Differential rates of gene expression monitored by green fluorescent protein

The use of green fluorescent protein (GFP) as a reporter gene has made a broad impact in several areas, especially in studies of protein trafficking, localization, and expression analysis. GFP's many advantages are that it is small, autocatalytic, and does not require fixation, cell disruption, or the addition of cofactors or substrates. Two characteristics of GFP, extreme stability and chromophore cyclization lag time, pose a hindrance to the application of GFP as a real-time gene expression reporter in bioprocess applications. In this report, we present analytical methods that overcome these problems and enable the temporal visualization of discrete gene regulatory events. The approach we present measures the rate of change in GFP fluorescence, which in turn reflects the rate of gene expression. We conducted fermentation and microplate experiments using a protein synthesis inhibitor to illustrate the feasibility of this system. Additional experiments using the classic gene regulation of the araBAD operon show the utility of GFP as a near real-time indicator of gene regulation. With repetitive induction and repression of the arabinose promoter, the differential rate of GFP fluorescence emission shows corresponding cyclical changes during the culture.     

绿色荧光蛋白及其在植物研究中的应用

绿色荧光蛋白(GFP)是海洋生物水母(Aequorea victoria)体内的一种发光蛋白,分子量27kD,由238个氨基酸组成。该蛋白65~67位Ser-Tyr-Gly三种氨基酸环化加氧形成特殊的生色团结构。野生型GFP发光较弱,而且gfp-cDNA含有隐蔽型剪切位点,而加工改造的GFP在植物中能够正常表达并且加强了荧光信号。GFP作为新的报告基因和遗传标记被广泛应用于植物研究之中。     

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 Integrative transformants in which one of the two ACT1 alleles had been replaced by a GFP gene exhibited a homogeneous, constitutive fluorescent phenotype.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     

Structural basis of fluorescence quenching in caspase activatable‐GFP

Apoptosis is critical for organismal homeostasis and a wide variety of diseases. Caspases are the ultimate executors of the apoptotic programmed cell death pathway. As caspases play such a central role in apoptosis, there is significant demand for technologies to monitor caspase function. We recently developed a caspase activatable‐GFP (CA‐GFP) reporter. CA‐GFP is unique due to its “dark” state, where chromophore maturation of the GFP is inhibited by the presence of a C‐terminal peptide. Here we show that chromophore maturation is prevented because CA‐GFP does not fold into the robust β‐barrel of GFP until the peptide has been cleaved by active caspase. Both CA‐GFP and GFP_1‐10, a split form of GFP lacking the 11th strand, have similar secondary structure, different from mature GFP. A similar susceptibility to proteolytic digestion indicates that this shared structure is not the robust, fully formed GFP β‐barrel. We have developed a model that suggests that as CA‐GFP is translated in vivo it follows the same folding path as wild‐type GFP; however, the presence of the appended peptide does not allow CA‐GFP to form the barrel of the fully matured GFP. CA‐GFP is therefore held in a “pro‐folding” intermediate state until the peptide is released, allowing it to continue folding into the mature barrel geometry. This new understanding of the structural basis of the dark state of the CA‐GFP reporter will enable manipulation of this mechanism in the development of reporter systems for any number of cellular processes involving proteases and potentially other enzymes.     

Construction of an engineered yeast with glucose-inducible emission of green fluorescence from the cell surface

An engineered yeast with emission of fluorescence from the cell surface was constructed. Cell surface engineering was applied to display a visible reporter molecule, green fluorescent protein (GFP). A glucose-inducible promoter GAPDH as a model promoter was selected to control the expression of the reporter gene in response to environmental changes. The GFP gene was fused with the gene encoding the C-terminal half of α-agglutinin of Saccharomyces cerevisiae having a glycosylphosphatidylinositol anchor attachment signal sequence. A secretion signal sequence of the fungal glucoamylase precursor protein was connected to the N-terminal of GFP. This designed gene was integrated into the TRP1 locus of the chromosome of S. cerevisiae with homologous recombination. Fluorescence microscopy demonstrated that the transformant cells emitted green fluorescence derived from functionally expressed GFP involved in the fusion molecule. The surface display of GFP was further verified by immunofluorescence labeling with a polyclonal antibody (raised in rabbits) against GFP as the first antibody and Rhodamine Red-X-conjugated goat anti-rabbit IgG as the second antibody which cannot penetrate into the cell membrane. The display of GFP on the cell surface was confirmed using a confocal laser scanning microscope and by measuring fluorescence in each cell fraction obtained after the subcellular fractionation. As GFP was proved to be displayed as an active form on the cell surface, selection of promoters will endow yeast cells with abilities to respond to changes in environmental conditions, including nutrient concentrations in the media, through the emission of fluorescence. Received: 23 August 1999 / Received revision: 16 November 1999 / Accepted: 29 November 1999     

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.     

Deletion mapping of the Aequorea victoria green fluorescent protein

Aequorea victoria green fluorescent protein (GFP) is a promising fluorescent marker which is active in a diverse array of prokaryotic and eukaryotic organisms. A key feature underlying the versatility of GFP is its capacity to undergo heterocyclic chromophore formation by cyclization of a tripeptide present in its primary sequence and thereby acquiring fluorescent activity in a variety of intracellular environments. In order to define further the primary structure requirements for chromophore formation and fluorescence in GFP, a series of N- and C-terminal GFP deletion variant expression vectors were created using the polymerase chain reaction. Scanning spectrofluorometric analyses of crude soluble protein extracts derived from eleven GFP expression constructs revealed that amino acid (aa) residues 2–232, of a total of 238 aa in the native protein, were required for the characteristic emission and absorption spectra of native GFP. Heterocyclic chromophore formation was assayed by comparing the absorption spectrum of GFP deletion variants over the 300–500-nm range to the absorption spectra of full-length GFP and GFP deletion variants missing the chromophore substrate domain from the primary sequence. GFP deletion variants lacking fluorescent activity showed no evidence of heterocyclic ring structure formation when the soluble extracts of their bacterial expression hosts were studied at pH 7.9. These observations suggest that the primary structure requirements for the fluorescent activity of GFP are relatively extensive and are compatible with the view that much of the primary structure serves an autocatalytic function.     

Dual color microscopic imagery of cells expressing the green fluorescent protein and a red-shifted variant

The green fluorescent protein (GFP) from the jellyfish, Aequorea victoria, has become a versatile reporter for monitoring gene expression and protein localization in a variety of cells and organisms. GFP emits bright green light (λ_max = 510 nm) when excited with ultraviolet (UV) or blue light (λ_max = 395 nm, minor peak at 470 nm). The chromophore in GFP is intrinsic to the primary structure of the protein, and fluorescence from GFP does not require additional gene products, substrates or other factors. GFP fluorescence is stable, species-independent and can be monitored noninvasively using the techniques of fluorescence microscopy and flow cytometry [Chalfie et al., Science 263 (1994) 802–805; Stearns, Curr. Biol. 5 (1995) 262–264]. The protein appears to undergo an autocatalytic reaction to create the fluorophore [Heim et al., Proc. Natl. Acad. Sci. USA 91 (1994) 12501–12504] in a process involving cyclization of a Tyr⁶⁶ aa residue. Recently [Delagrave et al., Bio/Technology 13 (1995) 151–154], a combinatorial mutagenic strategy was targeted at aa 64 through 69, which spans the chromophore of A. victoria GFP, yielding a number of different mutants with redshifted fluorescence excitation spectra. One of these, RSGFP4, retains the characteristic green emission spectra (λ_max = 505 nm), but has a single excitation peak (λ_max = 490 nm). The fluorescence properties of RSGFP4 are similar to those of another naturally occurring GFP from the sea pansy, Renilla reniformis [Ward and Cormier, Photobiochem. Photobiol. 27 (1978) 389–396]. In the present study, we demonstrate by fluorescence microscopy that selective excitation of A. victoria GFP and RSGFP4 allows for spectral separation of each fluorescent signal, and provides the means to image these signals independently in a mixed population of bacteria or mammalian cells.     

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.     

Synthesis and maturation of green fluorescent protein in a cell-free translation system

Summary A cell-free translation system producing mature green fluorescent protein (GFP) can be a useful tool for studying the mechanism and kinetics of GFP chromophore formation, as well as for fast protein engineering. We report here that the mature GFP can be formed in the cell-free translation system from E.coli. The synthesis of GFP in the cell-free system reaches a plateau in 30 to 40 min whereas its maturation is completed in 4 h from the beginning of translation. The delay between the GFP synthesis and the chromophore formation in the cell-free system provides the possibility to isolate and to analyse maturation intermediates for elucidation of the modification pathway.     

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.     

Can the fluorescence of green fluorescent protein chromophore be related directly to the nativity of protein structure?

In studies of green fluorescence protein (GFP) or other proteins with the use of GFP as a marker, the fluorescence of GFP is for the most part related directly to the nativity of its structure. Naturally, such a relation does exist since the chromophore of this protein is formed autocatalytically only just after GFP acquires its native structure. However, the fluorescence method may not yield reliable information on protein structure when studying renaturation and denaturation of this protein (with the formed chromophore). Using proteolysis, denaturant gradient gel electrophoresis and circular dichroism, we demonstrate herein that at major disturbances of the native structure of protein GFP-cycle3 the intensity of fluorescence of its chromophore can change insignificantly. In other words, the chromophore fluorescence does not reliably mirror alterations in protein structure. Since the main conclusions of this study are especially qualitative, it can be suggested that during renaturation/denaturation of wild-type GFP and its “multicolored” mutants their fluorescence is also not always associated with the changes in the structure of these proteins.     

Confocal quantification of cis-regulatory reporter gene expression in living sea urchin

Quantification of GFP reporter gene expression at single cell level in living sea urchin embryos can now be accomplished by a new method of confocal laser scanning microscopy (CLSM). Eggs injected with a tissue-specific GFP reporter DNA construct were grown to gastrula stage and their fluorescence recorded as a series of contiguous Z-section slices that spanned the entire embryo. To measure the depth-dependent signal decay seen in the successive slices of an image stack, the eggs were coinjected with a freely diffusible internal fluorescent standard, rhodamine dextran. The measured rhodamine fluorescence was used to generate a computational correction for the depth-dependent loss of GFP fluorescence per slice. The intensity of GFP fluorescence was converted to the number of GFP molecules using a conversion constant derived from CLSM imaging of eggs injected with a measured quantity of GFP protein. The outcome is a validated method for accurately counting GFP molecules in given cells in reporter gene transfer experiments, as we demonstrate by use of an expression construct expressed exclusively in skeletogenic cells.     

Facilitating chromophore formation of engineered Ca binding green fluorescent proteins

Green fluorescent protein (GFP) containing a self-coded chromophore has been applied in protein trafficking and folding, gene expression, and as sensors in living cells. While the “cycle3” mutation denoted as C3 mutation (F99S/M153T/V163A) offers the ability to increase GFP fluorescence at 37 °C, it is not clear whether such mutations will also be able to assist the folding and formation of the chromophore upon the addition of metal ion binding sites. Here, we investigate in both bacterial and mammalian systems, the effect of C2 (M153T/V163A) and C3 (F99S/M153T/V163A) mutations on the folding of enhanced GFP (EGFP, includes F64L/S65T) and its variants engineered with two types of Ca²⁺ binding sites: (1) a designed discontinuous Ca²⁺ binding site and (2) a grafted continuous Ca²⁺ binding motif. We show that, for the constructed EGFP variants, the C2 mutation is sufficient to facilitate the production of fluorescence in both bacterial and mammalian cells. Further addition of the mutation F99S decreases the folding efficiency of these variants although a similar effect is not detectable for EGFP, likely due to the already greatly enhanced mutation F64L/S65T from the original GFP, which hastens the chromophore formation. The extinction coefficient and quantum yield of purified proteins of each construct were also examined to compare the effects of both C2 and C3 mutations on protein spectroscopic properties. Our quantitative analyses of the effect of C2 and C3 mutations on the folding and formation of GFP chromophore that undergoes different folding trajectories in bacterial versus mammalian cells provide insights into the development of fluorescent protein-based analytical sensors.     

A rapid reporter system using GFP as a reporter protein for identification and screening of synthetic stationary-phase promoters in Escherichia coli

To develop a rapid reporter system for the screening of stationary-phase promoters in Escherichia coli, the expression pattern of the green fluorescent protein (GFP) during bacterial cultivation was compared with that of the commonly used β-galactosidase. Using GFP with enhanced fluorescence, the expression pattern of both reporter systems GFP and β-galactosidase were similar and showed a typical induction of gene activity of the reporter genes, i.e. increase of expression at the transition from exponential to stationary phase. The expression was affected by the culture medium, i.e. in contrast to the complex medium (LB medium), the stationary-phase specific induction was only observed in synthetic medium (M9) when amino acids were added, whereas there was generally no induction in MOPS medium. To develop a rapid screening method on agar plates for stationary-phase promoters, a photographic approach was used, continued with computational image treatment. A screening method is presented which enables an on-line monitoring of gene activity.     

Choosing a reporter for gene expression studies in transgenic actinorhizal plants of the Casuarinaceae family

Transgenic Casuarinaceae and reporter genes provide valuable tools to study gene expression in transgenic actinorhizal nodules. In this paper, we discuss the use of ß-glucuronidase for the histochemical localization and quantification of gene expression in transgenic plants of Allocasuarina verticillata and Casuarina glauca nodulated by the actinomycete Frankia. We also report on the genetic transformation of A. verticillata by the Agrobacterium tumefaciens strain C58C1(pGV2260) containing the 35S-mgfp5-ER construct encoding a modified green fluorescent protein of Aequorea victoria in a binary vector. The evolution of the GFP fluorescence was monitored through all stages of the regeneration process. The data indicate that GFP is not toxic in Casuarinaceae and that this reporter gene can be used for visual screening of transformed calli and transgenic plants. The fluorescence pattern of gfp provides a new tool for monitoring in vivo transgene expression in actinorhizal plants.     

Use of the green fluorescent protein variant (YFP) to monitor MetArg human proinsulin production in Escherichia coli.

Green fluorescent protein (GFP), a relatively new reporter gene, is making an impact on many aspects of science. The attributes of GFP could also be applied to the area of recombinant protein production. The work described here represents the first experiments using GFP as a tool to monitor recombinant protein production in real time in the fermentation process. We have constructed plasmids containing an operon fusion of the gene encoding MetArg-human proinsulin and reporter gene GFP (GFP, BFP, and YFP variants). The MetArg-proinsulin and GFP variant reporter protein were overexpressed in Escherichia coli BL21(DE3) after isopropyl beta-d-thiogalactoside induction. The MetArg-proinsulin to YFP protein ratio did not change in the cells during the bioprocess. Since there is a quantitative relationship between the level of MetArg-proinsulin concentration and YFP fluorescence, it is possible to measure only YFP fluorescence in order to monitor the production of MetArg-proinsulin during the bioprocess. The expression level of MetArg-proinsulin could reach 20-25%. Some 140 mg recombinant MetArg-human proinsulin could be obtained easily from 1 liter of fermentation medium. The MetArg-proinsulin could simply be changed into human insulin by trypsin and carboxypeptidase B treatment in later steps. These experiments provide possibilities for using the YFP reporter gene as a convenient tool to monitor protein expression in biotechnological processes. The proposed technique could reduce the time- and labor-intensive analysis of protein production and would improve the efficiency of process development.     

Characterization of Promoter Activities of Four Different Japanese Flounder Promoters in Transgenic Zebrafish

An important consideration in transgenic research is the choice of promoter for regulating the expression of a foreign gene. In this study several tissue-specific and inducible promoters derived from Japanese flounder Paralichthys olivaceus were identified, and their promoter activity was examined in transgenic zebrafish. The 5′ flanking regions of the Japanese flounder complement component C3, gelatinase B, keratin, and tumor necrosis factor (TNF) genes were linked to green fluorescence protein (GFP) as a reporter gene. The promoter regulatory constructs were introduced into fertilized zebrafish eggs. As a result we obtained several stable transgenic zebrafish that displayed green fluorescence in different tissues. Complement component C3 promoter regulated GFP expression in liver, and gelatinase B promoter regulated it in the pectoral fin and gills. Keratin promoter regulated GFP expression in skin and liver. TNF gene promoter regulated GFP expression in the pharynx and heart. TNF promoter had lipoplysaccharide-inducible activity, such that when transgenic embryos were immersed lipopolysaccharide, GFP expression increased in the epithelial tissues. These 4 promoters regulated the expression of GFP in different patterns in transgenic zebrafish.     

Green fluorescent protein as an all-purpose reporter in Petunia

Two critical attributes of a reporter gene are ease of scoring for activity and capacity for expression in all cell types. We have examined a variant of the gene encoding green fluorescent protein,mgfp5, for its ability to meet these criteria in petunia. Under regulation of the Cauliflower Mosaic Virus (CaMV) 35S promoter, GFP was detectable in all vegetative and most floral cell types. Promoters from petuniaadhl andadh2 allowed for production of GFP in those few cell types lacking GFP production from the CaMV 35S promoter, verifying its capacity for expression in all cell types. With the appropriate promoter, GFP fluorescence was thus readily detectable throughout the plant. A potential complication is the green autofluorescence exhibited by some plant tissues. This auto-fluorescence is for the most part distinguishable from that contributed by GFP, but under-scores the need for appropriate controls in GFP-reporter-based experiments. An erratum to this article is available at .     

Transient expression of green fluorescent protein in various plastid types following microprojectile bombardment

The green fluorescent protein gene ( gfp ) is a widely used reporter in both animals and plants. Fusions between the plastid rrn promoter or the Escherichia coli trc promoter and the gfp coding region have been delivered to chloroplasts using gold or tungsten microprojectiles, and fluorescence from GFP was visible in individual tobacco chloroplasts and in the abnormally large chloroplasts of the arc 6 mutant of Arabidopsis thaliana 2–4 days after bombardment. The fusion of the gfp coding region to the bacterial trc promoter demonstrated that a bacterial promoter is active in chloroplasts in vivo . GFP was also detectable in amyloplasts of potato tubers and in chromoplasts of marigold petals, carrot roots and pepper fruits 4 days after bombardment. This demonstrates that GFP can be used as a reporter for transient gene expression in chloroplasts and in non-photosynthetic plastids in a range of higher plants.