Expression, selection, and organellar targeting of the green fluorescent protein in Toxoplasma gondii

We have engineered a mutant version of the green fluorescent protein GFP (Cormack et al. Selected for bright fluorescence in E. coli. Gene 1996;173:33-38) for expression in the protozoan parasite Toxoplasma gondii. Although intact GFP was not expressed at any detectable level, GFP fusion proteins could be detected by fluorescence microscopy, flow cytometry (FACS), and immunoblotting. Both extracellular tachyzoites and T. gondii-infected host cells could readily be sorted by FACS, which should facilitate a variety of selection strategies. Several selectable markers were tested for their ability to produce stable green transgenic parasites. Fluorescence intensity was directly correlated with gene copy number and protein expression level. Weak selectable markers such as chloramphenicol acetyl transferase (CAT) driven by the SAG1 promoter, which yield multicopy insertions, are therefore most effective for selecting green fluorescent parasites-particularly when coupled to constructs which employ a strong promoter to drive GFP expression. Transformation vectors developed in the course of this work should be of general utility for the overexpression of heterologous transgenes in Toxoplasma. CAT-GFP fusion proteins were expressed in the parasite cytoplasm. GFP fusions to the P30 major surface antigen (linked on the same plasmid to a CAT selectable marker under control of various promoters) could be detected in dense granules within living cells, and were efficiently secreted into the parasitophorous vacuole. GFP fusions to the rhoptry protein ROP1 were targeted to rhoptries (specialized secretory organelles at the apical end of the parasite).     

Making genes green: creating green fluorescent protein (GFP) fusions with blunt-end PCR products

The jellyfish green fluorescent protein (GFP) has proven to be a useful tool in protein localization and trafficking studies. Fused to GFP, a protein of interest can be visualized and tracked in vivo through fluorescence microscopy. However, the process of making these fusion proteins is often tedious and painstaking. Here, we describe a simple and quick method for creating GFP fusion proteins using blunt-end PCR product ligation.     

Random insertion of GFP into the cAMP-dependent protein kinase regulatory subunit from Dictyostelium discoideum

The green fluorescent protein (GFP) is currently being used for diverse cellular biology approaches, mainly as a protein tag or to monitor gene expression. Recently it has been shown that GFP can also be used to monitor the activation of second messenger pathways by the use of fluorescence resonance energy transfer (FRET) between two different GFP mutants fused to a Ca2+sensor. We show here that GFP fusions can also be used to obtain information on regions essential for protein function. As FRET requires the two GFPs to be very close, N- or C-terminal fusion proteins will not generally produce FRET between two interacting proteins. In order to increase the probability of FRET, we decided to study the effect of random insertion of two GFP mutants into a protein of interest. We describe here a methodology for random insertion of GFP into the cAMP-dependent protein kinase regulatory subunit using a bacterial expression vector. The selection and analysis of 120 green fluorescent colonies revealed that the insertions were distributed throughout the R coding region. 14 R/GFP fusion proteins were partially purified and characterized for cAMP binding, fluorescence and ability to inhibit PKA catalytic activity. This study reveals that GFP insertion only moderately disturbed the overall folding of the protein or the proper folding of another domain of the protein, as tested by cAMP binding capacity. Furthermore, three R subunits out of 14, which harbour a GFP inserted in the cAMP binding site B, inhibit PKA catalytic subunit in a cAMP-dependent manner. Random insertion of GFP within the R subunit sets the path to develop two-component FRET with the C subunit.     

PRIM: proximity imaging of green fluorescent protein-tagged polypeptides

We report a serendipitous discovery that extends the impressive catalog of reporter functions performed by green fluorescent protein (GFP) or its derivatives. When two GFP molecules are brought into proximity, changes in the relative intensities of green fluorescence emitted upon excitation at 395 vs. 475 nm result. These spectral changes provide a sensitive ratiometric index of the extent of self-association that can be exploited to quantitatively image homo-oligomerization or clustering processes of GFP-tagged proteins in vivo. The method, which we term proximity imaging (PRIM), complements fluorescence resonance energy transfer between a blue fluorescent protein donor and a GFP acceptor, a powerful method for imaging proximity relationships between different proteins. However, unlike fluorescence resonance energy transfer (which is a spectral interaction), PRIM depends on direct contact between two GFP modules, which can lead to structural perturbations and concomitant spectral changes within a module. Moreover, the precise spatial arrangement of the GFP molecules within a given dimer determines the magnitude and direction of the spectral change. We have used PRIM to detect FK1012-induced dimerization of GFP fused to FK506-binding protein and clustering of glycosylphosphatidylinositol-anchored GFP at cell surfaces.     

Activity of foreign proteins targeted within the bacteriophage T4 head and prohead: implications for packaged DNA structure

The phage-derived expression, packaging, and processing (PEPP) system was used to target foreign proteins into the bacteriophage capsid to probe the intracapsid environment and the structure of packaged DNA. Small proteins with minimal requirements for activity were selected, staphylococcal nuclease (SN) and green fluorescent protein (GFP). These proteins were targeted into the T4 head by means of IPIII (internal protein III) fusions or CTS (capsid targeting sequence) fusions. Additional evidence is provided that foreign proteins are targeted into T4 by the N-terminal ten amino acid residue consensus CTS of IPIII identified in previous work. Fusion proteins were produced within host bacteria by expression from plasmids or by produc tion from recombinant phage carrying the fusion genes. Packaged fusion proteins CTS IPIII SN, CTS IPIII TSN, CTS IPIII GFP, CTS IPIII TGFP, and CTS GFP, where [symbol: see text] indicates a linkage peptide sequence Leu(Ile)-N-Glu cleaved by the T4 head morphogenetic proteinase gp21 during head maturation, are observed to exhibit intracapsid activity. SN activity within the head is demonstrated by loss of phage viability and by digested genomic DNA patterns visualized by gel electrophoresis when viable phage are incubated in Ca2+. Green fluorescent phage result immediately after packaging GFP produced at 30 degreesC and below, and continue to give green fluorescence under 470 nm light after CsCl purification. Non-fluorescent GFP-fusions are produced in bacteria at 37 degreesC, and phage packaged with these proteins achieve a fluorescent state after incubation for several months at 4 degreesC. GFP-packaged phage and proheads analyzed by fluorescence spectroscopy show that the mature head and the DNA-empty prohead package identical numbers of GFP-fusion proteins. Encapsidated GFP and SN can be injected into bacteria and rapidly exhibit intracellular activity. In vivo SN digestion of encapsidated DNA gives an intriguing pattern of DNA fragments by gel analysis, predominantly a repeat pattern of 160 bp multiples, reminiscent of a nucleosome digestion ladder, This quasi-limit DNA digestion pattern, reached >100-fold more slowly than the loss of titer, is invariant over a range 相似文献   

Spatial dynamics of GFP-tagged proteins investigated by local fluorescence enhancement

We describe a method of monitoring the spatial dynamics of proteins in intact cells by locally enhancing the blue excited fluorescence of green fluorescent protein (GFP) using a spatially focused ultraviolet-laser pulse. GFP fusion proteins were efficiently expressed by micro-electroporation of in vitro synthesized mRNA into adherent mammalian cells. We found that the diffusion coefficient of cycle 3 mutant GFP was 43 microns2/sec, compared to 4 microns2/sec for wild-type GFP, suggesting that cycle 3 GFP diffuses freely in mammalian cells and is ideally suited as a fusion tag. The local fluorescence enhancement method was used to study the membrane dissociation rate of GFP-tagged K-ras, a small GTP binding protein that localizes to plasma membranes by a farnesyl lipid group and a polybasic region. Our data suggest that K-ras exists in a dynamic equilibrium and rapidly switches between a plasma membrane bound form and a cytosolic form with a plasma membrane dissociation time constant of 1.5 sec.     

Optimized codon usage and chromophore mutations provide enhanced sensitivity with the green fluorescent protein

The green fluorescent protein (GFP) from Aequorea victoria is a versatile reporter protein for monitoring gene expression and protein localization in a variety of cells and organisms. Despite many early successes using this reporter, wild type GFP is suboptimal for most applications due to low fluorescence intensity when excited by blue light (488 nm), a significant lag in the development of fluorescence after protein synthesis, complex photoisomerization of the GFP chromophore and poor expression in many higher eukaryotes. To improve upon these qualities, we have combined a mutant of GFP with a significantly larger extinction coefficient for excitation at 488 nm with a re-engineered GFP gene sequence containing codons preferentially found in highly expressed human proteins. The combination of improved fluorescence intensity and higher expression levels yield an enhanced GFP which provides greater sensitivity in most systems.     

Rehospitalizations and outpatient contacts of mothers and neonates after hospital discharge after vaginal delivery

In this study we report the use of the S. pombe leader sequence of pho1+ acid phosphatase (Elliott et al., J. Biol. Chem. 216, 2916-2941, 1986) for the secretion of heterologous proteins into the medium. The green fluorescent protein (GFP) and the Human Papillomavirus (HPV) type 16 E7 protein are normally not secreted; fusion of the S. pombe pho1 leader peptide (SPL) to GFP and HPV 16 E7 resulted in an efficient secretion of these proteins although the latter contains a nuclear targeting sequence. These data suggest that SPL fused constructs could be applied for the production of other recombinant proteins using the S. pombe expression system. Furthermore, since GFP retains its intrinsic fluorescence during the secretion, this system may be useful to study the secretory pathway of fission yeast in vivo.     

Dual-function reporter protein for analysis of gene expression in living cells

The firefly luciferase (Luc) protein and the jellyfish green fluorescent protein (GFP) are two commonly used molecular reporters that can be detected noninvasively in living cells. The properties that make GFP or Luc useful for a particular experimental application are quite distinct. A recombinant protein with both fluorescent and bioluminescent characteristics might take advantage of the strengths of both reporters. An expression vector encoding a chimeric protein in which GFP was tethered to Luc through a 19-amino acid linker was prepared and characterized. Western blotting with antibodies specific for either GFP or Luc showed that a protein of appropriate size was expressed in transfected cells. Fluorescence microscopy revealed bright green fluorescence from transfected cells, indicating proper formation of the GFP chromophore. Luc enzymatic activity in protein extracts from transfected cells showed that Luc was fully functional. The treatment of living cell cultures stably expressing the GFP-Luc fusion protein with the protein translation-inhibitor cycloheximide (Chx) was used to show that the half-life for Luc protein activity was approximately 2 h at 37 degrees C. The utility of this dual-function reporter protein was shown by the identification of single living cells expressing the chimeric protein within a population by fluorescence microscopy, followed by quantification of Luc activity from the same living cells.     

Glycogenin, the primer of glycogen synthesis, binds to actin

We have studied the intracellular localization of glycogenin by fusing green fluorescent protein (GFP) to the N-terminus of rabbit muscle glycogenin and expressing the chimeric protein in C2C12, COS-1 and rat hepatic cells. The fusion protein showed a nuclear and cytosolic distribution and partially co-localized with actin in the cytosol. Disruption of the actin cytoskeleton with cytochalasin D led to a change in the pattern of green fluorescence, which coincided with that observed for the remaining non-depolymerized actin. The distribution of the single point mutant K324A was completely uniform and was not affected by this drug. These findings indicate that rabbit muscle glycogenin binds to actin through the heptapeptide 321DNIKKKL327, a common motif found in other actin-binding proteins, which is located at the C-terminal end of this protein, and suggest that the actin cytoskeleton plays an important role in glycogen metabolism.     

Incorporation of the green fluorescent protein into the herpes simplex virus type 1 capsid

The herpes simplex virus type 1 (HSV-1) UL35 open reading frame (ORF) encodes a 12-kDa capsid protein designated VP26. VP26 is located on the outer surface of the capsid specifically on the tips of the hexons that constitute the capsid shell. The bioluminescent jellyfish (Aequorea victoria) green fluorescent protein (GFP) was fused in frame with the UL35 ORF to generate a VP26-GFP fusion protein. This fusion protein was fluorescent and localized to distinct regions within the nuclei of transfected cells following infection with wild-type virus. The VP26-GFP marker was introduced into the HSV-1 (KOS) genome resulting in recombinant plaques that were fluorescent. A virus, designated K26GFP, was isolated and purified and was shown to grow as well as the wild-type virus in cell culture. An analysis of the intranuclear capsids formed in K26GFP-infected cells revealed that the fusion protein was incorporated into A, B, and C capsids. Furthermore, the fusion protein incorporated into the virion particle was fluorescent as judged by fluorescence-activated cell sorter (FACS) analysis of infected cells in the absence of de novo protein synthesis. Cells infected with K26GFP exhibited a punctate nuclear fluorescence at early times in the replication cycle. At later times during infection a generalized cytoplasmic and nuclear fluorescence, including fluorescence at the cell membranes, was observed, confirming visually that the fusion protein was incorporated into intranuclear capsids and mature virions.     

Constitutive and inducible green fluorescent protein expression in Bartonella henselae

The green fluorescent protein (GFP) gene was expressed on a plasmid in B. henselae, and GFP-expressing bacteria were visualized by fluorescence microscopy. HEp-2 cells infected with GFP-expressing bacteria were separated from uninfected cells with a fluorescence activated cell sorter. Promoter fusions of B. henselae chromosomal DNA to gfp were examined by flow cytometry, and a B. henselae groEL promoter fusion which induced expression at 37 degreesC was isolated.     

Visualization of mitochondria with green fluorescent protein in cultured fibroblasts from patients with mitochondrial diseases

cDNAs for green fluorescent protein (GFP) and for a GFP fusion protein containing the presequence of human ornithine transcarbamylase (pOTC-GFP) were transfected into cultured human fibroblasts. GFP cDNA gave diffuse fluorescence throughout the cytoplasm and the nucleus, whereas pOTC-GFP cDNA gave mitochondria-associated fluorescence. Fluorescent mitochondrial structures could be classified into five patterns: thread-like mitochondria, fine thread-like ones, rod-like ones, granular ones, and granular ones with weak cytosolic fluorescence. pOTC-GFP mutants resulted in a loss of mitochondrial fluorescence and an appearance of weak fluorescence throughout the cytoplasm. pOTC-GFP cDNA was transfected into fibroblasts from patients with various mitochondrial diseases. Higher ratios of fibroblasts with granular mitochondria and those with fine thread-like ones were observed in a patient with Reye's syndrome and a patient with Kearns-Sayre syndrome. Weak cytosolic fluorescence was sometimes observed in fibroblasts from these patients. This method will be useful to analyze mitochondrial structural alterations and disorders of mitochondrial protein import.     

The effect of uterine contractions on intrapartum fetal heart rate analyzed by a computerized system

In vivo electro-transfection efficiency and manner of transferred gene expression were investigated by fluorescence microscopic image analysis. Green fluorescent protein (GFP) gene was used as the genetic marker. Electroporation was carried out on the liver of live rats by use of disk electrodes mounted in the tips of tweezers, which were directly pressed onto the surface of a liver lobe in situ. Electroporation with eight electric pulses of 50 ms in duration at 50 V gave a good efficiency of transfection as judged by the induced GFP expression. Bright fluorescence of GFP appeared as dots, which were scattered around the area damaged by electroporation. The transfection efficiency increased as the amount of injected DNA was increased. The results indicate that the amount of induced gene expression can be controlled. Estimation of the efficiency of electro-gene transfer using the fluorescence of GFP and digital analysis of microscopic images was useful to determine the optimum conditions for local gene therapy in tissues and organs.     

Direct observation of a central bare zone in a native thick filament isolated from the anterior byssus retractor muscle of Mytilus edulis using fluorescent ATP analogue

Green fluorescent protein (GFP) and herpes simplex virus type-I thymidine kinase (TK) are commonly used markers in gene transfer studies. The latter gene has also proven to be an effective tool in cancer "suicide" gene therapy. To facilitate rapid and reliable selection of cells expressing TK, we constructed a plasmid expressing a TK-green fluorescent protein fusion gene (TK-GFP). In this fusion gene, the expression of each component is coupled to one another, permitting accurate determination of the percentage of cells expressing TK by detecting the green fluorescence produced by GFP. Transfection of the fusion plasmid to mammalian cells revealed that the construct is fully functional, making the cells both fluorescent and sensitive to ganciclovir.     

GFP:HIV-1 protease production and packaging with a T4 phage expression-packaging processing system

A bacteriophage T4-derived protein expression, packaging and processing system was used to create recombinant phage that encode, produce and package a protein composed of human HIV-1 protease fused to green fluorescent protein (GFP). The fusion protein is targeted within the phage capsid by an N-terminal capsid targeting sequence (CTS), which is cleaved through proteolysis by the viral scaffold protease P21. The fusion protein is designated CTS [symbol see text] GFP:PR. The [symbol see text] symbol indicates the linkage peptide sequence leu(ile)-N-glu that is cleaved by the T4 head morphogenetic proteinase gp21 during head maturation. The fusion protein is fluorescent and has protease activity as detected by the appearance of the expected substrate cleavage product on a Western blot. CTS [symbol see text] GFP:PR packaging occurs at about 200 molecules per phage particle. The CTS [symbol see text] GFP:PR fusion protein, when protected within the phage capsid, has been maintained stably for over 16 months at 4 degrees C. Production and storage of fusion protein within the phage circumvents problems of toxicity and solubility encountered with E. coli expression systems. Because recombinant phage inhibit host proteolytic enzymes, foreign proteins are stabilized. This phage system packages and processes the fusion protein by means of the CTS. Proteins can be purified from the phage to give high yields of soluble, proteolytically processed protein. The T4 phage packaging system provides a novel means of identification, purification and long-term storage of toxic proteins whose folding and DNA-directed activities can be studied readily in vivo.     

Circular mRNA can direct translation of extremely long repeating-sequence proteins in vivo

Many proteins with unusual structural properties are comprised of multiple repeating amino acid sequences and are often fractious to expression in recombinant systems. To facilitate recombinant production of such proteins for structural and engineering studies, we have produced circular messenger RNAs with infinite open reading frames. We show that a circular mRNA containing a simple green fluorescent protein (GFP) open reading frame can direct GFP expression in Escherichia coli. A circular mRNA with an infinite GFP open reading frame produces extremely long protein chains, proving that bacterial ribosomes can internally initiate and repeatedly transit a circular mRNA. Only the monomeric forms of GFP produced from circular mRNA are fluorescent. Analysis of the translation initiation region shows that multiple sequences contribute to maximal translation from circular mRNA. This technology provides a unique means of producing a very long repeating-sequence protein, and may open the way for development of proteinaceous materials with novel properties.     

Green fluorescent protein tag for studies of drug-induced translocation of nucleolar protein RH-II/Gu

We have constructed a human osteogenic sarcoma cell line, U-2 OS/GFP-Gu, that expresses nucleolar RNA helicase RH-II/Gu tagged with green fluorescent protein (GFP). The presence of a GFP tag does not inhibit RNA helicase, RNA folding and ATPase activities of RH-II/Gu protein. The derived cell line responds to cytotoxic agents like the parental cell line U-2 OS. In the presence of either actinomycin D or toyocamycin, the GFP-RH-II/Gu fusion protein translocates from the nucleolus to the nucleoplasm in the same way as the translocation of endogenous RH-II/Gu. The drug-induced translocation of GFP-RH-II/Gu is easily monitored by direct observation of live cells in vivo. This cell line can be used to screen cytotoxic drugs and to study the mechanisms of drug-induced translocation of RH-II/Gu. The cellular localization of RH-II/Gu during the cell cycle-dependent formation of the nucleolus is readily monitored. Real-time results are obtained more quickly without the disadvantages associated with cell fixation and immunofluorescence-based staining.     

Use of a fusion protein between GFP and an actin-binding domain to visualize transient filamentous-actin structures

Many important processes in eukaryotic cells involve changes in the quantity, location and the organization of actin filaments [1] [2] [3]. We have been able to visualize these changes in live cells using a fusion protein (GFP-ABD) comprising the green fluorescent protein (GFP) of Aequorea victoria and the 25 kDa highly conserved actin-binding domain (ABD) from the amino terminus of the actin cross-linking protein ABP-120 [4]. In live cells of the soil amoeba Dictyostelium that were expressing GFP-ABD, the three-dimensional architecture of the actin cortex was clearly visualized. The pattern of GFP-ABD fluorescence in these cells coincided with that of rhodamine-phalloidin, indicating that GFP-ABD specifically binds filamentous (F) actin. On the ventral surface of non-polarized vegetative cells, a broad ring of F actin periodically assembled and contracted, whereas in polarized cells there were transient punctate F-actin structures; cells cycled between the polarized and non-polarized morphologies. During the formation of pseudopods, an increase in fluorescence intensity coincided with the initial outward deformation of the membrane. This is consistent with the models of pseudopod extension that predict an increase in the local density of actin filaments. In conclusion, GFP-ABD specifically binds F actin and allows the visualization of F-actin dynamics and cellular behavior simultaneously.