Four-color flow cytometric detection of retrovirally expressed red, yellow, green, and cyan fluorescent proteins

Flow cytometric procedures are described to detect a "humanized" version of a new red fluorescent protein (DsRed) from the coral Discosoma sp. in conjunction with various combinations of three Aequorea victoria green fluorescent protein (GFP) variants--EYFP, EGFP, and ECFP. In spite of overlapping emission spectra, the combination of DsRed with EYFP, EGFP, and ECFP generated fluorescence signals that could be electronically compensated in real time using dual-laser excitation at 458 and 568 nm. Resolution of fluorescence signals from DsRed, EYFP, and EGFP was also readily achieved by single-laser excitation at 488 nm. Since many flow cytometers are equipped with an argon-ion laser that can be tuned to 488 nm, the DsRed/EYFP/EGFP combination is expected to have broad utility for facile monitoring of gene transfer and expression in mammalian cells. The dual-laser technique is applicable for use on flow cytometers equipped with tunable multiline argon-ion and krypton-ion lasers, providing the framework for studies requiring simultaneous analysis of four fluorescent gene products within living cells.     

Expression and recombination of the EGFP and EYFP genes in lentiviral vectors carrying two heterologous promoters

BACKGROUND: Expressing two genes in the progeny of stem and progenitor cells that are transduced with a unique viral vector is desirable in certain situations. We tested the ability of two lentiviral vectors to transduce human cells of hematopoietic origin and concomitantly express two reporter genes, either EGFP (enhanced green fluorescent protein) and DsRed2, or EGFP and EYFP (enhanced yellow fluorescent protein), from two internal promoters. METHODS: The vectors were generated from the pTRIP deltaU3 EF1alpha EGFP lentiviral vector. Following transduction of hematopoietic and non-hematopoietic cell lines, we performed FACS, PCR and Southern blot analyzes to quantify transduction, integration efficiencies and size of integrated lentiviral vectors, respectively. RESULTS: The detection of DsRed2 fluorescence appeared unexpectedly low in human cells of hematopoietic origin. Alternatively, a modification in the flow cytometry assay allowed us to distinguish between the two overlapping fluorescence signals emitted by EGFP and EYFP, when transduced cells were excited with a 488-nm laser beam. However, the low frequency of double-positive EGFP+ EYFP+ cells, and the existence of single-positive, mostly EGFP- EYFP+, cells, prompted us to search for recombinations in the vector sequence. Southern blotting of DNA obtained from transduced cells indeed demonstrated that recombination had occurred between the two closely related EGFP and EYFP sequences. DISCUSSION: These observations suggest that recombination occurred within the EGFP and EYFP genes, which differ by only four amino acids. We conclude that the insertion of two highly homologous sequences into a lentiviral backbone can favor recombination.     

Red fluorescent protein from Discosoma as a fusion tag and a partner for fluorescence resonance energy transfer

The biochemical and biophysical properties of a red fluorescent protein from a Discosoma species (DsRed) were investigated. The recombinant DsRed expressed in E. coli showed a complex absorption spectrum that peaked at 277, 335, 487, 530, and 558 nm. Excitation at each of the absorption peaks produced a main emission peak at 583 nm, whereas a subsidiary emission peak at 500 nm appeared with excitation only at 277 or 487 nm. Incubation of E. coli or the protein at 37 degrees C facilitated the maturation of DsRed, resulting in the loss of the 500-nm peak and the enhancement of the 583-nm peak. In contrast, the 500-nm peak predominated in a mutant DsRed containing two amino acid substitutions (Y120H/K168R). Light-scattering analysis revealed that DsRed proteins expressed in E. coli and HeLa cells form a stable tetramer complex. DsRed in HeLa cells grown at 37 degrees C emitted predominantly at 583 nm. The red fluorescence was imaged using a two-photon laser (Nd:YLF, 1047 nm) as well as a one-photon laser (He:Ne, 543.5 nm). When fused to calmodulin, the red fluorescence produced an aggregation pattern only in the cytosol, which does not reflect the distribution of calmodulin. Despite the above spectral and structural complexity, fluorescence resonance energy transfer (FRET) between Aequorea green fluorescent protein (GFP) variants and DsRed was achieved. Dynamic changes in cytosolic free Ca2+ concentrations were observed with red cameleons containing yellow fluorescent protein (YFP), cyan fluorescent protein (CFP), or Sapphire as the donor and RFP as the acceptor, using conventional microscopy and one- or two-photon excitation laser scanning microscopy. Particularly, the use of the Sapphire-DsRed pair rendered the red cameleon tolerant of acidosis occurring in hippocampal neurons, because both Sapphire and DsRed are extremely pH-resistant.     

Spatio-temporal activation of caspase revealed by indicator that is insensitive to environmental effects

Indicator molecules for caspase-3 activation have been reported that use fluorescence resonance energy transfer (FRET) between an enhanced cyan fluorescent protein (the donor) and enhanced yellow fluorescent protein (EYFP; the acceptor). Because EYFP is highly sensitive to proton (H+) and chloride ion (Cl-) levels, which can change during apoptosis, this indicator's ability to trace the precise dynamics of caspase activation is limited, especially in vivo. Here, we generated an H+- and Cl--insensitive indicator for caspase activation, SCAT, in which EYFP was replaced with Venus, and monitored the spatio-temporal activation of caspases in living cells. Caspase-3 activation was initiated first in the cytosol and then in the nucleus, and rapidly reached maximum activation in 10 min or less. Furthermore, the nuclear activation of caspase-3 preceded the nuclear apoptotic morphological changes. In contrast, the completion of caspase-9 activation took much longer and its activation was attenuated in the nucleus. However, the time between the initiation of caspase-9 activation and the morphological changes was quite similar to that seen for caspase-3, indicating the activation of both caspases occurred essentially simultaneously during the initiation of apoptosis.     

Cyclic AMP-dependent protein kinase binding to A-kinase anchoring proteins in living cells by fluorescence resonance energy transfer of green fluorescent protein fusion proteins.

A-kinase anchoring proteins tether cAMP-dependent protein kinase (PKA) to specific subcellular locations. The purpose of this study was to use fluorescence resonance energy transfer to monitor binding events in living cells between the type II regulatory subunit of PKA (RII) and the RII-binding domain of the human thyroid RII anchoring protein (Ht31), a peptide containing the PKA-binding domain of an A-kinase anchoring protein. RII was linked to enhanced yellow fluorescent protein (EYFP), Ht31 was linked to enhanced cyan fluorescent protein (ECFP), and these constructs were coexpressed in Chinese hamster ovary cells. Upon excitation of the donor fluorophore, Ht31.ECFP, an increase in emission of the acceptor fluorophore, RII.EYFP, and a decrease in emission from Ht31.ECFP were observed. The emission ratio (acceptor/donor) was increased 2-fold (p < 0.05) in cells expressing Ht31.ECFP and RII.EYFP compared with cells expressing Ht31P.ECFP, the inactive form of Ht31, and RII.EYFP. These results provide the first in vivo demonstration of RII/Ht31 interaction in living cells and confirm previous in vitro findings of RII/Ht31 binding. Using surface plasmon resonance, we also showed that the green fluorescent protein tags did not significantly alter the binding of Ht31 to RII. Thus, fluorescence resonance energy transfer can be used to directly monitor protein-protein interactions of the PKA signaling pathway in living cells.     

Application of the fluorescence resonance energy transfer method for studying the dynamics of caspase-3 activation during UV-induced apoptosis in living HeLa cells

Activation of caspase-3 is a central event in apoptosis. We have developed a GFP-based FRET (fluorescence resonance energy transfer) probe that is highly sensitive to the activation of caspase-3 in intact living cells. This probe was constructed by fusing a CFP (cyan fluorescent protein) and a YFP (yellow fluorescent protein) with a specialized linker containing the caspase-3 cleavage sequence: DEVD. The linker design was optimized to produce a large FRET effect. Using purified protein, we observed a fivefold change in the fluorescence emission ratio when the probe was cleaved by caspase-3. To demonstrate the usefulness of this method, we introduced this FRET probe into HeLa cells by both transient and stable transfection. We observed that during UV-induced apoptosis, the activation of caspase-3 varied significantly between different cells; but once the caspase was activated, the enzyme within the cell became fully active within a few minutes. This technique will be highly useful for correlating the caspase-3 activation with other apoptotic events and for rapid-screening of potential drugs that may target the apoptotic process.     

A new pair for inter- and intra-molecular FRET measurement

Fluorescence resonance energy transfer between mutant green fluorescent proteins provides powerful means to monitor in vivo protein-protein proximity and intracellular signaling. However, the current widely applied FRET pair of this class (CFP/YFP) requires excitation by expensive UV lasers, thereby hindering FRET imaging on many confocal microscopes. Further challenges arise from the large spectral overlap of CFP/YFP emission. Another FRET pair GFP/DsRed could obviate such limitations. However, the use of DsRed as a FRET acceptor is hampered by several critical problems, including a slow and incomplete maturation and obligate tetramerization. A tandem dimer mutant of DsRed (TDimer2) has similar spectral properties as those of DsRed. The rapid maturation and non-oligomerization make TDimer2 a promising substitute for DsRed in FRET experiments. Here, we have explored the possibility of using TDimer2 as a FRET acceptor for the donor EGFP. FRET was demonstrated between the EGFP-TDimer2 chimeric fusion protein. By substituting CFP/YFP in the Ca2+-sensor cameleon with EGFP/TDimer2, dynamic changes in cytosolic free Ca2+ concentrations were observed with 488nm excitation under conventional wide-field microscopy. The EGFP/TDimer2 pair was further successfully employed to monitor inter-molecular interaction between Syntaxin and SNAP25. These results reveal EGFP/TDimer2 as a promising FRET pair in monitoring intra-molecular conformation change as well as inter-molecular interaction.     

Room temperature spectrally resolved single-molecule spectroscopy reveals new spectral forms and photophysical versatility of aequorea green fluorescent protein variants

It is known from ensemble spectroscopy at cryogenic temperatures that variants of the Aequorea green fluorescent protein (GFP) occur in interconvertible spectroscopically distinct forms which are obscured in ensemble room temperature spectroscopy. By analyzing the fluorescence of the GFP variants EYFP and EGFP by spectrally resolved single-molecule spectroscopy we were able to observe spectroscopically different forms of the proteins and to dynamically monitor transitions between these forms at room temperature. In addition to the predominant EYFP B-form we have observed the blue-shifted I-form thus far only seen at cryogenic temperatures and have followed transitions between these forms. Further we have identified for EYFP and for EGFP three more, so far unknown, forms with red-shifted fluorescence. Transitions between the predominant forms and the red-shifted forms show a dark time which indicates the existence of a nonfluorescent intermediate. The spectral position of the newly-identified red-shifted forms and their formation via a nonfluorescent intermediate hint that these states may account for the possible photoactivation observed in bulk experiments. The comparison of the single-protein spectra of the red-shifted EYFP and EGFP forms with single-molecule fluorescence spectra of DsRed suggest that these new forms possibly originate from an extended chromophoric pi-system analogous to the DsRed chromophore.     

Two-wavelength fluorescence assay for DNA repair

A simple and reliable quantitative assay for measuring cellular DNA repair capacity has been developed. It is based on the host cell reactivation of the UV-irradiated plasmid pEGFP carrying the marker gene for the enhanced green fluorescent protein (EGFP). As a reference we used the plasmid pEYFP carrying the gene for a red-shifted fluorescent protein (EYFP). Both proteins can be excited by visible light with a maximum at 488 nm, but EGFP emits with a maximum at 509 nm, while EYFP emits with a maximum at 527 nm. This makes it possible to monitor the expression of the two genes simultaneously by measuring the fluorescence at two wavelengths. HEK293 cells were cotransfected with a mixture of UV-irradiated pEGFP and undamaged pEYFP. At different time intervals after transfection the fluorescence of EGFP was determined relative to the fluorescence of EYFP to compensate for any differences in the transfection efficiency or other experimental variables. It was used to calculate the number of UV lesions in DNA and hence the repair capacity of the host cells. It was found that HEK293 cells were able to repair approximately 1.4 UV lesions per 1000 nucleotides DNA for 12 h on the average.     

Genetically encoded FRET-pair on the basis of terbium-binding peptide and red fluorescent protein

The genetically encoded FRET-pair was developed on the basis of terbium-binding peptide and red fluorescent protein DsRed2. To study fluorescence resonance energy transfer within the FRET-pair, the engineered construction was obtained, where sequences of terbium-binding peptide and red fluorescent protein DsRed2 were fused in single reading frame. The expression of this construction in strain E. coli BL21(DE3) was studied and conditions of synthesis, isolation, and purification of recombinant protein were optimized. The hydrodynamic radius of hybrid protein was determined by the method of dynamic diffusion. Energy transfer between sensitized terbium and red fluorescent protein was confirmed by the methods of fluorescence spectroscopy. The obtained FRET-pair may be used both for studies in vitro and as reporters in living cells.     

Multiphoton-evoked color change of DsRed as an optical highlighter for cellular and subcellular labeling.

DsRed, a recently cloned red fluorescent protein, has attracted great interest as an expression tracer and fusion partner for multicolor imaging. We report that three-photon excitation (lambda <760 nm) rapidly changes the fluorescence of DsRed from red to green when viewed subsequently by conventional (one-photon) epifluorescence. Mechanistically, three-photon excitation (lambda <760 nm) selectively bleaches the mature, red-emitting form of DsRed, thereby enhancing emission from the immature green form through reduction of fluorescence resonance energy transfer (FRET). The "greening" effect occurs in live mammalian cells at the cellular and subcellular levels, and the resultant color change persists for >30 h without affecting cell viability. This technique allows individual cells, organelles, and fusion proteins to be optically marked and has potential utility for studying cell lineage, organelle dynamics, and protein trafficking, as well as for selective retrieval of cells from a population. We describe optimal parameters to induce the color change of DsRed, and demonstrate applications that show the potential of this optical highlighter.     

Effect of high pressure and reversed micelles on the fluorescent proteins

Two physico-chemical perturbations were applied to ECFP, EGFP, EYFP and DsRed fluorescent proteins: high hydrostatic pressure and encapsulation in reversed micelles. The observed fluorescence changes were described by two-state model and quantified by thermodynamic formalism. ECFP, EYFP and DsRed exhibited similar reaction volumes under pressure. The changes of the chemical potentials of the chromophore in bis(2-ethylhexyl)sulfosuccinate (AOT) micelles caused apparent chromophore protonation changes resulting in a fluorescence decrease of ECFP and EYFP. In contrast to the remarkable stability of DsRed, the highest sensitivity of EYFP fluorescence under pressure and in micelles is attributed to its chromophore structure.     

Fluorescent Protein Based FRET Pairs with Improved Dynamic Range for Fluorescence Lifetime Measurements

Fluorescence Resonance Energy Transfer (FRET) using fluorescent protein variants is widely used to study biochemical processes in living cells. FRET detection by fluorescence lifetime measurements is the most direct and robust method to measure FRET. The traditional cyan-yellow fluorescent protein based FRET pairs are getting replaced by green-red fluorescent protein variants. The green-red pair enables excitation at a longer wavelength which reduces cellular autofluorescence and phototoxicity while monitoring FRET. Despite the advances in FRET based sensors, the low FRET efficiency and dynamic range still complicates their use in cell biology and high throughput screening. In this paper, we utilized the higher lifetime of NowGFP and screened red fluorescent protein variants to develop FRET pairs with high dynamic range and FRET efficiency. The FRET variations were analyzed by proteolytic activity and detected by steady-state and time-resolved measurements. Based on the results, NowGFP-tdTomato and NowGFP-mRuby2 have shown high potentials as FRET pairs with large fluorescence lifetime dynamic range. The in vitro measurements revealed that the NowGFP-tdTomato has the highest Förster radius for any fluorescent protein based FRET pairs yet used in biological studies. The developed FRET pairs will be useful for designing FRET based sensors and studies employing Fluorescence Lifetime Imaging Microscopy (FLIM).     

Measuring dynamics of caspase-8 activation in a single living HeLa cell during TNFalpha-induced apoptosis

In this study, we reported the first measurement of the dynamics of activation of caspase-8 in a single living cell. This measurement was conducted using a specially developed molecular sensor based on the FRET (fluorescence resonance energy transfer) technique. This sensor was constructed by fusing a CFP (cyan fluorescent protein) and a YFP (yellow fluorescent protein) with a linker containing a tandem caspase-8-specific cleavage site. The change of the FRET ratio upon cleavage was larger than 4-fold. Using this sensor, we found that during TNFalpha-induced apoptosis, the activation of caspase-8 was a slower process than that of caspase-3, and it was initiated much earlier than the caspase-3 activation. Inhibition of caspase-9 delayed the full activation of caspase-3 but did not affect the dynamics of caspase-8. Results of these single-cell measurements suggested that caspase-3 was activated by caspase-8 through two parallel pathways during TNFalpha-induced apoptosis in HeLa cells.     

Photoswitchable cyan fluorescent protein for protein tracking

In recent years diverse photolabeling techniques using green fluorescent protein (GFP)-like proteins have been reported, including photoactivatable PA-GFP, photoactivatable protein Kaede, the DsRed 'greening' technique and kindling fluorescent proteins. So far, only PA-GFP, which is monomeric and gives 100-fold fluorescence contrast, could be applied for protein tracking. Here we describe a dual-color monomeric protein, photoswitchable cyan fluorescent protein (PS-CFP). PS-CFP is capable of efficient photoconversion from cyan to green, changing both its excitation and emission spectra in response to 405-nm light irradiation. Complete photoactivation of PS-CFP results in a 1,500-fold increase in the green-to-cyan fluorescence ratio, making it the highest-contrast monomeric photoactivatable fluorescent protein described to date. We used PS-CFP as a photoswitchable tag to study trafficking of human dopamine transporter in living cells. At moderate excitation intensities, PS-CFP can be used as a pH-stable cyan label for protein tagging and fluorescence resonance energy transfer applications.     

DNA-directed assembly of supramolecular fluorescent protein energy transfer systems

Fluorescent proteins with a wide variety of physicochemical properties have evolved in the past few years. The use of these proteins for applications in biomolecular nanosciences requires their precise positioning at the nanometer length scale. To address this challenge, we report here on the self-organization of DNA-tagged fluorescent probes to construct a set of photofunctional supramolecular complexes which include the enhanced yellow fluorescent protein (EYFP). The optical functionality is based on the strongly distance dependent fluorescence resonance energy transfer (FRET), occurring between the donor (EYFP) and an acceptor fluorophore, i.e., the fluorescent dye Atto647. The photophysical properties of four bimolecular FRET complexes, each possessing a well-defined donor-acceptor distance defined by the length of the interconnecting DNA backbone, are investigated by two-dimensional photoluminescence excitation spectroscopy (2D-PLE).     

Visualizing and quantifying the differential cleavages of the eukaryotic translation initiation factors eIF4GI and eIF4GII in the enterovirus‐infected cell

Enterovirus (EV) infection has been shown to cause a marked shutoff of host protein synthesis, an event mainly achieved through the cleavages of eukaryotic translation initiation factors eIF4GI and eIF4GII that are mediated by viral 2A protease (2A^pro). Using fluorescence resonance energy transfer (FRET), we developed genetically encoded and FRET‐based biosensors to visualize and quantify the specific proteolytic process in intact cells. This was accomplished by stable expression of a fusion substrate construct composed of the green fluorescent protein 2 (GFP²) and red fluorescent protein 2 (DsRed2), with a cleavage motif on eIF4GI or eIF4GII connected in between. The FRET biosensor showed a real‐time and quantifiable impairment of FRET upon EV infection. Levels of the reduced FRET closely correlated with the cleavage kinetics of the endogenous eIF4Gs isoforms. The FRET impairments were solely attributed to 2A^pro catalytic activity, irrespective of other viral‐encoded protease, the activated caspases or general inhibition of protein synthesis in the EV‐infected cells. The FRET biosensors appeared to be a universal platform for several related EVs. The spatiotemporal and quantitative imaging enabled by FRET can shed light on the protease–substrate behaviors in their normal milieu, permitting investigation into the molecular mechanism underlying virus‐induced host translation inhibition. Biotechnol. Bioeng. 2009; 104: 1142–1152. © 2009 Wiley Periodicals, Inc.     

Single- and dual-parameter FRET kinase probes based on pleckstrin

Here we describe protocols for preparing and using fluorescent probes that respond to conformational changes by altered Foerster resonance energy transfer (FRET) efficiencies upon phosphorylation or, in principle, other posttranslational modifications (PTMs). The sensor protein, a truncated version of pleckstrin, is sandwiched between short-wavelength-excitation green fluorescent protein (GFP2) and yellow fluorescent protein (EYFP). As a result of complex conformational changes of the protein upon phosphorylation, the introduction of a second PTM consensus sequence bestows sensitivity to a second modification and yields a dual-parameter probe. The first phase of the protocol lays out the cloning strategy for single- and dual-parameter FRET sensors, including the construction of a versatile platform into which different consensus sequences may be inserted to create diverse probes. Protocols for fluorescence microscopy of the probes in living cells and image processing are also described. Probe preparation takes 7 d; microscopy and image processing take 2 h.