Characterization of Novel Orange Fluorescent Protein Cloned from Cnidarian Tube Anemone <Emphasis Type="Italic">Cerianthus</Emphasis> sp.

A novel orange fluorescent protein (OFP) was cloned from the tentacles of Cnidarian tube anemone Cerianthus sp. It consists of 222 amino acid residues with a calculated molecular mass of 25.1 kDa. A BLAST protein sequence homology search revealed that native OFP has 81% sequence identity to Cerianthus membranaceus green fluorescent protein (cmFP512), 38% identity to Entacmaea quadricolor red fluorescent protein (eqFP611), 37% identity to Discosoma red fluorescent protein (DsRed), 36% identity to Fungia concinna Kusabira-orange fluorescent protein (KO), and a mere 21% identity to green fluorescent protein (GFP). It is most likely that OFP also adopts the 11-strand β-barrel structure of fluorescent proteins. Spectroscopic analysis indicated that it has a wide absorption spectrum peak at 548 nm with two shoulders at 487 and 513 nm. A bright orange fluorescence maximum at 573 nm was observed when OFP was excited at 515 nm or above. When OFP was excited well below 515 nm, a considerable amount of green emission maximum at 513 nm was also observed. It has a fluorescence quantum yield (Φ) of 0.64 at 25°C. The molar absorption coefficients (ɛ) of folded OFP at 278 and 548 nm are 47,000 and 60,000 M-1⁻¹ • cm-1⁻¹, respectively. Its fluorescent brightness (ɛ Φ) at 25°C is 38,400 M⁻¹-1 • cm⁻¹-1. Like other orange-red fluorescent proteins, OFP is also tetrameric. It was readily expressed as soluble protein in Escherichia coli at 37°C, and no aggregate was observed in transfected HeLa cells under our experimental conditions. Fluorescent intensity of OFP is detectable over a pH range of 3 to 12.     

A Green Fluorescent Protein with Photoswitchable Emission from the Deep Sea

A colorful variety of fluorescent proteins (FPs) from marine invertebrates are utilized as genetically encoded markers for live cell imaging. The increased demand for advanced imaging techniques drives a continuous search for FPs with new and improved properties. Many useful FPs have been isolated from species adapted to sun-flooded habitats such as tropical coral reefs. It has yet remained unknown if species expressing green fluorescent protein (GFP)-like proteins also exist in the darkness of the deep sea. Using a submarine-based and -operated fluorescence detection system in the Gulf of Mexico, we discovered ceriantharians emitting bright green fluorescence in depths between 500 and 600 m and identified a GFP, named cerFP505, with bright fluorescence emission peaking at 505 nm. Spectroscopic studies showed that ∼15% of the protein bulk feature reversible ON/OFF photoswitching that can be induced by alternating irradiation with blue und near-UV light. Despite being derived from an animal adapted to essentially complete darkness and low temperatures, cerFP505 maturation in living mammalian cells at 37°C, its brightness and photostability are comparable to those of EGFP and cmFP512 from shallow water species. Therefore, our findings disclose the deep sea as a potential source of GFP-like molecular marker proteins.     

Dual‐color‐emitting green fluorescent protein from the sea cactus Cavernularia obesa and its use as a pH indicator for fluorescence microscopy

We isolated and characterized a green fluorescent protein (GFP) from the sea cactus Cavernularia obesa. This GFP exists as a dimer and has absorption maxima at 388 and 498 nm. Excitation at 388 nm leads to blue fluorescence (456 nm maximum) at pH 5 and below, and green fluorescence (507 nm maximum) at pH 7 and above, and the GFP is remarkably stable at pH 4. Excitation at 498 nm leads to green fluorescence (507 nm maximum) from pH 5 to pH 9. We introduced five amino acid substitutions so that this GFP formed monomers rather than dimers and then used this monomeric form to visualize intracellular pH change during the phagocytosis of living cells by use of fluorescence microscopy. The intracellular pH change is visualized by use of a simple long‐pass emission filter with single‐wavelength excitation, which is technically easier to use than dual‐emission fluorescent proteins that require dual‐wavelength excitation. Copyright © 2013 John Wiley & Sons, Ltd.     

Variants of Green Fluorescent Protein GFPxm

As research progresses, fluorescent proteins useful for optical marking will evolve toward brighter, monomeric forms that are more diverse in color. We previously reported a new fluorescent protein from Aequorea macrodactyla, GFPxm, that exhibited many characteristics similar to wild-type green fluorescent protein (GFP). However, the application of GFPxm was limited because GFPxm expressed and produced fluorescence only at low temperatures. To improve the fluorescent properties of GFPxm, 12 variants were produced by site-directed mutagenesis and DNA shuffling. Seven of these mutants could produce strong fluorescence when expressed at 37°C. The relative fluorescence intensities of mutants GFPxm16, GFPxm18, and GFPxm19 were higher than that of EGFP (enhanced GFP) when the expression temperature was between 25 and 37°C, and mutants GFPxm16 and GFPxm163 could maintain a high fluorescence intensity even when expressed at 42°C. Meanwhile, at least 4 mutants could be successfully expressed in mammalian cell lines. The fluorescence spectra of 6 of the 12 mutants had a progressive red shift. The longest excitation-emission maximum was at 514/525 nm. In addition, 3 of the 12 mutants had two excitation peaks including an UV-excitation peak, while another mutant had only one UV-excitation peak.     

Spectral diversity among members of the green fluorescent protein family in hydroid jellyfish (Cnidaria,Hydrozoa)

The cDNAs encoding the genes of new proteins, homologous to the well-known Green Fluorescent Protein (GFP) from the hydroid jellyfish Aequorea victoria, were cloned. Two green fluorescent proteins from one unidentified anthomedusa, a yellow fluorescent protein from Phialidium sp., and a nonfluorescent chromoprotein from another unidentified anthomedusa were characterized. Thus, a broad diversity of GFP-like proteins among the organisms of the class Hydrozoa in both spectral properties and primary structure was shown.Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 1, 2005, pp. 49–53.Original Russian Text Copyright © 2005 by Yanushevich, Shagin, Fradkov, Shakhbazov, Barsova, Gurskaya, Labas, Matz, K. Lukyanov, S. Lukyanov.     

Agrobacterium tumefaciens-mediated transformation of the legume Astragalus sinicus using kanamycin resistance selection and green fluorescent protein expression

To develop an efficient protocol for the transformation of the legume Astragalus sinicus (Chinese milk vetch), cotyledon segments were infected with Agrobacterium tumefaciens strain EHA105 harboring the binary vector pBINm-gfp5-ER which carries the gfp5 gene encoding green fluorescent protein and the kanamycin (Km) resistance gene nptII. The infected explants were cultured on shoot regeneration (SR) medium containing 1.0 mg l^–1 -naphthaleneacetic acid (NAA) and 1.0 mg l^–1 thidiazuron (TDZ). Putative transformed shoots were selected on SR medium containing 75 g ml^–1 Km, 200 g ml^–1 Timentin, and transformation was monitored by observation of GFP expression under a dissecting fluorescence microscope with appropriate filters. The identification of GFP-expressing shoots or callus in combination with Km selection allowed the visual selection of growing transgenic cells and shoots with no escapes. Plants were regenerated from seven independent transgenic events and five plants have set seed. GFP expression segregated in the T₁ seedlings of the two lines tested in a 3 – 1 ratio. In addition to the GFP expression of the transgenic plants, the transgenic nature of individual plants was confirmed by Southern and Western blot analyses.     

Temperature influence on fluorescence intensity and enzyme activity of the fusion protein of GFP and hyperthermophilic xylanase

By constructing the expression system for fusion protein of GFPmut1 (a green fluorescent protein mutant) with the hyperthermophilic xylanase obtained from Dictyoglomus thermophilum Rt46B.1, the effects of temperature on the fluorescence of GFP and its relationship with the activities of GFP-fused xylanase have been studied. The fluorescence intensities of both GFP and GFP-xylanase have proved to be thermally sensitive, with the thermal sensitivity of the fluorescence intensity of GFP-xylanase being 15% higher than that of GFP. The lost fluorescence intensity of GFP inactivated at high temperature of below 60°C in either single or fusion form can be completely recovered by treatment at 0°C. By the fluorescence recovery of GFP domain at low temperature, the ratios of fluorescence intensity to xylanase activity (R _gfp/A _xyl) at 15°C and 37°C have been compared. Even though the numbers of molecules of GFP and xylanase are equivalent, the R _gfp/A _xyl ratio at 15°C is ten times of that at 37°C. This is mainly due to the fact that lower temperature is more conducive to the correct folding of GFP than the hyperthermophilic xylanase during the expression. This study has indicated that the ratio of GFP fluorescence to the thermophilic enzyme activity for the fusion proteins expressed at different temperatures could be helpful in understanding the folding properties of the two fusion partners and in design of the fusion proteins.     

Peptide-bound Lysinoalanine Absorbed and Transported to the Kidney—Observation in a Feeding Test with Rats

Specific interaction between green fluorescent protein (GFP)-tagged human α- or γ-enolase^97-242 (α or γENO^97-242) and the rhodamine-labeled DNA fragment containing the c-myc P2 promoter was detected by a fluorescence resonance energy transfer (FRET)-based assay, designated as a “real-time FRET assay.” The approach of donor (GFP) and acceptor (rhodamine) was caused by the association between ENO^97-242 and the c-myc P2 promoter, and the time-dependent increase in fluorescence intensity of the reaction mixture was observed at ex=400 nm and em=590 nm. The relative affinity (R_as) of ENO^97-242 mutants to the wild type was investigated with a real-time FRET assay, and it was clarified that the amino acids that participated in the interaction existed comparatively broadly. Although it was difficult to measure the absolute value of the affinity for the binding protein by using this method, it was possible to investigate the relative affinity of mutants for the wild type. A real-time FRET assay using the GFP-tagged protein could be used as not only a qualitative, but also as a quantitative analysis, this being the best for investigating the key amino acids in binding proteins.     

Testicular somatic cells in the stony coral Euphyllia ancora express an endogenous green fluorescent protein

In a variety of organisms, adult gonads contain several specialized somatic cells that regulate and support the development of germline cells. In stony corals, the characteristics and functions of gonadal somatic cells remain largely unknown. No molecular markers are currently available that allow for the identification and enrichment of gonadal somatic cells in corals. Here, we showed that the testicular somatic cells of a stony coral, Euphyllia ancora, express an endogenous green fluorescent protein (GFP). Fluorescence microscopy showed that, in contrast to the endogenous expression of the red fluorescent protein of E. ancora ovaries that we have previously reported, the testes displayed a distinct green fluorescence. Molecular identification and spectrum characterization demonstrated that E. ancora testes expressed a GFP (named EaGFP) that is a homolog of the GFP from the jellyfish Aequorea victoria and that possesses an excitation maximum of 506 nm and an emission maximum of 514 nm. Immunohistochemical analyses revealed that the testicular somatic cells, but not the germ cells, expressed EaGFP. EaGFP was enclosed within one or a few granules in the cytoplasm of testicular somatic cells, and the granule number decreased as spermatogenesis proceeded. We also showed that testicular somatic cells could be enriched by using endogenous GFP as an indicator. The present study not only revealed one of the unique cellular characteristics of coral testicular cells but also established a technical basis for more in‐depth investigations of the function of testicular somatic cells in spermatogenesis in future studies.     

High-level expression of a polypeptides encoded by a large segment of the envelope gene of HIV-1 in E. coli by directed evolution

A random mutagenesis library of gp120-801 (a large segment of the envelope protein gene of HIV-1) was constructed using error-prone PCR and DNA shuffling methods, and one mutant of gp120-801 was selected from this library using a green fluorescent protein (GFP) fusion vector. After being cloned into pEX31b and expressed in E. coli, the expressed fusion protein reached to 15% of total bacterial proteins for the mutant but was just 1–2% for the wild type.     

The Dependence of Stability of the Green Fluorescent Protein–Obelin Hybrids on the Nature of Their Constituent Modules and the Structure of the Amino Acid Linker

Recombinant plasmids containing genes for the green fluorescent protein (GFP) from Aequorea victoriaand the photoprotein obelin from Obelia longissimalinked in-frame by inserts differing in nucleotides sequences were constructed. The expression of the chimeric genes in Escherichia colicells resulted in synthesis of the GFP–obelin hybrid proteins. These proteins were purified to homogeneity and subjected to limited trypsinolysis. It was shown that the resistance of GFP–obelin hybrid proteins to trypsin depends on the nature of their constituent modules and the amino acid sequences of linkers between the modules. The kinetics of accumulation of full-length hybrid proteins during the growth of bacterial cells does not depend on the structure of the peptide linkers. Most of the full-length product accumulates in cells in the form of inclusion bodies resistant to endogenous proteases. The soluble fraction of the protein undergoes considerable proteolysis regardless of the linker structure.     

Green fluorescent protein (GFP) as a direct biosensor for mutation detection: elimination of false-negative errors in target gene expression

A new method was developed to determine the mutagenic efficacy of a suspected mutagen by employing green fluorescent protein (GFP) as a direct biosensor for mutation detection. Alterations in target gene (AcGFP1) expression after mutagen [(±)-7p,8a-dihydroxy-9a,10a-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE)] treatment were measured to detect the mutagenic efficacy of the carcinogen. In contrast to mutagen treatment of the entire plasmid or cell culture, the target AcGFP1gene devoid of the plasmid backbone was exposed to BPDE (10–500 μM) to eliminate the need for an additional fusion gene. Shuttle vectors (pAcGFP-N1) were religated to the AcGFP1 gene with BPDE adducts (0–8.59 μM) and replicated in the eukaryotic host. This approach eliminated false-negative errors in target gene expression that arose from BPDE adduct formation in the residual plasmid backbone rather than in the AcGFP1 gene. Determination of the BPDE–AcGFP1 adducts allowed the quantitative mutagenic effect of the BPDE adducts on AcGFP1 gene expression to be monitored. The results obtained with flow cytometry and confocal microscopy validate our method and demonstrate efficient and direct use of GFP as a biosensor for mutation detection.     

Binding of chimeric metal-binding green fluorescent protein to lipid monolayer

Membrane-based bioanalytical devices for metal determination using green fluorescent protein as the sensor molecule may be a useful future biomimetic material. However, in order to develop such a device, it is necessary first to understand the interaction of the protein with lipid membranes. Thus we have investigated the interaction between chimeric cadmium-binding green fluorescent proteins (CdBPGFPs) and lipid monolayers, using a film-balance technique complemented with epifluorescence microscopy. The binding avidity was monitored from the surface pressure vs. area isotherms or from the measured increase in the lateral pressure upon injection of the chimeric CdBPGFPs beneath the lipid monolayer. Increased fluidization as well as expansion of the surface area were shown to depend on the concentration of the CdBPGFPs. The kinetics of the protein-induced increase in lateral pressure was found to be biphasic. The chimeric CdBPGFPs possessed high affinity to the 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) monolayer with a dissociation constant of K_d=10^–8M. Epifluorescence measurements showed that this affinity is due to the presence of the Cd-binding peptide, which caused the GFP to incorporate preferentially to the liquid phase and defect part of the rigid domain at low interfacial pressure. At high compression, the Cd-binding peptide could neither incorporate nor remain in the lipid core. However, specific orientation of the chimeric CdBPGFPs underneath the air–water interface was achieved, even under high surface pressure, when the proteins were applied to the metal-chelating lipid-containing surfaces. This specific binding could be controlled reversibly by the addition of metal ions or metal chelator. The reversible binding of the chimeric CdBPGFPs to metal-chelating lipids provided a potential approach for immobilization, orientation and lateral organization of a protein at the membrane interface. Furthermore, the feasibility of applying the chelator lipids for the codetermination of metal ions with specific ligands was also revealed. Our finding clearly demonstrates that a strong interaction, particularly with fluid lipid domains, could potentially be used for sensor development in the future.Abbreviations GFP green fluorescent protein - CdBPGFPs cadmium-binding green fluorescent protein - DPPC 1,2-dipalmitoyl-sn-glycero-3-phosphocholine - AAS atomic absorption spectrometry - Cd²⁺ cadmium (II) - Zn²⁺ zinc (II) - Cu²⁺ copper (II) - Ni²⁺ nickel (II) - E. coli Escherichia coli - NTA-DOGS 1,2-dioleoyl-sn-glycero-3-(N-(5-amino-1-carboxypentyl iminodiacetic acid) succinyl) - His6GFP hexahistidine green fluorescent protein - CdBP4GFP four-repeat cadmium-binding peptide green fluorescent protein - His6CdBP4GFP hexahistidine four-repeat cadmium-binding peptide green fluorescent protein - IMAC immobilized-metal-affinity chromatography - PBS phosphate-buffered saline - mN/m millinewton per metre - le liquid expanded - lc liquid condensed - PE phosphatidyl ethanolamine - PI phosphatidyl inositol - NTA nitrilotriacetic acid - EDTA ethylenediamine tetraacetic acid - RESA ring-infected erythrocyte surface antigen - CdBP cadmium-binding peptide     

Green fluorescent protein is superior to blue fluorescent protein as a quantitative reporter of promoter activity in <Emphasis Type="Italic">E. coli</Emphasis>

Fluorescent proteins related to and derived from green fluorescent protein (GFP) are widely used as tools for investigating a wide range of biological processes. In particular, GFP and its relatives have been used extensively as qualitative reporters of gene expression in many different organisms, but relatively few studies have investigated fluorescent proteins as quantitative reporters of gene expression. GFP has some limitations as a reporter gene, including possible toxicity when expressed at high levels. Therefore, it would be useful if other fluorescent proteins could be identified for use as quantitative reporters. Toward this end, we investigated BFP as a quantitative reporter of promoter activity in E. coli and directly compared it with GFPuv using a set of well-characterized synthetic constitutive promoters. The fluorescence produced in E. coli strains expressing GFPuv or BFP grown on solid medium was quantified using a CCD camera and fluorimetry. GFPuv consistently gave more reliable and statistically significant results than did BFP in all assays. Correspondingly, we found that the signal-to-noise ratio for GFPuv fluorescence is substantially higher than for BFP. We conclude that, under the conditions assessed in this study, GFPuv is superior to BFP as a quantitative reporter of promoter activity in E. coli. J. Bayes, M. Calvey, L. Reineke, A. Colagiavanni, and M. Tscheiner made equivalent contributions to this work.     

Expression of a chromosomally integrated, single-copy GFP gene in Candida albicans , and its use as a reporter of gene regulation

Genetically engineered versions of the GFP gene, which encodes the green fluorescent protein of Aequorea victoria, were placed under the control of the constitutively active Candida albicansACT1 promoter and integrated in single copy into the genome of this pathogenic yeast. Integrative transformants in which one of the two ACT1 alleles had been replaced by a GFP gene exhibited a homogeneous, constitutive fluorescent phenotype. Cells expressing GFP with the wild-type chromophore exhibited very weak fluorescence compared to those GFP proteins with the S65T or S65A, V68L, S72A (GFPmut2) chromophore mutations. Substitution of the CTG codon, which specifies serine instead of leucine in C. albicans, by TTG was absolutely necessary for GFP expression. Although GFP mRNA levels in cells containing a GFP gene with the CTG codon were comparable to those of transformants containing GFP with the TTG substitution, only the latter produced GFP protein, as detected by Western blotting, suggesting that the frequent failure to express heterologous genes in C. albicans is principally due to the non-canonical codon usage. Transformants expressing the modified GFP gene from the promoter of the SAP2 gene, which encodes one of the secreted acid proteinases of C. albicans, showed fluorescence only under conditions which promote proteinase expression, thereby demonstrating the utility of stable, chromosomally integrated GFP reporter genes for the study of gene activation in C. albicans. Received: 27 June 1997 / Accepted: 26 September 1997     

Development of Lactococcus lactis encoding fluorescent proteins,GFP, mCherry and iRFP regulated by the nisin-controlled gene expression system

Fluorescent proteins are useful reporter molecules for a variety of biological systems. We present an alternative strategy for cloning reporter genes that are regulated by the nisin-controlled gene expression (NICE) system. Lactoccocus lactis was genetically engineered to express green fluorescent protein (GFP), mCherry or near-infrared fluorescent protein (iRFP). The reporter gene sequences were optimized to be expressed by L. lactis using inducible promoter pNis within the pNZ8048 vector. Expression of constructions that carry mCherry or GFP was observed by fluorescence microscopy 2 h after induction with nisin. Expression of iRFP was evaluated at 700 nm using an infrared scanner; cultures induced for 6 h showed greater iRFP expression than non-induced cultures or those expressing GFP. We demonstrated that L. lactis can express efficiently GFP, mCherry and iRFP fluorescent proteins using an inducible expression system. These strains will be useful for live cell imaging studies in vitro or for imaging studies in vivo in the case of iRFP.     

Probing the structural determinants of yellow fluorescence of a protein from Phialidium sp

Fluorescent proteins homologous to green fluorescent protein (avGFP) display pronounced spectral variability due to different chromophore structures and variable chromophore interactions with the surrounding amino acids. To gain insight into the structural basis for yellow emission, the 3D structure of phiYFP (λ_em = 537 nm), a protein from the sea medusa Phialidium sp., was built by a combined homology modeling – mass spectrometry approach. Mass spectrometry of the isolated chromophore-bearing peptide reveals that the chromophore of phiYFP is chemically identical to that of avGFP (λ_em = 508 nm). The experimentally acquired chromophore structure was combined with the homology-based model of phiYFP, and the proposed 3D structure was used as a starting point for identification of the structural features responsible for yellow fluorescence. Mutagenesis of residues in the local chromophore environment of phiYFP suggests that multiple factors cooperate to establish the longest-wavelength emission maximum among fluorescent proteins with an unmodified GFP-like chromophore.     

珊瑚和海葵来源红荧光蛋白的研究和应用

绿色荧光蛋白作为标记蛋白和报告蛋白在生物学研究中应用越来越广。但在荧光共振能量转移(fluorescenceresonanceenergytransfer,FRET)等技术中存在一些缺陷,需要更大波长范围的荧光蛋白。最近研究发现了多种来源于珊瑚和海葵的红荧光蛋白,这些长波长的荧光蛋白对绿色荧光蛋白是一种很好的代替和补充,可以实现细胞内多荧光标记,提供更理想的FRET荧光对。经随机突变和定点突变等方法改建获得的红荧光蛋白变种显示出更高的荧光强度,成熟时间也更短。目前应用较多的是来源于香菇珊瑚(Discosomasp.)的红荧光蛋白DsRed。     

Green fluorescent protein as a visual selection marker for papaya (<Emphasis Type="Italic">Carica papaya</Emphasis> L.) transformation

Chemical-based selection for plant transformation is associated with a number of real and perceived problems that might be avoided through visual selection. We have used green fluorescent protein (GFP), as a visual selectable marker to produce transformed papaya (Carica papaya) plants following microprojectile bombardment of embryogenic callus. GFP selection reduced the selection time from 3 months on a geneticin (G418) antibiotic-containing medium to 3–4 weeks. Moreover, GFP selection increased the number of transformed papaya plants by five-to eightfold compared to selection in the presence of antibiotics. Overall, the use of GFP for selecting transgenic papaya lines improved our throughput for transformation by 15- to 24-fold while avoiding the drawbacks associated with the use of antibiotic resistance-based selection markers.Abbreviations BA: Benzyladenine - 2, 4-D: 2,4-Dichlorophenoxyacetic acid - GFP: Green fluorescent protein - IBA: Indole-3-butyric acid - NAA: -Naphthaleneacetic acid - MS: Murashige and Skoog plant culture mediumCommunicated by R.J. Rose