High-order photobleaching of green fluorescent protein inside live cells in two-photon excitation microscopy

Combination of green fluorescent protein (GFP) and two-photon excitation fluorescence microscopy (TPE) has been used increasingly to study dynamic biochemical events within living cells, sometimes even in vivo. However, the high photon flux required in TPE may lead to higher-order photobleaching within the focal volume, which would introduce misinterpretation about the fine biochemical events. Here we first studied the high-order photobleaching rate of GFP inside live cells by measuring the dependence of the photobleaching rate on the excitation power. The photobleaching rate under one- and two-photon excitation increased with 1-power and 4-power of the incident intensity, respectively, implying the excitation photons might interact with excited fluorophore molecules and increase the probability of photobleaching. These results suggest that in applications where two-photon imaging of GFP is used to study dynamic molecular process, photobleaching may ruin the imaging results and attention should be paid in interpreting the imaging results.     

Use of enhanced green fluorescent protein to determine pepsin at high sensitivity

A fluorometric assay for pepsin and pepsinogen was developed using enhanced green fluorescent protein (EGFP) as a substrate. Acid denaturation of EGFP resulted in a complete loss of fluorescence that was completely reversible on neutralization. In the proteolytic assay procedure, acid-denatured EGFP was digested by pepsin or activated pepsinogen. After neutralization, the remaining amount of undigested EGFP refolded and was determined by fluorescence. Under standard digestion conditions, 4.8-24.0 ng pepsin or pepsinogen was used. Using porcine pepsin as a standard, 38+/-6.7 ng EGFP was digested per min-1 ng pepsin-1. Activated porcine pepsinogen revealed a similar digestion rate (37.2+/-5.2 ng EGFP min-1 ng activated pepsinogen-1). The sensitivity of the proteolysis assay depended on the time of digestion and the temperature. Increasing temperature and incubation time allowed quantification of pepsin or pepsinogen in a sample even in the picogram range. The pepsin-catalyzed EGFP digestion showed typical Michaelis-Menten kinetics. Km and Vmax values were determined for the pepsin and activated pepsinogen. Digestion of EGFP by pepsin revealed distinct cleavage sites, as analyzed by SDS-PAGE.     

GFP在绿色荧光裸鼠不同组织中的表达及分析

目的研究外源绿色荧光蛋白（green fluorescent protein,简称GFP）基因在BALB/c绿色荧光裸鼠主要器官组织中的表达及其差异。方法小动物成像系统和RT-PCR方法检测GFP的组织分布以及荧光表达水平情况。结果经活体荧光影像系统观察及PCR方法检测发现GFP可以在裸鼠多个器官组织中表达,其中在胰腺、心脏、全脑、皮肤、睾丸中表达量较高。结论外源绿色荧光蛋白可以在模型动物体内成功表达且稳定遗传,其中在胰腺组织中高表达。     

Monitoring of conformational change in maltose binding protein using split green fluorescent protein

In this study, we describe a novel method for the detection of conformational changes in proteins, which is predicated on the reconstitution of split green fluorescent protein (GFP). We employed fluorescence complementation assays for the monitoring of the conformationally altered proteins. In particular, we used maltose binding protein (MBP) as a model protein, as MBP undergoes a characteristic hinge-twist movement upon substrate binding. The common feature of this approach is that GFP, as a reporter protein, splits into two non-fluorescent fragments, which are genetically fused to the N- and C-termini of MBP. Upon binding to maltose, the chromophores move closer together, resulting in the generation of fluorescence. This split GFP method also involves the reconstitution of GFP, which is determined via observations of the degree to which fluorescence intensity is restored. As a result, reconstituted GFP has been observed to generate fluorescence upon maltose binding in vitro, thereby allowing for the direct detection of changes in fluorescence intensity in response to maltose, in a concentration- and time-dependent fashion. Our findings showed that the fluorescence complementation assay can be used to monitor the conformational alterations of a target protein, and this ability may prove useful in a number of scientific and medical applications.     

Purification of green fluorescent protein using a two-intein system

A two-intein purification system was developed for the affinity purification of GFPmut3*, a mutant of green fluorescent protein. The GFPmut3* was sandwiched between two self-cleaving inteins. This approach avoided the loss of the target protein which may result from in vivo cleavage of a single intein tag. The presence of N- and C-terminal chitin-binding domains allowed the affinity purification by a single-affinity chitin column. After the fusion protein was expressed and immobilized on the affinity column, self-cleavage of the inteins was sequentially induced to release the GFPmut3*. The yield was 2.41 mg from 1 l of bacterial culture. Assays revealed that the purity was up to 98% of the total protein. The fluorescence and circular dichroism spectrum of GFPmut3* demonstrated that the purified protein retains the correctly folded structure and function.     

Metal-enhanced fluorescence of single green fluorescent protein (GFP)

The green fluorescent protein (GFP) has emerged as a powerful reporter molecule for monitoring gene expression, protein localization, and protein-protein interaction. However, the detection of low concentrations of GFPs is limited by the weakness of the fluorescent signal and the low photostability. In this report, we observed the proximity of single GFPs to metallic silver nanoparticles increases its fluorescence intensity approximately 6-fold and decreases the decay time. Single protein molecules on the silvered surfaces emitted 10-fold more photons as compared to glass prior to photobleaching. The photostability of single GFP has increased to some extent. Accordingly, we observed longer duration time and suppressed blinking. The single-molecule lifetime histograms indicate the relatively heterogeneous distributions of protein mutants inside the structure.     

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     

Transgenic pig expressing the enhanced green fluorescent protein produced by nuclear transfer using colchicine-treated fibroblasts as donor cells

Fetal-derived fibroblast cells were transduced with replication defective vectors containing the enhanced green fluorescent protein (EGFP). The transgenic cells were treated with colchicine, which theoretically would synchronize the cells into G2/M stage, and then used as donor nuclei for nuclear transfer. The donor cells were transferred into the perivitalline space of enucleated in vitro matured porcine oocytes, and fused and activated with electrical pulses. A total of 8.3% and 28.6% of reconstructed oocytes showed nuclear envelope breakdown and premature chromosome condensation 0.5 and 2 hr after activation, respectively. Percentage of pronuclear formation was 62.5, 12 hr after activation. Most (91.4%) of the 1-cell embryos with pronuclei did not extrude a polar body. Most (77.2%) embryos on day 5 were diploid. Within 2 hr after fusion, strong fluorescence was detectable in most reconstructed oocytes (92.3%). The fluorescence in all NT embryos became weak 15 hr after fusion and disappeared when culture to 48 hr. But from day 3, cleaved embryos at the 2- to 4-cell stage started to express EGFP again. On day 7, 85.8% of cleaved embryos expressed EGFP. A total of 9.4% of reconstructed embryos developed to blastocyst stage and 71.5% of the blastoctysts expressed EGFP. After 200 reconstructed 1-cell stage embryos were transferred into four surrogate gilts, three recipients were found to be pregnant. One of them maintained to term and delivered a healthy transgenic piglet expressing EGFP. Our data suggest that the combination of transduction of somatic cells by a replication defective vector with the nuclear transfer of colchicine-treated donors is an alternative to produce transgenic pigs. Furthermore, the tissues expressing EGFP from descendents of this pig may be very useful in future studies using pigs that require genetically marked cells.     

Transgenic oat plants via visual selection of cells expressing green fluorescent protein

 New selectable markers and selection systems are needed to increase the efficiency and flexibility of plant transformation. The objective of this research was to determine if the green fluorescent protein (gfp) gene could be utilized as a visual selectable marker for transformation of oat (Avena sativa L.). A modified gfp gene was delivered into oat cells by microprojectile bombardment. Cell clusters expressing gfp were visually identified using fluorescence microscopy and physically isolated at each subculture. Eleven independent transgenic cell lines were obtained, and fertile plants regenerated from all lines. Transgene integration and expression were confirmed in transgenic plants and progeny. Transgene expression segregated in a 3 : 1 ratio in progeny of the majority of the transgenic lines. Received: 11 May 1999 / Revision received: 31 August 1999 / Accepted: 2 September 1999     

Use of green fluorescent protein to monitor Lactobacillus sakei in fermented meat products

Lactobacillus sakei is a lactic acid bacterium naturally found on meat and often used as starter for the production of dry sausages or other fermented meat products. The gene encoding the green fluorescent protein (GFP) was cloned downstream from the constitutive L-lactate dehydrogenase promoter (pldhL) of L. sakei. The pldhL::gfp fusion was introduced in L. sakei either on a replicative plasmid or by double crossover integration into the chromosome, as a single copy. Both constructions were stable. Expression of GFP did not alter growth and was detectable by epifluorescence microscopy allowing the detection and monitoring of the development of GFP+ specific L. sakei strains both under growth laboratory conditions and in dry sausage samples.     

Optimization of the green fluorescent protein (GFP) expression from a lactose-inducible promoter in Lactobacillus casei

An expression vector for Lactobacillus casei has been constructed containing the inducible lac promoter and the gene encoding ultraviolet visible green fluorescent protein (GFP(UV)) as reporter. Different conditions to grow L. casei were assayed and fluorescence as well as total protein synthesized were quantified. The maintenance of neutral pH had the greatest incidence on GFP(UV) expression, followed by aeration and a temperature of 30 degrees C. Environmental factors favoring GFP(UV) accumulation did not exactly correlate with those enhancing fluorescence. Therefore, oxygenation, by stirring the culture, had the greatest influence on the proportion of fluorescent protein, which is in accordance with the structural requirements of this protein. The highest yield obtained was 1.3 microg of GFP per mg of total protein, from which 55% was fluorescent.     

The green fluorescent protein (GFP) as a vital screenable marker in rice transformation

 An engineered green fluorescent protein (GFP) from the jellyfish Aequora victoria was used to develop a facile and rapid rice transformation system using particle bombardment of immature embryos. The mgfp4 gene under the control of the 35s Cauliflower Mosaic Virus promoter produced bright-green fluorescence easily detectable and screenable in rice tissue 12–22 days after bombardment. Visual screening of transformed rice tissue, associated with a low level of antibiotic selection, drastically reduced the quantity of tissue to be handled and the time required for the recovery of transformed plants. GFP expression was observed in primary transformed rice plants (T₀) and their progeny (T₁). We describe various techniques to observe GFP in vitro and in vivo. The advantages of this new screenable marker in rice genetic engineering programmes are discussed. Received: 6 October 1997 / Accepted: 9 October 1997     

绿色荧光蛋白融合人核糖核酸酶抑制因子表达载体pEGFP-C1-hri的构建及鉴定

目的构建表达绿色荧光蛋白融合人核糖核酸酶抑制因子的表达载体pEGFP—C1—hri,为探讨人核糖核酸酶抑制因子抗肿瘤作用的分子机制打下基础。方法用亚克隆法,将目的片段从表达载体pGEX-6p-1-hri克隆到pEGFP-C1上,用双酶切筛选得到阳性重组质粒pEGFP—C1—hri,用脂质体法将其瞬时转染到小鼠黑色素瘤细胞B16中,在荧光显微镜下检测其表达。结果pEGFP—C1—hri中插入了hri序列,绿色荧光高效表达于B16细胞浆中。结论pEGFP—C1—hri表达载体已成功构建。     

Amino terminal interaction in the prion protein identified using fusion to green fluorescent protein

In contrast to the well-characterized carboxyl domain, the amino terminal half of the mature cellular prion protein has no defined structure. Here, following fusion of mouse prion protein fragments to green fluorescence protein as a reporter of protein stability, we report extreme variability in fluorescence level that is dependent on the prion fragment expressed. In particular, exposure of the extreme amino terminus in the context of a truncated prion protein molecule led to rapid degradation, whereas the loss of only six amino terminal residues rescued high level fluorescence. Study of the precise endpoints and residue identity associated with high fluorescence suggested a domain within the amino terminal half of the molecule defined by a long-range intramolecular interaction between 23KKRPKP28 and 143DWED146 and dependent upon the anti-parallel beta-sheet ending at residue 169 and normally associated with the structurally defined carboxyl terminal domain. This previously unreported interaction may be significant for understanding prion bioactivity and for structural studies aimed at the complete prion structure.     

Concentrating rotavirus and recombinant enhanced green fluorescent protein fromE. coli using a temperature-sensitive hydrogel

Recombinant enhanced green fluorescent protein (EGFP) fromE. coli was concentrated 1.9 times by ultrafiltration using a temperature-sensitive hydrogel. Protein recovery and separation efficiency were 64% and 45%, respectively. Increased concentration of recombinant EGFP was confirmed by SDS-PAGE. Rotavirus was concentrated 3.2 times by ultrafiltration using a temperature-sensitive hydrogel, at 95% of virus recovery and 93% of separation efficiency. Hydrogel ultrafiltration appears to be an attractive alternative for the concentration of rotavirus and recombinant proteins fromE. coli.     

Isolation of peroxisome-defective CHO mutant cells using green fluorescent protein

The authors constructed a recombinant green fluorescent protein (GFP) (PTS-GFP), which carries peroxisome targeting signal (PTS1 or PTS2) as an additional sequence, by polymerase chain reaction. The gene encoding for the recombinant GFP was constructed into an eukaryotic expression vector, and stable transformant of CHO cell expressing PTS-GFP was isolated, following the transfection of the plasmid encoding for the GFP. Each expressed PTS-GFP appeared to be localized in peroxisomes, because the GFP was observed in cellular structures, as was catalase. The observation proposed a visual screening procedure for isolating peroxisome-defective mutant. Following an enrichment of mutant cells by use of 9-(1′-pyrene)nonanol/ultraviolet irradiation (P9OH/UV) method, five peroxisome-defective mutants were isolated by pursuing the fluorescent signals from GFP. Two mutants (SK24 and SK32) were isolated from CHO cells expressing PTS1-GFP, and three mutants (PT13, PT32, and PT54) were isolated from cells expressing PTS2-GFP. Four mutants, except for PT13, showed cytosolic distributions of both PTS-GFP and catalase. On the other hand, mutant PT13 showed a cytosolic distribution on PTS2-GFP, but a peroxisomal distribution on catalase. Cell fusion analysis between SK24 mutant and other mutants indicated that PT54 mutant is in the same complementation group (CG) as SK24, but that SK32, PT13, and PT32 mutants are in different complementation group(s) from SK24.     

Androgen receptor transactivation assay using green fluorescent protein as a reporter

For screening of a large number of samples for androgenic activity, a robust system with minimal handling is required. The coding sequence for human androgen receptor (AR) was inserted into expression plasmid YEpBUbi-FLAG1, resulting in the plasmid YEpBUbiFLAG-AR, and the estrogen response element (ERE) on the reporter vector YRpE2 was replaced by an androgen response element (ARE), resulting in the plasmid YRpE2-ARE. Thus, a fully functional transactivation assay system with beta-galactosidase as a reporter gene could be created. Furthermore, green fluorescent protein (GFP) was introduced as an alternative reporter gene that resulted in a simplification of the whole assay procedure. For evaluation of both reporter systems, seven steroidal compounds with known AR agonistic properties (5 alpha-dihydrotestosterone, testosterone, androstenedione, 17 alpha-methyltestosterone, progesterone, epitestosterone, and d-norgestrel) were tested, and their potencies obtained in the different assays were compared. Furthermore, potencies from the transactivation assays were compared with IC(50) values obtained in radioligand binding assays. The newly developed androgen receptor transactivation assay is a useful tool for characterizing compounds with androgenic activity.     

Transient expression and stable transformation of soybean using the jellyfish green fluorescent protein

 Embryogenic soybean [Glycine max (L.) Merrill.] suspension cultures were bombarded with five different gene constructions encoding the jellyfish (Aequorea victoria) green fluorescent protein (GFP). These constructions had altered codon usage compared to the native GFP gene and mutations that increased the solubility of the protein and/or altered the native chromophore. All of the constructions produced green fluorescence in soybean cultures upon blue light excitation, although a soluble modified red-shifted GFP (smRS-GFP) was the easiest to detect based on the brightness and number of foci produced. Expression of smRS-GFP was visible as early as 1.5 h after bombardment, with peak expression at approximately 6.5 h. Large numbers of smRS-GFP-expressing areas were visible for 48 h postbombardment and declined rapidly thereafter. Stably transformed cultures and plants exhibited variation in the intensity and location of GFP expression. PCR and Southern hybridization analyses confirmed the presence of introduced GFP genes in stably transformed cultures. Received: 23 September 1998 / Revision received: 4 January 1999 / Accepted: 15 January 1999     

A novel reporter mouse strain that expresses enhanced green fluorescent protein upon Cre-mediated recombination

The success of Cre-mediated conditional gene targeting depends on the specificity of Cre recombinase expression in Cre-transgenic mouse lines. As a tool to evaluate the specificity of Cre expression, we developed a reporter transgenic mouse strain that expresses enhanced green fluorescent protein (EGFP) upon Cre-mediated recombination. We demonstrate that the progeny resulting from a cross between this reporter strain and a transgenic strain expressing Cre in zygotes show ubiquitous EGFP fluorescence. This reporter strain should be useful to monitor the Cre expression directed by various promoters in transgenic mice, including mice in which Cre is expressed transiently during embryogenesis under a developmentally regulated promoter.