A human expression system based on HEK293 for the stable production of recombinant erythropoietin

Chin, Christine Lin; Goh, Justin B.; Srinivasan, Harini; Liu, Kaiwen Ivy; Ali, Gowher; Shanmugam, Raghuvaran; Lim, Hsueh Lee; Choo, Matthew S F; Tang, Wen Qin; Tan, Andy Hee-Meng; Nguyen-Khuong, Terry; Tan, Meng How; Ng, Say Kong

doi:10.1038/s41598-019-53391-z

Cited by 42 publications

(45 citation statements)

References 53 publications

(65 reference statements)

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“…39,[44][45][46] The specific cell productivities observed in our four stable clone cultures (5.33 +/-0.7 pg cell -1 day -1 ) were above the range of values obtained in previous studies that used similar or more complex cell engineering strategies on HEK cells. 35,47,48 These titer, productivity, and specific productivity values are competitive for experimental cultures but still distant (although in the same order of magnitude) from those expected for commercial scale production (approximately 20-40 pg cell -1 day -1 ). 43 We anticipate that the application of standard optimization protocols (i.e., fed-batch feeding protocols) could enhance productivity by at least one order of magnitude.…”

Section: Generation Of Hek293 Cells With Stable Expression Of Mab13c6mentioning

confidence: 87%

“…43 Further optimization is expected from adaptation of the clones to suspended culture conditions and development of perfusion feeding protocols. These two optimization stages frequently result in a titer enhancement of at least two orders of magnitude 48 . The methodologies presented here can be directly generalized to any other mAb and easily adapted to any other glycosylated protein.…”

Section: Discussionmentioning

confidence: 99%

“…43 We anticipate that the application of standard optimization protocols (i.e., fed-batch feeding protocols) could enhance productivity by at least one order of magnitude. 49,50 Further enhancement is possible by translating to suspended culture in instrumented bioreactors 48,51 or culturing by continuous perfusion in cell adherent culture systems.…”

Section: Generation Of Hek293 Cells With Stable Expression Of Mab13c6mentioning

confidence: 99%

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Rapid and cost-effective development of stable clones for the production of anti-Ebola monoclonal antibodies in HEK293T cells

Gonzalez‐González

Palestino-Díaz

López-Pacheco

et al. 2020

Preprint

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The Ebola virus (EBOV) disease has caused serious and recurrent epidemics in recent years, resulting in a fatality rate of nearly 50%. The most effective experimental therapy against the EBOV is the use of monoclonal antibodies (mAbs). In this work, we describe the development of HEK293T cells engineered for the transient and stable expression of mAb13C6, a neutralizing anti-EBOV monoclonal antibody. We transfected the HEK293T cells with a tricistronic vector to produce the heavy and the light chain of the antibody 13C6 and intracellular Green Fluorescent Protein (GFP) using Lipofectamine 3000. We then selected the transfected cells using puromycin pressure, dilution cloning, and cloning disks. This integrated strategy generated mAb-producing cells in 7 days with a transient expression of ~1 mg/L. Stable pools were produced after 4 weeks, with expression levels of ~0.8 mg/L. Stable clones with expression levels of ~1.8 mg/L were obtained within 10 weeks. The produced antibodies exhibited the expected functionality; they recognized the GP glycoprotein of the Ebola virus in both ELISA assays and cell binding experiments using HEK293T cells engineered to express the EBOV GP at their membrane surface. By the combined use of GFP and the set of selection techniques here described, we drastically reduced the time from transfection to stable clone generation without resorting to costly equipment. In outbreaks or emergencies, this platform can significantly shorten the development of new biopharmaceuticals and vaccines.

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Section: Generation Of Hek293 Cells With Stable Expression Of Mab13c6mentioning

confidence: 87%

Section: Discussionmentioning

confidence: 99%

Section: Generation Of Hek293 Cells With Stable Expression Of Mab13c6mentioning

confidence: 99%

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Rapid and cost-effective development of stable clones for the production of anti-Ebola monoclonal antibodies in HEK293T cells

Gonzalez‐González

Palestino-Díaz

López-Pacheco

et al. 2020

Preprint

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“…This fact indicates that the gene release rates of gene complexes could differentially affect cells to express transgenes depending on the cell. HEK293 cells, a human embryonic kidney cell line, have often been used to transfect genes of interest in biological experiments and to produce recombinant proteins due to their high and stable gene expressing capability [ 29 , 30 ]. On the other hand, although HepG2 cells (a human hepatocellular carcinoma cell line) have been used as a well-known and suitable in vitro model of human hepatocytes to understand cellular functions and disease mechanisms [ 31 , 32 ], their gene of interest expression levels are poor.…”

Section: Introductionmentioning

confidence: 99%

Effects of Decomplexation Rates on Ternary Gene Complex Transfection with α-Poly(l-Lysine) or ε-Poly(l-Lysine) as a Decomplexation Controller in An Easy-To-Transfect Cell or A Hard-To-Transfect Cell

et al. 2020

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The tight binding of pDNA with a cationic polymer is the crucial requirement that prevents DNA degradation from undesired DNase attack to safely deliver the pDNA to its target site. However, cationic polymer-mediated strong gene holding limits pDNA dissociation from the gene complex, resulting in a reduction in transfection efficiency. In this study, to control the decomplexation rate of pDNA from the gene complex in a hard-to-transfect cell or an easy-to-transfect cell, either α-poly(l-lysine) (APL) or ε-poly(l-lysine) (EPL) was incorporated into branched polyethylenimine (bPEI)-based nanocomplexes (NCs). Compared to bPEI/pDNA NCs, the addition of APL or EPL formed smaller bPEI-APL/pDNA NCs with similar zeta potentials or larger bPEI-EPL/pDNA NCs with reduced zeta potentials, respectively, due to the different characteristics of the primary amines in the two poly(l-lysine)s (PLs). Interestingly, although both bPEI-APL/pDNA NCs and bPEI-EPL/pDNA NCs showed similar pDNA compactness to bPEI/pDNA NCs, the addition of APL or EPL resulted in slower or faster pDNA release, respectively, from the bPEI-PL/pDNA NCs than from the bPEI/pDNA NCs. bPEI-EPL/pDNA NCs with a decomplexation enhancer (i.e., EPL) improved the transfection efficiency (TE) in both a hard-to-transfect HepG2 cell and an easy-to-transfect HEK293 cell. However, although a decomplexation inhibitor (i.e., APL) reduced the TE of bPEI-APL/pDNA NCs in both cells, the degree of reduction in the TE could be compensated by PL-mediated enhanced nuclear delivery, particularly in HepG2 cells but not HEK293 cells, because both PLs facilitate nuclear localization of the gene complex per its cellular uptake. In conclusion, a decomplexation rate controller could be a potential factor to establish a high TE and design clinically available gene complex systems.

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“…Although human derived cell-lines benefit from the ability to generate human PTMs, challenges still remain, such as increasing the protein production titer (Chin et al, 2019;Dietmair et al, 2012;Mori et al, 2020) and creating a genetic engineering toolbox with specialized tools for human cells (Xu and Qi, 2019). Recent publications have pursued some of these challenges, including the aim to increase the protein production and secretion power either by cell-line development approaches (Chin et al, 2019;Rahimpour et al, 2013) or cell culture process optimization (Schwarz et al, 2019), as well as to increase the quality of the secreted proteins by engineering folding and PTM pathways (Behrouz et al, 2020;Del Val et al, 2016;Liang et al, 2020;Meuris et al, 2014). However, despite the current knowledge of protein production and secretion in mammalian cells, there is still notable ambiguity in understanding and predicting the production and secretion rates and product quality under different conditions.…”

mentioning

confidence: 99%

Transcriptome analysis of EPO and GFP HEK293 Cell-lines Reveal Shifts in Energy and ER Capacity Support Improved Erythropoietin Production in HEK293F Cells

Saghaleyni

Malm

Zrimec

et al. 2020

Preprint

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SummaryHigher eukaryotic cell lines like HEK293 are the preferred hosts for production of therapeutic proteins requiring human post translational processing. However, recombinant protein production can result in severe stress on the cellular machinery, resulting in limited titre and product quality. To investigate the cellular and metabolic characteristics associated with these limitations, we compared erythropoietin (secretory) and GFP (non-secretory) protein producer HEK293 cell-lines using transcriptomics analysis. Despite the high demand for ATP in all protein producer clones, a significantly higher capacity for ATP production was observed with erythropoietin producers as evidenced by the enrichment of upregulated genes in the oxidative phosphorylation pathway. In addition, ribosomal genes exhibited specific patterns of expression depending on the recombinant protein and the production rate. In a clone displaying a dramatically increased erythropoietin secretion, we detected higher ER stress, including upregulation of the ATF6B gene. Our results are significant in recognizing key pathways for recombinant protein production and identifying potential target genes for further development of secretory power in mammalian cell factories.In BriefAlthough the protein secretion process has been widely studied, the complexity of it leaves many questions with regards to defining bottlenecks for successful protein secretion to be answered. By investigating the transcriptomic profiles of different HEK293 clones with varying translational rates producing either the secreted protein erythropoietin or the intracellular GFP, we reveal that high ATP production and improved capacity of specific post-translational pathways are key factors associated with boosting erythropoietin production.HighlightsTranscriptomics analysis of a panel of HEK293 stable cell lines expressing GFP or erythropoietin (EPO) at varying translational ratesExpression of mitochondrial ribosomal genes is positively correlated with EPO secretionExpression of different cytosolic ribosomal genes are correlated with productivity in a recombinant-protein specific mannerHigh EPO producing clones have significant upregulation of ATF6B, potentially enabling a beneficial ER stress response to cope with high protein secretionGraphical Abstract

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A human expression system based on HEK293 for the stable production of recombinant erythropoietin

Cited by 42 publications

References 53 publications

Rapid and cost-effective development of stable clones for the production of anti-Ebola monoclonal antibodies in HEK293T cells

Rapid and cost-effective development of stable clones for the production of anti-Ebola monoclonal antibodies in HEK293T cells

Effects of Decomplexation Rates on Ternary Gene Complex Transfection with α-Poly(l-Lysine) or ε-Poly(l-Lysine) as a Decomplexation Controller in An Easy-To-Transfect Cell or A Hard-To-Transfect Cell

Transcriptome analysis of EPO and GFP HEK293 Cell-lines Reveal Shifts in Energy and ER Capacity Support Improved Erythropoietin Production in HEK293F Cells

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