Genetic manipulation of an exogenous non-immunoglobulin protein by gene conversion machinery in a chicken B cell line

During culture, a chicken B cell line DT40 spontaneously mutates immunoglobulin (Ig) genes by gene conversion, which involves activation-induced cytidine deaminase (AID)-dependent homologous recombination of the variable (V) region gene with upstream pseudo-V genes. To explore whether this mutation mechanism can target exogenous non-Ig genes, we generated DT40 lines that bears a gene conversion substrate comprising the green fluorescent protein (GFP) gene as a donor and the blue fluorescent protein (BFP) gene as an acceptor. A few percent of the initially BFP-expressing cells converted their fluorescence from blue to green after culture for 2–3 weeks when the substrate construct was integrated in the Ig light chain locus, but not in the ovalbumin locus. This was the result of AID-dependent and the GFP gene-templated gene conversion of the BFP gene, thereby leading to the introduction of various sizes of GFP-derived gene segment into the BFP gene. Thus, G/B construct may be used to visualize gene conversion events. After switching off AID expression in DT40 cells, the mutant clones were isolated stably and maintained with their mutations being fixed. Thus, the gene conversion machinery in DT40 cells will be a useful means to engineer non-Ig proteins by a type of DNA shuffling.     

超正电荷绿荧光蛋白+36GFP作为核酸载体的细胞穿透性分析

旨在通过原核表达纯化超正电荷绿色荧光蛋白+36GFP,研究其与核酸的结合作用及作为核酸载体的细胞转导功能。将pET+36GFP-HA2质粒转化到大肠杆菌BL21(DE3)菌株中,然后表达纯化+36GFP蛋白。将得到的目的蛋白在特定浓度下分别转导293细胞、HepG2细胞、A549细胞和B16细胞,流式细胞仪检测+36GFP的转导效率;+36GFP蛋白(100 nmol/L)转导A549细胞,激光共聚焦显微镜观察结果;将+36GFP蛋白与质粒DNA按不同比例孵育,凝胶阻滞实验检测+36GFP与DNA的结合能力;激光共聚焦显微镜和流式细胞仪检测+36GFP蛋白携带质粒DNA转导细胞后报告基因的表达。结果显示,+36GFP蛋白具有较高的细胞转导效率,且随浓度升高转导效率增加,呈浓度依赖性。凝胶阻滞实验显示,+36GFP能够与质粒DNA结合,阻滞DNA在凝胶中迁移,且呈现一定的浓度依赖性。+36GFP包裹质粒转导细胞后,可高效携带质粒DNA转导进入细胞,使质粒报告基因得到表达。本研究成功表达纯化了+36GFP蛋白,证实该蛋白具有较高的细胞转导效率,可将外源核酸携带入细胞使外源基因得到表达。     

Three-color imaging using fluorescent proteins in living zebrafish embryos

The zebrafish embryo is especially valuable for cell biological studies because of its optical clarity. In this system, use of an in vivo fluorescent reporter has been limited to green fluorescent protein (GFP). We have examined other fluorescent proteins alone or in conjunction with GFP to investigate their efficacy as markers for multi-labeling purposes in live zebrafish. By injecting plasmid DNA containing fluorescent protein expression cassettes, we generated single-, double-, or triple-labeled embryos using GFP, blue fluorescent protein (BFP, a color-shifted GFP), and red fluorescent protein (DsRed, a wild-type protein structurally related to GFP). Fluorescent imaging demonstrates that GFP and DsRed are highly stable proteins, exhibiting no detectable photoinstability, and a high signal-to-noise ratio. BFP demonstrated detectable photoinstability and a lower signal-to-noise ratio than either GFP or DsRed. Using appropriate filter sets, these fluorescent proteins can be independently detected even when simultaneously expressed in the same cells. Multiple labels in individual zebrafish cells open the door to a number of biological avenues of investigation, including multiple, independent tags of transgenic fish lines, lineage studies of wild-type proteins expressed using polycistronic messages, and the detection of protein-protein interactions at the subcellular level using fluorescent protein fusions.     

Oligonucleotide‐directed mutagenesis for precision gene editing

Differences in gene sequences, many of which are single nucleotide polymorphisms, underlie some of the most important traits in plants. With humanity facing significant challenges to increase global agricultural productivity, there is an urgent need to accelerate the development of these traits in plants. oligonucleotide‐directed mutagenesis (ODM), one of the many tools of Cibus’ Rapid Trait Development System ( RTDS ^?) technology, offers a rapid, precise and non‐transgenic breeding alternative for trait improvement in agriculture to address this urgent need. This review explores the application of ODM as a precision genome editing technology, with emphasis on using oligonucleotides to make targeted edits in plasmid, episomal and chromosomal DNA of bacterial, fungal, mammalian and plant systems. The process of employing ODM by way of RTDS technology has been improved in many ways by utilizing a fluorescence conversion system wherein a blue fluorescent protein (BFP) can be changed to a green fluorescent protein (GFP) by editing a single nucleotide of the BFP gene (CAC→TAC; H66 to Y66). For example, dependent on oligonucleotide length, applying oligonucleotide‐mediated technology to target the BFP transgene in Arabidopsis thaliana protoplasts resulted in up to 0.05% precisely edited GFP loci. Here, the development of traits in commercially relevant plant varieties to improve crop performance by genome editing technologies such as ODM, and by extension RTDS , is reviewed.     

Dual labeling of Pseudomonas putida with fluorescent proteins for in situ monitoring of conjugal transfer of the TOL plasmid

We describe here a dual-labeling technique involving the green fluorescent protein (GFP) and the red fluorescent protein (DsRed) for in situ monitoring of horizontal gene transfer via conjugation. A GFPmut3b-tagged derivative of narrow-host-range TOL plasmid (pWWO) was delivered to Pseudomonas putida KT2442, which was chromosomally labeled with dsRed by transposon insertion via biparental mating. Green and red fluorescent proteins were coexpressed in donor P. putida cells. Cells expressing both fluorescent proteins were smaller in size than cells expressing GFP alone. Donors and transconjugants in mixed culture or sludge samples were discriminated on the basis of their fluorescence by using confocal laser scanning microscopy. Conjugal plasmid transfer frequencies on agar surfaces and in sludge microcosms were determined microscopically without cultivation. This method worked well for in situ monitoring of horizontal gene transfer in addition to tracking the fate of microorganisms released into complex environments. To the best of our knowledge, this is the first study that discusses the coexpression of GFP and DsRed for conjugal gene transfer studies.     

Bacterial plasmid conjugation on semi-solid surfaces monitored with the green fluorescent protein (GFP) from Aequorea victoria as a marker

Horizontal transfer of the TOL plasmid was examined in Pseudomonas putida (Pp) KT2442 micro-colonies on semi-solid agar surfaces. Horizontal gene transfer is usually studied in large populations where all information is based on average estimates of the transfer events in the entire population. We have used the green fluorescent protein (GFP) from the jellyfish Aequorea victoria as a plasmid marker, in combination with single-cell observations. This provided hitherto unknown details on the distribution of cells active in conjugation. In the present study, donor cells containing the gfp gene expressed from the bacteriophage T7 Φ10 promoter on the TOL plasmid, and recipient cells expressing the corresponding phage RNA polymerase allowed us to monitor the occurrence of ex-conjugants as green fluorescent cells upon illumination with blue light (470–490 nm). Further, the recipients were labeled with the luxAB genes to distinguish micro-colonies of donor cells from recipient cells. We conclude that conjugal plasmid transfer in Pp KT2442 cells on semi-solid surfaces occurs mainly during a short period of time after the initial contact of donors and recipients, indicating that spread of the TOL plasmid is limited in static, but viable cultures.     

Dual Labeling of Pseudomonas putida with Fluorescent Proteins for In Situ Monitoring of Conjugal Transfer of the TOL Plasmid

We describe here a dual-labeling technique involving the green fluorescent protein (GFP) and the red fluorescent protein (DsRed) for in situ monitoring of horizontal gene transfer via conjugation. A GFPmut3b-tagged derivative of narrow-host-range TOL plasmid (pWWO) was delivered to Pseudomonas putida KT2442, which was chromosomally labeled with dsRed by transposon insertion via biparental mating. Green and red fluorescent proteins were coexpressed in donor P. putida cells. Cells expressing both fluorescent proteins were smaller in size than cells expressing GFP alone. Donors and transconjugants in mixed culture or sludge samples were discriminated on the basis of their fluorescence by using confocal laser scanning microscopy. Conjugal plasmid transfer frequencies on agar surfaces and in sludge microcosms were determined microscopically without cultivation. This method worked well for in situ monitoring of horizontal gene transfer in addition to tracking the fate of microorganisms released into complex environments. To the best of our knowledge, this is the first study that discusses the coexpression of GFP and DsRed for conjugal gene transfer studies.     

RNA干扰技术抑制内源性绿色荧光蛋白的表达

目的建立稳定表达绿色荧光蛋白(GFP)的细胞株;构建短发夹RNA(shRNA)表达质粒并观察其对内源性GFP的抑制作用。方法转染pEGFP-N1至HepG2细胞,利用G418筛选获得稳定表达GFP的细胞株(HepG2.GFP);设计合成针对GFP基因的siRNA对应的DNA片段,插入转录载体pTZU6 1,构建shRNA表达载体pSHGFP,转染HepG2.GFP,荧光显微镜观察细胞荧光强度,以western blot检测GFP蛋白水平,以RT-PCR检测mRNA水平。结果利用PCR方法从HepG2.GFP细胞基因组DNA中检测到GFP基因;pSHGFP能够显著抑制该细胞中GFP的表达。结论GFP基因成功整合至HepG2细胞基因组中,pSHGFP能够显著抑制内源性GFP的表达,该系统能够用于RNA干扰机制等研究中。     

GFP-reporter for a high throughput assay to monitor estrogenic compounds

In vitro test systems using yeast cells are a useful tool for the determination of the estrogenic activity of estrogens, phyto- and xeno-estrogens and can be used for monitoring large sample numbers in a routine analysis procedure. Our conventional transactivation assay functions with an expression plasmid expressing estrogen receptor α (ERα) under the control of a copper-inducible CUP1 promoter and a reporter plasmid expressing β-galactosidase under the control of the vitellogenin estrogen response element (ERE). In the novel yeast screen system the lacZ gene in the reporter plasmid was substituted by a gene for green fluorescent protein (GFP). Incubation of yeast with various concentrations of estrogenically active substances led to expression of the reporter gene product GFP in a dose dependent manner. The yeast transactivation assay was further down-scaled to be performed in a microplate scale, which is an important step to facilitate handling of large sample numbers. The sensitivity and reproducibility of the novel test system could be confirmed by analysis of the potencies of various estrogenically active substances. Thus, the newly developed yeast estrogen screen using GFP as a reporter can substitute the assay that has been used for a period of several years.     

Green fluorescent protein is superior to blue fluorescent protein as a quantitative reporter of promoter activity in <Emphasis Type="Italic">E. coli</Emphasis>

Fluorescent proteins related to and derived from green fluorescent protein (GFP) are widely used as tools for investigating a wide range of biological processes. In particular, GFP and its relatives have been used extensively as qualitative reporters of gene expression in many different organisms, but relatively few studies have investigated fluorescent proteins as quantitative reporters of gene expression. GFP has some limitations as a reporter gene, including possible toxicity when expressed at high levels. Therefore, it would be useful if other fluorescent proteins could be identified for use as quantitative reporters. Toward this end, we investigated BFP as a quantitative reporter of promoter activity in E. coli and directly compared it with GFPuv using a set of well-characterized synthetic constitutive promoters. The fluorescence produced in E. coli strains expressing GFPuv or BFP grown on solid medium was quantified using a CCD camera and fluorimetry. GFPuv consistently gave more reliable and statistically significant results than did BFP in all assays. Correspondingly, we found that the signal-to-noise ratio for GFPuv fluorescence is substantially higher than for BFP. We conclude that, under the conditions assessed in this study, GFPuv is superior to BFP as a quantitative reporter of promoter activity in E. coli. J. Bayes, M. Calvey, L. Reineke, A. Colagiavanni, and M. Tscheiner made equivalent contributions to this work.     

Characterization of Förster resonance energy transfer in a botulinum neurotoxin protease assay

Our previous article described a fluorescence-based assay for monitoring the proteolytic activity of botulinum neurotoxin types A and E (BoNT/A and BoNT/E). As detailed in that article, the assay is based on depolarization due to Förster resonance energy transfer between blue fluorescent protein (BFP) and green fluorescent protein (GFP) moieties linked via residues 134–206 of SNAP-25 (synaptosome-associated protein of 25 kDa), the protein substrate for BoNT/A and BoNT/E. Before cleavage of this recombinant substrate, the polarization observed for the GFP emission, excited near the absorption maximum of the BFP, is very low due to depolarization following energy transfer from BFP to GFP. After substrate cleavage and diffusion of the fluorescent proteins beyond the energy transfer distance, the polarization is high due to observation of the emission only from directly excited GFP. This change in fluorescence polarization allows an assay, termed DARET (depolarization after resonance energy transfer), that is robust and sensitive. In this article, we characterize the spectroscopic parameters of the system before and after substrate cleavage, including excitation and emission spectra, polarizations, and lifetimes.     

Recombination of the GFP gene to the BFP gene using a man-made site-selective DNA cutter

By using the recently developed man-made DNA cutter [a combination of Ce(IV)/EDTA and two DNA additives], green fluorescent protein (GFP) was converted to closely related blue fluorescent protein (BFP). The phosphodiester linkages at T196-A200 in the sense strand of GFP were hydrolyzed by the cutter, and the A1-T196 fragment in the product was selectively connected with the downstream fragment (C197-A720) of BFP by T4 DNA ligase. This recombination changed three codons in the GFP gene (TGC at 196–198, TAT at 199–201, and ACC at 502–504) to TCT, CAT, and ATC in BFP, and accordingly three amino acids in GFP (Cys65, Tyr66, and Thr167) were altered to Ser65, His66, and Ile167. The recombinant gene was successfully expressed in Escherichia coli and emitted blue fluorescence, confirming the absence of undesired side reactions (mutation, deletion, insertion, depurination, etc.) in the DNA manipulation. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Efficient transfection of primary zebrafish fibroblasts by nucleofection

Although various gene delivery techniques are available, their application in zebrafish cell cultures has not been extensively studied. Here, we report that nucleofection of zebrafish primary embryonic fibroblasts results in higher transfection efficiency in comparison to other non-viral gene delivery methods. The transfection was performed using green fluorescent protein (GFP) gene constructs of a different size. Greatest DNA uptake was obtained with 4.9-kb plasmid, resulting in 43% GFP positive cells. Nucleofection with 7.4-kb pH2B-GFP plasmid followed by geneticin (G418) selection was successfully used to establish a cell line expressing nuclear histone 2B-GFP fusion protein. Efficient transfection of zebrafish fibroblasts by nucleofection offers a non-viral technique of plasmid delivery and can be used to overexpress genes of interest in these cells.     

Stable expression of green fluorescent protein after liposomal transfection of K562 cells without selective growth conditions

Little is known about the durability of plasmid DNA transgene expression in mammalian cells in the absence of growth selection. For this purpose, we have begun the study of liposomal transfer and expression of plasmid DNA encoding green fluorescent protein (GFP) in human erythroleukemia K562 cells. Detection and selection of GFP expression were accomplished visually and by flow cytometry. GFP expression was noticeable in cells within 4 h of transfection. In nine separate transfections, approximately 20% of the transfected cells expressed GFP with a mean fluorescence 40-50x that of control cells (15 fluorescent units [FU] vs. 0.3 FU) during the first five days after transfection. The percentage of GFP positive cells dropped rapidly to 0.1% by day 14 post-transfection, but fluorescence activated cell sorting on this day resulted in the identification of stable transfectants expressing GFP for an additional 6-12 months in culture. GFP expression is adequate for the identification, isolation and monitoring of stable transfection events after lipid-mediated transfection of eukaryotic cells.     

Limited utility of blue fluorescent protein (BFP) in monitoring plant virus movement

While the green fluorescent protein (GFP) is a routinely used marker gene in higher plants, there are only a few data concerning the use of blue fluorescent protein (BFP). These proteins together are used for dual colour tagging experiments in various biological systems; however, the benefits of this technique in plant virology have not been exploited yet. In this work, our aim was to determine whether the BFP is a suitable second marker in conjunction with GFP for following the progress of virus infection. Nicotiana clevelandii, N. benthamiana and N. tabacum cv. Xanthi-nc plants were infected with potato virus X vector carrying the GFP or the Y66H type BFP gene. While GFP was brightly fluorescent in all species, the fluorescence intensity of BFP varied widely, from the bright fluorescence observed in N. clevelandii to the absence of fluorescence in N. tabacum cv. Xanthi-nc. Since at even mild acidic pH BFP rapidly fades, the more acidic cytosol of N. tabacum could be responsible for impaired in vivo fluorescence. After infiltration of the infected leaves of N. clevelandii with pH 5 phosphate buffer, the fluorescence faded thus confirming this situation.     

Depolarization after resonance energy transfer (DARET): a sensitive fluorescence-based assay for botulinum neurotoxin protease activity

The DARET (depolarization after resonance energy transfer) assay is a coupled Förster resonance energy transfer (FRET)–fluorescence polarization assay for botulinum neurotoxin type A or E (BoNT/A or BoNT/E) proteolytic activity that relies on a fully recombinant substrate. The substrate consists of blue fluorescent protein (BFP) and green fluorescent protein (GFP) flanking SNAP-25 (synaptosome-associated protein of 25 kDa) residues 134–206. In this assay, the substrate is excited with polarized light at 387 nm, which primarily excites the BFP, whereas emission from the GFP is monitored at 509 nm. Energy transfer from the BFP to the GFP in the intact substrate results in a substantial depolarization of the GFP emission. The energy transfer is eliminated when the fluorescent domains separate on cleavage by the endopeptidase, and emission from the directly excited GFP product fragment is then highly polarized, resulting in an overall increase in polarization. This increase in polarization can be monitored to assay the proteolytic activity of BoNT/A and BoNT/E in real time. It allows determination of the turnover rate of the substrate and the kinetic constants (V_max and k_cat) based on the concentration of cleaved substrate determined directly from the measurements using the additivity properties of polarization. The assay is amenable to high-throughput applications.     

The methyl donor S-Adenosylmethionine inhibits active demethylation of DNA: a candidate novel mechanism for the pharmacological effects of S-Adenosylmethionine

S-Adenosylmethionine (AdoMet) is the methyl donor of numerous methylation reactions. The current model is that an increased concentration of AdoMet stimulates DNA methyltransferase reactions, triggering hypermethylation and protecting the genome against global hypomethylation, a hallmark of cancer. Using an assay of active demethylation in HEK 293 cells, we show that AdoMet inhibits active demethylation and expression of an ectopically methylated CMV-GFP (green fluorescent protein) plasmid in a dose-dependent manner. The inhibition of GFP expression is specific to methylated GFP; AdoMet does not inhibit an identical but unmethylated CMV-GFP plasmid. S-Adenosylhomocysteine (AdoHcy), the product of methyltransferase reactions utilizing AdoMet does not inhibit demethylation or expression of CMV-GFP. In vitro, AdoMet but not AdoHcy inhibits methylated DNA-binding protein 2/DNA demethylase as well as endogenous demethylase activity extracted from HEK 293, suggesting that AdoMet directly inhibits demethylase activity, and that the methyl residue on AdoMet is required for its interaction with demethylase. Taken together, our data support an alternative mechanism of action for AdoMet as an inhibitor of intracellular demethylase activity, which results in hypermethylation of DNA.     

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.     

Rapid isolation and characterization of CHO mutants deficient in peroxisome biogenesis using the peroxisomal forms of fluorescent proteins

We isolated and characterized CHO mutants deficient in peroxisome assembly using green fluorescent protein (GFP) and blue fluorescent protein (BFP) as the fluorescent probes to study the molecular mechanism of peroxisome biogenesis. We used stable transformants of CHO cells expressing GFP appending peroxisome targeting signal-1 (PTS1) and/or peroxisome targeting signal-2 (PTS2) as the parent strains for rapid isolation of the mutants. We have obtained six peroxisome-deficient mutants by visual screening of the mislocalizations of the peroxisomal GFPs. Mutual cell fusion experiments indicated that the six mutants isolated were divided into four complementation groups. Several of the mutants obtained possessed defective genes: the PEX2 gene was defective in SK24 and PT54; the PEX5 gene in SK32 and the PEX7 gene in PT13 and PT32. BE41, which belonged to the fourth complementation group, was not determined. When peroxisomal forms of BFP were transiently expressed in mutant cells, the peroxisomal BFPs appending both PTS1 and PTS2 appeared to bypass either the PTS1 or PTS2 pathway for localization in SK32. This observation suggested that other important machinery, in addition to the PTS1 or PTS2 pathway, could be involved in peroxisome biogenesis. Thus, our approach using peroxisomal fluorescent proteins could facilitate the isolation and analysis of peroxisome-deficient CHO mutants and benefit studies on the identification and role of the genes responsible for peroxisome biogenesis.     

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.