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.     

Resonance energy transfer between green fluorescent protein variants: complexities revealed with myosin fusion proteins

Green fluorescent protein and its variants are frequently used as F?rster (fluorescence) resonance energy transfer (FRET) pairs to determine the proximity of protein domains. We prepared fusion proteins comprising yellow fluorescent protein-Dictyostelium myosin II motor domain-cyan fluorescent protein (YFP-myosin-CFP) and compared their FRET properties with an existing construct (GFP-myosin-BFP), containing a green fluorescent protein acceptor and blue fluorescent protein donor [Suzuki, Y., Yasunaga, T., Ohkura, R., Wakabayashi, T. and Sutoh, K. (1998) Nature 396, 380-383]. The latter construct showed an apparent 40% reduction in acceptor fluorescence on ATP addition, when excited via the donor, compared with the YFP-myosin-CFP constructs which showed a small increase (相似文献   

Circularly permuted variants of the green fluorescent protein.

Folding of the green fluorescent protein (GFP) from Aequorea victoria is characterized by autocatalytic formation of its p-hydroxybenzylideneimidazolidone chromophore, which is located in the center of an 11-stranded beta-barrel. We have analyzed the in vivo folding of 20 circularly permuted variants of GFP and find a relatively low tolerance towards disruption of the polypeptide chain by introduction of new termini. All permuted variants with termini in strands of the beta-barrel and about half of the variants with termini in loops lost the ability to form the chromophore. The thermal stability of the permuted GFPs with intact chromophore is very similar to that of the wild-type, indicating that chromophore-side chain interactions strongly contribute to the extraordinary stability of GFP.     

Enhanced fluorescence resonance energy transfer between spectral variants of green fluorescent protein through zinc-site engineering

Although spectral variants of GFP should in theory be suited for fluorescence resonance energy transfer (FRET) and therefore suited for studies of protein-protein interactions, the unfavorable location of the fluorophore 15 A deep inside the GFP molecule has especially impaired this application. Here, metal-ion site engineering around the dimerization interface known from the X-ray structure of GFP is applied to the cyan and the yellow spectral variant of GFP to stabilize the heterodimeric form of these molecules and thereby increase FRET signaling. The FRET signal, determined as the ratio between the maximal emission for the yellow variant, 530 nm, and the cyan variant, 475 nm, during excitation of the cyan variant at 433 nm was increased up to 8-10-fold in the presence of 10(-4) M ZnCl2 by engineering of two symmetric metal-ion sites being either bidentate or tridentate. A similar increase in FRET signaling was however obtained in a pair of molecules in which a single bidentate metal-ion site was generated by introducing a zinc-binding residue in each of the two spectral variants of GFP and therefore creating an obligate heterodimeric pair. It is concluded that FRET signaling between spectral variants of GFP can be increased by stabilizing dimer formation and especially by favoring heterodimer formation in this case performed by metal-ion site engineering.     

A chimera of green fluorescent protein with single chain variable fragment antibody against ginsenosides for fluorescence-linked immunosorbent assay

A chimera of green fluorescent protein extracted from Aequorea coerulescens (AcGFP), a mutant that has been codon optimized for mammalian expression, with single-chain variable fragment (scFv) antibody against ginsenoside Re (GRe-scFv), named fluobody, has been successfully expressed in Escherichia coli (E. coli) to develop simple, speedy, and sensitive fluorescence-linked immunosorbent assay (FLISA). Two chimera proteins were constructed to contain GRe-scFv at the C-terminus of AcGFP (C-fluobody) and at the N-terminus of AcGFP (N-fluobody). These fluobodies were then purified by ion metal affinity chromatography and refolded by stepwise dialysis. The characterization of both fluobodies revealed that C-fluobody was found to be appropriate probe for FLISA as compare with N-fluobody. Furthermore, improvement of limit of detection (LOD) was observed in FLISA using C-fluobody (10 ng/mL) due to its strong fluorescence intensity of AcGFP compared with conventional enzyme-linked immunosorbent assay (ELISA) using parental monoclonal antibody against ginsenoside Re (G-Re), MAb-4G10 (100 ng/mL). Since some steps required in ELISA can be avoided in this present FLISA, speedy and sensitive immunoassay also could be performed using fluobody instead of monoclonal antibody and scFv.     

Homogeneous noncompetitive immunoassay based on the energy transfer between fluorolabeled antibody variable domains (open sandwich fluoroimmunoassay).

The antigen-dependent stabilization of an anti-hen egg lysozyme (HEL) antibody HyHEL-10 variable region was monitored with fluorescence resonance energy transfer (FRET) between fluorolabeled heavy chain (VH) and light chain (VL) fragments. The VH and VL fragments labeled with succinimide esters of fluorescein and rhodamine-X, respectively, were mixed in a cooled cuvette, and the change in fluorescence spectra upon antigen addition was monitored. When excited at 490 nm, significant decrease in the fluorescence at 520 nm and its increase at 605 nm were observed when an increasing amount of HEL was added to the mixture in the concentration range of 1-100 micrograms/mL. The assay, named open sandwich fluoroimmunoassay (FIA), is noncompetitive and homogeneous and can be conducted with one clone of antibody. With the use of appropriate antibodies, it is thought to be a quick and inexpensive alternative to the conventional laborious and/or expensive immunoassays.     

Structural and spectral response of green fluorescent protein variants to changes in pH

The green fluorescent protein (GFP) from the jellyfish Aequorea victoria has become a useful tool in molecular and cell biology. Recently, it has been found that the fluorescence spectra of most mutants of GFP respond rapidly and reversibly to pH variations, making them useful as probes of intracellular pH. To explore the structural basis for the titration behavior of the popular GFP S65T variant, we determined high-resolution crystal structures at pH 8.0 and 4.6. The structures revealed changes in the hydrogen bond pattern with the chromophore, suggesting that the pH sensitivity derives from protonation of the chromophore phenolate. Mutations were designed in yellow fluorescent protein (S65G/V68L/S72A/T203Y) to change the solvent accessibility (H148G) and to modify polar groups (H148Q, E222Q) near the chromophore. pH titrations of these variants indicate that the chromophore pKa can be modulated over a broad range from 6 to 8, allowing for pH determination from pH 5 to pH 9. Finally, mutagenesis was used to raise the pKa from 6.0 (S65T) to 7.8 (S65T/H148D). Unlike other variants, S65T/H148D exhibits two pH-dependent excitation peaks for green fluorescence with a clean isosbestic point. This raises the interesting possibility of using fluorescence at this isosbestic point as an internal reference. Practical real time in vivo applications in cell and developmental biology are proposed.     

Sequential bioluminescence resonance energy transfer-fluorescence resonance energy transfer-based ratiometric protease assays with fusion proteins of firefly luciferase and red fluorescent protein

We report here the preparation of ratiometric luminescent probes that contain two well-separated emission peaks produced by a sequential bioluminescence resonance energy transfer (BRET)–fluorescence resonance energy transfer (FRET) process. The probes are single soluble fusion proteins consisting of a thermostable firefly luciferase variant that catalyze yellow-green (560 nm maximum) bioluminescence and a red fluorescent protein covalently labeled with a near-infrared fluorescent dye. The two proteins are connected by a decapeptide containing a protease recognition site specific for factor Xa, thrombin, or caspase 3. The rates of protease cleavage of the fusion protein substrates were monitored by recording emission spectra and plotting the change in peak ratios over time. Detection limits of 0.41 nM for caspase 3, 1.0 nM for thrombin, and 58 nM for factor Xa were realized with a scanning fluorometer. Our results demonstrate for the first time that an efficient sequential BRET–FRET energy transfer process based on firefly luciferase bioluminescence can be employed to assay physiologically important protease activities.     

Detection of antigen-antibody reaction using a fluorescent probe and its application to homogeneous competitive-type immunoassay for insulin

The interaction of bovine insulin with anti-human insulin antibody (mAb) was examined using a fluorescent probe. The fluorescence intensity of fluoresceinthiocarbamyl (FTC)-insulin was increased by adding mAb, and the increase was saturated at 53% at a molar ratio of FTC-insulin to mAb of 2.0. Based on the change in fluorescence intensity, a standard curve of the homogeneous competitive-type immunoassay was constructed, and the detection range of insulin was found to be 50-400 nM.     

Improved method to raise polyclonal antibody using enhanced green fluorescent protein transgenic mice

Recombinant fusion protein is widely used as an antigen to raise antibodies against the epitope of a target protein. However, the concomitant anticarrier antibody in resulting antiserum reduces the production of the desired antibody and brings about unwanted non-specific immune reactions. It is proposed that the carrier protein transgeulc animal could be used to solve this problem. To validate this hypothesis, enhanced green fluorescent protein （EGFP） transgenic mice were produced. By immunizing the mice with fusion protein His6HAtag-EGFP, we showed that the antiserum from the transgenic mice had higher titer antibody against His6HA tag and lower titer antibody against EGFP compared with that from wild-type mice. Therefore, this report describes an improved method to raise high titer antipeptide polyclonal antibody using EGFP transgenic mice that could have application potential in antibody preparation.     

Use of green fluorescent protein color variants expressed on stable broad-host-range vectors to visualize rhizobia interacting with plants

We developed two sets of broad-host-range vectors that drive expression of the green fluorescent protein (GFP) or color variants thereof (henceforth collectively called autofluorescent proteins [AFPs]) from the lac promoter. These two sets are based on different replicons that are maintained in a stable fashion in Escherichia coli and rhizobia. Using specific filter sets or a dedicated confocal laser scanning microscope setup in which emitted light is split into its color components through a prism, we were able to unambiguously identify bacteria expressing enhanced cyan fluorescent protein (ECFP) or enhanced yellow fluorescent protein (EYFP) in mixtures of the two. Clearly, these vectors will be valuable tools for competition, cohabitation, and rescue studies and will also allow the visualization of interactions between genetically marked bacteria in vivo. Here, we used these vectors to visualize the interaction between rhizobia and plants. Specifically, we found that progeny from different rhizobia can be found in the same nodule or even in the same infection thread. We also visualized movements of bacteroids within plant nodule cells.     

Fluorescence resonance energy transfer analysis of cell surface receptor interactions and signaling using spectral variants of the green fluorescent protein

BACKGROUND: Fluorescence resonance energy transfer (FRET) is a powerful technique for measuring molecular interactions at Angstrom distances. We present a new method for FRET that utilizes the unique spectral properties of variants of the green fluorescent protein (GFP) for large-scale analysis by flow cytometry. METHODS: The proteins of interest are fused in frame separately to the cyan fluorescent protein (CFP) or the yellow fluorescent protein (YFP). FRET between these differentially tagged fusion proteins is analyzed using a dual-laser FACSVantage cytometer. RESULTS: We show that homotypic interactions between individual receptor chains of tumor necrosis factor receptor (TNFR) family members can be detected as FRET from CFP-tagged receptor chains to YFP-tagged receptor chains. Noncovalent molecular complexation can be detected as FRET between fusions of CFP and YFP to either the intracellular or extracellular regions of the receptor chains. The specificity of the assay is demonstrated by the absence of FRET between heterologous receptor pairs that do not biochemically associate with each other. Interaction between a TNFR-like receptor (Fas/CD95/Apo-1) and a downstream cytoplasmic signaling component (FADD) can also be demonstrated by flow cytometric FRET analysis. CONCLUSIONS: The utility of spectral variants of GFP in flow cytometric FRET analysis of membrane receptors is demonstrated. This method of analyzing FRET allows probing of noncovalent molecular interactions that involve both the intracellular and extracellular regions of membrane proteins as well as proteins within the cells. Unlike biochemical methods, FRET allows the quantitative determination of noncovalent molecular associations at Angstrom level in living cells. Moreover, flow cytometry allows quantitative analyses to be carried out on a cell-by-cell basis on large number of cells. Published 2001 Wiley-Liss, Inc.     

Soluble,highly fluorescent variants of green fluorescent protein (GFP) for use in higher plants

Green fluorescent protein (GFP) from Aequorea victoria has rapidly become a standard reporter in many biological systems. However, the use of GFP in higher plants has been limited by aberrant splicing of the corresponding mRNA and by protein insolubility. It has been shown that GFP can be expressed in Arabidopsis thaliana after altering the codon usage in the region that is incorrectly spliced, but the fluorescence signal is weak, possibly due to aggregation of the encoded protein. Through site-directed mutagenesis, we have generated a more soluble version of the codon-modified GFP called soluble-modified GFP (smGFP). The excitation and emission spectra for this protein are nearly identical to wild-type GFP. When introduced into A. thaliana, greater fluorescence was observed compared to the codon-modified GFP, implying that smGFP is brighter because more of it is present in a soluble and functional form. Using the smGFP template, two spectral variants were created, a soluble-modified red-shifted GFP (smRS-GFP) and a soluble-modified blue-fluorescent protein (smBFP). The increased fluorescence output of smGFP will further the use of this reporter in higher plants. In addition, the distinct spectral characters of smRS-GFP and smBFP should allow for dual monitoring of gene expression, protein localization, and detection of in vivo protein-protein interactions.     

Protease-sensitive signalling by chemically engineered intramolecular fluorescent resonance energy transfer mutants of green fluorescent protein

The native cysteine residues of green fluorescent protein (GFP) at positions 48 and 70 were replaced by non-thiolic amino acids, and new cysteine sites were introduced at specific, surface positions. Based on molecular modeling of the GFP structure, the sites chosen for mutagenesis to Cys were glutamic acid at position 6 and isoleucine at position 229. These new, unique cysteine sites provided reactive thiol groups suitable for site-specific chemical modification by eosin-based fluorescence labels. The new constructs were designed to serve as the basis of proof of principle for fluorescence resonance energy transfer (FRET) using an enzyme-activated (trypsin) intervening sequence between native and chemically conjugated fluorophores. These eosin moieties provided chemical FRET partners for the native GFP chromophore. On excitation, these GFP-eosin constructs exhibited strong intramolecular FRET, with quenching of the native GFP (511 nm) fluorophore emission and emission around 540 nm, corresponding to eosin. GFP mutants engineered with trypsin-sensitive sequences close to the eosin site, so that on trypsinolysis FRET was destroyed, the emission wavelength switching from that of the chemical FRET partner back to that of the native GFP fluorophore, providing efficient, ratio-based detection. This protein engineering provides the basis for novel bioprobes for enzymatic triggering using intramolecular FRET between GFP and carefully sited chemical labels.     

Crystallographic and energetic analysis of binding of selected anions to the yellow variants of green fluorescent protein

The fluorescence emission of yellow fluorescent proteins (YFPs) has been shown to respond rapidly and reversibly to changes in the concentration of some small anions such as halides; this allows for the use of YFPs as genetically encodable Cl(-) sensors that may be targeted to specific organelles in living cells. Fluorescence is suppressed due to protonation of the chromophore upon anion binding, with a stronger level of interaction at low pH values. At pH 6.0, the apparent dissociation constant (K(app)) for Cl(-) is 32 mM for YFP and 22 mM for YFP-H148Q, whereas at pH 7.5, K(app) is 777 mM and 154 mM, respectively. In the cytosol, YFP-H148Q appears most promising as a halide sensor due to its high degree of sensitivity towards I(-) (K(app)=23 mM at pH 7.5). To aid in the design of variants with improved levels of specificity and affinity for Cl(-), we solved apo and I(-)-bound crystal structures of YFP-H148Q to 2.1 A resolution. The halide-binding site is found near van der Waals contact with the chromophore imidazolinone oxygen atom, in a small buried cavity adjacent to Arg96, which provides electrostatic stabilization. The halide ion is hydrogen bonded to the phenol group of T203Y, consistent with a mutational analysis that indicates that T203Y is indispensible for tight binding. A series of conformational changes occurs in the amphiphilic site upon anion binding, which appear to be propagated to the beta-bulge region around residue 148 on the protein surface. Anion binding raises the chromophore pK(a) values, since delocalization of the phenolate negative charge over the chromophore skeleton is suppressed. Extraction of microscopic binding constants for the linked equilibrium between anion and proton binding indicates that anion selectivity by YFP is related to hydration forces. Specific suggestions to improve Cl(-) binding to YFP-H148Q based on size and hydration energy are proposed.     

A pair of fluorescent resonance energy transfer-based probes for tyrosine phosphorylation of the CrkII adaptor protein in vivo.

An adaptor protein, CrkII, which is involved in a variety of signaling cascades such as cell growth, migration, and apoptosis, becomes phosphorylated on Tyr(221) upon stimulation. Here, we report on a fluorescent resonance energy transfer-based sensor, which consists of CrkII sandwiched with cyan- and yellow-emitting variants of green fluorescent protein. This protein enabled us to monitor rapid and transient phosphorylation of CrkII upon epidermal growth factor stimulation in a living cell. However, rapid diffusion of the probes prevented us from specifying where the phosphorylation started within the cell. To overcome this problem, we fused the CAAX box of Ki-Ras to the carboxyl terminus of this probe and restricted its localization mostly to the plasma membrane. With this modified probe, we found that epidermal growth factor-induced phosphorylation of CrkII was initiated at the peripheral plasma membrane, moving toward the center of the cell. Moreover, this CAAX box-fused probe showed improvement in sensitivity and time resolution of the monitoring of CrkII phosphorylation. Thus, this pair of CrkII probes visualizes dynamic changes in the total and local levels of the tyrosine phosphorylation of CrkII in a living cell.     

A simple estimation of peroxisomal degradation with green fluorescent protein - an application for cell cycle analysis.

When nutrients are depleted from the environment, mammalian cells begin to degrade their own cytosol and organelles. This bulk protein degradation is mediated by autophagy. In this study, peroxisomes in living CHO-K1 cells were visualized by targeting the green fluorescent protein (GFP) tagged with a type 1 peroxisomal targeting signal. The nutrient-starved condition induced a decay of GFP fluorescence in the peroxisomes and autophagic inhibitors such as 3-methyladenine suppressed the decay of GFP fluorescence (13-60% of starvation). By double labeling the nuclear DNA and peroxisomal GFP, the autophagy specifically occurred at the G1 phase of the cell cycle and the autophagic inhibitors suppressed the G1 arrest. The vital stain technique with GFP is a very simple and useful marker to quantitatively estimate or to further study peroxisomal degradation.