A natural fluorescent protein that changes its fluorescence during maturation

The gene of a new red fluorescent protein zoan2RFP from a coral polyp Zoanthus sp., a homologue of the known green fluorescent protein from the Aequorea victoria jellyfish, was cloned. At early maturation stages, zoan2RFP exhibits a green fluorescence, which then turns into the red one. A similar phenomenon was recently reported for the E5 mutant of the red fluorescent coral protein DsRed. Zoan2RFP differs from E5 by faster maturation kinetics and the complete disappearance of green fluorescence in the mature protein. Naturally occurring proteins of this type can be considered as intermediate forms between the green and red fluorescent proteins, which are formed during the microevolution of fluorescent proteins.     

Combining protein complementation assays with resonance energy transfer to detect multipartner protein complexes in living cells

A variety of fluorescent proteins with different spectral properties have been created by mutating green fluorescent protein. When these proteins are split in two, neither fragment is fluorescent per se, nor can a fluorescent protein be reconstituted by co-expressing the complementary N- and C-terminal fragments. However, when these fragments are genetically fused to proteins that associate with each other in cellulo, the N- and C-terminal fragments of the fluorescent protein are brought together and can reconstitute a fluorescent protein. A similar protein complementation assay (PCA) can be performed with two complementary fragments of various luciferase isoforms. This makes these assays useful tools for detecting the association of two proteins in living cells. Bioluminescence resonance energy transfer (BRET) or fluorescence resonance energy transfer (FRET) occurs when energy from, respectively, a luminescent or fluorescent donor protein is non-radiatively transferred to a fluorescent acceptor protein. This transfer of energy can only occur if the proteins are within 100 Å of each other. Thus, BRET and FRET are also useful tools for detecting the association of two proteins in living cells. By combining different protein fragment complementation assays (PCA) with BRET or FRET it is possible to demonstrate that three or more proteins are simultaneous parts of the same protein complex in living cells. As an example of the utility of this approach, we show that as many as four different proteins are simultaneously associated as part of a G protein-coupled receptor signalling complex.     

Green fluorescent protein: a perspective

A brief personal perspective is provided for green fluorescent protein (GFP), covering the period 1994-2011. The topics discussed are primarily those in which my research group has made a contribution and include structure and function of the GFP polypeptide, the mechanism of fluorescence emission, excited state protein transfer, the design of ratiometric fluorescent protein biosensors and an overview of the fluorescent proteins derived from coral reef animals. Structure-function relationships in photoswitchable fluorescent proteins and nonfluorescent chromoproteins are also briefly covered.     

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.     

Fluorescent proteins as tools to aid protein production

Fluorescent proteins are genetically encoded, highly versatile reporters useful for monitoring various aspects of recombinant protein production. In addition to the widely popular green fluorescent protein (GFP) from Aequorea victoria, a variety of other fluorescent proteins have been discovered that display a wide range of spectral properties. Synthetic variants have also been developed to overcome limitations associated with their wild-type counterparts. Having a large repertoire of fluorescent proteins with diverse traits opens new opportunities for rapid monitoring and optimization of recombinant protein production.     

Simultaneous visualization of two protein complexes in a single plant cell using multicolor fluorescence complementation analysis

Bimolecular fluorescence complementation (BiFC) is an approach used to analyze protein–protein interaction in vivo, in which non-fluorescent N-terminal and C-terminal fragments of a fluorescent protein are reconstituted to emit fluorescence only when they are brought together by interaction of two proteins to fuse both fragments. A method for simultaneous visualization of two protein complexes by multicolor BiFC with fragments from green fluorescent protein (GFP) and its variants such as cyan and yellow fluorescent proteins (CFP and YFP) was recently reported in animal cells. In this paper we describe a new strategy for simultaneous visualization of two protein complexes in plant cells using the multicolor BiFC with fragments from CFP, GFP, YFP and a red fluorescent protein variant (DsRed-Monomer). We identified nine different BiFC complexes using fragments of CFP, GFP and YFP, and one BiFC complex using fragments of DsRed-Monomer. Fluorescence complementation did not occur by combinations between fragments of GFP variants and DsRed-Monomer. Based on these findings, we achieved simultaneous visualization of two protein complexes in a single plant cell using two colored fluorescent complementation pairs (cyan/red, green/red or yellow/red).     

Chromoproteins of the green fluorescent protein family: Properties and applications

The distribution in nature and the spectral and structural properties of chromoproteins of the green fluorescent protein (GFP) family and their differences from one another and other fluorescent proteins of this family are considered. Discussed in detail are practical applications of the chromoproteins and their mutant variants that have unique characteristics not found among natural proteins of the GFP family, such as far-red or photoconvertible fluorescence, a large Stokes shift, enhanced phototoxicity, etc.     

Peptide signals encode protein localization

Many bacterial proteins are localized to precise intracellular locations, but in most cases the mechanism for encoding localization information is not known. Screening libraries of peptides fused to green fluorescent protein identified sequences that directed the protein to helical structures or to midcell. These peptides indicate that protein localization can be encoded in 20-amino-acid peptides instead of complex protein-protein interactions and raise the possibility that the location of a protein within the cell could be predicted from bioinformatic data.     

Expression of green or red fluorescent protein (GFP or DsRed) linked proteins in nonmuscle and muscle cells

The introduction of the green fluorescent protein (GFP) plasmids that allow proteins and peptides to be expressed with a fluorescent tag has had a major impact on the field of cell biology. It has enabled the dynamics of a wide variety of proteins to be analyzed that could not otherwise be detected in live cells. Transient transfections of muscle and nonmuscle cells with plasmids encoding various cytoskeletal proteins ligated to green fluorescent protein or Ds red protein allow changes in the cytoskeletal network to be studied in the same cell for time periods up to several days. With this approach, proteins that could not be purified and directly labeled with fluorescent dyes and microinjected into cells can now be expressed and visualized in a wide variety of cells. Procedures are presented for transfection of the nonmuscle cell, PtK2, and primary cultures of embryonic chick myocytes, and for studying the live transfected cells.     

A green-emitting fluorescent protein from Galaxeidae coral and its monomeric version for use in fluorescent labeling

We have cloned a gene which encodes a fluorescent protein from the stony coral, Galaxeidae. This protein absorbs light maximally at 492 nm and emits green light at 505 nm, and as a result, we have designated it "Azami-Green (AG)." Despite sharing a similar spectral profile with enhanced green fluorescent protein (EGFP) (Clontech), the most popular variant of the Aequorea victoria green fluorescent protein, the identity between these two proteins at the amino acid level is only 5.7%. However, since AG has a high extinction coefficient, fluorescence quantum yield, and acid stability, it produces brighter green fluorescence in cultured cells than EGFP. Similar to other fluorescent proteins isolated from coral animals, AG forms a tight tetrameric complex, resulting in poor labeling of subcellular structures such as the plasma membrane and mitochondria. We have converted tetrameric AG into a monomeric form by the introduction of three amino acid substitutions, which were recently reported to be effective for monomerizing the red fluorescent protein from Discosoma coral (DsRed, Clontech). The resultant monomeric AG allowed for efficient fluorescent labeling of all of the subcellular structures and proteins tested while retaining nearly all of the brightness of the original tetrameric form. Thus, monomeric AG is a useful monomeric green-emitting fluorescent protein comparable to EGFP.     

Patterns of fluorescent protein expression in Scleractinian corals

Biofluorescence exists in only a few classes of organisms, with Anthozoa possessing the majority of species known to express fluorescent proteins. Most species within the Anthozoan subgroup Scleractinia (reef-building corals) not only express green fluorescent proteins, they also localize the proteins in distinct anatomical patterns.We examined the distribution of biofluorescence in 33 coral species, representing 8 families, from study sites on Australia's Great Barrier Reef. For 28 of these species, we report the presence of biofluorescence for the first time. The dominant fluorescent emissions observed were green (480-520 nm) and red (580-600 nm). Fluorescent proteins were expressed in three distinct patterns (highlighted, uniform, and complementary) among specific anatomical structures of corals across a variety of families. We report no significant overlap between the distribution of fluorescent proteins and the distribution of zooxanthellae. Analysis of the patterns of fluorescent protein distribution provides evidence that the scheme in which fluorescent proteins are distributed among the anatomical structures of corals is nonrandom. This targeted expression of fluorescent proteins in corals produces contrast and may function as a signaling mechanism to organisms with sensitivity to specific wavelengths of light.     

Human glutaredoxin 2 affinity tag for recombinant peptide and protein purification

Recombinant proteins are commonly expressed in fusion with an affinity tag to facilitate purification. We have in the present study evaluated the possible use of the human glutaredoxin 2 (Grx2) as an affinity tag for purification of heterologous proteins. Grx2 is a glutathione binding protein and we have shown in the present study that the protein can be purified from crude bacterial extracts by a one-step affinity chromatography on glutathione-Sepharose. We further showed that short peptides could be fused to either the N- or C-terminus of Grx2 without affecting its ability to bind to the glutathione column. However, when Grx2 was fused to either the 27 kDa green fluorescent protein or the 116 kDa beta-galactosidase, the fusion proteins lost their ability to bind glutathione-Sepharose. Insertion of linker sequences between the Grx2 and the fusion protein did not restore binding to the column. In summary, our findings suggest that Grx2 may be used as an affinity tag for purification of short peptides and possibly also certain proteins that do not interfere with the binding to glutathione-Sepharose. However, the failure of purifying either green fluorescent protein or beta-galactosidase fused to Grx2 suggests that the use of Grx2 as an affinity tag for recombinant protein purification is limited.     

Random PCR-based screening for soluble domains using green fluorescent protein

A novel approach to screen soluble protein domains is presented, by combining tagged random primer polymerase chain reaction (PCR) method and protein-folding assay using green fluorescent protein. Tagged random primer PCR method was used to amplify random DNA fragments from a template cDNA. The PCR products were fused to the green fluorescent protein (GFP) gene. Then solubilities of their translation products were rapidly monitored by the fluorescence of transformed Escherichia coli colonies on plates. We succeeded in cloning four soluble domains from Vav protein using this method. The present method is applicable to all proteins when cDNAs are available.     

Structural characterization of the photoswitchable fluorescent protein Dronpa-C62S

The photoswitching behavior of green fluorescent proteins (GFPs) or GFP-like proteins is increasingly recognized as a new technique for optical marking. Recently, Ando and his colleagues developed a new green fluorescent protein Dronpa, which possesses the unique photochromic property of being photoswitchable in a non-destructive manner. To better understand this mechanism, we determined the crystal structures of a new GFP Dronpa and its mutant C62S, at 1.9 Angstroms and 1.8 Angstroms, respectively. Determination of the structures demonstrates that a unique hydrogen-bonding network and the sulfur atom of the chromophore are critical to the photoswitching property of Dronpa. Reversible photoswitching was lost in cells expressing the Dronpa-C62S upon repetitive irradiation compared to the native protein. Structural and mutational analyses reveal the chemical basis for the functional properties of photoswitchable fluorescent proteins and provide the basis for subsequent coherent engineering of this subfamily of Dronpa homologs.     

A bi-cistronic baculovirus expression vector for improved recombinant protein production

Baculoviruses are one of the most studied insect viruses both in basic virology research and in biotechnology applications. Incorporating an internal ribosome entry site (IRES) into the baculovirus genome generates bi-cistronic baculoviruses expression vectors that produce two genes of interest. The bi-cistronic baculoviruses also facilitate recombinant virus isolation and titer determination when the green fluorescent protein was co-expressed. Furthermore, when the secretion proteins were co-expressed with the cytosolic green fluorescent protein, the cell lysis and cytosolic protein released into the culture medium could be monitored by the green fluorescence, thus facilitating purification of the secreted proteins.     

Natural animal coloration can Be determined by a nonfluorescent green fluorescent protein homolog

It is generally accepted that the colors displayed by living organisms are determined by low molecular weight pigments or chromoproteins that require a prosthetic group. The exception to this rule is green fluorescent protein (GFP) from Aequorea victoria that forms a fluorophore by self-catalyzed protein backbone modification. Here we found a naturally nonfluorescent homolog of GFP to determine strong purple coloration of tentacles in the sea anemone Anemonia sulcata. Under certain conditions, this novel chromoprotein produces a trace amount of red fluorescence (emission lambda(max) = 595 nm). The fluorescence demonstrates unique behavior: its intensity increases in the presence of green light but is inhibited by blue light. The quantum yield of fluorescence can be enhanced dramatically by single amino acid replacement, which probably restores the ancestral fluorescent state of the protein. Other fluorescent variants of the novel protein have emission peaks that are red-shifted up to 610 nm. They demonstrate that long wavelength fluorescence is attainable in GFP-like fluorescent proteins.     

The use of FRET imaging microscopy to detect protein-protein interactions and protein conformational changes in vivo.

Intermolecular and intramolecular FRET between two spectrally overlapping green fluorescent protein variants fused to two different host proteins or at two different sites within the same protein offers a unique opportunity to monitor real-time protein-protein interactions or protein conformational changes. By using fluorescence digital imaging microscopy, one can visualize the location of green fluorescent proteins within a living cell and follow the time course of the changes in FRET corresponding to cellular events at a millisecond time resolution. The observation of such dynamic molecular events in vivo provides vital insight into the action of biological molecules.     

Red fluorescent protein (DsRed) as a reporter in Saccharomyces cerevisiae

We describe the utilization of a red fluorescent protein (DsRed) as an in vivo marker for Saccharomyces cerevisiae. Clones expressing red and/or green fluorescent proteins with both cytoplasmic and nuclear localization were obtained. A series of vectors are now available which can be used to create amino-terminal (N-terminal) and carboxyl-terminal (C-terminal) fusions with the DsRed protein.     

Incomplete proteasomal degradation of green fluorescent proteins in the context of tandem fluorescent protein timers

Tandem fluorescent protein timers (tFTs) report on protein age through time-dependent change in color, which can be exploited to study protein turnover and trafficking. Each tFT, composed of two fluorescent proteins (FPs) that differ in maturation kinetics, is suited to follow protein dynamics within a specific time range determined by the maturation rates of both FPs. So far, tFTs have been constructed by combining slower-maturing red fluorescent proteins (redFPs) with the faster-maturing superfolder green fluorescent protein (sfGFP). Toward a comprehensive characterization of tFTs, we compare here tFTs composed of different faster-maturing green fluorescent proteins (greenFPs) while keeping the slower-maturing redFP constant (mCherry). Our results indicate that the greenFP maturation kinetics influences the time range of a tFT. Moreover, we observe that commonly used greenFPs can partially withstand proteasomal degradation due to the stability of the FP fold, which results in accumulation of tFT fragments in the cell. Depending on the order of FPs in the timer, incomplete proteasomal degradation either shifts the time range of the tFT toward slower time scales or precludes its use for measurements of protein turnover. We identify greenFPs that are efficiently degraded by the proteasome and provide simple guidelines for the design of new tFTs.     

From fixed to FRAP: measuring protein mobility and activity in living cells

Experiments with fluorescence recovery after photobleaching (FRAP) started 30 years ago to visualize the lateral mobility and dynamics of fluorescent proteins in living cells. Its popularity increased when non-invasive fluorescent tagging became possible with the green fluorescent protein (GFP). Many researchers use GFP to study the localization of fusion proteins in fixed or living cells, but the same fluorescent proteins can also be used to study protein mobility in living cells. Here we review the potential of FRAP to study protein dynamics and activity within a single living cell. These measurements can be made with most standard confocal laser-scanning microscopes equipped with photobleaching protocols.