Improving titer while maintaining quality of final formulated drug substance via optimization of CHO cell culture conditions in low-iron chemically defined media

ABSTRACT During biopharmaceutical process development, it is important to improve titer to reduce drug manufacturing costs and to deliver comparable quality attributes of therapeutic proteins, which helps to ensure patient safety and efficacy. We previously reported that relative high-iron concentrations in media increased titer, but caused unacceptable coloration of a fusion protein during early-phase process development. Ultimately, the fusion protein with acceptable color was manufactured using low-iron media, but the titer decreased significantly in the low-iron process. Here, long-term passaging in low-iron media is shown to significantly improve titer while maintaining acceptable coloration during late-phase process development. However, the long-term passaging also caused a change in the protein charge variant profile by significantly increasing basic variants. Thus, we systematically studied the effect of media components, seed culture conditions, and downstream processing on productivity and quality attributes. We found that removing β-glycerol phosphate (BGP) from basal media reduced basic variants without affecting titer. Our goals for late-phase process development, improving titer and matching quality attributes to the early-phase process, were thus achieved by prolonging seed culture age and removing BGP. This process was also successfully scaled up in 500-L bioreactors. In addition, we demonstrated that higher concentrations of reactive oxygen species were present in the high-iron Chinese hamster ovary cell cultures compared to that in the low-iron cultures, suggesting a possible mechanism for the drug substance coloration caused by high-iron media. Finally, hypotheses for the mechanisms of titer improvement by both high-iron and long-term culture are discussed.

[1]  Yantian Chen,et al.  Different fermentation processes produced variants of an anti-CD52 monoclonal antibody that have divergent in vitro and in vivo characteristics , 2017, Applied Microbiology and Biotechnology.

[2]  Hiroaki Nagashima,et al.  Effect of temperature shift on levels of acidic charge variants in IgG monoclonal antibodies in Chinese hamster ovary cell culture. , 2015, Journal of bioscience and bioengineering.

[3]  M. Hentze,et al.  Balancing Acts Molecular Control of Mammalian Iron Metabolism , 2004, Cell.

[4]  N. Lewen,et al.  Brown drug substance color investigation in cell culture manufacturing using chemically defined media: A case study , 2014 .

[5]  J. Zwiller,et al.  Iron-induced L1210 cell growth: evidence of a transferrin-independent iron transport. , 1986, Cancer research.

[6]  P. Aisen,et al.  Chemistry and biology of eukaryotic iron metabolism. , 2001, The international journal of biochemistry & cell biology.

[7]  Effects of high passage cultivation on CHO cells: a global analysis , 2012, Applied Microbiology and Biotechnology.

[8]  K. Fujimori,et al.  Hydroxocobalamin association during cell culture results in pink therapeutic proteins , 2013, mAbs.

[9]  Thomas Ryll,et al.  Maximizing productivity of CHO cell‐based fed‐batch culture using chemically defined media conditions and typical manufacturing equipment , 2010, Biotechnology progress.

[10]  Wai Lam W Ling,et al.  Role of iron and sodium citrate in animal protein‐free CHO cell culture medium on cell growth and monoclonal antibody production , 2011, Biotechnology progress.

[11]  J. Poetzl,et al.  GP2015, a proposed etanercept biosimilar: Pharmacokinetic similarity to its reference product and comparison of its autoinjector device with prefilled syringes , 2016, British journal of clinical pharmacology.

[12]  R. Hanning,et al.  In vitro solubility of calcium glycerophosphate versus conventional mineral salts in pediatric parenteral nutrition solutions. , 1989, Journal of pediatric gastroenterology and nutrition.

[13]  T. Omasa,et al.  The enhancement of antibody concentration and achievement of high cell density CHO cell cultivation by adding nucleoside , 2017, Cytotechnology.

[14]  P. Rohrbach,et al.  The Rapeutic Antibodies and Antibody Fusion Proteins , 2003, Biotechnology & genetic engineering reviews.

[15]  Marcella Yu,et al.  Effects of cell culture conditions on antibody N‐linked glycosylation—what affects high mannose 5 glycoform , 2011, Biotechnology and bioengineering.

[16]  R. Field,et al.  THE USE OF 2-HYDROXY-2,4,6-CYCLOHEPTARIN-l-ONE (TROPOLONE) AS A REPLACEMENT FOR TRANSFERRIN , 1994 .

[17]  Feng Li,et al.  Cell culture processes for monoclonal antibody production , 2010, mAbs.

[18]  B. Fitzpatrick,et al.  Manufacturing history of etanercept (Enbrel®): Consistency of product quality through major process revisions , 2018, mAbs.

[19]  Michael C. Borys,et al.  Optimizing amino acid composition of CHO cell culture media for a fusion protein production , 2011 .

[20]  J. Musilkova,et al.  Additive stimulatory effect of extracellular calcium and potassium on non-transferrin ferric iron uptake by HeLa and K562 cells. , 2001, Biochimica et biophysica acta.

[21]  J. Reichert,et al.  Evolution of Antibody Therapeutics , 2017 .

[22]  Martin Gawlitzek,et al.  Effect of cell culture medium components on color of formulated monoclonal antibody drug substance , 2013, Biotechnology progress.

[23]  Gary Walsh,et al.  Biopharmaceutical benchmarks , 2000, Nature Biotechnology.

[24]  L. Berrino,et al.  Biosimilars in the European Union from comparability exercise to real world experience: What we achieved and what we still need to achieve. , 2017, Pharmacological research.

[25]  Chung-Jr Huang,et al.  A robust method for increasing Fc glycan high mannose level of recombinant antibodies , 2015, Biotechnology and bioengineering.

[26]  P. Salmon,et al.  A novel function for selenium in biological system: Selenite as a highly effective iron carrier for Chinese hamster ovary cell growth and monoclonal antibody production , 2006, Biotechnology and bioengineering.

[27]  Michael C. Borys,et al.  Vitamin B12 association with mAbs: Mechanism and potential mitigation strategies , 2018, Biotechnology and bioengineering.

[28]  M. Wessling-Resnick,et al.  Characterization of transferrin-independent iron transport in K562 cells. Unique properties provide evidence for multiple pathways of iron uptake. , 1993, The Journal of biological chemistry.

[29]  Ashraf Amanullah,et al.  Characterization of the basic charge variants of a human IgG1 , 2011, mAbs.

[30]  Z. Li,et al.  Investigation of Color in a Fusion Protein Using Advanced Analytical Techniques: Delineating Contributions from Oxidation Products and Process Related Impurities , 2016, Pharmaceutical Research.

[31]  Jared T. Broddrick,et al.  Red colored IgG4 caused by vitamin B12 from cell culture media combined with disulfide reduction at harvest , 2014, mAbs.

[32]  L. S. Young,et al.  Effect of process change from perfusion to fed-batch on product comparability for biosimilar monoclonal antibody , 2012 .

[33]  B. Snedecor,et al.  FX knockout CHO hosts can express desired ratios of fucosylated or afucosylated antibodies with high titers and comparable product quality , 2017, Biotechnology and bioengineering.

[34]  R. Kelley,et al.  Framework selection can influence pharmacokinetics of a humanized therapeutic antibody through differences in molecule charge , 2014, mAbs.

[35]  M. Butler,et al.  A semi-empirical glycosylation model of a camelid monoclonal antibody under hypothermia cell culture conditions , 2017, Journal of Industrial Microbiology & Biotechnology.

[36]  W. Xu,et al.  Chromatographic analysis of the acidic and basic species of recombinant monoclonal antibodies , 2012, mAbs.

[37]  Ashraf Amanullah,et al.  Comparative metabolite analysis to understand lactate metabolism shift in Chinese hamster ovary cell culture process , 2012, Biotechnology and bioengineering.

[38]  Fatemeh Torkashvand,et al.  Main Quality Attributes of Monoclonal Antibodies and Effect of Cell Culture Components , 2017, Iranian biomedical journal.

[39]  Nicholas R. Abu-Absi,et al.  Effects of culture conditions on N‐glycolylneuraminic acid (Neu5Gc) content of a recombinant fusion protein produced in CHO cells , 2010, Biotechnology and bioengineering.

[40]  Martin Gawlitzek,et al.  Identification of cell culture conditions to control N‐glycosylation site‐occupancy of recombinant glycoproteins expressed in CHO cells , 2009, Biotechnology and bioengineering.

[41]  F. Wurm CHO Quasispecies—Implications for Manufacturing Processes , 2013 .

[42]  D. Richardson,et al.  Growth of human tumor cell lines in transferrin-free, low-iron medium , 1995, In Vitro Cellular & Developmental Biology - Animal.

[43]  C. Craven,et al.  Characterization of a transferrin-independent uptake system for iron in HeLa cells. , 1990, The Journal of biological chemistry.

[44]  Gary Walsh,et al.  Biopharmaceutical benchmarks 2014 , 2014, Nature Biotechnology.

[45]  Kurt Brorson,et al.  N-Glycosylation Design and Control of Therapeutic Monoclonal Antibodies. , 2016, Trends in biotechnology.

[46]  Chris Chumsae,et al.  When Good Intentions Go Awry: Modification of a Recombinant Monoclonal Antibody in Chemically Defined Cell Culture by Xylosone, an Oxidative Product of Ascorbic Acid. , 2015, Analytical chemistry.

[47]  Sen Xu,et al.  Improving lactate metabolism in an intensified CHO culture process: productivity and product quality considerations , 2016, Bioprocess and Biosystems Engineering.

[48]  Chris Chumsae,et al.  Cell culture media supplementation of bioflavonoids for the targeted reduction of acidic species charge variants on recombinant therapeutic proteins , 2015, Biotechnology progress.