Green fluorescent protein functions as a reporter for protein localization in Escherichia coli

The use of green fluorescent protein (GFP) as a reporter for protein localization in Escherichia coli was explored by creating gene fusions between malE (encoding maltose-binding protein [MBP]) and a variant of gfp optimized for fluorescence in bacteria (GFPuv). These constructs encode hybrid proteins composed of GFP fused to the carboxy-terminal end of MBP. Fluorescence was not detected when the hybrid protein was synthesized with the MBP signal sequence. In contrast, when the MBP signal sequence was deleted, fluorescence was observed. Cell fractionation studies showed that the fluorescent MBP-GFP hybrid protein was localized in the cytoplasm, whereas the nonfluorescent version was localized to the periplasmic space. Smaller MBP-GFP hybrid proteins, however, exhibited abnormal fractionation. Expression of the gene fusions in different sec mutants, as well as signal sequence processing assays, confirmed that the periplasmically localized hybrid proteins were exported by the sec-dependent pathway. The distinction between fluorescent and nonfluorescent colonies was exploited as a scorable phenotype to isolate malE signal sequence mutations. While expression of hybrid proteins comprised of full-length MBP did not result in overproduction lethality characteristic of some exported beta-galactosidase hybrid proteins, synthesis of shorter, exported hybrid proteins was toxic to the cells. Purification of MBP-GFP hybrid protein from the different cellular compartments indicated that GFP is improperly folded when localized outside of the cytoplasm. These results suggest that GFP could serve as a useful reporter for genetic analysis of bacterial protein export and of protein folding.     

Green fluorescent protein as a reporter for macromolecular localization in bacterial cells

Green fluorescent protein (GFP) is a highly useful fluorescent tag for studying the localization, structure, and dynamics of macromolecules in living cells, and has quickly become a primary tool for analysis of DNA and protein localization in prokaryotes. Several properties of GFP make it an attractive and versatile reporter. It is fluorescent and soluble in a wide variety of species, can be monitored noninvasively by external illumination, and needs no external substrates. Localization of GFP fusion proteins can be analyzed in live bacteria, therefore eliminating potential fixation artifacts and enabling real-time monitoring of dynamics in situ. Such real-time studies have been facilitated by brighter, more soluble GFP variants. In addition, red-shifted GFPs that can be excited by blue light have lessened the problem of UV-induced toxicity and photobleaching. The self-contained domain structure of GFP reduces the chance of major perturbations to GFP fluorescence by fused proteins and, conversely, to the activities of the proteins to which it is fused. As a result, many proteins fused to GFP retain their activities. The stability of GFP also allows detection of its fluorescence in vitro during protein purification and in cells fixed for indirect immunofluorescence and other staining protocols. Finally, the different properties of GFP variants have given rise to several technological innovations in the study of cellular physiology that should prove useful for studies in live bacteria. These include fluorescence resonance energy transfer (FRET) for studying protein-protein interactions and specially engineered GFP constructs for direct determination of cellular ion fluxes.     

Green fluorescent protein as a marker in transgenic mice

Green fluorescent protein (GFP) found in Aequorea victoria absorbs blue light and emits green fluorescence without exogenous substrates or co-factors. We studied the possibility of using the GFP as a marker in mammals. Transgenic mice were produced using the GFP coding sequence, ligated with the chicken beta-actin promoter. Green fluorescence was observed in muscle, pancreas, kidney, heart and other organs in all the three transgenic mouse lines. Detection of the transgenic mouse was possible by observing a tail or fingers of new born pups under a fluorescent microscope. The marker also enabled us to detect localized expression of the transgene in intact tissues without preliminary steps. It was also demonstrated that the GFP expression could be quantified by measuring the fluorescence in tissue extracts.     

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 .     

Green fluorescent protein (GFP) as a reporter gene for the plant pathogenic oomycete Phytophthora palmivora

Transgenic Phytophthora palmivora strains that produce green fluorescent protein (GFP) or beta-glucuronidase (GUS) constitutively were obtained after stable DNA integration using a polyethylene-glycol and CaCl2-based transformation protocol. GFP and GUS production were monitored during several stages of the life cycle of P. palmivora to evaluate their use in molecular and physiological studies. 40% of the GFP transformants produced the GFP to a level detectable by a confocal laser scanning microscope, whereas 75% of the GUS transformants produced GUS. GFP could be visualised readily in swimming zoospores and other developmental stages of P. palmivora cells. For high magnification microscopic studies, GFP is better visualised and was superior to GUS. In contrast, for macroscopic examination, GUS was superior. Our findings indicate that both GFP and GUS can be used successfully as reporter genes in P. palmivora.     

Green fluorescent protein: an in vivo reporter of plant gene expression

Summary Protoplasts were isolated from H89, an embryogenic sweet orange (Citrus sinensis (L.) Osbeck cv. Hamlin) suspension culture, and electroporated with p35S-GFP, a plasmid carrying the gene for the green fluorescent protein (GFP) from the bioluminescent jellyfish Aequorea victoria. p35S-GFP was constructed by replacing the GUS coding sequence of pBI221 with a functional GFP gene, thereby placing the GFP gene under the control of the CaMV 35S promoter. Protoplasts were viewed by incident-light fluorescence microscopy twentyfour h after electroporation. 20–60% of the protoplasts emitted an intense green light when illuminated with blue (450–490 nm) light.Abbreviations GUS -glucuronidase - LUC luciferase - NPTII neomycinphosphotransferase - CaMV cauliflower mosaic virus - MUG 4-methylumbelliferyl -D-glucuronide     

Green fluorescent protein as a reporter system in the transformation of barley cultivars

A cereal transformation vector, pN1473, containing the strong constitutive rice actin promoter Act-1 , a multiple cloning site, and the nos terminator, was constructed. Fusion of a plant-optimized gfp gene to Act-1 in pN1473 resulted in the vector pN1473GFP. To assess the suitability of pN1473, and GFP as a reporter system in barley transformation, two barley cultivars (Baronesse and Golden Promise) were transformed by microprojectile bombardment. Transient gfp expression in transformed embryogenic callus material was detectable by fluorescence microscopy less than 12 h after transformation. The presence of the gfp gene in callus and regenerated plantlets was confirmed by PCR amplification and DNA gel-blot analysis.     

Green fluorescent protein as a reporter for gene expression in the mucoralean fungus Absidia glauca

Mucoralean fungi (Zygomycota) are used for many industrial processes and also as important model organisms for investigating basic biological problems. Their genetic analysis is severely hampered by low transformation frequencies, by their strong tendency towards autonomous replication of plasmids instead of stable integration, and by the lack of reliable genetic reporter systems. We constructed plasmids for transforming the model zygomycete Absidia glauca that carry the versatile reporter gene coding for green fluorescent protein (GFP). gfp expression is controlled either by the homologous actin promoter or the promoter for the elongation factor of translation, EF1alpha. These plasmids also confer neomycin resistance and carry one of two genetic elements (rag1, seg1) that improve mitotic stability of the plasmid. The gfp constructs were replicated extrachromosomally and could be recovered from retransformed Escherichia coli cells. gfp expression was monitored by epifluorescence microscopy. The gfp reporter gene plasmids presented here for the model zygomycete A. glauca constitute the first reliable system that allows the monitoring of gene expression in this important group of fungi.     

Detection of mutation in transgenic CHO cells using green fluorescent protein as a reporter

A novel approach was developed for rapidly estimating the frequency of specific mutations in genetically engineered Chinese hamster ovary (CHO) cells. We designed double-transgenic CHO cell lines that contain a transgene consisting of the sequence coding for green fluorescent protein under the control of a tetracycline (Tet) responsive promoter and a second transgene coding for the constitutively expressed Tet repressor. Cultures of these CHO cells were treated with gamma-radiation, N-methyl-N-nitrosourea or methyl methanesulfonate, and the fluorescence of individual cells from both control and treated cultures was measured by flow cytometry. The treatments increased the number of highly fluorescent cells, those with presumed mutations in the Tet-repressor gene. Mutant cells from gamma-radiation-exposed cultures were isolated by fluorescence-activated cell sorting, cultured, and individual clones expanded. A PCR-based analysis indicated that the highly fluorescent expanded cells had lost the transgene coding for the Tet repressor, suggesting that the system mainly detects large genetic alterations. A similar approach may be useful for making high-throughput in vivo models for mutation detection.     

Dual transgenic reporter mice as a tool for monitoring expression of glial fibrillary acidic protein

Glial fibrillary acidic protein (GFAP) is the major intermediate filament protein of astrocytes, and its expression changes dramatically during development and following injury. To facilitate study of the regulation of GFAP expression, we have generated dual transgenic mice expressing both firefly luciferase under the control of a 2.2 kb human GFAP promoter and Renilla luciferase under the control of a 0.5 kb human Glyceraldehyde 3 phosphate dehydrogenase (GAPDH) promoter for normalization of the GFAP signal. The GFAP-fLuc was highly expressed in brain compared to other tissues, and was limited to astrocytes, whereas the GAPDH-RLuc was more widely expressed. Normalization of the GFAP signal to the GAPDH signal reduced the inter-individual variability compared to using the GFAP signal alone. The GFAP/GAPDH ratio correctly reflected the up-regulation of GFAP that occurs following retinal degeneration in FVB/N mice because of the rd mutation. Following kainic acid-induced seizures, changes in the GFAP/GAPDH ratio precede those in total GFAP protein. In knock-in mice expressing the R236H Alexander disease mutant, GFAP promoter activity is only transiently elevated and may not entirely account for the accumulation of GFAP protein that takes place.     

Green fluorescent protein as a novel tool to measure apoptosis and necrosis

BACKGROUND: Several apoptosis-detecting methods are currently available. Many of them are work intensive and require the additional use of antibodies, dyes, specific substrates, or enzymatic reactions. A simple, fast, and reliable method was developed to test for apoptosis or necrosis using mouse and human cell lines (e.g., Jurkat, A20.2J, and PB3c cells) stably transfected with a vector coding for green fluorescent protein (GFP) as indicator cells. METHODS: Apoptosis in GFP-transfected cell lines was induced either by soluble Fas-Ligand (sFasL), recombinant human TRAIL (rhTRAIL), or interleukin-3 (IL-3) deprivation. Necrosis was induced by polyclonal anti-A20 and complement treatment of GFP-transfected A20. Cells were analyzed by flow cytometry for GFP fluorescence. Propidium iodide and Annexin V staining were used to confirm the results obtained with the GFP-method. RESULTS: Live GFP-transfected cells show a strong fluorescence intensity, which is significantly diminished upon induction of apoptosis, whereas necrotic GFP-transfected cells almost completely lose their GFP-associated fluorescence. Apoptosis but not necrosis of GFP-transfected cells was blocked by the use of a caspase inhibitor. The results are highly comparable to conventional apoptosis-detecting methods. CONCLUSIONS: The advantage of our GFP-based assay compared with other methods is the analysis of apoptosis or necrosis without the necessity for additional staining or washing steps, making it an ideal tool for screening apoptotic or necrotic stimuli.     

Improved green fluorescent protein as a fast reporter of gene expression in plant cells

An improved green fluorescent protein (GFP), S65TGFP, has new properties that make itself more suitable as a reporter of gene expression. The coding sequence for S65TGFP was placed under the control of the rice actin1 (Act1) promoter in pAct1-S65TGFP reconstruction. We transformed pAct1-S65TGFP into rice callus cells by particle bombardment and bright green fluorescent dots could be seen after 6-8 hours.     

Green fluorescent protein as a quantitative reporter of relative promoter activity in E. coli

Green fluorescent protein (GFP) has become a valuable tool for the detection of gene expression in prokaryotes and eukaryotes. To evaluate its potential for quantitation of relative promoter activity in E. coli, we have compared GFP with the commonly used reporter gene lacZ, encoding beta-galactosidase. We cloned a series of previously characterized synthetic E. coli promoters into GFP and beta-galactosidase reporter vectors. Qualitative and quantitative assessments of these constructs show that (a) both reporters display similar sensitivities in cells grown on solid or liquid media and (b) GFP is especially well suited for quantitation of promoter activity in cells grown on agar. Thus, GFP provides a simple, rapid and sensitive tool for measuring relative promoter activity in intact E. coli cells.     

Green fluorescent protein as a marker for expression of a second gene in transgenic plants.

The use of transgenic crops has generated concerns about transgene movement to unintended hosts and the associated ecological consequences. Moreover, the in-field monitoring of transgene expression is of practical concern (e.g., the underexpression of an herbicide tolerance gene in crop plants that are due to be sprayed with herbicide). A solution to these potential problems is to monitor the presence and expression of an agronomically important gene by linking it to a marker gene, such as GFP. Here we show that GFP fluorescence can indicate expression of the Bacillus thuringiensus cry1Ac gene when co-introduced into tobacco and oilseed rape, as demonstrated by insect bioassays and western blot analysis. Furthermore we conducted two seasons of field experiments to characterize the performance of three different GFP genes in transgenic tobacco. The best gene tested was mGFP5er, a mutagenized GFP gene that is targeted to the endoplasmic reticulum. We also demonstrated that host plants synthesizing GFP in the field suffered no fitness costs.     

Jellyfish green fluorescent protein as a reporter for virus infections

The gene encoding green fluorescent protein (GFP) of Aequorea victoria was introduced into the expression cassette of a virus vector based on potato virus X (PVX). Host plants of PVX inoculated with PVX.GFP became systemically infected. Production of GFP in these plants was detected initially between 1 and 2 days postinoculation by the presence of regions on the inoculated leaf that fluoresced bright green under UV light. Subsequently, this green fluorescence was evident in systemically infected tissue. The fluorescence could be detected by several methods. The simplest of these was by looking at the UV-illuminated plants in a darkened room. The PVX.GFP-infected tissue has been analysed either by epifluorescence or confocal laser scanning microscopy. These microscopical methods allow the presence of the virus to be localized to individual infected cells. It was also possible to detect the green fluorescence by spectroscopy or by electrophoresis of extracts from infected plants. To illustrate the potential application of this reporter gene in virological studies a derivative of PVX.GFP was constructed in which the coat protein gene of PVX was replaced by GFP. Confocal laser scanning microscopy of the inoculated tissue showed that the virus was restricted to the inoculated cells thereby confirming earlier speculation that the PVX coat protein is essential for cell-to-cell movement. It is likely that GFP will be useful as a reporter gene in transgenic plants as well as in virus-infected tissue.     

Green fluorescent protein as a vital marker for non-destructive detection of transformation events in transgenic plants

Transformation of plants is a popular tool for modifying various desirable traits. Marker genes, like those encoding for bacterial β-glucuronidase (GUS), firefly luciferase (LUC) or jellyfish green fluorescent protein (GFP) have been shown to be very useful for establishing of efficient transformation protocols. Due to favourable properties such as no need of exogenous substrates and easy visualization, GFP has been found to be superior in to other markers in many cases. However, the use of GFP fluorescence is associated with some obstacles, mostly related to the diminishing of green fluorescence in older tissues, variation in fluorescence levels among different tissues and organs, and occasional interference with other fluorescing compounds in plants. This paper briefly summarizes basic GFP properties and applications, and describes in more detail the contribution of GFP to the establishment, evaluation and improvement of transformation procedures for plants. Moreover, features and possible obstacles associated with monitoring GFP fluorescence are discussed.