Spectral Diversity of Fluorescent Proteins from the Anthozoan <Emphasis Type="Italic">Corynactis californica</Emphasis>

Color morphs of the temperate, nonsymbiotic corallimorpharian Corynactis californica show variation in pigment pattern and coloring. We collected seven distinct color morphs of C. californica from subtidal locations in Monterey Bay, California, and found that tissue– and color–morph-specific expression of at least six different genes is responsible for this variation. Each morph contains at least three to four distinct genetic loci that code for these colors, and one morph contains at least five loci. These genes encode a subfamily of new GFP-like proteins, which fluoresce across the visible spectrum from green to red, while sharing between 75% to 89% pairwise amino-acid identity. Biophysical characterization reveals interesting spectral properties, including a bright yellow protein, an orange protein, and a red protein exhibiting a “fluorescent timer” phenotype. Phylogenetic analysis indicates that the FP genes from this species evolved together but that diversification of anthozoan fluorescent proteins has taken place outside of phylogenetic constraints, especially within the Corallimorpharia. The discovery of more examples of fluorescent proteins in a non-bioluminescent, nonsymbiotic anthozoan highlights possibilities of adaptive ecological significance unrelated to light regulation for algal symbionts. The patterns and colors of fluorescent proteins in C. californica and similar species may hold meaning for organisms that possess the visual pigments to distinguish them. Christine E. Schnitzler and Robert J. Keenan contributed equally to this work. Data deposition footnote: The GenBank () accession numbers for the genes and gene products discussed in this paper are: ccalRFP1 (AY823226); ccalYFP1 (AY823227); ccalRFP2 (DQ065851); ccalGFP1 (DQ065852); ccalOFP1 (DQ065853); ccalGFP3 (DQ899732)     

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.     

An enhanced monomeric blue fluorescent protein with the high chemical stability of the chromophore

Commonly used monomeric blue fluorescent proteins suffer from moderate brightness. The brightest of them, mTagBFP, has a notably low chemical stability over time. Prolonged incubation of mTagBFP leads to its transition from a blue fluorescent state with absorbance at 401 nm to a non-fluorescent state with absorbance at 330 nm. Here, we have determined the chemical structure of the degraded product of the blue mTagBFP-like chromophore. On the basis of mTagBFP we have developed an improved variant, named mTagBFP2. mTagBFP2 exhibits 2-fold greater chemical stability and substantially higher brightness in live cells than mTagBFP. mTagBFP2 is also 1.2-fold and 1.7-fold more photostable than mTagBFP in widefield and confocal microscopy setups, respectively. mTagBFP2 maintains all other beneficial properties of the parental mTagBFP including the high pH stability and fast chromophore formation. The enhanced photostability and chromophore chemical stability of mTagBFP2 make it a superior protein tag. mTagBFP2 performs well in the numerous protein fusions and surpasses mTagBFP as a donor in Förster resonance energy transfer with several green fluorescent protein acceptors.     

Fluorescent "Turn-on" system utilizing a quencher-conjugated peptide for specific protein labeling of living cells

A specific protein fluorescent labeling method has been used as a tool for bio-imaging in living cells. We developed a novel system of switching “fluorescent turn on” by the recognition of a fluorescent probe to a hexahistidine-tagged (His-tag) protein. The tetramethyl rhodamine bearing three nitrilotriacetic acids, which was used as a fluorescent probe to target a His-tagged protein, formed a reversible complex with the quencher, (Dabcyl)-conjugated oligohistidines, in the homogeneous solution, causing fluorescence of the fluorophore to be quenched. The complex when applied to living cells (COS-7) expressing His-tagged proteins on the cell surface caused the quencher-conjugated oligohistidines to be dissociated from the complex by specific binding of the fluorescent probe to the tagged protein, resulting in the fluorescent emission. The complex that did not participate in the binding event remained in the quenched state to maintain a low level of background fluorescence.     

Tagging of Escherichia coli proteins with new cassettes allowing in vivo systematic fluorescent and luminescent detection,and purification from physiological expression levels

We designed cassettes allowing the systematic fusion of fluorescent or luminescent proteins preceded by the calmodulin binding peptide tag to the C–terminus of Escherichia coli proteins. The chromosomal insertion, and thus physiological expression level of these fusions, permits the study of protein localization by fluorescent microscopy and protein quantification, in vivo and dynamically in diverse conditions. Furthermore, the calmodulin binding peptide tag allows standard detection, affinity purification, and co–purification experiments. These cassettes are therefore very valuable for the versatility of experiments they make available for a given strain, from biochemistry to dynamic and in vivo studies.     

Towards Multiparametric Fluorescent Imaging of Amyloid Formation: Studies of a YFP Model of α-Synuclein Aggregation

Misfolding and aggregation of proteins are characteristics of a range of increasingly prevalent neurodegenerative disorders including Alzheimer's and Parkinson's diseases. In Parkinson's disease and several closely related syndromes, the protein α-synuclein (AS) aggregates and forms amyloid-like deposits in specific regions of the brain. Fluorescence microscopy using fluorescent proteins, for instance the yellow fluorescent protein (YFP), is the method of choice to image molecular events such as protein aggregation in living organisms. The presence of a bulky fluorescent protein tag, however, may potentially affect significantly the properties of the protein of interest; for AS in particular, its relative small size and, as an intrinsically unfolded protein, its lack of defined secondary structure could challenge the usefulness of fluorescent-protein-based derivatives. Here, we subject a YFP fusion of AS to exhaustive studies in vitro designed to determine its potential as a means of probing amyloid formation in vivo. By employing a combination of biophysical and biochemical studies, we demonstrate that the conjugation of YFP does not significantly perturb the structure of AS in solution and find that the AS-YFP protein forms amyloid deposits in vitro that are essentially identical with those observed for wild-type AS, except that they are fluorescent. Of the several fluorescent properties of the YFP chimera that were assayed, we find that fluorescence anisotropy is a particularly useful parameter to follow the aggregation of AS-YFP, because of energy migration Förster resonance energy transfer (emFRET or homoFRET) between closely positioned YFP moieties occurring as a result of the high density of the fluorophore within the amyloid species. Fluorescence anisotropy imaging microscopy further demonstrates the ability of homoFRET to distinguish between soluble, pre-fibrillar aggregates and amyloid fibrils of AS-YFP. Our results validate the use of fluorescent protein chimeras of AS as representative models for studying protein aggregation and offer new opportunities for the investigation of amyloid aggregation in vivo using YFP-tagged proteins.     

灰葡萄孢菌过氧化物酶体及细胞核的荧光蛋白标记

[目的]对灰葡萄孢菌(Botrytis cinerea)的细胞核和过氧化物酶体进行荧光蛋白标记,为研究其生长发育和侵染过程中细胞结构和细胞器动态提供基础.[方法]以绿色荧光蛋白(GFP)和红色荧光蛋白(DsRED、mCherry)为报告基因,利用根癌农杆菌介导转化(Agrobacterium tumefaciens m...     

Fluorescent labelling of Na+,K+-ATPase in intact cells by use of a fluorescent derivative of ouabain: Salinity and teleost chloride cells

Summary Anthroylouabain, a fluorescent derivative of ouabain, was used to localize Na⁺,K⁺-ATPase in transport epithelia of two species of teleosts. Exposure of the opercular membrane of seawater-adapted tilapia (Oreochromis mossambicus) and the jaw skin of the long-jawed mudsucker (Gillichthys mirabilis) to a 2 M anthroylouabain solution resulted in the appearance of cells stained bright blue. These were deemed to be chloride cells by their large size, distinct morphology and co-localization of DASPEI fluorescence, a mitochondrial stain. Addition of ouabain (1 mM final concentration) greatly decreased anthroylouabain fluorescent staining of chloride cells of seawater-adapted fish. Exposure of opercular membranes from freshwater tilapia to 2 M anthroylouabain did not result in significant staining. Anthroylouabain is therefore a useful vital stain for localizing Na⁺,K⁺-ATPase in chloride cells of seawater-adapted teleosts, and may be useful for fluorescent labelling of ouabain-sensitive Na⁺,K⁺-ATPase in other tissues and species.     

Split-wrmScarlet and split-sfGFP: tools for faster,easier fluorescent labeling of endogenous proteins in Caenorhabditis elegans

We create and share a new red fluorophore, along with a set of strains, reagents and protocols, to make it faster and easier to label endogenous Caenorhabditis elegans proteins with fluorescent tags. CRISPR-mediated fluorescent labeling of C. elegans proteins is an invaluable tool, but it is much more difficult to insert fluorophore-size DNA segments than it is to make small gene edits. In principle, high-affinity asymmetrically split fluorescent proteins solve this problem in C. elegans: the small fragment can quickly and easily be fused to almost any protein of interest, and can be detected wherever the large fragment is expressed and complemented. However, there is currently only one available strain stably expressing the large fragment of a split fluorescent protein, restricting this solution to a single tissue (the germline) in the highly autofluorescent green channel. No available C. elegans lines express unbound large fragments of split red fluorescent proteins, and even state-of-the-art split red fluorescent proteins are dim compared to the canonical split-sfGFP protein. In this study, we engineer a bright, high-affinity new split red fluorophore, split-wrmScarlet. We generate transgenic C. elegans lines to allow easy single-color labeling in muscle or germline cells and dual-color labeling in somatic cells. We also describe a novel expression strategy for the germline, where traditional expression strategies struggle. We validate these strains by targeting split-wrmScarlet to several genes whose products label distinct organelles, and we provide a protocol for easy, cloning-free CRISPR/Cas9 editing. As the collection of split-FP strains for labeling in different tissues or organelles expands, we will post updates at doi.org/10.5281/zenodo.3993663     

Condensed Mitotic Chromosome Structure at Nanometer Resolution Using PALM and EGFP- Histones

Photoactivated localization microscopy (PALM) and related fluorescent biological imaging methods are capable of providing very high spatial resolutions (up to 20 nm). Two major demands limit its widespread use on biological samples: requirements for photoactivatable/photoconvertible fluorescent molecules, which are sometimes difficult to incorporate, and high background signals from autofluorescence or fluorophores in adjacent focal planes in three-dimensional imaging which reduces PALM resolution significantly. We present here a high-resolution PALM method utilizing conventional EGFP as the photoconvertible fluorophore, improved algorithms to deal with high levels of biological background noise, and apply this to imaging higher order chromatin structure. We found that the emission wavelength of EGFP is efficiently converted from green to red when exposed to blue light in the presence of reduced riboflavin. The photon yield of red-converted EGFP using riboflavin is comparable to other bright photoconvertible fluorescent proteins that allow <20 nm resolution. We further found that image pre-processing using a combination of denoising and deconvolution of the raw PALM images substantially improved the spatial resolution of the reconstruction from noisy images. Performing PALM on Drosophila mitotic chromosomes labeled with H2AvD-EGFP, a histone H2A variant, revealed filamentous components of ∼70 nm. This is the first observation of fine chromatin filaments specific for one histone variant at a resolution approximating that of conventional electron microscope images (10–30 nm). As demonstrated by modeling and experiments on a challenging specimen, the techniques described here facilitate super-resolution fluorescent imaging with common biological samples.     

Dynamic Regulation of Fluorescent Proteins from a Single Species of Coral

To gain a better understanding of the natural function of fluorescent proteins, we have undertaken quantitative analyses of these proteins in a single species of coral, Montastraea cavernosa, residing around Turneffe atoll, on the Belizean Barrier Reef. We identified at least 10 members of a fluorescent protein family in this species, which consist of 4 distinct spectral classes. As much as a 10-fold change in the overall expression of fluorescent proteins was observed from specimen to specimen, suggesting that fluorescent proteins are dynamically regulated in response to environmental or physiological conditions. We found that the expression of some proteins was inversely correlated with depth, and that groups of proteins were coordinately expressed. There was no relationship between the expression of fluorescent proteins and the natural coloration of the Montastraea cavernosa specimens in this study. These findings have implications for current hypotheses regarding the properties and natural function of fluorescent proteins.     

Superresolution imaging of multiple fluorescent proteins with highly overlapping emission spectra in living cells

Localization-based superresolution optical imaging is rapidly gaining popularity, yet limited availability of genetically encoded photoactivatable fluorescent probes with distinct emission spectra impedes simultaneous visualization of multiple molecular species in living cells. We introduce PAmKate, a monomeric photoactivatable far-red fluorescent protein, which facilitates simultaneous imaging of three photoactivatable proteins in mammalian cells using fluorescence photoactivation localization microscopy (FPALM). Successful probe identification was achieved by measuring the fluorescence emission intensity in two distinct spectral channels spanning only ∼100 nm of the visible spectrum. Raft-, non-raft-, and cytoskeleton-associated proteins were simultaneously imaged in both live and fixed fibroblasts coexpressing Dendra2-hemagglutinin, PAmKate-transferrin receptor, and PAmCherry1-β-actin fusion constructs, revealing correlations between the membrane proteins and membrane-associated actin structures.     

Engineering of a monomeric green-to-red photoactivatable fluorescent protein induced by blue light

Green fluorescent protein (GFP) and GFP-like proteins represent invaluable genetically encoded fluorescent probes. In the last few years a new class of photoactivatable fluorescent proteins (PAFPs) capable of pronounced light-induced spectral changes have been developed. Except for tetrameric KFP1 (ref. 4), all known PAFPs, including PA-GFP, Kaede, EosFP, PS-CFP, Dronpa, PA-mRFP1 and KikGR require light in the UV-violet spectral region for activation through one-photon excitation--such light can be phototoxic to some biological systems. Here, we report a monomeric PAFP, Dendra, derived from octocoral Dendronephthya sp. and capable of 1,000- to 4,500-fold photoconversion from green to red fluorescent states in response to either visible blue or UV-violet light. Dendra represents the first PAFP, which is simultaneously monomeric, efficiently matures at 37 degrees C, demonstrates high photostability of the activated state, and can be photoactivated by a common, marginally phototoxic, 488-nm laser line. We demonstrate the suitability of Dendra for protein labeling and tracking to quantitatively study dynamics of fibrillarin and vimentin in mammalian cells.     

Localisation and synthesis of α-fetoprotein in the rabbit

Summary The cellular location and sites of synthesis of -fetoprotein (AFP) in the foetal, neonatal and maternal rabbit, were studied by the fluorescent antibody technique and by culturing tissuesin vitro with labelled amino acids. AFP was found to be localised intracellularly within liver hepatocytes and yolk sac endoderm of the foetus, and within the maternal uterine epithelium. Analysis of extracts of the cultured tissues for incorporation of radioactivity into serum proteins separated by polyacrylamide gel electrophoresis or analysed by autoradiography of immuno-precipitation lines, confirmed that the foetal liver and yolk sac splanchnopleur were the principal sites of primary synthesis of AFP. Localisation of AFP in the uterine epithelium and other foetal organs was consistent with a secondary derivation from the uterine fluid or from the blood circulation. These findings are discussed in relationship to findings in man and other mammals.Supported by an award from the Medical Research Council to whom grateful acknowledgement is made.     

Cell migration within the embryonic limb primordium of Drosophila as revealed by a novel fluorescence method to visualize mRNA and protein

 We report a new technique using fluorescent probes to detect a mRNA and a protein simultaneously in the Drosophila embryo. For in situ hybridization, 3-hydroxy-N-2′-biphenyl-2-naphthalenecarboxamide phosphate ester (HNPP)/Fast Red TR was used as a fluorescent substrate for alkaline phosphatase. It was possible to compare protein and mRNA expression on a cell by cell basis with a laser scanning confocal microscope. We applied this technique to analyse the dynamics of Distal-less (Dll) enhancer activity in the thoracic limb primordium in the early Drosophila embryo. We stained embryos bearing the Dll early enhancer (Dll-304) fused to the Escherichia coli lacZ gene. LacZ mRNA was detectable in the ventral region of the limb primordium, and β-galactosidase protein in the dorsal region. In the middle, both mRNA and protein were detectable. These results suggest that the Dll enhancer is activated in the ventral region of the limb primordium and that Dll-positive cells migrate from a ventral position to a dorsal one within a single limb primordium. Received: 7 April 1997 / Accepted: 15 May 1997     

荧光蛋白在双色蜡蘑中的构建与表达

菌根是真菌与植物之间形成的互惠互利的营养共生体,对生态环境有重大的意义。外生菌根真菌与植物互作机制以及真菌基因功能的深入研究都需要对菌根真菌进行遗传转化,本研究以外生菌根真菌模式生物双色蜡蘑(Laccaria bicolor)为研究对象,选择细胞核中的核小体蛋白H₂B基因为目的基因,以pCEBN为表达载体,融合红色荧光蛋白,最终构建在真菌中表达的双元载体,使用根瘤农杆菌介导转化法转化双色蜡蘑菌丝,随后利用PCR对真菌转化子进行验证后,通过激光共聚焦显微镜观察到菌丝细胞核中的红色荧光,成功将融合荧光蛋白转化菌根真菌,为后续研究菌根真菌中基因的亚细胞定位提供了实验平台。结果表明,利用双元载体和农杆菌转化方法,建立了高效的双色蜡蘑转化体系(93.33%),在激光共聚焦显微镜下观察到菌丝细胞核中红色荧光信号,验证了融合荧光蛋白在双色蜡蘑中的成功表达。本研究成功地构建了菌根真菌中的核小体蛋白和红色荧光蛋白融合表达的真菌转化体系。     

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.     

Photomodulatable fluorescent proteins for imaging cell dynamics and cell fate

An organism arises from the coordinate generation of different cell types and the stereotypical organization of these cells into tissues and organs. Even so, the dynamic behaviors, as well as the ultimate fates, of cells driving the morphogenesis of an organism, or even an individual organ, remain largely unknown. Continued innovations in optical imaging modalities, along with the discovery and evolution of improved genetically-encoded fluorescent protein reporters in combination with model organism, stem cell and tissue engineering paradigms are providing the means to investigate these unresolved questions. The emergence of fluorescent proteins whose spectral properties can be photomodulated is one of the most significant new developments in the field of cell biology where they are primarily used for studying protein dynamics in cells. Likewise, the use of photomodulatable fluorescent proteins holds great promise for use in developmental biology. Photomodulatable fluorescent proteins also represent attractive and emergent tools for studying cell dynamics in complex populations by facilitating the labeling and tracking of individual or defined groups of cells. Here, we review the currently available photomodulatable fluorescent proteins and their application in model organisms. We also discuss prospects for their use in mice, and by extension in embryonic stem cell and tissue engineering paradigms.Key words: fluorescent protein, photomodulation, photoactivation, photoconversion, mouse, live imaging, embryonic development, organogenesis, GFP, PA-GFP, PS-CFP, Kaede, KikGR