction of tetracaine with gel phase bilayers. The relative quenching efficiencies of the series of n-AS dyes depend on the phase state of the bilayer and suggest a deeper incorporation of tetracaine in fluid phase than in gel phase membranes. Resonance energy transfer measurements support the view that tetracaine is incorporated predominantly in the region of the 9-AS chromophore in DMPC-bilayers.     

Fluorescence-based sensing of glucose using engineered glucose/galactose-binding protein: a comparison of fluorescence resonance energy transfer and environmentally sensitive dye labelling strategies

Fluorescence-based glucose sensors using glucose-binding protein (GBP) as the receptor have employed fluorescence resonance energy transfer (FRET) and environmentally sensitive dyes, but with widely varying sensitivity. We therefore compared signal changes in (a) a FRET system constructed by transglutaminase-mediated N-terminal attachment of Alexa Fluor 488/555 as donor and QSY 7 as acceptor at Cys 152 or 182 mutations with (b) GBP labelled with the environmentally sensitive dye badan at C152 or 182. Both FRET systems had a small maximal fluorescence change at saturating glucose (7% and 16%), badan attached at C152 was associated with a 300% maximal fluorescence increase with glucose, though with badan at C182 there was no change. We conclude that glucose sensing based on GBP and FRET does not produce a larger enough signal change for clinical use; both the nature of the environmentally sensitive dye and its site of conjugation seem important for maximum signal change; badan-GBP152C has a large glucose-induced fluorescence change, suitable for development as a glucose sensor.     

Live cell imaging of protein interactions in poliovirus RNA replication complex using fluorescence resonance energy transfer (FRET)

Poliovirus RNA replication is directed by a replication complex on the rosette-like arrangement of membranous vesicles. Proteins derived from the p3 region of the polioviral genome, such as 3D, 3AB, and 3B (VPg), play key roles in the formation and function of the replication complex. In the present study, by using an acceptor photobleaching protocol for fluorescence resonance energy transfer (FRET) imaging, we visualized the interactions of 3D, 3AB, and VPg in living cells. The interaction of 3AB-VPg was determined by live cell FRET analysis. Quantitative analyses showed that the FRET efficiencies of 3AB-3D, VPg-3D, and 3AB-VPg were 3.9 ± 0.4% (n = 36), 4.5 ± 0.4% (n = 39), and 8.3 ± 0.6% (n = 44), respectively, in the cell cytoplasm where viral replication complexes are formed and function. Poliovirus infection enhanced the protein interactions of VPg-3D and 3AB-3D, with FRET efficiencies in the virus-infected cells of 10.7 ± 1.1% (n = 39) and 9.0 ± 0.9% (n = 37), respectively. This method of live cell analysis of protein interactions in the poliovirus RNA replication complex lays the foundation for further understanding of the real-time process of poliovirus RNA replication.     

Caspase-3 sensitive signaling in vivo in apoptotic HeLa cells by chemically engineered intramolecular fluorescence resonance energy transfer mutants of green fluorescent protein

Green fluorescent protein (UV5) was re-engineered to remove native cysteine residues, and a new cysteine was introduced near the C-terminus, approximately 20 A from the native fluorophore, for site-specific attachment of chemical fluorophores. The resultant efficient intramolecular FRET quenched GFP emission and gave a new emission band from the conjugated fluorophore. Caspase-3 cleavage of constructs with a caspase-3 sequence near the C-terminus in the sequence between the native fluorophore and the new cysteine, located C-terminal to the caspase site, destroyed the FRET, the emitted color reverting to that of unmodified GFP. This process was demonstrated in vitro with caspase-3 and lysates from cells undergoing apoptosis. Real-time emission changes for the Alexa Fluor 532 conjugate of this GFP, studied quantitatively in vivo for single HeLa cells using the ratios of fluorescence at the red and green maxima by confocal microscopy, showed that caspase-3 action in the cytosol preceded that in the nucleus.     

Use of fluorescence resonance energy transfer to analyze oligomerization of G-protein-coupled receptors expressed in yeast

Oligomerization or dimerization of G-protein-coupled receptors (GPCRs) has emerged as an important theme in signal transduction. This concept has recently gained widespread interest due to the application of direct and noninvasive biophysical techniques such as fluorescence resonance energy transfer (FRET), which have shown unequivocally that several types of GPCR can form dimers or oligomers in living cells. Current challenges are to determine which GPCRs can self-associate and/or interact with other GPCRs, to define the molecular principles that govern these specific interactions, and to establish which aspects of GPCR function require oligomerization. Although these questions ultimately must be addressed by using GPCRs expressed endogenously in their native cell types, analysis of GPCR oligomerization in heterologous expression systems will be useful to survey which GPCRs can interact, to conduct structure-function studies, and to identify peptides or small molecules that disrupt GPCR oligomerization and function. Here, we describe methods employing scanning fluorometry to detect FRET between GPCRs tagged with enhanced cyan and yellow fluorescent proteins (CFP and YFP) in living yeast cells. This approach provides a powerful means to analyze oligomerization of a variety of GPCRs that can be expressed in yeast, such as adrenergic, adenosine, C5a, muscarinic acetylcholine, vasopressin, opioid, and somatostatin receptors.     

Advanced online monitoring of cell culture off‐gas using proton transfer reaction mass spectrometry

Mass spectrometry has been frequently applied to monitor the O₂ and CO₂ content in the off‐gas of animal cell culture fermentations. In contrast to classical mass spectrometry the proton transfer reaction mass spectrometry (PTR‐MS) provides additional information of volatile organic compounds by application of a soft ionization technology. Hence, the spectra show less fragments and can more accurately assigned to particular compounds. In order to discriminate between compounds of non‐metabolic and metabolic origin cell free experiments and fed‐batch cultivations with a recombinant CHO cell line were conducted. As a result, in total eight volatiles showing high relevance to individual cultivation or cultivation conditions could be identified. Among the detected compounds methanethiol, with a mass‐to‐charge ratio of 49, qualifies as a key candidate in process monitoring due to its strong connectivity to lactate formation. Moreover, the versatile and complex data sets acquired by PTR MS provide a valuable resource for statistical modeling to predict non direct measurable parameters. Hence, partial least square regression was applied to the complete spectra of volatiles measured and important cell culture parameters such as viable cell density estimated (R² = 0.86). As a whole, the results of this study clearly show that PTR‐MS provides a powerful tool to improve bioprocess‐monitoring for mammalian cell culture. Thus, specific volatiles emitted by cells and measured online by the PTR‐MS and complex variables gained through statistical modeling will contribute to a deeper process understanding in the future and open promising perspectives to bioprocess control. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 30:496–504, 2014     

Visualization of beta-secretase cleavage in living cells using a genetically encoded surface-displayed [corrected] FRET probe

The human beta-secretase, BACE, plays a key role in the generation of pathogenic amyloid beta-peptide (Abeta) in Alzheimer's disease and has been identified as an ideal target for therapy. Previous studies reported the monitoring of BACE activity in vitro utilizing chemical synthesized sensors. Here we describe the first genetically encoded FRET probe that can detect BACE activity in vivo. The FRET probe was constructed with the BACE substrate site (BSS) and two mutated green fluorescent proteins. In living cell, the FRET probe was directed to the secretory pathway and anchored on the cell surface to measure BACE enzymatic activity. The results show that the FRET probe can be cleaved by BACE effectively in vivo, suggesting that the probe can be used for real-time monitoring of BACE activity. This assay provides a novel platform for BACE inhibitor screening in vivo.