Fluorescent biosensors of protein function

Fluorescent biosensors allow researchers to image and quantify protein activity and small molecule signals in living cells with high spatial and temporal resolution. Genetically encoded sensors are coded by a DNA sequence and hence constructed entirely out of amino acids. These biosensors typically utilize light-emitting proteins, such as derivatives of the green fluorescent protein (GFP), and have been developed for a wide range of small molecules and enzyme activities. Fluorescent biosensors can be genetically targeted to distinct locations within cells, such as organelles and membranes. This feature facilitates elucidation of how protein activities and cellular signals are modulated in different regions of the cell. Improvements in the dynamic range and robustness of sensors have enabled high throughput screening for molecules that act as agonists or antagonists of protein function.     

New tools for in vivo fluorescence tagging

Engineering of fluorescent proteins continues to produce new tools for in vivo studies. The current selection contains brighter, monomeric, spectral variants that will facilitate multiplex imaging and FRET, and a collection of optical highlighter proteins that might replace photoactivatable-GFP. These new highlighter proteins, which include proteins that have photoswitchable fluorescence characteristics and a protein whose fluorescence can be repeatedly turned on and off, should simplify refined analyses of protein dynamics and kinetics. Fluorescent protein-based systems have also been developed to allow facile detection of protein-protein interactions in planta. In addition, new tags in the form of peptides that bind fluorescent ligands and quantum dots offer the prospect of overcoming some of the limitations of fluorescent proteins such as excessive size and insufficient brightness.     

Live-cell imaging with EosFP and other photoactivatable marker proteins of the GFP family

Fluorescent proteins from the green fluorescent protein family have become indispensable imaging tools for cell biology. A wide variety of these proteins were discovered in nonbioluminescent anthozoa in recent years. Some of them feature exciting new properties, with the possibility to alter their intensity and/or fluorescence color by irradiation with light of specific wavelengths. Fluorescent highlighter proteins enable many interesting applications based on regional optical marking in live cells and tissues. This review provides an overview of photoactivatable marker proteins, with a focus on EosFP, a protein that can be switched from green to red fluorescence by approximately 400-nm light. A variety of applications are presented to illustrate the versatility of EosFP in live-cell imaging.     

Live-cell imaging with EosFP and other photoactivatable marker proteins of the GFP family

Fluorescent proteins from the green fluorescent protein family have become indispensable imaging tools for cell biology. A wide variety of these proteins were discovered in nonbioluminescent anthozoa in recent years. Some of them feature exciting new properties, with the possibility to alter their intensity and/or fluorescence color by irradiation with light of specific wavelengths. Fluorescent highlighter proteins enable many interesting applications based on regional optical marking in live cells and tissues. This review provides an overview of photoactivatable marker proteins, with a focus on EosFP, a protein that can be switched from green to red fluorescence by approximately 400-nm light. A variety of applications are presented to illustrate the versatility of EosFP in live-cell imaging.     

Improved Blue,Green, and Red Fluorescent Protein Tagging Vectors for S. cerevisiae

Fluorescent protein fusions are a powerful tool to monitor the localization and trafficking of proteins. Such studies are particularly easy to carry out in the budding yeast Saccharomyces cerevisiae due to the ease with which tags can be introduced into the genome by homologous recombination. However, the available yeast tagging plasmids have not kept pace with the development of new and improved fluorescent proteins. Here, we have constructed yeast optimized versions of 19 different fluorescent proteins and tested them for use as fusion tags in yeast. These include two blue, seven green, and seven red fluorescent proteins, which we have assessed for brightness, photostability and perturbation of tagged proteins. We find that EGFP remains the best performing green fluorescent protein, that TagRFP-T and mRuby2 outperform mCherry as red fluorescent proteins, and that mTagBFP2 can be used as a blue fluorescent protein tag. Together, the new tagging vectors we have constructed provide improved blue and red fluorescent proteins for yeast tagging and three color imaging.     

Novel fluorescent protein from Hydnophora rigida possesses green emission

Fluorescent proteins are a family of proteins capable of producing fluorescence at various specific wavelengths of ultra violet light. We have previously reported the identification and characterization of a novel cyan fluorescent protein (HriCFP) from a reef coral species, Hydnophora rigida. In search of new members of the diverse family of fluorescent proteins, here we report a new green fluorescent protein (HriGFP) from H. rigida. HriGFP was identified, cloned, expressed in Escherichia coli and purified to homogeneity by metal affinity and size exclusion chromatography. The dynamic light scattering and gel filtration experiments suggested the presence of monomers in solution. The peptide mass fingerprint on the purified protein established the identity of HriGFP. HriGFP had excitation peak at 507 nm and emission peak at 527 nm. HriGFP was similar to HriCFP except the last 16 amino acid sequence at the C-terminal; however, they have shown least similarity with other known fluorescent proteins. Moreover the computational model suggests that HriGFP is a globular protein which consists of 6 α-helices and 3 β-sheets. Taken together our results suggested that HriGFP is a novel naturally occurring fluorescent protein that exists as a monomer in solution.     

含Dsred类似生色团的红色荧光蛋白的发展及应用

自从绿色荧光蛋白(GFP)被发现以来,荧光蛋白在生物医学领域已经成为一种重要的荧光成像工具．随着红色荧光蛋白DsRed的出现,各种优化的DsRed突变体和远红荧光蛋白也不断涌现．其中荧光蛋白生色团的形成机制对改建更优的荧光蛋白变种影响很大,对于红色荧光蛋白而言,大多数的红色荧光蛋白的生色团类型为DsRed类似生色团,在此基础上又出现了Far-red DsRed类似生色团．目前,含DsRed类似生色团的荧光蛋白主要有单体红色荧光蛋白、光转换荧光蛋白、斯托克斯红移蛋白、荧光计时器等．这些优化的荧光蛋白作为分子探针可以实现对活细胞、细胞器或胞内分子的时空标记和追踪,已经在生物工程学、细胞生物学、基础医学领域得到广泛应用．本文综述了含DsRed类似生色团的荧光蛋白的研究进展及其应用,以及由此发展起来的远红荧光蛋白在活体显微成像技术中的应用,并展望了荧光探针技术研究的新方向．     

From fluorescent proteins to fluorogenic RNAs: Tools for imaging cellular macromolecules

The explosion in genome‐wide sequencing has revealed that noncoding RNAs are ubiquitous and highly conserved in biology. New molecular tools are needed for their study in live cells. Fluorescent RNA–small molecule complexes have emerged as powerful counterparts to fluorescent proteins, which are well established, universal tools in the study of proteins in cell biology. No naturally fluorescent RNAs are known; all current fluorescent RNA tags are in vitro evolved or engineered molecules that bind a conditionally fluorescent small molecule and turn on its fluorescence by up to 5000‐fold. Structural analyses of several such fluorescence turn‐on aptamers show that these compact (30–100 nucleotides) RNAs have diverse molecular architectures that can restrain their photoexcited fluorophores in their maximally fluorescent states, typically by stacking between planar nucleotide arrangements, such as G‐quadruplexes, base triples, or base pairs. The diversity of fluorogenic RNAs as well as fluorophores that are cell permeable and bind weakly to endogenous cellular macromolecules has already produced RNA–fluorophore complexes that span the visual spectrum and are useful for tagging and visualizing RNAs in cells. Because the ligand binding sites of fluorogenic RNAs are not constrained by the need to autocatalytically generate fluorophores as are fluorescent proteins, they may offer more flexibility in molecular engineering to generate photophysical properties that are tailored to experimental needs.     

ReAsH/FlAsH Labeling and Image Analysis of Tetracysteine Sensor Proteins in Cells

Fluorescent proteins and dyes are essential tools for the study of protein trafficking, localization and function in cells. While fluorescent proteins such as green fluorescence protein (GFP) have been extensively used as fusion partners to proteins to track the properties of a protein of interest¹, recent developments with smaller tags enable new functionalities of proteins to be examined in cells such as conformational change and protein-association ^{2, 3}. One small tag system involves a tetracysteine motif (CCXXCC) genetically inserted into a target protein, which binds to biarsenical dyes, ReAsH (red fluorescent) and FlAsH (green fluorescent), with high specificity even in live cells ². The TC/biarsenical dye system offers far less steric constraints to the host protein than fluorescent proteins which has enabled several new approaches to measure conformational change and protein-protein interactions ^4-7. We recently developed a novel application of TC tags as sensors of oligomerization in cells expressing mutant huntingtin, which when mutated aggregates in neurons in Huntington disease ⁷. Huntingtin was tagged with two fluorescent dyes, one a fluorescent protein to track protein location, and the second a TC tag which only binds biarsenical dyes in monomers. Hence, changes in colocalization between protein and biarsenical dye reactivity enabled submicroscopic oligomer content to be spatially mapped within cells. Here, we describe how to label TC-tagged proteins fused to a fluorescent protein (Cherry, GFP or CFP) with FlAsH or ReAsH in live mammalian cells and how to quantify the two color fluorescence (Cherry/FlAsH, CFP/FlAsH or GFP/ReAsH combinations).Download video file.^{(77M, mov)}     

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.     

Synthesis of two fluorescent GTPγS molecules and their biological relevance

Fluorescent GTP analogues are utilized for an assortment of nucleic acid and protein characterization studies. Non-hydrolysable analogues such as GTPγS offer the advantage of keeping proteins in a GTP-bound conformation due to their resistance to hydrolysis into GDP. Two novel fluorescent GTPγS molecules were developed by linking fluorescein and tetramethylrhodamine to the γ-thiophosphate of GTPγS. Chemical and biological analysis of these two compounds revealed their successful synthesis and ability to bind to the nucleotide-binding site of tubulin. These two new fluorescent non-hydrolysable nucleotides offer new possibilities for biophysical and biochemical characterization of GTP-binding proteins.     

Ratiometric detection of Zn(II) using chelating fluorescent protein chimeras

Fluorescent indicators for the real-time imaging of small molecules or metal ions in living cells are invaluable tools for understanding their physiological function. Genetically encoded sensors based on fluorescence resonance energy transfer (FRET) between fluorescent protein domains have important advantages over synthetic probes, but often suffer from a small ratiometric change. Here, we present a new design approach to obtain sensors with a large difference in emission ratio between the bound and unbound states. De novo Zn(II)-binding sites were introduced directly at the surface of both fluorescent domains of a chimera of enhanced cyan and yellow fluorescent protein, connected by a flexible peptide linker. The resulting sensor ZinCh displayed an almost fourfold change in fluorescence emission ratio upon binding of Zn(II). Besides a high affinity for Zn(II), the sensor was shown to be selective over other physiologically relevant metal ions. Its unique biphasic Zn(II)-binding behavior could be attributed to the presence of two distinct Zn(II)-binding sites and allowed ratiometric fluorescent detection of Zn(II) over a concentration range from 10 nM to 1 mM. Size-exclusion chromatography and fluorescence anisotropy were used to provide a detailed picture of the conformational changes associated with each Zn(II)-binding step. The high affinity for Zn(II) was mainly due to a high effective concentration of the fluorescent proteins and could be understood quantitatively by modeling the peptide linker between the fluorescent proteins as a random coil. The strategy of using chelating fluorescent protein chimeras to develop FRET sensor proteins with a high ratiometric change is expected to be more generally applicable, in particular for other metal ions and small molecules.     

Improved green and blue fluorescent proteins for expression in bacteria and mammalian cells

Fluorescent proteins have become an invaluable tool in cell biology. The green fluorescent protein variant EGFP is especially widely applied. Use of fluorescent proteins, including EGFP, however can be hindered by inefficient protein folding, resulting in protein aggregation and reduced fluorescence. This is especially profound in prokaryotic cells. Furthermore, EBFP, a blue fluorescent variant of EGFP, is rarely used because of its dim fluorescence and fast photobleaching. Thus, efforts to improve properties such as protein folding, fluorescence brightness, and photostability are important. Strongly enhanced green fluorescent (SGFP2) and strongly enhanced blue fluorescent (SBFP2) proteins were created, based on EGFP and EBFP, respectively. We used site-directed mutagenesis to introduce several mutations, which were recently shown to improve the fluorescent proteins EYFP and ECFP. SGFP2 and SBFP2 exhibit faster and more efficient protein folding and accelerated chromophore oxidation in vitro. For both strongly enhanced fluorescent proteins, the photostability was improved 2-fold and the quantum yield of SBFP2 was increased 3-fold. The improved folding efficiency reduced the extent of protein aggregation in Escherichia coli, thereby increasing the brightness of bacteria expressing SGFP2 7-fold compared to the brightness of those expressing EGFP. Bacteria expressing SBFP2 were 16-fold more fluorescent than those expressing EBFP. In mammalian cells, the improvements were less pronounced. Cells expressing SGFP2 were 1.7-fold brighter than those expressing EGFP, which was apparently due to more efficient protein expression and/or chromophore maturation. Mammalian cells expressing SBFP2 were 3.7-fold brighter than cells expressing EBFP. This increase in brightness closely resembled the increase in intrinsic brightness observed for the purified recombinant protein. The increased maturation efficiency and photostability of SGFP2 and SBFP2 facilitate detection and extend the maximum duration of fluorescence imaging.     

Use of the fluorescent timer DsRED-E5 as reporter to monitor dynamics of gene activity in plants

Fluorescent proteins, such as green fluorescent protein and red fluorescent protein (DsRED), have become frequently used reporters in plant biology. However, their potential to monitor dynamic gene regulation is limited by their high stability. The recently made DsRED-E5 variant overcame this problem. DsRED-E5 changes its emission spectrum over time from green to red in a concentration independent manner. Therefore, the green to red fluorescence ratio indicates the age of the protein and can be used as a fluorescent timer to monitor dynamics of gene expression. Here, we analyzed the potential of DsRED-E5 as reporter in plant cells. We showed that in cowpea (Vigna unguiculata) mesophyll protoplasts, DsRED-E5 changes its fluorescence in a way similar to animal cells. Moreover, the timing of this shift is suitable to study developmental processes in plants. To test whether DsRed-E5 can be used to monitor gene regulation in plant organs, we placed DsRED-E5 under the control of promoters that are either up- or down-regulated (MtACT4 and LeEXT1 promoters) or constitutively expressed (MtACT2 promoter) during root hair development in Medicago truncatula. Analysis of the fluorescence ratios clearly provided more accurate insight into the timing of promoter activity.     

DNA binding fluorescent proteins for the direct visualization of large DNA molecules

Fluorescent proteins that also bind DNA molecules are useful reagents for a broad range of biological applications because they can be optically localized and tracked within cells, or provide versatile labels for in vitro experiments. We report a novel design for a fluorescent, DNA-binding protein (FP-DBP) that completely ‘paints’ entire DNA molecules, whereby sequence-independent DNA binding is accomplished by linking a fluorescent protein to two small peptides (KWKWKKA) using lysine for binding to the DNA phosphates, and tryptophan for intercalating between DNA bases. Importantly, this ubiquitous binding motif enables fluorescent proteins (K_d = 14.7 μM) to confluently stain DNA molecules and such binding is reversible via pH shifts. These proteins offer useful robust advantages for single DNA molecule studies: lack of fluorophore mediated photocleavage and staining that does not perturb polymer contour lengths. Accordingly, we demonstrate confluent staining of naked DNA molecules presented within microfluidic devices, or localized within live bacterial cells.     

Using electroporation and lipid-mediated transfection of GFP-expressing plasmids to label embryonic avian cells for vital confocal and two-photon microscopy

Fluorescent proteins have emerged as an ideal fluorescent marker for studying cell morphologies in vital systems. These proteins were first applied in whole organisms with established germ-line transformation protocols, but now it is possible to label cells with fluorescent proteins in other organisms. Here we present two ways to introduce GFP expressing plasmids into avian embryos for vital confocal and two-photon imaging. First, electroporation is a powerful approach to introduce GFP into the developing neural tube, offering several advantages over dye labeling. Second, we introduce a new lipid-based transfection system for introducing plasmid DNA directly to a small group of injected cells within live, whole embryos. These complementary approaches make it possible to transfect a wide-range of cell types in the avian embryo and the bright, stable, uniform expression of GFP offers great advantages for vital fluorescence imaging.     

Whole-body imaging with fluorescent proteins

The intrinsic brightness of fluorescent proteins has been taken advantage of to develop a technology of whole-body imaging of tumors and gene expression in mouse internal organs. Stable transformation with fluorescent protein genes can be effected using retroviral vectors containing a selectable marker such as neomycin resistance. The cells that stably express fluorescent proteins can then be transplanted into appropriate mouse models. For whole-body imaging, nude mice are very appropriate. If wild-type mice are used, then hair must be removed by shaving or depilation. The instruments used can range from a simple LED flashlight and appropriate excitation and emission filters to sophisticated equipment such as the Olympus OV100 with a wide range of magnification, enabling both macroimaging and microimaging. It is crucial that proper filters be used such that background autofluorescence is minimal. Fluorescent protein-based imaging technology can be used for whole-body imaging of fluorescent cells on essentially all organs. The timeline for these experiments varies from 2 days to 2 months.     

Subcellular imaging in the live mouse

Fluorescent proteins are available in multiple colors and have properties such as intrinsic brightness and high quantum yield that make them optimally suited for in vivo imaging with subcellular resolution in the live mouse. In this protocol, cancer cells in live mice are labeled with green fluorescent protein (GFP) in the nucleus and red fluorescent protein (RFP) in the cytoplasm. GFP nuclear labeling is effected by linkage of GFP to histone H2B, and a retroviral vector is used for cytoplasmic labeling with RFP. Double-labeled cells are injected by various methods. High-resolution imaging systems with microscopic optics, in combination with reversible skin flaps over various organs, enable the imaging of dual-color labeled cells at the subcellular level in live animals. The double transfection and selection procedures described here take 6-8 weeks. Cancer cell trafficking, deformation, extravasation, mitosis and cell death can be imaged with clarity.     

Color-coded fluorescence imaging of tumor-host interactions

Fluorescent proteins have the properties of being very bright with high quantum yield and are available in many colors. Tumor-host models consist of transgenic mice expressing green fluorescent protein (GFP) in essentially all cells and tissues or expressing GFP selectively in specific tissues such as blood vessels. Particularly useful are the corresponding nude mice transgenic for GFP expression, as they can accept human tumors. When tumor cells expressing red fluorescent protein are implanted in mice expressing GFP, various types of tumor-host interactions can be observed, including those involving host blood vessels, lymphocytes, tumor-associated fibroblasts, macrophages, dendritic cells and others. The 'color-coded' tumor-host models enable imaging and therefore a deeper understanding of the host cells involved and their function in tumor progression. Approximately 4-8 weeks are needed for these procedures.