An approach for reducing unwanted oligomerisation of DsRed fusion proteins

Oligomerisation of the red fluorescent protein, DsRed, can interfere with the localisation and function of proteins to which it is fused. We demonstrate an approach that may help to reduce significantly the impact of oligomerisation on the biology of the protein fusion partner. Growth of yeast (Saccharomyces cerevisiae) cells expressing ATP synthase containing subunit gamma-DsRed fusion was compromised relative to control cells. Furthermore, ATP synthase was found to exist as oligomeric structures when isolated under conditions where monomers would normally be present. The compromised growth phenotype was partially reversed and the oligomerisation of the ATP synthase reduced when a non-fluorescent variant of DsRed not fused to another protein was targeted to the mitochondrion in addition to the gamma-DsRed fusion protein. This strategy may also be applicable to the reduction of unwanted interactions between fusion proteins that contain the normally dimeric fluorescent proteins HcRed or Renilla GFP.     

EFGP and DsRed expressing cultures of Escherichia coli imaged by confocal, two-photon and fluorescence lifetime microscopy

The green fluorescent protein (GFP) has become an invaluable marker for monitoring protein localization and gene expression in vivo. Recently a new red fluorescent protein (drFP583 or DsRed), isolated from tropical corals, has been described [Matz, M.V. et al. (1999) Nature Biotech. 17, 969-973]. With emission maxima at 509 and 583 nm respectively, EGFP and DsRed are suited for almost crossover free dual color labeling upon simultaneous excitation. We imaged mixed populations of Escherichia coli expressing either EGFP or DsRed by one-photon confocal and by two-photon microscopy. Both excitation modes proved to be suitable for imaging cells expressing either of the fluorescent proteins. DsRed had an extended maturation time and E. coli expressing this fluorescent protein were significantly smaller than those expressing EGFP. In aging bacterial cultures DsRed appeared to aggregate within the cells, accompanied by a strong reduction in its fluorescence lifetime as determined by fluorescence lifetime imaging microscopy.     

利用荧光蛋白对大肠杆菌蛋白质Tat转运系统的研究

探讨了荧光蛋白作为报告蛋白用于蛋白质转运系统研究的可行性 ,结果表明海葵红色荧光蛋白聚集在细胞质内 ,不能转运至周质空间。而水母绿色荧光蛋白在Tat信号肽和Tat转运酶的共同作用下 ,以折叠形式转运至周质空间。通过荧光定量分析表明信号肽保守序列中的双精氨酸是保证绿色荧光蛋白转运及转运效率所必需的 ,且第二个精氨酸比第一个精氨酸更为重要。同时 ,揭示了Tat信号肽需要一定的高级结构才能行使功能 ;Tat信号肽不仅引导蛋白质的转运 ,而且也参与蛋白质的折叠。因此 ,绿色荧光蛋白是非常理想的报告蛋白 ,可用于研究Tat系统 ,但是海葵红色荧光蛋白易于聚集而不适合于此目的。     

Three-color imaging using fluorescent proteins in living zebrafish embryos

The zebrafish embryo is especially valuable for cell biological studies because of its optical clarity. In this system, use of an in vivo fluorescent reporter has been limited to green fluorescent protein (GFP). We have examined other fluorescent proteins alone or in conjunction with GFP to investigate their efficacy as markers for multi-labeling purposes in live zebrafish. By injecting plasmid DNA containing fluorescent protein expression cassettes, we generated single-, double-, or triple-labeled embryos using GFP, blue fluorescent protein (BFP, a color-shifted GFP), and red fluorescent protein (DsRed, a wild-type protein structurally related to GFP). Fluorescent imaging demonstrates that GFP and DsRed are highly stable proteins, exhibiting no detectable photoinstability, and a high signal-to-noise ratio. BFP demonstrated detectable photoinstability and a lower signal-to-noise ratio than either GFP or DsRed. Using appropriate filter sets, these fluorescent proteins can be independently detected even when simultaneously expressed in the same cells. Multiple labels in individual zebrafish cells open the door to a number of biological avenues of investigation, including multiple, independent tags of transgenic fish lines, lineage studies of wild-type proteins expressed using polycistronic messages, and the detection of protein-protein interactions at the subcellular level using fluorescent protein fusions.     

A red fluorescent protein, DsRed2, as a visual reporter for transient expression and stable transformation in soybean

Fluorescent proteins such as green fluorescent protein (GFP) from Aequorea victoria are often used as markers for transient expression and stable transformation in plants, given that their detection does not require a substrate and they can be monitored in a nondestructive manner. We have now evaluated the red fluorescent protein DsRed2 (a mutant form of DsRed from Discosoma sp.) for its suitability as a visual marker in combination with antibiotic selection for genetic transformation of soybean [Glycine max (L.) Merrill]. Transient and stable expression of DsRed2 in somatic embryos was readily detected by fluorescence microscopy, allowing easy confirmation of gene introduction. We obtained several fertile transgenic lines, including homozygous lines, that grew and produced seeds in an apparently normal manner. The red fluorescence of DsRed2 was detected by fluorescence microscopy without background fluorescence in both leaves and seeds of the transgenic plants. Furthermore, in contrast to seeds expressing GFP, those expressing DsRed2 were readily identifiable even under white light by the color conferred by the transgene product. The protein composition of seeds was not affected by the introduction of DsRed2, with the exception of the accumulation of DsRed2 itself, which was detectable as an additional band on electrophoresis. These results indicate that DsRed2 is a suitable reporter (even more suitable than GFP) for genetic transformation of soybean.     

An enhanced mutant of red fluorescent protein DsRed for double labeling and developmental timer of neural fiber bundle formation.

We developed a new variant of coral-derived red fluorescent protein, DsRed S197Y, which is brighter and essentially free from secondary fluorescence peak. This makes it an ideal reporter for double labeling with green fluorescent protein (GFP). Though purified protein shows only 20% stronger fluorescence emission, culture cells that express DsRed S197Y exhibit a 3-3.5 times higher level of fluorescence than the cells that express wild-type DsRed. The much slower fluorescence maturation of DsRed than that of GFP is a beneficial feature for a fluorescent developmental timer application. When GFP and DsRed S197Y are expressed simultaneously, emissions start at different latency. This provides information about the time after the onset of expression. It reflects the order of cell differentiation if the expression is activated upon differentiation of certain types of cells. We applied this system to the developing brain of Drosophila and visualized, for the first time, the formation order of neural fibers within a large bundle. Our results showed that newly extending fibers of the mushroom body neurons mainly run into the core rather than to the periphery of the existing bundle. DsRed-based timer thus presents an indispensable tool for developmental biology and genetics of model organisms.     

Simultaneous detection of DsRed2-tagged and EGFP-tagged human beta-interferons in the same single cells

The red fluorescent protein DsRed2 is a useful fusion tag for various proteins, together with the enhanced green fluorescent protein (EGFP). These chromoproteins have spectral properties that allow simultaneous distinctive detection of tagged proteins in the same single cells by dual color imaging. We used them for tagging a secretory protein, human interferon-beta (IFN-beta). Expression plasmids for human IFN-beta tagged with DsRed2 or with EGFP at the carboxyl terminal were constructed and their coexpression was examined in Mardin-Darby canine kidney epithelial cells. Although maturation of DsRed2 for coloration was slow and the color intensity was weak compared with EGFP, low temperature treatment (20 degrees C) allowed DsRed2-tagged human IFN-beta to be detected in the cells using color imaging. Consequently, the two chimeric proteins were shown to be colocalized in the same single cells by dual color confocal microscopy. This approach will be useful for investigating subcellular localization of not only cell resident proteins but also secretory proteins.     

The structural basis for red fluorescence in the tetrameric GFP homolog DsRed

Green fluorescent protein (GFP) has rapidly become a standard tool for investigating a variety of cellular activities, and has served as a model system for understanding spectral tuning in chromophoric proteins. Distant homologs of GFP in reef coral and anemone display two new properties of the fluorescent protein family: dramatically red-shifted spectra, and oligomerization to form tetramers. We now report the 1.9 A crystal structure of DsRed, a red fluorescent protein from Discosoma coral. DsRed monomers show similar topology to GFP, but additional chemical modification to the chromophore extends the conjugated pi-system and likely accounts for the red-shifted spectra. Oligomerization of DsRed occurs at two chemically distinct protein interfaces to assemble the tetramer. The DsRed structure reveals the chemical basis for the functional properties of red fluorescent proteins and provides the basis for rational engineering of this subfamily of GFP homologs.     

Dual labeling of Pseudomonas putida with fluorescent proteins for in situ monitoring of conjugal transfer of the TOL plasmid

We describe here a dual-labeling technique involving the green fluorescent protein (GFP) and the red fluorescent protein (DsRed) for in situ monitoring of horizontal gene transfer via conjugation. A GFPmut3b-tagged derivative of narrow-host-range TOL plasmid (pWWO) was delivered to Pseudomonas putida KT2442, which was chromosomally labeled with dsRed by transposon insertion via biparental mating. Green and red fluorescent proteins were coexpressed in donor P. putida cells. Cells expressing both fluorescent proteins were smaller in size than cells expressing GFP alone. Donors and transconjugants in mixed culture or sludge samples were discriminated on the basis of their fluorescence by using confocal laser scanning microscopy. Conjugal plasmid transfer frequencies on agar surfaces and in sludge microcosms were determined microscopically without cultivation. This method worked well for in situ monitoring of horizontal gene transfer in addition to tracking the fate of microorganisms released into complex environments. To the best of our knowledge, this is the first study that discusses the coexpression of GFP and DsRed for conjugal gene transfer studies.     

Ataxin-1 fusion partners alter polyQ lethality and aggregation

Intranuclear inclusion bodies (IBs) are the histopathologic markers of multiple protein folding diseases. IB formation has been extensively studied using fluorescent fusion products of pathogenic polyglutamine (polyQ) expressing proteins. These studies have been informative in determining the cellular targets of expanded polyQ protein as well as the methods by which cells rid themselves of IBs. The experimental thrust has been to intervene in the process of polyQ aggregation in an attempt to alleviate cytotoxicity. However new data argues against the notion that polyQ aggregation and cytotoxicity are inextricably linked processes. We reasoned that changing the protein context of a disease causing polyQ protein could accelerate its precipitation as an IB, potentially reducing its cytotoxicity. Our experimental strategy simply exploited the fact that conjoined proteins influence each others folding and aggregation properties. We fused a full-length pathogenic ataxin-1 construct to fluorescent tags (GFP and DsRed1-E5) that exist at different oligomeric states. The spectral properties of the DsRed1-E5-ataxin-1 transfectants had the additional advantage of allowing us to correlate fluorochrome maturation with cytotoxicity. Each fusion protein expressed a distinct cytotoxicity and IB morphology. Flow cytometric analyses of transfectants expressing the greatest fluorescent signals revealed that the DsRed1-E5-ataxin-1 fusion was more toxic than GFP fused ataxin-1 (31.8+/-4.5% cell death versus 12.85+/-3%), although co-transfection with the GFP fusion inhibited maturation of the DsRed1-E5 fluorochrome and diminished the toxicity of the DsRed1-E5-ataxin-1 fusion. These data show that polyQ driven aggregation can be influenced by fusion partners to generate species with different toxic properties and provide new opportunities to study IB aggregation, maturation and lethality.     

Dual Labeling of Pseudomonas putida with Fluorescent Proteins for In Situ Monitoring of Conjugal Transfer of the TOL Plasmid

We describe here a dual-labeling technique involving the green fluorescent protein (GFP) and the red fluorescent protein (DsRed) for in situ monitoring of horizontal gene transfer via conjugation. A GFPmut3b-tagged derivative of narrow-host-range TOL plasmid (pWWO) was delivered to Pseudomonas putida KT2442, which was chromosomally labeled with dsRed by transposon insertion via biparental mating. Green and red fluorescent proteins were coexpressed in donor P. putida cells. Cells expressing both fluorescent proteins were smaller in size than cells expressing GFP alone. Donors and transconjugants in mixed culture or sludge samples were discriminated on the basis of their fluorescence by using confocal laser scanning microscopy. Conjugal plasmid transfer frequencies on agar surfaces and in sludge microcosms were determined microscopically without cultivation. This method worked well for in situ monitoring of horizontal gene transfer in addition to tracking the fate of microorganisms released into complex environments. To the best of our knowledge, this is the first study that discusses the coexpression of GFP and DsRed for conjugal gene transfer studies.     

Ligand-dependent inhibition of oligomerization at the human thyrotropin receptor

Recently, several studies have reported oligomerization of G protein-coupled receptors, although the functional implications of this phenomenon are still unclear. Using fluorescence resonance energy transfer (FRET) and coimmunoprecipitation (COIP), we previously reported that the human thyrotropin (TSH) receptor tagged with green fluorescent protein (TSHR(GFP)) and expressed in a heterologous system was present as oligomeric complexes on the cell surface. Here, we have extended this biophysical and biochemical approach to study the regulation of such oligomeric complexes. Co-expression of TSHR(GFP) and TSHR(Myc) constructs in Chinese hamster ovary cells resulted in FRET-positive cells. The specificity of the FRET signal was verified by the absence of energy transfer in individually transfected TSHR(GFP) and TSHR(Myc):Cy3 cells cultured together and also by acceptor photobleaching. Occupation of the receptor molecule by the ligand (TSH) resulted in a dose-dependent decrease in the FRET index from 20% in the absence of TSH to <1% with 10(3) microunits/ml of TSH. Such reduction in oligomeric forms was also confirmed by coimmunoprecipitation. Exposure of TSHR(GFP/Myc) cells to forskolin or cytochalasin D caused no change in the FRET index, confirming that the decrease in the oligomeric complexes was a receptor-dependent phenomenon and free of energy or microtuble requirements. The TSH-induced decrease in TSHR oligomers was found to be secondary to dissociation of the TSHR complexes as evidenced by an increase in fluorescent intensity of photobleached spots of GFP fluorescence with 10(3) microunits/ml of TSH. These data indicated that the less active conformation of the TSHR was comprised of receptor complexes and that such complexes were dissociated on the binding of ligand. Such observations support the concept of a constitutively active TSHR dimer or monomer that is naturally inhibited by the formation of higher order complexes. Inhibition of these oligomeric forms by ligand binding returns the TSHR to an activated state.     

New rfp- and pES213-derived tools for analyzing symbiotic Vibrio fischeri reveal patterns of infection and lux expression in situ

Genetically altered or tagged Vibrio fischeri strains can be observed in association with their mutualistic host Euprymna scolopes, providing powerful experimental approaches for studying this symbiosis. Two limitations to such in situ analyses are the lack of suitably stable plasmids and the need for a fluorescent tag that can be used in tandem with green fluorescent protein (GFP). Vectors previously used in V. fischeri contain the p15A replication origin; however, we found that this replicon is not stable during growth in the host and is retained by fewer than 20% of symbionts within a day after infection. In contrast, derivatives of V. fischeri plasmid pES213 were retained by approximately 99% of symbionts even 3 days after infection. We therefore constructed pES213-derived shuttle vectors with a variety of selectable and visual markers. To include a visual tag that can be used in conjunction with GFP, we compared seven variants of the DsRed2 red fluorescent protein (RFP): mRFP1, tdimer2(12), DsRed.T3, DsRed.T4, DsRed.M1, DsRed.T3_S4T, and DsRed.T3(DNT). The last variant was brightest, displaying >20-fold more fluorescence than DsRed2 in V. fischeri. RFP expression did not detectably affect the fitness of V. fischeri, and cells were readily visualized in combination with GFP-expressing cells in mixed infections. Interestingly, even when inocula were dense enough that most E. scolopes hatchlings were infected by two strains, there was little mixing of the strains in the light organ crypts. We also used constitutive RFP in combination with the luxICDABEG promoter driving expression of GFP to visualize the spatial and temporal induction of this bioluminescence operon during symbiotic infection. Our results demonstrate the utility of pES213-based vectors and RFP for in situ experimental approaches in studies of the V. fischeri-E. scolopes symbiosis.     

Characterization of a randomized FRET library for protease specificity determination

Protease specificity determination is an important first step when characterizing novel proteases. Given the large number of proteases that are known to exist from genomic sequencing efforts, we reason that sensitive, reliable, and high-throughput methods to determine protease specificity must be developed. This study describes the construction and initial characterization of a protein based FRET library using the fluorescent proteins GFP and DsRed for such a purpose. Using a DNA "cassette" that allowed for directional insertion of annealed oligonucleotides between the genes encoding the GFP and DsRed proteins, we constructed a library using a mixture of standard nucleotide bases at 27 positions in the center of the oligonucleotide cassette. This resulted in a randomized linker region between these fluorescent donor-acceptor pairs to produce substrates with varied amino acids located between the proteins. Kinetic assays were then performed and monitored using the increase in GFP fluorescence to arrive at relative reaction velocities for a set of enzymes. These results demonstrated the ability of the enzymes tested to discriminate between different substrates and the resistance of GFP and DsRed to proteolysis. Colony screening, using color development and restriction enzyme digests, were shown to help eliminate DNA samples in the library that contained stop codons and/or deletions and a flow plan for the efficient use of the library is presented.     

Fluorescent proteins for single‐molecule fluorescence applications

We present single‐molecule fluorescence data of fluorescent proteins GFP, YFP, DsRed, and mCherry, a new derivative of DsRed. Ensemble and single‐molecule fluorescence experiments proved mCherry as an ideally suited fluorophore for single‐molecule applications, demonstrated by high photostability and rare fluorescence‐intensity fluctuations. Although mCherry exhibits the lowest fluorescence quantum yield among the fluorescent proteins investigated, its superior photophysical characteristics suggest mCherry as an ideal alternative in single‐molecule fluorescence experiments. Due to its spectral characteristics and short fluorescence lifetime of 1.46 ns, mCherry complements other existing fluorescent proteins and is recommended for tracking and localization of target molecules with high accuracy, fluorescence resonance energy transfer (FRET), fluorescence lifetime imaging microscopy (FLIM), or multicolor applications. (© 2008 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Coordinate expression of multiple proteins in plant cells by exploiting endogenous kex2p-like protease activity

Simultaneous expression of multiple proteins in plants finds ample applications. Here, we examined the biotechnological application of native kex2p-like protease activity in plants for coordinate expression of multiple secretory proteins from a single transgene encoding a cleavable polyprotein precursor. We expressed a secretory red fluorescent protein (DsRed) or human cytokine (GMCSF), fused to a downstream green fluorescent protein (GFP) by a linker containing putative recognition sites of the kex2p-like protease in tobacco cells and referred to them as RKG and GKG cells, respectively. Our analyses showed that GFP is cleaved off the fusion proteins and secreted into the media by both RKG and GKG cells. The cleaved GFP product displayed the expected fluorescence characteristics. Using GFP immunoprecipitation and fluorescence analysis, the cleaved DsRed product in the RKG cells was found to be functional as well. However, DsRed was not detected in the RKG culture medium, possibly due to its tetramer formation. Cleaved and biologically active GMCSF could also be detected in GKG cell extracts, but secreted GMCSF was found to be only at a low level, likely because of instability of GMCSF protein in the medium. Processing of polyprotein precursors was observed to be similarly effective in tobacco leaf, stem and root tissues. Importantly, we also demonstrated that, via agroinfiltration, polyprotein precursors can be efficiently processed in plant species other than tobacco. Collectively, our results demonstrate the utility of native kex2p-like protease activity for the expression of multiple secretory proteins in plant cells using cleavable polyprotein precursors containing kex2p linker(s).     

Mobilization of rubisco and stroma-localized fluorescent proteins of chloroplasts to the vacuole by an ATG gene-dependent autophagic process

During senescence and at times of stress, plants can mobilize needed nitrogen from chloroplasts in leaves to other organs. Much of the total leaf nitrogen is allocated to the most abundant plant protein, Rubisco. While bulk degradation of the cytosol and organelles in plants occurs by autophagy, the role of autophagy in the degradation of chloroplast proteins is still unclear. We have visualized the fate of Rubisco, stroma-targeted green fluorescent protein (GFP) and DsRed, and GFP-labeled Rubisco in order to investigate the involvement of autophagy in the mobilization of stromal proteins to the vacuole. Using immunoelectron microscopy, we previously demonstrated that Rubisco is released from the chloroplast into Rubisco-containing bodies (RCBs) in naturally senescent leaves. When leaves of transgenic Arabidopsis (Arabidopsis thaliana) plants expressing stroma-targeted fluorescent proteins were incubated with concanamycin A to inhibit vacuolar H(+)-ATPase activity, spherical bodies exhibiting GFP or DsRed fluorescence without chlorophyll fluorescence were observed in the vacuolar lumen. Double-labeled immunoelectron microscopy with anti-Rubisco and anti-GFP antibodies confirmed that the fluorescent bodies correspond to RCBs. RCBs could also be visualized using GFP-labeled Rubisco directly. RCBs were not observed in leaves of a T-DNA insertion mutant in ATG5, one of the essential genes for autophagy. Stroma-targeted DsRed and GFP-ATG8 fusion proteins were observed together in autophagic bodies in the vacuole. We conclude that Rubisco and stroma-targeted fluorescent proteins can be mobilized to the vacuole through an ATG gene-dependent autophagic process without prior chloroplast destruction.     

Light-induced flickering of DsRed provides evidence for distinct and interconvertible fluorescent states

Green fluorescent protein (GFP) from jellyfish Aequorea victoria, the powerful genetically encoded tag presently available in a variety of mutants featuring blue to yellow emission, has found a red-emitting counterpart. The recently cloned red fluorescent protein DsRed, isolated from Discosoma corals (), with its emission maximum at 583 nm, appears to be the long awaited tool for multi-color applications in fluorescence-based biological research. Studying the emission dynamics of DsRed by fluorescence correlation spectroscopy (FCS), it can be verified that this protein exhibits strong light-dependent flickering similar to what is observed in several yellow-shifted mutants of GFP. FCS data recorded at different intensities and excitation wavelengths suggest that DsRed appears under equilibrated conditions in at minimum three interconvertible states, apparently fluorescent with different excitation and emission properties. Light absorption induces transitions and/or cycling between these states on time scales of several tens to several hundreds of microseconds, dependent on excitation intensity. With increasing intensity, the emission maximum of the static fluorescence continuously shifts to the red, implying that at least one state emitting at longer wavelength is preferably populated at higher light levels. In close resemblance to GFP, this light-induced dynamic behavior implies that the chromophore is subject to conformational rearrangements upon population of the excited state.     

Rapidly maturing variants of the Discosoma red fluorescent protein (DsRed).

The red fluorescent protein DsRed has spectral properties that are ideal for dual-color experiments with green fluorescent protein (GFP). But wild-type DsRed has several drawbacks, including slow chromophore maturation and poor solubility. To overcome the slow maturation, we used random and directed mutagenesis to create DsRed variants that mature 10-15 times faster than the wild-type protein. An asparagine-to-glutamine substitution at position 42 greatly accelerates the maturation of DsRed, but also increases the level of green emission. Additional amino acid substitutions suppress this green emission while further accelerating the maturation. To enhance the solubility of DsRed, we reduced the net charge near the N terminus of the protein. The optimized DsRed variants yield bright fluorescence even in rapidly growing organisms such as yeast.