Reporter system for the detection of in vivo gene conversion

We have devised a system for the study of in vivo gene correction based on the detection of color variants of the green fluorescent protein (GFP) from the jellyfish Aequorea victoria. The intensity and spectra of the fluorescence emitted by the blue (BFP) and red-shifted (EGFP) variants of GFP differ from each other. We modified one nucleotide from an EGFP expression vector that we predicted would yield a blue variant (TAC-CAC, Tyr⁶⁶-His⁶⁶). Cells that were either transiently or stably transfected with the reporter system were used to test the functionality and feasibility of the detection of in vivo gene correction. A thio-protected single-stranded oligonucleotide designed to convert the genotype of the blue variant to that of the EGFP variant by the correction of a single base pair was delivered to the reported cells using a variety of methodologies and strategies. Conversion events were easily observed using fluorescent microscopy because of the enhanced emission intensity and different spectra of the EGFP variant.     

Red fluorescent protein DsRed from Discosoma sp. as a reporter protein in higher plants

GFP from Aequorea victoria is a standard genetic marker widely used to visualize cellular events in a noninvasive manner. For simultaneous imaging of different processes, in vivo mutants of GFP with shifted wavelength spectra (e.g., blue fluorescent protein) are conventionally used. The recently reported red fluorescent protein from Discosoma sp., DsRed, represents a new marker that can be used together with GFP variants for multicolor imaging. DsRed is an interesting marker protein for use in plants because of its red-shifted wavelength spectrum that will avoid damaging cells and tissues by excitation light. In this report, we show that DsRed is an excellent marker in higher plants in spite of the interfering red autofluorescence of chlorophyll, which can be eliminated by using the appropriate filter sets. Transient expression of DsRed1-C1 and a soluble-modified, red-shifted GFP variant has been carried out both individually and jointly in the epidermal cells of three different Nicotiana species and Chenopodium quinoa, which gives rise to dual labeling in plants. For this purpose, a human codon-optimized variant of DsRed has been adopted for expression in plants. Moreover, the DsRed reporter gene was expressed by using a labeled plant viral vector derived from an infectious full-length clone of potato virus X.     

Green Fluorescent Protein As a Cell-Labeling Tool and a Reporter of Gene Expression in Transgenic Rainbow Trout

Green fluorescent protein (GFP) has been used as an indicator of transgene expression in living cells and organisms. For testing the utility of GFP in rainbow trout, we microinjected fertilized eggs with four types of supercoiled constructs containing two variants of GFP complementary DNA (S65T and EGFP), driven by two ubiquitous regulatory elements, human cytomegalovirus immediate early enhancer-promoter (CMV) and Xenopus laevis elongation factor 1α enhancer-promoter (EF1). Green fluorescence was first observed at 3 days postfertilization, when the embryo was in the mid-blastula stage. Fluorescence could be detected mosaically in various types of embryonic cells and tissues of swim-up fry. Both the percentage of fluorescent cells and the fluorescence intensity of GFP-expressing cells on blastoderms, measured with a microscopic photometry system, were highest in CMV-EGFP-microinjected embryos. We conclude that GFP is capable of producing detectable fluorescence in rainbow trout, and can be a powerful tool as a cell marker and reporter gene for cold-water fish, and that analysis of GFP expression in living cells is useful for characterizing the activity of cis-elements in vivo. Received December 21, 1998; accepted March 31, 1999.     

The color of mice: in the light of GFP-variant reporters

The mouse currently represents the premier model organism for mammalian genetic studies. Over the past decade the production of targeted and transgenic lines of mice has become commonplace, with current technology allowing the creation of mutations at base pair resolution. Such genome modifications are becoming increasingly elaborate and often incorporate gene-based reporters for tagging different cellular populations. Until recently, lacZ, the bacterial beta-galactosidase gene has been the marker of choice for most studies in the mouse. However, over the past 3 years another valuable reporter has emerged, and its attractiveness is reflected by an explosion in its use in mice. Green fluorescent protein (GFP), a novel autofluorescent genetic reporter derived from the bioluminescent jellyfish Aequorea victoria, currently represents a unique alternative to other gene-based reporters in that its visualization is non-invasive and so can be monitored in real-time in vitro or in vivo. It has the added advantage that it can be quantified by, for example, flow cytometry, confocal microscopy, and fluorometric assays. Several mutants of the original wild-type GFP gene that improve thermostability and fluorescence have been engineered. Enhanced GFP is one such variant, which has gained popularity for use in transgenic or targeted mice. Moreover, various GFP spectral variants have also been developed, and two of these novel color variants, enhanced yellow fluorescent protein (EYFP) and enhanced cyan fluorescent protein (ECFP), can also be used in mice. Since the spectral profiles of the ECFP and EYFP color variants are distinct and non-overlapping, these two reporters can be co-visualized, and are therefore ideal for in vivo double-labeling or fluorescent energy transfer analyses. The use of GFP and its color variants as reporters provides an unprecedented level of sophistication and represents the next step in mouse genome engineering technology by opening up the possibility of combinatorial non-invasive reporter usage within a single animal.     

Dynamic characterization of recombinant Chinese hamster ovary cells containing an inducible c-fos promoter GFP expression system as a biomarker.

An inducible reporter gene system for Chinese Hamster Ovary (CHO-DHFR(-)) cells has been developed and characterized with respect to its dynamic properties. The reporter gene system consists of the human c-fos promoter and variants of the green fluorescence protein (GFP), either EGFP with enhanced fluorescence or its destabilized form d2EGFP. The expression of wild-type EGFP or its destabilized form was studied in CHO-DHFR(-) cells in response to serum addition or deprivation. It was shown that serum-induced c-fos promoter mediated EGFP expression was considerably higher than expression from the human CMV promoter, a strong, constitutive promoter preferentially used for high-level expression in CHO cells. However, EGFP was less suitable for studying expression dynamics than d2EGFP due to the protein's long half-life in mammalian cells. The use of d2EGFP resulted in a significant improvement in the dynamic characteristics of the biomarker, particularly when the recombinant cells were selected for high-level GFP expression by subcloning or fluorescence activated cell/sorting (FACS). GFP expression in different subclones and cell populations sorted by FACS was characterized with respect to its dynamic responses in the presence or absence of serum in the culture medium. Significant differences in the GFP expression dynamics were observed for the isolated cell populations. The experimental results indicate that cells with high-level GFP expression also have a faster dynamic response and are thus, desirable for practical application of the reporter gene system e.g. in toxicity monitoring.     

Simultaneous flow cytometric analyses of enhanced green and yellow fluorescent proteins and cell surface antigens in doubly transduced immature hematopoietic cell populations

BACKGROUND: Cell transduction with multiple genes offers opportunities to investigate specific gene interactions on cell function. Detection of multiple transduced genes in hematopoietic cells requires strategies to combine measurements of gene expression with phenotypic cell discriminants. We describe simultaneous flow cytometric detection of two green fluorescent protein (GFP) variants in immunophenotypically defined human hematopoietic subpopulations using only a minor physical adjustment to a standard FACSCalibur. METHODS: The accuracy and sensitivity of enhanced GFP (EGFP) and enhanced yellow fluorescent protein (EYFP) detection in mixtures of transduced and nontransduced PG13 packaging cells were evaluated by flow cytometry. Retroviral vectors encoding EGFP or EYFP were used to transduce CD34(+) hematopoietic cells derived from umbilical cord blood. The transduction efficiency into subpopulations of hematopoietic cells was measured using multivariate flow cytometry. RESULTS: A bicistronic retroviral vector containing the EGFP and puromycin N-acetyltransferase (pac) genes afforded brighter EGFP signals in transduced cells than a retroviral vector encoding a pac-EGFP fusion protein. The sensitivity of detecting EGFP and EYFP-expressing cells among a background of nonexpressing cells was 0.01% and 0.05%, respectively. EGFP or EYFP was expressed in up to 95% of CD34(+) DR(-) or CD34(+) 38(-) subpopulations in cord blood 48 h posttransduction. Simultaneous transduction with EGFP and EYFP viral supernatants (1:1 mixture) led to coexpression of both GFP variants in 15% of CD34(+) DR(-) and 20% of CD34(+) 38(-) cells. CONCLUSIONS: These results demonstrate simultaneous detection of EGFP and EYFP in immunophenotypically discriminated human hematopoietic cells. This technique will be useful to quantify transduction of multiple retroviral constructs in discriminated subpopulations.     

In vivo tracking of Campylobacter jejuni by using a novel recombinant expressing green fluorescent protein

Campylobacter jejuni is a leading cause of food-borne disease in developed countries. The goal of this study was to develop a plasmid-based reporter system with green fluorescent protein (GFP) to facilitate the study of C. jejuni in a variety of niches. C. jejuni transformants harboring the pMEK91 GFP gene (gfp)-containing vector were readily detectable by both fluorescence microscopy and flow cytometry. Given the ease of detecting these organisms, additional experiments were performed in which BALB/c mice were injected intraperitoneally with C. jejuni harboring the gfp-containing vector. Four hours after injection of the mice, flow cytometry analyses determined that C. jejuni synthesizing GFP were predominantly associated with granulocytes. More specifically, the proportion of CD11b(+) Gr-1(+) lavage neutrophils with green fluorescence ranged from 99.7 to 100%, while the proportion of CD11b(+) Gr-1(-) lavage macrophages ranged from 77.0 to 80.0%. In contrast, few CD11b(-) CD45R(+) B lymphocytes from the lavage of the C. jejuni-injected mice were associated with green-fluorescent C. jejuni (proportions ranged from 0.75 to 0.77%). Cell-free C. jejuni was recovered from tissue homogenates after intraperitoneal injection. Macrorestriction profiling with pulsed-field gel electrophoresis identified a genotypic variant of the C. jejuni F38011 wild-type isolate. In vivo this variant displayed a phenotype identical to that of the wild-type isolate. In summary, we demonstrate that C. jejuni associates with marker-defined cellular subsets in vivo with a novel gfp reporter system and that C. jejuni genotypic variants can be isolated from both in vitro and in vivo systems.     

Development of combinatorial bioengineering using yeast cell surface display--order-made design of cell and protein for bio-monitoring

A genetic system to display proteins as their active and functional forms on the cell surface of yeast, Saccharomyces cerevisiae, has been exploited. Surface-engineered (arming) cells displaying amylase or cellulase could assimilate starch or cellulose as the sole carbon source, although S. cerevisiae can not intrinsically assimilate them. Arming cells with a green fluorescent protein (GFP) from Aequorea victoria can emit green fluorescence from the cell surface in response to the environmental conditions. From these results, we attempted to construct a system to monitor the foreign protein production in yeast by simultaneous displaying the enhanced GFP (EGFP). The expression in yeast of the Escherichia coli beta-galactosidase-encoding gene was examined as an example of intracellular production and that of the human interferon-alpha (omega, IFN-omega)-encoding gene as an example of extracellular production. Their productions and the simultaneous surface-display of EGFP as a reporter were controlled by the same promoter, GAL1. The relationship among fluorescence signals and their productions was evaluated. The surface-display system, unlike one using tag-proteins, would be able to facilitate the monitoring of native protein productions in bioprocesses using living cells in real time by the combination of promoters and GFP variants.     

Quantitative analysis of gene expression with an improved green fluorescent protein. p6.

The fast and easy in vivo detection predestines the green fluorescent protein (GFP) for its use as a reporter to quantify promoter activities. We have increased the sensitivity of GFP detection 320-fold compared to the wild-type by constructing gfp+, which contains mutations improving the folding efficiency and the fluorescence yield of GFP+. Twelve expression levels were measured using fusions of the gfp+ and lacZ genes with the tetA promoter in Escherichia coli. The agreement of GFP+ fluorescence with beta-galactosidase activities was excellent, demonstrating that the gfp+ gene can be used to accurately quantify gene expression in vivo. However, expression of the gfp+ gene from the stronger hsp60 promoter revealed that high cellular concentrations of GFP+ caused an inner filter effect reducing the fluorescence by 50%, thus underestimating promoter activity. This effect is probably due to the higher absorbance of cells containing GFP+. Thus promoters with activities differing by about two orders of magnitude can be correctly quantified using the gfp+ gene. Possibilities of using GFP variants beyond this range are discussed.     

Use of green fluorescent protein as A non-destructive marker for peanut genetic transformation

Summary The ability to non-destructively visualize transient and stable gene expression has made green fluorescent protein (GFP) a most efficient reporter gene for routine plant transformation studies. We have assessed two fluorescent protein mutants, enhanced GFP (EGFP) and enhanced yellow fluorescent protein (EYFP), under the control of the CaMV35S promoter, for their transient expression efficiencies after particle bombardment of embryogenic cultures of the peanut cultivar, Georgia Green. A third construct (p524EGFP.1) that expressed EGFP from a double 35S promoter with an AMV enhancer sequence also was compared. The brightest and most dense fluorescent signals observed during transient expression were from p524EGFP. 1 and EYFP. Optimized bombardment conditions consisted of 0.6 μm diameter gold particles, 12410 kPa bombardment pressure, 95 kPa vacuum pressure, and pretreatment with 0.4 M mannitol. Bombardments with p524EGFP.1 produced tissue sectors expressing GFP that could be visually selected under the fluorescence microscope over multiple subcultures. Embryogenic lines selected for GFP expression initially may have been chimeric since quantitative analysis of expression sometimes showed an increase when GFP-expressing lines, that also contained a hygromycin-resistance gene, subsequently were cultured on hygromycin. Transformed peanut plants expressing GFP were obtained from lines selected either visually or on hygromycin. Integration of the gfp gene in the genomic DNA of regenerated plants was confirmed by Southern blot hybridization and transmission to progeny.     

Polyubiquitin-regulated DsRed marker for transgenic insects.

Genetic transformation of most insect systems requires dominant-acting markers that do not depend on reverting a mutant phenotype in a host strain, andfor this purpose GFP has proven to be useful in several insect orders. However, detection of multiple transgenes and reporters for gene expression requires the development of new visible markers that can be unambiguously detected when co-expressed with GFP The DsRed fluorescentprotein has spectral characteristics that are most distinct from GFP and GFP variants, and we have explored the use of DsRed as a selectable marker for piggyBac transformation in Drosophila melanogaster and its use as a reporter when co-expressed with GFP. Transformants marked with polyubiquitin-regulated DsRed1 were detected throughout development at a relatively high frequency, and they exhibited brighter fluorescence than transformants marked with EGFP. The use of a Texas Red filter set eliminated detection of EGFP fluorescence and autofluorescence, and DsRed expressedfrom a reporter construct could be unambiguously detected when co-expressed with EGFP DsRed should prove to be a highly efficient marker system for the selection of transformant insects and as a reporter in gene expression studies.     

The dynamic microbe: green fluorescent protein brings bacteria to light

The demonstration that the green fluorescent protein (GFP) from the jellyfish Aequorea victoria required no jellyfish-specific cofactors and could be expressed as a fluorescent protein in heterologous hosts including both prokaryotes and eukaryotes sparked the development of GFP as one of the most common reporters in use today. Over the past several years, the utility of GFP as a reporter has been optimized through the isolation and engineering of variants with increased folding rates, different in vivo stabilities and colour variants with altered excitation and emission spectral properties. One of the great utilities of GFP is as a probe for characterizing spatial and temporal dynamics of gene expression, protein localization and protein-protein interactions in living cells. The innovative application of GFP as a reporter in bacteria has made a significant contribution to microbial cell biology. This review will highlight recent studies that demonstrate the potential of GFP for real-time analysis of gene expression, protein localization and the dynamics of signalling transduction pathways through protein-protein interactions.     

A photostable monomeric superfolder green fluorescent protein

The green fluorescent protein (GFP) from Aequorea victoria has been engineered extensively in the past to generate variants suitable for protein tagging. Early efforts produced the enhanced variant EGFP and its monomeric derivative mEGFP, which have useful photophysical properties, as well as superfolder GFP, which folds efficiently under adverse conditions. We previously generated msGFP, a monomeric superfolder derivative of EGFP. Unfortunately, compared to EGFP, msGFP and other superfolder GFP variants show faster photobleaching. We now describe msGFP2, which retains monomeric superfolder properties while being as photostable as EGFP. msGFP2 contains modified N‐ and C‐terminal peptides that are expected to reduce nonspecific interactions. Compared to EGFP and mEGFP, msGFP2 is less prone to disturbing the functions of certain partner proteins. For general‐purpose protein tagging, msGFP2 may be the best available derivative of A. victoria GFP.     

Creation of cell surface-engineered yeast that display different fluorescent proteins in response to the glucose concentration

We have successfully created a novel yeast strain able to monitor changes in environmental conditions by displaying either green fluorescent protein (GFP) from Aequorea victoria or blue fluorescent protein (BFP), a variant of GFP, on its cell surface as a visible reporter. For the display of these fluorescent proteins on the cell surface of Saccharomyces cerevisiase, our cell-surface-engineering system was utilized. The GAPDH promoter, which is active in the presence of glucose, and the UPR-ICL promoter from Candida tropicalis, which starts to function in the presence of a reduced level of glucose, were employed simultaneously to express the GFP-encoding gene and the BFP-encoding gene, respectively. This cell-surface-engineered yeast strain emitted green fluorescence from the cell surface when sufficient glucose was present in the medium, and blue fluorescence from the same cell surface when the glucose in the medium was consumed. The fluorescent proteins displayed on the cell surface using the different promoters enabled us to monitor the concentrations of intra- and/or extracellular glucose that regulated activation or inactivation of the promoters. This novel yeast strain could facilitate the computerized control of various bioprocesses measuring emitted fluorescence.     

Measurement of green fluorescent protein concentration in single cells by image analysis

The gene encoding the green fluorescent protein (GFP) has been widely used in studies of gene expression. The GFP can be detected nondestructively in living cells or tissues by the green fluorescence of the protein under blue light. Solutions of enhanced GFP (EGFP) of known concentration were filled in glass capillaries and used to calibrate a method for quantitative determination of EGFP or GFP-S65T in plant cells. Images captured by a digital camera were analyzed to determine the linear range for measurement of EGFP expression. The value of the method was illustrated by analysis of the relative levels of GFP expression under control of different promoters in aleurone cells of barley.     

Green fluorescent protein causes mitochondria to aggregate in the presence of the Bcl-2 family proteins

Green fluorescent protein (GFP) has been widely used in a variety of experiments in cell biology. When cells were co-transfected with the GFP gene and the bcl-2 family genes bcl-2, bcl-x(L), and bax, mitochondria appeared to aggregate at the periphery of the nucleus specifically where GFP was expressed. Little aggregation was seen in the presence of other members of the GFP family, EGFP (enhanced GFP), ECFP (enhanced cyan variant), and EYFP (enhanced yellow-green variant). GFP but not EGFP seemed to promote cell death induced by pro-apoptotic Bax. Thus, GFP specifically promotes the aggregation of mitochondria when co-expressed with a member of the Bcl-2 family in association with apoptosis.     

Exploration of new chromophore structures leads to the identification of improved blue fluorescent proteins

The variant of Aequorea green fluorescent protein (GFP) known as blue fluorescent protein (BFP) was originally engineered by substituting histidine for tyrosine in the chromophore precursor sequence. Herein we report improved versions of BFP along with a variety of engineered fluorescent protein variants with novel and distinct chromophore structures that all share the property of a blue fluorescent hue. The two most intriguing of the new variants are a version of GFP in which the chromophore does not undergo excited-state proton transfer and a version of mCherry with a phenylalanine-derived chromophore. All of the new blue fluorescing proteins have been critically assessed for their utility in live cell fluorescent imaging. These new variants should greatly facilitate multicolor fluorescent imaging by legitimizing blue fluorescing proteins as practical and robust members of the fluorescent protein "toolkit".     

Fluorescence resonance energy transfer between blue-emitting and red-shifted excitation derivatives of the green fluorescent protein

We report fluorescent resonance energy transfer (FRET) between two linked variants of the green fluorescent protein (GFP). The C terminus of a red-shifted variant of GFP (RSGFP4) is fused to a flexible polypeptide linker containing a Factor X_a protease cleavage site. The C terminus of this linker is in turn fused to the N terminus of a blue variant of GFP (BFP5). The gene product has spectral properties that suggest energy transfer is occurring from BFP5 to RSGFP4. Upon incubation with Factor X_a, the protein is cleaved, and the two fluorescent proteins dissociate. This is accompanied by a marked decrease in energy transfer. The RSGFP4::BFP5 fusion protein demonstrates the feasibility of using FRET between two GFP derivatives as a tool to monitor protein-protein interactions; in addition, this construct may find applications as an intracellular screen for protease inhibitors.     

Balancing GFP reporter plasmid quantity in large-scale transient transfections for recombinant anti-human Rhesus-D IgG1 synthesis

Using transient expression, high amounts (>20 mg/mL) of secreted anti-human Rhesus-D IgG1 were produced in a suspension-adapted HEK293 EBNA cell line (Meissner et al., Biotechnol Bioeng 75: 197-203, 2001). Time of harvest was 3 days after transfection. For the estimation of transfection efficiencies, we routinely co-transfected EGFP reporter DNA. At higher reporter plasmid concentrations, >2% of total transfecting plasmid DNA, a substantial reduction of recombinant antibody synthesis, was observed. This phenomenon was investigated in detail by co-expressing various green fluorescent protein (GFP) reporter constructs, which were targeted at different subcellular locations. Enhanced and humanized GFPs targeted to either the endoplasmic reticulum, the cytosol, or the nucleus reduced recombinant antibody production by 30 to 40% when present at higher concentrations in the transfection solution. The most severe effects were observed when the co-transfected EGFP was targeted to the endoplasmic reticulum, leading to a reduction of up to 80% in the presence of only 5% of reporter DNA. Interestingly, one nuclear-targeted GFP variant that was not codon optimized for expression in human cell lines could be added, to up to almost half of the total amount of transfecting DNA, without adverse effect on antibody production. Although the minimum amount of this reporter DNA needed for fluorescence reading was 10 times higher than for the other variants, it provided a much broader quantity range within which the transfection process could be studied without being negatively affected.