Fluorescence resonance energy transfer-based detection of analytes using antiidiotypic affinity protein pairs

A new method for specific detection of proteins based on fluorescence resonance energy transfer (FRET) using affinity proteins (affibodies) derived from combinatorial engineering of Staphylococcal protein A has been developed. Antiidiotypic affibody pairs were used in a homogeneous competitive binding assay, where the idiotypic, target-specific affibody was labeled with fluorescein and the antiidiotypic affibody was labeled with tetramethylrhodamine. Intermolecular FRET between the two fluorescent probes was observed in the antiidiotypic affibody complex, but upon addition of target protein the antiidiotypic affibody was displaced, which was monitored by a shift in the relative emission of the donor and acceptor fluorophores. The feasibility of the system was demonstrated by the detection of IgA and Taq DNA polymerase with high specificity, using two different antiidiotypic affibody pairs. Detection of Taq DNA polymerase in 25% human plasma was successfully carried out, demonstrating that the method can be used for analysis of proteins in samples of complex composition.     

Fluorescence resonance energy transfer-based stoichiometry in living cells

Imaging of fluorescence resonance energy transfer (FRET) between fluorescently labeled molecules can measure the timing and location of intermolecular interactions inside living cells. Present microscopic methods measure FRET in arbitrary units, and cannot discriminate FRET efficiency and the fractions of donor and acceptor in complex. Here we describe a stoichiometric method that uses three microscopic fluorescence images to measure FRET efficiency, the relative concentrations of donor and acceptor, and the fractions of donor and acceptor in complex in living cells. FRET stoichiometry derives from the concept that specific donor-acceptor complexes will give rise to a characteristic FRET efficiency, which, if measured, can allow stoichiometric discrimination of interacting components. A first equation determines FRET efficiency and the fraction of acceptor molecules in complex with donor. A second equation determines the fraction of donor molecules in complex by estimating the donor fluorescence lost due to energy transfer. This eliminates the need for acceptor photobleaching to determine total donor concentrations and allows for repeated measurements from the same cell. A third equation obtains the ratio of total acceptor to total donor molecules. The theory and method were confirmed by microscopic measurements of fluorescence from cyan fluorescent protein (CFP), citrine, and linked CFP-Citrine fusion protein, in solutions and inside cells. Together, the methods derived from these equations allow sensitive, rapid, and repeatable detection of donor-, acceptor-, and donor-acceptor complex stoichiometry at each pixel in an image. By accurately imaging molecular interactions, FRET stoichiometry opens new areas for quantitative study of intracellular molecular networks.     

A high-throughput fluorescence resonance energy transfer-based assay for DNA ligase

DNA ligase is the enzyme that catalyzes the formation of the backbone phosphodiester bond between the 5'-PO(4) and 3'-OH of adjacent DNA nucleotides at single-stranded nicks. These nicks occur between Okazaki fragments during replication of the lagging strand of the DNA as well as during DNA repair and recombination. As essential enzymes for DNA replication, the NAD(+)-dependent DNA ligases of pathogenic bacteria are potential targets for the development of antibacterial drugs. For the purposes of drug discovery, a high-throughput assay for DNA ligase activity is invaluable. This article describes a straightforward, fluorescence resonance energy transfer-based DNA ligase assay that is well suited for high-throughput screening for DNA ligase inhibitors as well as for use in enzyme kinetics studies. Its use is demonstrated for measurement of the steady-state kinetic constants of Haemophilus influenzae NAD(+)-dependent DNA ligase and for measurement of the potency of an inhibitor of this enzyme.     

A fluorescence resonance energy transfer-based method for histone methyltransferases

A simple dye–quencher fluorescence resonance energy transfer (FRET)-based assay for methyltransferases was developed and used to determine kinetic parameters and inhibitory activity at EHMT1 and EHMT2. Peptides mimicking the truncated histone H3 tail were functionalized in each end with a dye and a quencher, respectively. When lysine-9 residues in the peptides were methylated, they were protected from cleavage by endoproteinase–EndoLysC, whereas unmethylated peptides were cleaved, resulting in an increase in fluorescent intensity.     

Fluorescence resonance energy transfer-based assay for DNA-binding protein tagged by green fluorescent protein

Specific interaction between green fluorescent protein (GFP)-tagged human alpha- or gamma-enolase(97-242) (alpha or gammaENO(97-242)) and the rhodamine-labeled DNA fragment containing the c-myc P2 promoter was detected by a fluorescence resonance energy transfer (FRET)-based assay, designated as a "real-time FRET assay." The approach of donor (GFP) and acceptor (rhodamine) was caused by the association between ENO(97-242) and the c-myc P2 promoter, and the time-dependent increase in fluorescence intensity of the reaction mixture was observed at ex=400 nm and em=590 nm. The relative affinity (R(as)) of ENO(97-242) mutants to the wild type was investigated with a real-time FRET assay, and it was clarified that the amino acids that participated in the interaction existed comparatively broadly. Although it was difficult to measure the absolute value of the affinity for the binding protein by using this method, it was possible to investigate the relative affinity of mutants for the wild type. A real-time FRET assay using the GFP-tagged protein could be used as not only a qualitative, but also as a quantitative analysis, this being the best for investigating the key amino acids in binding proteins.     

Upconversion luminescence resonance energy transfer-based aptasensor for the sensitive detection of oxytetracycline

In this work, a biosensor based on luminescence resonance energy transfer (LRET) from NaYF₄:Yb,Tm upconversion nanoparticles (UCNPs) to SYBR Green I has been developed. The aptamers are covalently linked to UCNPs and hybridized with their complementary strands. The subsequent addition of SYBR Green allows SYBR Green I to insert into the formed double-stranded DNA (dsDNA) duplex and brings the energy donor and acceptor into close proximity, leading to the fluorescence of UCNPs transferred to SYBR Green I. When excited at 980 nm, the UCNPs emit luminescence at 477 nm, and this energy is transferred to SYBR Green I, which emits luminescence at 530 nm. In the presence of oxytetracycline (OTC), the aptamers prefer to bind to its corresponding analyte and dehybridize with the complementary DNA. This dehybridization leads to the liberation of SYBR Green I, which distances SYBR Green I from the UCNPs and recovers the UCNPs' luminescence. Under optimal conditions, a linear calibration is obtained between the ratio of I₅₃₀ to I₄₇₇ nm (I₅₃₀/I₄₇₇) and the OTC concentration, which ranges from 0.1 to 10 ng/ml with a limit of detection (LOD) of 0.054 ng/ml.     

A homogeneous, high-throughput fluorescence resonance energy transfer-based DNA polymerase assay

A homogeneous, fluorescence resonance energy transfer (FRET)-based DNA polymerase assay that is suitable for high-throughput screening for inhibitors, and can also be used for steady-state kinetic investigations, is described. The activity, kinetic mechanism, and processivity of the isolated alpha subunit of DNA polymerase III, the product of the dnaE gene, from the gram-negative pathogen Haemophilus influenzae were investigated using the FRET assay.     

Fluorescence lifetime imaging of nuclear DNA: effect of fluorescence resonance energy transfer

BACKGROUND: DNA fluorescence dyes have been used to study DNA dynamics, chromatin structure, and cell cycle analysis. However, most microscopic fluorescence studies of DNA use only steady-state measurements and do not take advantage of the additional information content of the time-resolved fluorescence. In this paper, we combine fluorescence imaging of DNA with time-resolved measurements to examine the proximity of donors and acceptors bound to chromatin. METHODS: We used frequency-domain fluorescence lifetime imaging microscopy to study the spatial distribution of DNA-bound donors and acceptors in fixed 3T3 nuclei. Over 50 cell nuclei were imaged in the presence of an AT-specific donor, Hoechst 33258 (Ho), and a GC-specific acceptor, 7-aminoactinomycin D (7-AAD). RESULTS: The intensity images of Ho alone showed a spatially irregular distribution due to the various concentrations of DNA or AT-rich DNA throughout the nuclei. The lifetime imaging of the Ho-stained nuclei was typically flat. Addition of 7-AAD decreased the fluorescence intensity and lifetime of the Ho-stained DNA. The spatially dependent phase and modulation values of Ho in the presence of 7-AAD showed that the Ho decay becomes nonexponential, as is expected for a resonance energy transfer (RET) with multiple acceptors located over a range of distances. In approximately 40 nuclei, the intensity and lifetime decrease was spatially homogeneous. In approximately 10 nuclei, addition of 7-AAD resulted in a spatially nonhomogeneous decrease in intensity and lifetime. The RET efficiency was higher in G(2)/M than in G(0/1) phase cells. CONCLUSIONS: Because RET efficiency depends on the average distance between Ho and 7-AAD, data suggest that the heterogeneity of lifetimes and spatial variation of the RET efficiency are caused by the presence of highly condensed regions of DNA in nuclei.     

A homogeneous resonance energy transfer-based assay to monitor MutS/DNA interactions

Probing the interactions of the DNA mismatch repair protein MutS with altered and damaged DNA is of great interest both for the understanding of the mismatch repair system function and for the development of tools to detect mutations. Here we describe a homogeneous time-resolved fluorescence (HTRF) assay to study the interactions of Escherichia coli MutS protein with various DNA substrates. First, we designed an indirect HTRF assay on a microtiter plate format and demonstrated its general applicability through the analysis of the interactions between MutS and mismatched DNA or DNA containing the most common lesion of the anticancer drug cisplatin. Then we directly labeled MutS with the long-lived fluorescent donor molecule europium tris-bipyridine cryptate ([TBP(Eu³⁺)]) and demonstrated by electrophoretic mobility shift assay that this chemically labeled protein retained DNA mismatch binding property. Consequently, we used [TBP(Eu³⁺)]-MutS to develop a faster and simpler semidirect HTRF assay.     

Fluorescence resonance energy transfer-based technologies in the study of protein-protein interactions at the cell surface

Understanding of the molecular mechanisms of protein-protein interactions (PPIs) at the cell surface of living cells is fundamental to comprehend the functional meaning of a large number of cellular processes. Here we discuss how new methodological strategies derived from non-invasive fluorescence-based approaches (i.e. fluorescence resonance energy transfer, FRET) have been successfully developed to characterize plasma membrane PPIs. Importantly, these technologies alone - or in concert with complementary methods (i.e. SNAP-tag/TR-FRET, TIRF/FRET) - can become extremely powerful approaches for visualizing cell surface PPIs, even between more than two proteins and also in native tissues. Interestingly, these methods would also be relevant in drug discovery in order to develop new high-throughput screening approaches or to identify new therapeutic targets. Accordingly, herein we provide a thorough assessment on all biotechnological aspects, including strengths and weaknesses, of these fluorescence-based methodologies when applied in the study of PPIs occurring at the cell surface of living cells.     

Detection of DNA mutations by fluorescence resonance energy transfer-based preferential homoduplex formation assay

Molecularly targeted agents for cancer therapy are recognized as being effective and are gaining in popularity. However, the efficacy of the agents depends on the status of the targeted molecule such as the number of molecules expressed, activity, and mutation. Therefore, the use of companion diagnostics for investigating the status of the targeted molecule prior to therapy is highly important. We developed a simple and cost-effective somatic mutation detection method called the fluorescence resonance energy transfer-based preferential homoduplex formation assay (FRET–PHFA). By using double-stranded labeled DNA and fluorescence measurement with thermal control, this method provides higher reproducibility, easier handling, less risk for contamination, shorter assay time (only ∼15 min), and less cost compared with conventional PHFA. Here we report the evaluation of FRET–PHFA on the detection of multiallelic KRAS mutations in codons 12 and 13 compared with the TheraScreen clinical diagnostics kit. We found that FRET–PHFA detected KRAS mutations (1.25–50%) from all cell line DNA titration samples.     

Fluorescence resonance energy transfer-based intracellular assay for the conformation of hepatitis C virus drug target NS5A

Nonstructural protein 5A (NS5A) is essential for hepatitis C virus (HCV) replication and assembly and is a critical drug target. Biochemical data suggest large parts of NS5A are unfolded as an isolated protein, but little is known about its folded state in the cell. We used fluorescence resonance energy transfer (FRET) to probe whether or not different regions of NS5A are in close proximity within the cell. Twenty-three separate reporter constructs were created by inserting one or more fluorophores into different positions throughout the three domains of NS5A. FRET efficiency was maximal when donor and acceptor fluorophores were positioned next to each other but also could be observed when the two fluorophores flanked NS5A domain 1 or domain 3. Informatic and biochemical analysis suggests that large portions of the carboxy terminus of NS5A are in an unfolded and disordered state. Quercetin, a natural product known to disrupt NS5A function in cells, specifically disrupted a conformationally specific domain 3 FRET signal. Intermolecular FRET indicated that the NS5A amino termini, but not other regions, are in close proximity in multimeric complexes. Overall, this assay provides a new window on the intracellular conformation(s) of NS5A and how the conformation changes in response to cellular and viral components of the replication and assembly complex as well as antiviral drugs.     

Fluorescence resonance energy transfer studies of U-shaped DNA molecules

Fluorescence resonance energy transfer studies allow to determine global shape properties of nucleic acids and nucleoprotein complexes. In many DNA-protein complexes, the DNA is more or less bent and the degree of bending can be obtained by FRET. For example, the DNA in complex with the integration host factor (IHF) is kinked by approximately 160 degrees building a U-shaped structure. The two DNA helix ends come close to one another in space in a distance range easily measurable by FRET. The global DNA structure of this complex can be mimicked by introducing two regions with unpaired bases ('bulges') into the DNA each producing a sharp kink of approximately 80 degrees. These U-shaped DNA constructs were used to measure the electrostatic interaction of the two nearly parallel negatively charged DNA helix arms. The electrostatic repulsion between the helix arms, and as a consequence their distance, decreases with growing salt concentration of mono- or divalent cations. This experimental approach also allows the sensitive study of the local structure of DNA sequences positioned between the two bulges.     

Establishment of a fluorescence resonance energy transfer-based bioassay for detecting dioxin-like compounds

Dioxins comprise a group of compounds which contain a double aromatic ring-like structure. They are among the most prevalent and toxic environmental pollutants. Accumulation of dioxins in human tissues poses a potential threat to human health. Currently, analytical chemical procedures dominate dioxin-detection protocols. In this study, we established a fluorescence resonance energy transfer (FRET)-based dioxin-detection bioassay. Aryl hydrocarbon receptor (AHR) and AHR nuclear translocator (ARNT) fused-cyan fluorescent protein (CFP) and -yellow fluorescent protein (YFP) constructed were transiently co-transfected into rat hepatoma cell line, H4IIEC3 cells. Our results showed that no FRET signals were detected in AHR-CFP- and ARNT-YFP-transfected H4IIEC3 cells. However, dioxin treatments upregulated FRET signals in these transfected cells in a dose-dependent manner. This work highlighted the potential of FRET technique in the detection of dioxin-like compounds.     

A time-resolved fluorescence resonance energy transfer-based assay for DEN1 peptidase activity

Neural precursor cell expressed, developmentally down-regulated gene 8 (NEDD8) is a recently discovered ubiquitin-like posttranslational modifier. NEDD8 acts predominantly as a regulator of ubiquitin-protein ligases and as a decoy for proteins targeted for proteasomal degradation. It thereby controls key events in cell cycle progression and embryogenesis. Deneddylase-1 (DEN1/NEDP1/SENP8) features a selective peptidase activity converting the proNEDD8 precursor to its mature form and an isopeptidase activity deconjugating NEDD8 from substrates such as cullins and p53. In this study, we describe a high-throughput screening (HTS)-compatible time-resolved fluorescent resonance energy transfer (TR-FRET) assay measuring the peptidase activity of DEN1.