A GFP-based method facilitates clonal selection of transfected CHO cells

The identification of highly expressing clones is a crucial step in the development of cell lines for production of recombinant proteins. Here we present a method based on the co-expression of enhanced green fluorescent protein (EGFP) that allows clonal selection in standard 96-well cell culture plates. The genes encoding the EGFP protein and the protein of interest are linked by an internal ribosome entry site and thus are transcribed into the same mRNA but are translated independently. Since both proteins arise from a common mRNA, the EGFP expression level correlates with the expression level of the therapeutic protein for each clone. By expressing recombinant growth factors in CHO cells, we demonstrate the robustness and performance of this technique. The method is an alternative to the identification of high-producer clones using various cell sorting methods, as it can be performed with standard laboratory equipment.     

Fluorescent labeling in semi-solid medium for selection of mammalian cells secreting high-levels of recombinant proteins

Background  

Despite the powerful impact in recent years of gene expression markers like the green fluorescent protein (GFP) to link the expression of recombinant protein for selection of high producers, there is a strong incentive to develop rapid and efficient methods for isolating mammalian cell clones secreting high levels of marker-free recombinant proteins. Recently, a method combining cell colony growth in methylcellulose-based medium with detection by a fluorescently labeled secondary antibody or antigen has shown promise for the selection of Chinese Hamster Ovary (CHO) cell lines secreting recombinant antibodies. Here we report an extension of this method referred to as fluorescent labeling in semi-solid medium (FLSSM) to detect recombinant proteins significantly smaller than antibodies, such as IGF-E5, a 25 kDa insulin-like growth factor derivative.     

Green fluorescent protein as a second selectable marker for selection of high producing clones from transfected CHO cells

Mammalian cells are often used for the expression of recombinant proteins. The process of screening transfected cells randomly for high producing clones is tedious and time consuming. We evaluated using green fluorescent protein (GFP) for selection of high producing clones by fluorescence-activated cell sorter (FACS) to reduce screening effort. We expressed neurotrophin-3 (NT3), deoxyribonuclease (DNase), or vascular endothelial growth factor (VEGF) with GFP in Chinese hamster ovary cells. The vector expressed the desired secreted protein and the selectable marker, dihydrofolate reductase, in one expression unit and the intracellular GFP in a second expression unit. Transfected cells were grown in selection medium and sorted by FACS. High fluorescence clones were obtained and found to produce high amounts of the desired protein; VEGF productivity correlated well with GFP fluorescence in 48 clones. Further studies demonstrated that productivity correlated very well with RNA of the desired protein. For comparison, we randomly picked and screened 144 VEGF clones, and the highest producing VEGF clone obtained produced 0.7 pg/cell/day. In contrast, the highest producing VEGF clone obtained by FACS sorting produced 4.4 pg/cell/day. FACS sorting therefore selected high producing clones efficiently. Since an assay for the desired protein is not required, high producing clones for a protein of unknown function can be obtained by FACS sorting followed by measuring the RNA level of the desired protein in the highly fluorescent clones.     

Utilization of non-AUG initiation codons in a flow cytometric method for efficient selection of recombinant cell lines

Here we describe a method that couples flow cytometric detection with the attenuated translation of a reporter protein to enable efficient selection of CHO clones producing high levels of recombinant proteins. In this system, a small cell surface reporter protein is expressed from an upstream open reading frame utilizing a non-AUG initiation (alternate start) codon. Due to the low translation initiation efficiency of this alternate start codon, the majority of translation initiation events occur at the first AUG of the downstream open reading frame encoding the recombinant protein of interest. While translation of the reporter is significantly reduced, the levels are sufficient for detection using flow cytometric methods and, in turn, predictive of protein expression from the gene of interest since both ORFs are translated from the same mRNA. Using this system, CHO cells have been sorted to obtain enriched pools producing significantly higher levels of recombinant proteins than the starting cell population and clones with significantly better productivity than those generated from limiting dilution cloning. This method also serves as an effective screening tool during clone expansion to enable resources to be focused solely on clones with both high and stable expression.     

A toolkit for graded expression of green fluorescent protein fusion proteins in mammalian cells

Green fluorescent protein (GFP) and GFP-like proteins of different colors are important tools in cell biology. In many studies, the intracellular targeting of proteins has been determined by transiently expressing GFP fusion proteins and analyzing their intracellular localization by fluorescence microscopy. In most vectors, expression of GFP is driven by the enhancer/promoter cassette of the immediate early gene of human cytomegalovirus (hCMV). This cassette generates high levels of protein expression in most mammalian cell lines. Unfortunately, these nonphysiologically high protein levels have been repeatedly reported to artificially alter the intracellular targeting of proteins fused to GFP. To cope with this problem, we generated a multitude of attenuated GFP expression vectors by modifying the hCMV enhancer/promoter cassette. These modified vectors were transiently expressed, and the expression levels of enhanced green fluorescent protein (EGFP) alone and enhanced yellow fluorescent protein (EYFP) fused to another protein were determined by fluorescence microscopy and/or Western blotting. As shown in this study, we were able to (i) clearly reduce the expression of EGFP alone and (ii) reduce expression of an EYFP fusion protein down to the level of the endogenous protein, both in a graded manner.     

Selectable high‐yield recombinant protein production in human cells using a GFP/YFP nanobody affinity support

Recombinant protein expression systems that produce high yields of pure proteins and multi‐protein complexes are essential to meet the needs of biologists, biochemists, and structural biologists using X‐ray crystallography and cryo‐electron microscopy. An ideal expression system for recombinant human proteins is cultured human cells where the correct translation and chaperone machinery are present. However, compared to bacterial expression systems, human cell cultures present several technical challenges to their use as an expression system. We developed a method that utilizes a YFP fusion‐tag to generate recombinant proteins using suspension‐cultured HEK293F cells. YFP is a dual‐function tag that enables direct visualization and fluorescence‐based selection of high expressing clones for and rapid purification using a high‐stringency, high‐affinity anti‐GFP/YFP nanobody support. We demonstrate the utility of this system by expressing two large human proteins, TOP2α (340 KDa dimer) and a TOP2β catalytic core (260 KDa dimer). This robustly and reproducibly yields >10 mg/L liter of cell culture using transient expression or 2.5 mg/L using stable expression.     

Production of cell lines secreting TAT fusion proteins.

Transduction of proteins and other macromolecules constitutes a potent technology to analyze cell functions and to achieve therapeutic interventions. In general, fusion proteins with protein transduction domains, such as TAT, are produced in a bacterial expression system. Here we describe the generation of a mammalian expression vector coding for TAT-EGFP fusion protein. Transfection of CHO-K1 cells by this vector and subsequent selection by Zeocin resulted in cell lines that express and secrete EGFP, a variant of the green fluorescent protein GFP. The ultimate cell line was produced by first cloning the stable integrants and subsequent selection of EGFP-expressing cells by flow cytometric sorting. In the resulting cell line approximately 98% of cells express EGFP. Using the same methodology, we generated cell lines that express DsRed fluorescent protein. The advantages of using such a mammalian expression system include the ease of generating TAT fusion proteins and the potential for sustained production of such proteins in vitro and, potentially, in vivo.     

Practical protocols for production of very high yields of recombinant proteins using Escherichia coli

The gram‐negative bacterium Escherichia coli offers a mean for rapid, high yield, and economical production of recombinant proteins. However, high‐level production of functional eukaryotic proteins in E. coli may not be a routine matter, sometimes it is quite challenging. Techniques to optimize heterologous protein overproduction in E. coli have been explored for host strain selection, plasmid copy numbers, promoter selection, mRNA stability, and codon usage, significantly enhancing the yields of the foreign eukaryotic proteins. We have been working on optimizations of bacterial expression conditions and media with a focus on achieving very high cell density for high‐level production of eukaryotic proteins. Two high‐cell‐density bacterial expression methods have been explored, including an autoinduction introduced by Studier (Protein Expr Purif 2005;41:207–234) recently and a high‐cell‐density IPTG‐induction method described in this study, to achieve a cell‐density OD₆₀₀ of 10–20 in the normal laboratory setting using a regular incubator shaker. Several practical protocols have been implemented with these high‐cell‐density expression methods to ensure a very high yield of recombinant protein production. With our methods and protocols, we routinely obtain 14–25 mg of NMR triple‐labeled proteins and 17–34 mg of unlabeled proteins from a 50‐mL cell culture for all seven proteins we tested. Such a high protein yield used the same DNA constructs, bacterial strains, and a regular incubator shaker and no fermentor is necessary. More importantly, these methods allow us to consistently obtain such a high yield of recombinant proteins using E. coli expression.     

Accelerated clone selection for recombinant CHO CELLS using a FACS-based high-throughput screen

Flow cytometry was partnered with a nonfluorescent reporter protein for rapid, early stage identification of clones producing high levels of a therapeutic protein. A cell surface protein, not normally expressed on CHO cells, is coexpressed, as a reporter, with the therapeutic protein and detected using a fluorescently labeled antibody. The genes encoding the reporter protein and the therapeutic protein are linked by an IRES, so that they are transcribed in the same mRNA but are translated independently. Since they each arise from a common mRNA, the reporter protein's expression level accurately predicts the relative expression level of the therapeutic protein for each clone. This method provides an effective process for generating recombinant cell lines producing high levels of therapeutic proteins, with the benefits of rapid and accurate 96-well plate clone screening and elimination of unstable clones at an earlier stage in the development process. Furthermore, because this method does not rely on the availability of an antibody specific for the therapeutic protein being expressed, it can be easily implemented into any cell line development process.     

Rapid production of a chimeric antibody-antigen fusion protein based on 2A-peptide cleavage and green fluorescent protein expression in CHO cells

To enable large-scale antibody production, the creation of a stable, high producer cell line is essential. This process often takes longer than 6 months using standard limited dilution techniques and is very labor intensive. The use of a tri-cistronic vector expressing green fluorescent protein (GFP) and both antibody chains, separated by a GT2A peptide sequence, allows expression of all proteins under a single promotor in equimolar ratios. By combining the advantages of 2A peptide cleavage and single cell sorting, a chimeric antibody-antigen fusion protein that contained the variable domains of mouse IgG with a porcine IgA constant domain fused to the FedF antigen could be produced in CHO-K1 cells. After transfection, a strong correlation was found between antibody production and GFP expression (r = 0.69) using image analysis of formed monolayer patches. This enables the rapid selection of GFP-positive clones using automated image analysis for the selection of high producer clones. This vector design allowed the rapid selection of high producer clones within a time-frame of 4 weeks after transfection. The highest producing clone had a specific antibody productivity of 2.32 pg/cell/day. Concentrations of 34 mg/L were obtained using shake-flask batch culture. The produced recombinant antibody showed stable expression, binding and minimal degradation. In the future, this antibody will be assessed for its effectiveness as an oral vaccine antigen.     

A one-step approach to obtain cell clones expressing tetracycline-responsive transactivators

Despite the wide application of the tetracycline-regulated gene expression system, several drawbacks in establishing the system in in vitro-cultured cells have been described. Most of the problems are related to obtaining a reliable tetracycline-regulated cell clone, which often results in arduous labor. We describe here a new approach to facilitate the screening and selection of such cell clones. We have constructed a tetracycline-responsive plasmid that harbors an antibiotic resistance gene fused to the enhanced green fluorescent protein (EGFP) gene and the luciferase gene, both under the control of a bidirectional promoter. We demonstrate that the selection of tetracycline-regulated clones is highly simplified by using this plasmid. Only clones expressing the system in a functional manner are able to survive under antibiotic selection. In addition, a quick characterization of the responsiveness of the clones is possible by monitoring GFP expression 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.     

Efficient generation of stably electrotransfected human hematopoietic cell lines without drug selection by consecutive FACsorting

BACKGROUND: Current methods to establish stably transfected cell lines by nonviral techniques involve coselection for a drug selection marker. However, this approach suffers from several drawbacks. We developed a fluorescence-activated cell sorting (FACS)-based protocol for the selection and isolation of stable hematopoietic electrotransfectants without the need for selective growth conditions. METHODS: Leukemic K562 cells were electroporated with the enhanced green fluorescent protein (EGFP) reporter gene and FACsorted to obtain stably EGFP-expressing cells. Stable EGFP(+) clones were established by single-cell sorting. RESULTS: Efficiency of stable EGFP gene expression increased steadily in function of number of consecutive FACsorts. Stable transfectants (>99% EGFP(+)) were obtained after four FACsorts. Furthermore, several single-cell derived clones with variable levels of stable EGFP expression were isolated and cultured without the use of selective growth media. CONCLUSIONS: EGFP is an effective selection marker for the generation and isolation of stably transfected hematopoietic cell clones without the need for selection in toxic media that could create a potentially undesirable stress environment for stably transfected cells.     

Development of a novel ER stress based selection system for the isolation of highly productive clones

Most biotherapeutic drugs are recombinant monoclonal antibodies which are mostly produced in monoclonal cell lines derived from Chinese hamster ovary (CHO) cells. Various clones expressing a monoclonal recombinant antibody were analyzed and a correlation of the antibody concentration and the relative mRNA level of calreticulin (CALR), glucose‐regulated protein 78 and 94 kDa (GRP78, GRP94) and spliced X‐box binding protein 1 (XPB1) was observed. By means of these results we were motivated to establish a novel selection system based on endoplasmic reticulum (ER) stress, which allows the rapid identification and isolation of high‐expressing clones out of a pool mainly consisting of low‐ and medium‐producing cells. Several ER stress responsive elements were tested with the aid of a recombinase mediated cassette exchange (RMCE) procedure. Very surprisingly, only GRP78 reporter constructs were strongly stimulated upon antibody expression. Furthermore we found that GRP78 reporter constructs are very suitable to reflect the level of antibody expression (IgG) in recombinant CHO cells. Based on these results, it is concluded, that the novel ER stress based selection system developed during this study is suitable to identify and isolate clones with a high level of antibody expression. Biotechnol. Bioeng. 2012; 109: 2599–2611. © 2012 Wiley Periodicals, Inc.     

Purification of GFP fusion proteins with high purity and yield by monoclonal antibody-coupled affinity column chromatography

GFP has often been used as a marker of gene expression, protein localization in living and fixed tissues as well as for protein targeting in intact cells and organisms. Monitoring foreign protein expression via GFP fusion is also very appealing for bioprocess applications. Many cells, including bacterial, fungal, plant, insect and mammalian cells, can express recombinant GFP (rGFP) efficiently. Several methods and procedures have been developed to purify the rGFP or recombinant proteins fused with GFP tag. However, most current GFP purification methods are limited by poor yields and low purity. In the current study, we developed an improved purification method, utilizing a FMU-GFP.5 monoclonal antibody (mAb) to GFP together with a mAb-coupled affinity chromatography column. The method resulted in a sample that was highly pure (more than 97% homogeneity) and had a sample yield of about 90%. Moreover, the GFP epitope permitted the isolation of almost all the active recombinant target proteins fused with GFP, directly and easily, from the crude cellular sources. Our data suggests this method is more efficient than any currently available method for purification of GFP protein.     

High-throughput clonal selection of recombinant CHO cells using a dominant selectable and amplifiable metallothionein-GFP fusion protein

Transfected mammalian cells can be used for the production of fully processed recombinant proteins for medical and industrial purposes. However, the isolation of high-producing clones is traditionally time-consuming. Therefore, we developed a high-throughput screening method to reduce the time and effort required to isolate high-producing cells. This involved the construction of an expression vector containing the amplifiable gene metallothionein (MT), fused in-frame to green fluorescent protein (GFP). The fusion gene (MTGFP) confers metal resistance similar to that of the wild-type metallothionein and expression can be monitored using either flow cytometry or a fluorometer to measure green fluorescence. Expression of MTGFP acted as a dominant selectable marker allowing rapid and more efficient selection of clones at defined metal concentrations than with the antibiotic G418. Cells harboring MTGFP responded to increasing metal concentrations with a corresponding increase in fluorescence. There was also a corresponding increase in recombinant protein production, indicating that MTGFP could be used as a selectable and amplifiable gene for the coexpression of foreign genes. Using our expression vector encoding MTGFP, we demonstrate a high-throughput clonal selection protocol for the rapid isolation of high-producing clones from transfected CHO cells. We were able to isolate cell lines reaching specific productivities of >10 microg hGH/10(6) cells/day within 4 weeks of transfection. The advantage of this method is that it can be easily adapted for automated procedures using robotic handling systems.     

Simple Purification of a Foreign Protein Using Polyhedrin Fusion in a Baculovirus Expression System

Previously, we found that expression by translational fusion of the polyhedrin (Polh)-green fluorescence protein (GFP) led to the formation of granular structures, and that these fluorescent granules were easily precipitated by high-speed centrifugation. Here, we developed an easy, fast, mass purification system using this baculovirus expression system (BES). An enhanced GFP (EGFP) fused with the Polh gene at the N-terminus, including a linker and enterokinase (EK) site between Polh and EGFP, was expressed in Sf9 cells. The cells infected by AcPolhEKA-EGFP produced fluorescent granules. The EGFP fusion protein was purified from granule-containing cells in three steps: cell harvest, sonication, and EK digestion. Through final enterokinase digestion, EGFP presented mainly in the supernatant, and this supernatant fraction also showed a pure EGFP band. These results suggest that a combined procedure of Polh fusion expression and enterokinase digestion can be used for rapid and easy purification of other proteins.