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.     

An integral membrane green fluorescent protein marker, Us9-GFP, is quantitatively retained in cells during propidium iodide-based cell cycle analysis by flow cytometry

Previously, we described GFP-spectrin, a membrane-localized derivative of the green fluorescent protein that can be employed as a marker during the simultaneous identification of transfected cells and cell cycle analysis by flow cytometry (Kalejta et al., Cytometry 29: 286-291, 1997). A membrane-anchored GFP fusion protein is necessary because the ethanol permeabilization step required to achieve efficient propidium iodide staining allows cytoplasmic GFP to leach out of the cell. However, viable cells expressing GFP-spectrin are not as bright as cells expressing cytoplasmic GFP and their fluorescence intensity is further diminished after ethanol treatment. Here, we demonstrate that the fluorescence intensity of cells expressing an integral membrane GFP fusion protein (Us9-GFP) is similar to that of cells expressing cytoplasmic GFP and is quantitatively maintained in cells after ethanol treatment. By allowing an accurate assessment of the expression level of GFP, Us9-GFP allows a more precise analysis of the effects of a cotransfected plasmid on the cell cycle and thus represents an improvement upon the original membrane-associated GFP fusion proteins employed in this assay.     

Nuclear aggresomes form by fusion of PML-associated aggregates

Nuclear aggregates formed by proteins containing expanded poly-glutamine (poly-Q) tracts have been linked to the pathogenesis of poly-Q neurodegenerative diseases. Here, we show that a protein (GFP170*) lacking poly-Q tracts forms nuclear aggregates that share characteristics of poly-Q aggregates. GFP170* aggregates recruit cellular chaperones and proteasomes, and alter the organization of nuclear domains containing the promyelocytic leukemia (PML) protein. These results suggest that the formation of nuclear aggregates and their effects on nuclear architecture are not specific to poly-Q proteins. Using GFP170* as a model substrate, we explored the mechanistic details of nuclear aggregate formation. Fluorescence recovery after photobleaching and fluorescence loss in photobleaching analyses show that GFP170* molecules exchange rapidly between aggregates and a soluble pool of GFP170*, indicating that the aggregates are dynamic accumulations of GFP170*. The formation of cytoplasmic and nuclear GFP170* aggregates is microtubule-dependent. We show that within the nucleus, GFP170* initially deposits in small aggregates at or adjacent to PML bodies. Time-lapse imaging of live cells shows that small aggregates move toward each other and fuse to form larger aggregates. The coalescence of the aggregates is accompanied by spatial rearrangements of the PML bodies. Significantly, we find that the larger nuclear aggregates have complex internal substructures that reposition extensively during fusion of the aggregates. These studies suggest that nuclear aggregates may be viewed as dynamic multidomain inclusions that continuously remodel their components.     

The nucleoprotein of Tomato spotted wilt virus as protein tag for easy purification and enhanced production of recombinant proteins in plants

Upon infection, Tomato spotted wilt virus (TSWV) forms ribonucleoprotein particles (RNPs) that consist of nucleoprotein (N) and viral RNA. These aggregates result from the homopolymerization of the N protein, and are highly stable in plant cells. These properties feature the N protein as a potentially useful protein fusion partner. To evaluate this potential, the N protein was fused to the Aequorea victoria green fluorescent protein (GFP), either at the amino or carboxy terminus, and expressed in plants from binary vectors in Nicotiana benthamiana leaves were infiltrated with Agrobacterium tumefaciens and evaluated after 4 days, revealing an intense GFP fluorescence under UV light. Microscopic analysis revealed that upon expression of the GFP:N fusion a small number of large aggregates were formed, whereas N:GFP expression led to a large number of smaller aggregates scattered throughout the cytoplasm. A simple purification method was tested, based on centrifugation and filtration, yielding a gross extract that contained large amounts of N:GFP aggregates, as confirmed by GFP fluorescence and Western blot analysis. These results show that the homopolymerization properties of the N protein can be used as a fast and simple way to purify large amounts of proteins from plants.     

枯草杆菌ylyA基因的绿色荧光蛋白标记

[目的]本研究对枯草杆菌ylyA基因进行荧光标记以便对其产物YlyA在菌体中的位置进行初步观察.[方法]以不同菌株基因组DNA为模板,对ylyA基因进行PCR扩增和序列分析;重新设计引物扩增全长的ylyA并将其克隆到载体pSG1729中,形成gfpmut1-ylyA融合而构建重组载体pNG426;将pNG426转化枯草杆菌168菌株,双交换使gfpmut1-ylyA插入染色体的amyE位点,用碘染色法和菌落PCR对阳性转化子BS363进行鉴定.NA固体培养基上生长的BS363经0.5%木糖诱导表达后,利用表面荧光显微镜技术进行观察.[结果]通过对多个PCR产物的序列分析确定了ylyA基因的正确序列以及正确的翻译起始位点;成功将重组载体pNG426转化枯草杆菌得到了BS363菌株;荧光检测结果表明GFP标记的YlyA分布于菌体的外周,在位置上靠近细胞膜并与之平行排列.[结论]生长缓慢的BS363菌体,在0.5%木糖诱导下产生的荧光标记YlyA蛋白分布在细胞外周,可能在膜生物学中发挥作用.     

In vivo aggregation of the HET-s prion protein of the fungus Podospora anserina

We have proposed that the [Het-s] infectious cytoplasmic element of the filamentous fungus Podospora anserina is the prion form of the HET-s protein. The HET-s protein is involved in a cellular recognition phenomenon characteristic of filamentous fungi and known as heterokaryon incompatibility. Under the prion form, the HET-s protein causes a cell death reaction when co-expressed with the HET-S protein, from which it differs by only 13 amino acid residues. We show here that the HET-s protein can exist as two alternative states, a soluble and an aggregated form in vivo. As shown for the yeast prions, transition to the infectious prion form leads to aggregation of a HET-s--green fluorescent protein (GFP) fusion protein. The HET-s protein is aggregated in vivo when highly expressed. However, we could not demonstrate HET-s aggregation at wild-type expression levels, which could indicate that only a small fraction of the HET-s protein is in its aggregated form in vivo in wild-type [Het-s] strains. The antagonistic HET-S form is soluble even at high expression level. A double amino acid substitution in HET-s (D23A P33H), which abolishes prion infectivity, suppresses in vivo aggregation of the GFP fusion. Together, these results further support the model that the [Het-s] element corresponds to an abnormal self-perpetuating aggregated form of the HET-s protein.     

Translocation of green fluorescent protein to cyanobacterial periplasm using ice nucleation protein

The translocation of proteins to cyanobacterial cell envelope is made complex by the presence of a highly differentiated membrane system. To investigate the protein translocation in cyanobacterium Synechococcus PCC 7942 using the truncated ice nucleation protein (InpNC) from Pseudomonas syringae KCTC 1832, the green fluorescent protein (GFP) was fused in frame to the carboxyl-terminus of InpNC. The fluorescence of GFP was found almost entirely as a halo in the outer regions of cells which appeared to correspond to the periplasm as demonstrated by confocal laser scanning microscopy, however, GFP was not displayed on the outermost cell surface. Western blotting analysis revealed that InpNC-GFP fusion protein was partially degraded. The N-terminal domain of InpNC may be susceptible to protease attack; the remaining C-terminal domain conjugated with GFP lost the ability to direct translocation across outer membrane and to act as a surface display motif. The fluorescence intensity of cells with periplasmic GFP was approximately 6-fold lower than that of cells with cytoplasmic GFP. The successful translocation of the active GFP to the periplasm may provide a potential means to study the property of cyanobacterial periplasmic substances in response to environmental changes in a non-invasive manner.     

Comparison of fixation protocols for adherent cultured cells applied to a GFP fusion protein of the epidermal growth factor receptor

BACKGROUND: The analysis of the subcellular distribution of proteins is essential for the understanding of processes such as signal transduction. In most cases, the parallel analysis of multiple components requires fixation and immunofluorescence labeling. Therefore, one has to ascertain that the fixation procedure preserves the in vivo protein distribution. Fusion proteins with the green fluorescent protein (GFP) are ideal tools for this purpose. However, one must consider specific aspects of the fluorophore formation or degradation, i.e. reactions that may interfere with the detection of GFP fusion proteins. METHODS: Fusion proteins of the epidermal growth factor receptor (EGFR) with GFP as well as free, soluble GFP stably or transiently expressed in adherent cultured cells served as test cases for comparing the distribution in vivo with that after fixation by conventional epifluorescence and laser scanning microscopy. Indirect immunofluorescence was employed to compare the distributions of the GFP signal and of the GFP polypeptide in the fusion protein. RESULTS: Paraformaldehyde (PFA) fixation with subsequent mounting in the antifading agent Mowiol, but not in Tris- or HEPES buffered saline, led to a partial redistribution of the EGFR from the plasma membrane to the perinuclear region. The redistribution was confirmed with the GFP and EGFR immunofluorescence. The in vivo distribution in Mowiol mounted cells was preserved if cells were treated with a combined PFA/methanol fixation procedure, which also retained the fluorescence of soluble GFP. The anti-GFP antiserum was negative for the N-terminal fusion protein. CONCLUSIONS: The combined PFA/methanol protocol is universally applicable for the fixation of transmembrane and soluble cytoplasmic proteins and preserves the fluorescence of GFP.     

A periplasmic fluorescent reporter protein and its application in high-throughput membrane protein topology analysis

We have developed a periplasmic fluorescent reporter protein suitable for high-throughput membrane protein topology analysis in Escherichia coli. The reporter protein consists of a single chain (scFv) antibody fragment that binds to a fluorescent hapten conjugate with high affinity. Fusion of the scFv to membrane protein sites that are normally exposed in the periplasmic space tethers the scFv onto the inner membrane. Following permealization of the outer membrane to allow diffusion of the fluorescent hapten into the periplasm, binding to the anchored scFv renders the cells fluorescent. We show that cell fluorescence is an accurate and sensitive reporter of the location of residues within periplasmic loops. For topological analysis, a set of nested deletions in the membrane protein gene is employed to construct two libraries of gene fusions, one to the scFvand one to the cytoplasmic reporter green fluorescent protein (GFP). Fluorescent clones are isolated by flow cytometry and the sequence of the fusion junctions is determined to identify amino acid residues within periplasmic and cytoplasmic loops, respectively. We applied this methodology to the topology analysis of E. coli TatC protein for which previous studies had led to conflicting results. The ease of screening libraries of fusions by flow cytometry enabled the rapid identification of almost 90 highly fluorescent scFv and GFP fusions, which, in turn, allowed the fine mapping of TatC membrane topology.     

Targeting of green fluorescent protein expression to the cell surface.

We have previously reported on GPI-anchored fusion proteins that bind radioactive isotopes. We targeted their expression to the cell surface to obtain a marker protein detectable by nuclear and optical imaging (1, 2). Here we suggest a novel approach for targeting a model protein (GFP) to the exoplasmic surface of the plasma membrane. An expression vector (pcPEP-GFP) was constructed containing GFP cDNA fused with the fragment encoding the N-terminal cytoplasmic domain and signal peptide/membrane anchoring domain of the rabbit neutral endopeptidase (PEP-GFP). Flow cytometry showed green fluorescence in 45% of cells transfected with GFP and in 34% of cells transfected with PEP-GFP (24 h after transfection). Fluorescence microscopy of fixed cells stained with rhodaminated anti-GFP antibodies showed positive reaction only in the case of PEP-GFP-transfected cells indicating cell-surface expression. The PEP-GFP fusion protein was identified as a component of the light microsomal and Golgi fractions by immunoblotting.     

High expression of green fluorescent protein in Pichia pastoris leads to formation of fluorescent particles

Wild type gene for green fluorescent protein (GFP) was stably integrated into the Pichia pastoris genome and yielded an expression level of over 40% of total cellular protein. The high cytoplasmic concentration of fluorescent (properly folded and processed) GFP caused the formation of fluorescent spherical structures, which could be observed by fluorescence or confocal microscopy after controlled permeabilization of the yeast cells with 0.2% N-lauroyl sarcosine (NLS). Fluorescent GFP particles were also isolated after removal of the cell wall and found to be quite resistant to 0.2% N-lauroyl sarcosine. SDS-PAGE analysis of the isolated fluorescent particles revealed the presence of an 80 kDa protein (alcohol oxidase) and GFP (30%). We conclude that GFP is able to enter spontaneously into the peroxisomes and is inserted into densely packed layers of alcohol oxidase. Consequently, the formation of similar fluorescent particles can also be expected in other organisms when using high-level expression systems. As GFP is widely used in fusion with other proteins as a reporter for protein localization and for many other applications in biotechnology, care must be taken to avoid false interpretations of targeting or trafficking mechanisms inside the cells. In addition, when whole cells or cytoplasmic fractions are used for the quantitative determination of GFP levels, incorrect and misleading values of GFP could be obtained due to the formation of fluorescent particles containing material inside which is not available for fluorescence measurements.     

Engineering green fluorescent protein as a dual functional tag

A hexa-histidine (6 x His) sequence was inserted into a surface loop of the green fluorescent protein (GFP) to develop a dual functional GFP useful for both monitoring and purification of recombinant proteins. Two variants (GFP172 and GFP157), differentiated by the site of insertion of the 6xHis sequence, were developed and compared with a control variant (GFPHis) having the 6xHis sequence at its C-terminus. The variants were produced in Escherichia coli and purified using immobilized metal affinity chromatography (IMAC). The purification efficiencies by IMAC for all variants were found to be comparable. Purified GFP172 and GFP157 variants retained approximately 60% of the fluorescence compared to that of GFPHis. The reduction in the fluorescence intensity associated with GFP172 and GFP157 was attributed to the lower percentage of fluorescent GFP molecules in these variants. Nonetheless, the rates of fluorescence acquisition were found to be similar for all functional variants. Protein misfolding at an elevated temperature (37 degrees C) was found to be less profound for GFP172 than for GFP157. The dual functional properties of GFP172 were tested with maltose binding protein (MBP) as the fusion partner. The MBP-GFP172 fusion protein remained fluorescent and was purified from E. coli lysate as well as from spiked tobacco leaf extracts in a single-step IMAC. For the latter, a recovery yield of approximately 75% was achieved and MBP-GFP172 was found to coelute with a degraded product of the fusion protein at a ratio of about 4:1. The primary advantage of the chimeric GFP tag having an internal hexa-histidine sequence is that such a tag allows maximum flexibility for protein or peptide fusions since both N- and C-terminal ends of the GFP are available for fusion.     

Assessment of membrane protein expression and stability using a split green fluorescent protein reporter

Membrane proteins are challenging targets for structural biologists. Finding optimal candidates for such studies requires extensive and laborious screening of protein expression and/or stability in detergent. The use of green fluorescent protein (GFP) as a reporter has enormously facilitated these studies; however, its 238 residues can potentially alter the intrinsic properties of the target (e.g., expression or stability). With the aim of minimizing undesired effects of full-length GFP, here we describe the utility of a split GFP reporter during precrystallization studies of membrane proteins. GFP fluorescence appeared by complementation of the first 15 residues of GFP (GFP(11)) (fused to the C terminus of a membrane protein target) with the remaining nonfluorescent GFP (GFP(1-10)). The signal obtained after sequential expression of SteT (l-serine/l-threonine exchanger of Bacillus subtilis) fused to GFP(11) followed by GFP(1-10) specifically measured the protein fraction inserted into the Escherichia coli cytoplasmic membrane, thereby discarding protein aggregates confined as inclusion bodies. Furthermore, in vitro complementation of purified SteT-GFP(11) with purified GFP(1-10) was exploited to rapidly assess the stability of wild-type and G294V mutant versions of SteT-GFP(11) following detergent solubilization and purification. This method can be applied in a medium- to high-throughput manner with multiple samples.     

Simultaneous detection of multiple green fluorescent proteins in live cells by fluorescence lifetime imaging microscopy

The green fluorescent protein (GFP) has proven to be an excellent fluorescent marker for protein expression and localisation in living cells [1] [2] [3] [4] [5]. Several mutant GFPs with distinct fluorescence excitation and emission spectra have been engineered for intended use in multi-labelling experiments [6] [7] [8] [9]. Discrimination of these co-expressed GFP variants by wavelength is hampered, however, by a high degree of spectral overlap, low quantum efficiencies and extinction coefficients [10], or rapid photobleaching [6]. Using fluorescence lifetime imaging microscopy (FLIM) [11] [12] [13] [14] [15] [16], four GFP variants were shown to have distinguishable fluorescence lifetimes. Among these was a new variant (YFP5) with spectral characteristics reminiscent of yellow fluorescent protein [8] and a comparatively long fluorescence lifetime. The fluorescence intensities of co-expressed spectrally similar GFP variants (either alone or as fusion proteins) were separated using lifetime images obtained with FLIM at a single excitation wavelength and using a single broad band emission filter. Fluorescence lifetime imaging opens up an additional spectroscopic dimension to wavelength through which novel GFP variants can be selected to extend the number of protein processes that can be imaged simultaneously in cells.     

Movement of the free catalytic subunit of cAMP-dependent protein kinase into and out of the nucleus can be explained by diffusion.

The catalytic (C) subunit of cyclic AMP (cAMP) dependent protein kinase (PKA) has previously been shown to enter and exit the nucleus of cells when intracellular cAMP is raised and lowered, respectively. To determine the mechanism of nuclear translocation, fluorescently labeled C subunit was injected into living REF52 fibroblasts either as free C subunit or in the form of holoenzyme (PKA) in which the catalytic and regulatory subunits were labeled with fluorescein and rhodamine, respectively. Quantification of nuclear and cytoplasmic fluorescence intensities revealed that free C subunit nuclear accumulation was most similar to that of macromolecules that diffuse into the nucleus. A glutathione S-transferase-C subunit fusion protein did not enter the nucleus following cytoplasmic microinjection. Puncturing the nuclear membrane did not decrease the nuclear concentration of C subunit, and C subunit entry into the nucleus did not appear to be saturable. Cooling or depleting cells of energy failed to block movement of C subunit into the nucleus. Photobleaching experiments showed that even after reaching equilibrium at high [cAMP], individual molecules of C subunit continued to leave the nucleus at approximately the same rate that they had originally entered. These results indicate that diffusion is sufficient to explain most aspects of C subunit subcellular localization.     

Characterization of the activity of a plastid-targeted green fluorescent protein in Arabidopsis.

In Arabidopsis thaliana the PALE CRESS (PAC) gene product is required for both chloroplast and cell differentiation. Transgenic Arabidopsis plants expressing a translational fusion of the N-terminal part of the PAC protein harboring the complete plastid-targeting sequence and the green fluorescent protein (GFP) exhibit high GFP fluorescence. Detailed analyses based on confocal imaging of various tissues and cell types revealed that the PAC-GFP fusion protein accumulates in chloroplasts of mature stomatal guard cells. The GFP fluorescence within the guard cell chloroplasts is not evenly distributed and appears to be concentrated in suborganellar regions. GFP localization studies demonstrate that thin tubular projections emanating from chloroplasts and etioplasts often connect the organelles with each other. Furthermore, imaging of non-green and etiolated tissue further revealed that GFP fluorescence is present in proplastids, etioplasts, chromoplasts, and amyloplasts. Even photobleaching of carotenoid-free plastids does not affect PAC-GFP accumulation in the organelles of the guard cells indicating that the protein translocation machinery is functional in all types of plastids. The specific accumulation of GFP in guard cell chloroplasts, their tubular connections, the translocation of the precursor polypeptide into the different types of organelles, as well as the use of a plastid-targeted GFP protein as a versatile marker is discussed in the context of previously described observations.     

Identification of a ternary complex between cAMP and a trimeric form of cAMP-dependent protein kinase

One of the intermediates involved in dissociation and reassociation of the subunits of the type II cAMP-dependent protein kinase has been characterized. This intermediate can be generated when the protein kinase is prepared from the isolated catalytic subunit (C) and the isolated regulatory subunit-[3H]cAMP complex (R2-[3H]cAMP4) by dialysis for 18 h followed by gel filtration. The intermediate, which could be separated from the holoenzyme and the isolated subunits by polyacrylamide gel electrophoresis, had an apparent molecular weight of 149,000, consistent with an R2C form. Following electrophoresis, measurements of R and bound nucleotide indicated that R2C was half-saturated with [3H]cAMP. The bound [3H]cAMP exhibited biphasic dissociation kinetics indicating that both types of cAMP binding sites were occupied. These findings suggested that the intermediate is R2C-cAMP2. This intermediate was not seen when the dialysis time was increased to 5 days, but could be observed when cAMP was added to the holoenzyme or when holoenzyme was mixed with R2cAMP4 and cAMP. The presence of two occupied cAMP binding sites on this intermediate suggests that there is minimal cooperativity between the two members of the regulatory subunit dimer, i.e. one member of the dimer binds 2 molecules of cAMP while the other binds C.     

Observations of green fluorescent protein as a fusion partner in genetically engineered Escherichia coli: monitoring protein expression and solubility

We have constructed three plasmid vectors for the expression of green fluorescent protein (GFP) fusion proteins using the following motif: (His)(6)-GFP-EK-X, where X represents chloramphenicol acetyl-transferase (CAT), human interleukin-2 (hIL-2), and organophosphorous hydrolase (OPH), respectively, (His)(6) represents a histidine affinity ligand for purification, and EK represents an enterokinase cleavage site for recovering the protein-of-interest from the fusion. The CAT and OPH fusion products ( approximately 63 kDa GFP/CAT and approximately 70 kDa GFP/OPH) were expressed at 4.85 microg/mL (19.9 microg/mg-total protein) and 1.42 microg/mL (4.2 microg/mg-total protein) in the cell lysis supernatant, and, in both cases, enzymatic activity was retained while coupled to GFP. In the case of hIL-2 fusion ( approximately 52 kDa), however, the GFP fluorescence was significantly reduced and most of the fusion was retained in the cell pellet. Linear relationships between GFP fluorescence and CAT or OPH concentration, and with enzymatic activity of CAT or OPH, indicated, for the first time, that in vivo noninvasive quantification of proteins-of-interest, was made possible by simple measurement of GFP fluorescence intensity. The utility of GFP as a reporter was not realized without disadvantages however, in particular, an incremental metabolic cost of GFP was found. This could be offset by many benefits foreseen in expression and purification efficiencies.     

Purification of human interleukin-2 fusion protein produced in insect larvae is facilitated by fusion with green fluorescent protein and metal affinity ligand

The fusion protein of green fluorescent protein (GFP) and human interleukin-2 (hIL-2) was produced in insect Trichoplusia ni larvae infected with recombinant baculovirus derived from the Autographa californica nuclear polyhedrosis virus (AcNPV). This fusion protein was composed of a metal ion binding site (His)6 for rapid one-step purification using immobilized metal affinity chromatography (IMAC), UV-optimized GFP (GFPuv), enterokinase cleavage site for recovering hIL-2 from purified fusion protein, and hIL-2 protein. The additional histidine residues on fusion protein enabled the efficient purification of fusion protein based on immobilized metal affinity chromatography. In addition to advantages of GFP as a fusion marker, GFP was able to be used as a selectable purification marker; we easily determined the correct purified fusion protein sample fraction by simply detecting GFP fluorescence.