The role of quarternary structure in fluorescent protein stability

The stability of fluorescent proteins (FPs) is of great importance for their use as reporters in studies of gene expression, protein dynamics and localization in cell. A comparative analysis of conformational stability of fluorescent proteins, having different association state was done. The list of studied proteins includes EGFP (monomer of green fluorescent protein, GFP), zFP506 (tetramer GFP), mRFP1 and "dimer2" (monomer and dimmer of red fluorescent protein), DsRed1 (red tetramer). The character of fluorescence intensity changes induced by guanidine hydrochloride (GdnHCl) of these proteins differs significantly. Green tetramer zFP506 has been shown to be more stable than green monomer EGFP, red dimmer "dimer2" has been shown to be less stable than red tetramer DsRed1, while red monomer mRFP1 has been shown to be practically as stable as tetramer DsRedl. It is concluded that the quaternary structure, being an important stabilizing factor, does not represent the only circumstance dictating the dramatic variations between fluorescent proteins in their conformational stability.     

Ubiquitous expression of the monomeric red fluorescent protein mcherry in transgenic mice

The use of the green fluorescent protein (GFP) to label specific cell types and track gene expression in animal models, such as mice, has evolved to become an essential tool in biological research. Transgenic animals expressing genes of interest linked to GFP, either as a fusion protein or transcribed from an internal ribosomal entry site (IRES) are widely used. Enhanced GFP (eGFP) is the most common form of GFP used for such applications. However, a red fluorescent protein (RFP) would be highly desirable for use in dual‐labeling applications with GFP derived fluorescent proteins, and for deep in vivo imaging of tissues. Recently, a new generation of monomeric (m)RFPs, such as monomeric (m)Cherry, has been developed that are potentially useful experimentally. mCherry exhibits brighter fluorescence, matures more rapidly, has a higher tolerance for N‐terminal fusion proteins, and is more photostable compared with its predecessor mRFP1. mRFP1 itself was the first true monomer derived from its ancestor DsRed, an obligate tetramer in vivo. Here, we report the successful generation of a transgenic mouse line expressing mCherry as a fluorescent marker, driven by the ubiquitin‐C promoter. mCherry is expressed in almost all tissues analyzed including pre‐ and post‐implantation stage embryos, and white blood cells. No expression was detected in erythrocytes and thrombocytes. Importantly, we did not encounter any changes in normal development, general physiology, or reproduction. mCherry is spectrally and genetically distinct from eGFP and, therefore, serves as an excellent red fluorescent marker alone or in combination with eGFP for labelling transgenic animals. genesis 48:723–729, 2010. © 2010 Wiley‐Liss, Inc.     

Monomeric red fluorescent protein as a reporter for macromolecular localization in Streptomyces coelicolor

The enhanced green fluorescent protein (eGFP) is widely used to investigate cell type specific gene expression and protein localization in the filamentous streptomycetes. To broaden the scope of cell biological investigation in these organisms, we have adapted shuttle vectors for the construction of gene fusions to the monomeric red fluorescent protein (mRFP1) and have tested them in Streptomyces coelicolor. Using fusions of mRFP1 to the cell division proteins DivIVA and FtsZ, we show that mRFP1 is comparable to eGFP for cell biological research in this organism and suggest that this paves the way for the future use of two-color imaging and FRET.     

Monomeric red fluorescent protein variants used for imaging studies in different species

Fluorescent proteins have proven to be excellent tools for live-cell imaging studies. In addition to green fluorescent protein (GFP) and its variants, recent progress was achieved in the development of monomeric red fluorescent proteins (mRFPs) that show improved properties in respect to maturation and intracellular fluorescence. mRFPmars, a red fluorescent protein designed especially for the use in Dictyostelium, has been employed to tag different proteins for live-cell investigations in Dictyostelium. mRFPruby, which differs in sequence from mRFPmars in four amino acids, has a codon usage optimised for the application in mammalian cells. Here, we show that both mRFP variants can also be applied for localisation studies in other organisms. mRFPmars was expressed in Hydra and fused to the Bcl-2 family protein Bax. mRFPruby in combination with histone 2B was expressed in Drosophila S2 cells to monitor mitosis. Using mouse cell lines, mRFPruby fused to beta-actin was assayed with high spatial resolution to study details of actin cytoskeleton dynamics. In addition, we demonstrate that both mRFP variants are also suitable for dual-colour microscopy in the different species.     

Comparative studies on the structure and stability of fluorescent proteins EGFP, zFP506, mRFP1, "dimer2", and DsRed1

To obtain more information about the structural properties and conformational stabilities of GFP-like fluorescent proteins, we have undertaken a systematic analysis of series of green and red fluorescent proteins with different association states. The list of studied proteins includes EGFP (green monomer), zFP506 (green tetramer), mRFP1 (red monomer), "dimer2" (red dimer), and DsRed1 (red tetramer). Fluorescent and absorbance parameters, near-UV and visible CD spectra, the accessibility of the chromophores and tryptophans to acrylamide quenching, and the resistance of these proteins to the guanidine hydrochloride unfolding and kinetics of the approaching of the unfolding equilibrium have been compared. Tetrameric zFP506 was shown to be dramatically more stable than the EGFP monomer, assuming that association might contribute to the protein conformational stability. This assumption is most likely valid even though the sequences OF GFP and zPF506 are only approximately 25% identical. Interestingly, red FPs possessed comparable conformational stabilities, where monomeric mRFP1 was the most stable species under the equilibrium conditions, whereas the tetrameric DsRed1 possessed the slowest unfolding kinetics. Furthermore, EGFP is shown to be considerably less stable than mRFP1, whereas tetrameric zFP506 is the most stable species analyzed in this study. This means that the quaternary structure, being an important stabilizing factor, does not represent the only circumstance dictating the dramatic variations between fluorescent proteins in their conformational stabilities.     

A brilliant monomeric red fluorescent protein to visualize cytoskeleton dynamics in Dictyostelium

Red fluorescent proteins (RFPs) combined with GFP are attractive probes for double-fluorescence labeling of proteins in live cells. However, the application of these proteins is restrained by stable oligomer formation and by their weak fluorescence in vivo. Previous attempts to eliminate these problems by mutagenesis of RFP from Discosoma (DsRed) resulted in the monomeric mRFP1 and in the tetrameric RedStar RFP, which is distinguished by its enhanced fluorescence in vivo. Based on these mutations, we have generated an enhanced monomeric RFP, mRFPmars, and report its spectral properties. Together with green fluorescent labels, we used mRFPmars to visualize filamentous actin structures and microtubules in Dictyostelium cells. This enhanced RFP proved to be suitable to monitor the dynamics of cytoskeletal proteins in cell motility, mitosis, and endocytosis using dual-wavelength fluorescence microscopy.     

Visualizing cytoskeleton dynamics in mammalian cells using a humanized variant of monomeric red fluorescent protein

Fluorescent proteins are versatile tools for live cell imaging studies. In particular, recent progress was achieved in the development of monomeric red fluorescent proteins (mRFPs) that show improved properties in respect to maturation and intracellular fluorescence. mRFPmars, a red fluorescent protein designed especially for the use in Dictyostelium, proved to be a brilliant label for different cytoskeletal elements. Here we report on the synthesis of a humanized version of a monomeric RFP, mRFPruby, which differs in sequence from mRFPmars in four amino acids and has a codon usage that is optimized for the application in mammalian cells. In order to demonstrate the usefulness of this new mRFP variant, mRFPruby fused to beta-actin was expressed in different mouse cell lines and used to visualize actin cytoskeleton dynamics by live cell microscopy.     

Mutants of monomeric red fluorescent protein mRFP1 at residue 66: Structure modeling by molecular dynamics and search for correlations with spectral properties

To study the interrelation between the spectral and structural properties of fluorescent proteins, structures of mutants of monomeric red fluorescent protein mRFP1 with all possible point mutations of Glu66 (except replacement by Pro) were simulated by molecular dynamics. A global search for correlations between geometrical structure parameters and some spectral characteristics (absorption maximum wavelength, integral extinction coefficient at the absorption maximum, excitation maximum wavelength, emission maximum wavelength, and quantum yield) was performed for the chromophore and its 6 A environment in mRFP1, Q66A, Q66L, Q66S, Q66C, Q66H, and Q66N. The correlation coefficients (0.81-0.87) were maximal for torsion angles in phenolic and imidazolidine rings as well as for torsion angles in the regions of connection between these rings and chromophore attachment to beta-barrel. The data can be used to predict the spectral properties of fluorescent proteins based on their structures and to reveal promising positions for directed mutagenesis.     

Dark states in monomeric red fluorescent proteins studied by fluorescence correlation and single molecule spectroscopy

Monomeric red fluorescent proteins (mRFPs) have become indispensable tools for studying protein dynamics, interactions and functions in the cellular environment. Their emission spectrum can be well separated from other fluorescent proteins, and their monomeric structure preserves the natural function of fusion proteins. However, previous photophysical studies of some RFPs have shown the presence of light-induced dark states that can complicate the interpretation of cellular experiments. In this article, we extend these studies to mRFP1, mCherry, and mStrawberry by means of fluorescence correlation spectroscopy and prove that this light-driven intensity flickering also occurs in these proteins. Furthermore, we show that the flickering in these proteins is pH-dependent. Single molecule spectroscopy revealed reversible transitions from a bright to a dark state in several timescales, even up to seconds. Time-resolved fluorescence spectroscopy showed multiexponential decays, consistent with a “loose” conformation. We offer a structural basis for the fluorescence flickering using known crystal structures and point out that the environment of Glu-215 is critical for the pH dependence of the flickering in RFPs. We apply dual-color fluorescence correlation spectroscopy inside live cells to prove that this flickering can seriously hamper cellular measurements if the timescales of the flickering and diffusion are not well separated.     

Optical properties of the monomeric red fluorescent protein mRFP1

For the expression in E. coli, the PCR-amplified fragment encoding mRFP1 from vector pMT-mRFP1 (Fungal Genetic Stock Center) was placed in the pQE-60 vector. Chemically competent E. coli ER1821 were transformed and grown overnight at 37°C. The protein was purified by Ni-NTA chromatography and dialyzed against 67mM Na₂HPO₄, 67mM KH₂PO₄, pH 7.5. There are two peaks (at 503 and 584 nm) in the mRFP1 absorption spectrum. The green component (503 nm) may correspond to a green fraction of the protein (a fraction that never matures beyond the green intermediate or a fraction which is trapped as a dead-end product such as the nonproductive trans conformation for the F65-Q66 peptide bond). The mRFP1’s extinction coefficient is equal to 42 mM^?1 cm^?1 at 584 nm; the emission maximum is at 607 nm; the excitation maximum is at 584–586 nm; the Stokes shift is equal to 23 nm; the fluorescence lifetime is about 1.8 ns; the quantum yield is 0.27; pKa is 4.0. Analysis of the mRFP1 absorption spectrum by high-order derivative spectroscopy shows that electron transition systems of both the fully matured form (absorption maximum at 584 nm) and the green fraction of the protein (absorption maximum at 503 nm) are practically identical.     

Dual-color photon counting histogram analysis of mRFP1 and EGFP in living cells

We investigate the potential of dual-color photon counting histogram (PCH) analysis to resolve fluorescent protein mixtures directly inside cells. Because of their small spectral overlap, we have chosen to look at the fluorescent proteins EGFP and mRFP1. We experimentally demonstrate that dual-color PCH quantitatively resolves a mixture of EGFP and mRFP1 in cells from a single measurement. To mimic the effect of protein association, we constructed a fusion protein of EGFP and mRFP1 (denoted EGFP-mRFP1). Fluorescence resonant energy transfer within the fusion protein alters the dual-channel brightness of the fluorophores. We describe a model for fluorescence resonant energy transfer effects on the brightness and incorporate it into dual-color PCH analysis. The model is verified using fluorescence lifetime measurements. Dual-color PCH analysis demonstrated that not all of the expressed EGFP-mRFP1 fusion proteins contained a fluorescent mRFP1 molecule. Fluorescence lifetime and emission spectra measurements confirmed this surprising result. Additional experiments show that the missing fluorescent fraction of mRFP1 is consistent with a dark state population of mRFP1. We successfully resolved this mixture of fusion proteins with a single dual-color PCH measurement. These results highlight the potential of dual-color PCH to directly detect and quantify protein mixtures in living cells.     

Genetic and spectrally distinct <Emphasis Type="Italic">in vivo</Emphasis>imaging: embryonic stem cells and mice with widespread expression of a monomeric red fluorescent protein

Background  

DsRed the red fluorescent protein (RFP) isolated from Discosoma sp. coral holds much promise as a genetically and spectrally distinct alternative to green fluorescent protein (GFP) for application in mice. Widespread use of DsRed has been hampered by several issues resulting in the inability to establish and maintain lines of red fluorescent protein expressing embryonic stem cells and mice. This has been attributed to the non-viability, or toxicity, of the protein, probably as a result of its obligate tetramerization. A mutagenesis approach directing the stepwise evolution of DsRed has produced mRFP1, the first true monomer. mRFP1 currently represents an attractive autofluorescent reporter for use in heterologous systems.     

Ubiquitous expression of mRFP1 in transgenic mice

Fluorescent proteins provide a powerful means to track gene expression and cellular behaviors in the study of model organisms such as mice. Among the new generation of fluorescent protein markers, the monomeric red fluorescent protein mRFP1 is particularly attractive because of its rapid maturation and minimal interference with GFP and GFP-derived markers. Here we evaluate the utility of mRFP1 as a marker in transgenic mice. We show that high level and ubiquitous expression of mRFP1 does not affect mouse development, general physiology, or reproduction. mRFP1 expression can be readily detected with unaided eyes under daylight in transgenic mice on the albino background. The intensity of mRFP1 signals can be used to distinguish homozygous and heterozygous transgenic mice. Together, these features make mRFP1 an attractive marker for broad applications in transgenic research.     

Development of pseudorabies virus strains expressing red fluorescent proteins: new tools for multisynaptic labeling applications

The transsynaptic retrograde transport of the pseudorabies virus Bartha (PRV-Bartha) strain has become an important neuroanatomical tract-tracing technique. Recently, dual viral transneuronal labeling has been introduced by employing recombinant strains of PRV-Bartha engineered to express different reporter proteins. Dual viral transsynaptic tracing has the potential of becoming an extremely powerful method for defining connections of single neurons to multiple neural circuits in the brain. However, the present use of recombinant strains of PRV expressing different reporters that are driven by different promoters, inserted in different regions of the viral genome, and detected by different methods limits the potential of these recombinant virus strains as useful reagents. We previously constructed and characterized PRV152, a PRV-Bartha derivative that expresses the enhanced green fluorescent protein. The development of a strain isogenic to PRV152 and differing only in the fluorescent reporter would have great utility for dual transsynaptic tracing. In this report, we describe the construction, characterization, and application of strain PRV614, a PRV-Bartha derivative expressing a novel monomeric red fluorescent protein, mRFP1. In contrast to viruses expressing DsRed and DsRed2, PRV614 displayed robust fluorescence both in cell culture and in vivo following transsynaptic transport through autonomic circuits afferent to the eye. Transneuronal retrograde dual PRV labeling has the potential to be a powerful addition to the neuroanatomical tools for investigation of neuronal circuits; the use of strain PRV614 in combination with strain PRV152 will eliminate many of the pitfalls associated with the presently used pairs of PRV recombinants.     

Bimolecular fluorescence complementation based on the red fluorescent protein FusionRed

The aim of this work is to construct split variants of the red fluorescent protein FusionRed, each of which consists of two separate polypeptides, nonfluorescent parts of FusionRed, that can form functional fluorescent proteins upon reassociation. At the first stage, various circularly permuted FusionRed variants have been created (in circular permutants the protein polypeptide chain is divided into two parts, which change places so that the C-terminal part is followed by the N-terminal part). Two variants with the highest rate of chromophore maturation (fluorescence development) have been selected out of 23 tested permutation points. These proteins called cpFR76-73 and cpFR189-188 (the first number indicates the last amino acid residue of the N-terminal part; the second number, the first residue of the C-terminal part) are spectrally similar to parental FusionRed but possess lower fluorescence quantum yields. Split variants corresponding to these two circular permutants have been tested in mammalian cells. For reassembly of the fluorescent protein fragments, heterodimerizing leucine zippers have been used. It has been shown that split variant FR189-188 matures at 37°C and possesses fluorescence brightness similar to that of FusionRed. Consequently, FR189-188 is potentially suitable for a wide range of applications, for example, the study of protein–protein interactions or visualization of cell populations, in which two target gene promoters are simultaneously active.     

The fluorescence theatre: a cost-effective device using theatre gels for fluorescent protein and dye screening

Here we report a simple cost-effective device for screening colonies on plates for expression of the monomeric red fluorescent protein mRFP1 and the fluorescent dye Nile red. This device can be built from any simple light source, in our case a Quebec Colony Counter, and cost-effective theatre gels. The device can be assembled in as little as 20 min, and it produces excellent results when screening a large number of colonies.     

A method for determining the individual optical characteristics of posttranslational fluorescent forms of fluorescent proteins with the use of nonlinear laser fluorimetry

A method for determining the individual optical characteristics (fluorescence quantum yield, the rate constant and quantum yield of singlet-triplet conversion, excitation of fluorescence cross-section, extinction coefficient) and concentration correlations between the fluorescent forms of fluorescent proteins arising in the reaction of posttranslational chromophore formation has been developed, which is based on combined application of absorption spectroscopy and classical and nonlinear laser fluorimretry. The method allows one to determine the share of fluorescent forms in the mixture of chromoproteins. The individual optical characteristics of the red form of the fluorescent protein mRFP1 has been determined: the fluorescence quantum yield eta = 0.24 +/- 0.03; the extinction coefficient in the maximum of absorbance band (584 nm) epsilon = 213 +/- 40 mM(-1) cm(-1) (the cross-section of absorbance sigma = (8.2 +/- 1.5).10(-16) cm2); the constant of singlet-triplet conversion rate K32 = (0 +/- 0.6)-10970 s(-1). The part of the red form in the mixture of chromoproteins is 26 +/- 6%.     

Production of rhesus monkey cloned embryos expressing monomeric red fluorescent protein by interspecies somatic cell nuclear transfer

Interspecies somatic cell nuclear transfer (iSCNT) is a promising method to clone endangered animals from which oocytes are difficult to obtain. Monomeric red fluorescent protein 1 (mRFP1) is an excellent selection marker for transgenically modified cloned embryos during somatic cell nuclear transfer (SCNT). In this study, mRFP-expressing rhesus monkey cells or porcine cells were transferred into enucleated porcine oocytes to generate iSCNT and SCNT embryos, respectively. The development of these embryos was studied in vitro. The percentage of embryos that underwent cleavage did not significantly differ between iSCNT and SCNT embryos (P > 0.05; 71.53% vs. 80.30%). However, significantly fewer iSCNT embryos than SCNT embryos reached the blastocyst stage (2.04% vs. 10.19%, P < 0.05). Valproic acid was used in an attempt to increase the percentage of iSCNT embryos that developed to the blastocyst stage. However, the percentages of embryos that underwent cleavage and reached the blastocyst stage were similar between untreated iSCNT embryos and iSCNT embryos treated with 2 mM valproic acid for 24 h (72.12% vs. 70.83% and 2.67% vs. 2.35%, respectively). These data suggest that porcine-rhesus monkey interspecies embryos can be generated that efficiently express mRFP1. However, a significantly lower proportion of iSCNT embryos than SCNT embryos reach the blastocyst stage. Valproic acid does not increase the percentage of porcine-rhesus monkey iSCNT embryos that reach the blastocyst stage. The mechanisms underling nuclear reprogramming and epigenetic modifications in iSCNT need to be investigated further.     

Quaternary structure is critical for protein display on capsid-like particles (CLPs): efficient generation of hepatitis B virus CLPs presenting monomeric but not dimeric and tetrameric fluorescent proteins

Self-organizing assemblies such as viral capsids may be used as symmetrical molecular platforms for the display of heterologous sequences, with applications ranging from vaccines to structural studies. The 183-amino-acid hepatitis B virus (HBV) core protein assembles spontaneously into icosahedral capsid-like particles (CLPs). The most exposed, and most immunogenic, substructure on the CLPs is a small loop that connects two long antiparallel alpha-helices which act as dimerization interface. Ninety (90) or 120 dimers multimerize into the capsid; the four-helix bundles formed by the dimers protrude as spikes from the surface. We recently demonstrated that the entire enhanced green fluorescent protein (eGFP) can be inserted into this loop, yielding CLPs that natively displayed eGFP on their surface. The central location of the insertion site requires that any insert be fixed to the carrier via both termini, with corresponding restrictions regarding insert size and structure. eGFP obviously satisfied these criteria but, surprisingly, all attempts to produce CLPs with the isostructural red fluorescent proteins DsRed1, DsRed2, and HcRed failed. Suspecting their oligomerization tendency to be responsible, we generated fusions containing instead monomeric yellow, cyan, and red fluorescent proteins (mYFP, mCFP and mRFP1). This strongly increased the yields of YFP and CFP-CLPs, and it allowed for the first time to efficiently generate red fluorescent CLPs. Hence insert quaternary structure is a highly critical factor for CLP assembly. These data have important implications for the rational design of self-assembling fusion proteins.     

Pharmacological characterization of a recombinant, fluorescent somatostatin receptor agonist

Somatostatin (SST) is a peptide neurotransmitter/hormone found in several mammalian tissue types. Apart from its natural importance, labeled SST/analogues are utilized in clinical applications such as targeting/diagnosis of neuroendocrine tumors. We report on the development and characterization of a novel, recombinant, fluorescent somatostatin analogue that has potential to elucidate somatostatin-activated cell signaling. SST was genetically fused with a monomeric-red fluorescent protein (mRFP) as the fluorescent label. The attachment of SST to mRFP had no detectable effect on its fluorescent properties. This analogue's potency to activate the endogenous and transfected somatostatin receptors was characterized using assays of membrane potential and Ca(2+) mobilization and immunocytochemistry. SST-mRFP was found to be an effective somatostatin receptor agonist, able to trigger the membrane hyperpolarization, mobilization of the intracellular Ca(2+) and receptor-ligand internalization in cells expressing somatostatin receptors. This complex represents a novel optical reporter due to its red emission spectral band suitable for in vivo imaging and tracking of the somatostatin receptor signaling pathways, affording higher resolution and sensitivity than those of the state-of-the-art radiolabeling bioassays.