Harnessing metabolic plasticity in CHO cells for enhanced perfusion cultivation

Matthias Nöbel, Craig Barry, Michael A. MacDonald, Kym Baker, Evan Shave, Stephen Mahler, Trent Munro, Verónica S. Martínez, Lars K. Nielsen, Esteban Marcellin

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Abstract

Chinese Hamster Ovary (CHO) cells have rapidly become a cornerstone in biopharmaceutical production. Recently, a reinvigoration of perfusion culture mode in CHO cell cultivation has been observed. However, most cell lines currently in use have been engineered and adapted for fed-batch culture methods, and may not perform optimally under perfusion conditions. To improve the cell's resilience and viability during perfusion culture, we cultured a triple knockout CHO cell line, deficient in three apoptosis related genes BAX, BAK, and BOK in a perfusion system. After 20 days of culture, the cells exhibited a halt in cell proliferation. Interestingly, following this phase of growth arrest, the cells entered a second growth phase. During this phase, the cell numbers nearly doubled, but cell specific productivity decreased. We performed a proteomics investigation, elucidating a distinct correlation between growth arrest and cell cycle arrest and showing an upregulation of the central carbon metabolism and oxidative phosphorylation. The upregulation was partially reverted during the second growth phase, likely caused by intragenerational adaptations to stresses encountered. A phase-dependent response to oxidative stress was noted, indicating glutathione has only a secondary role during cell cycle arrest. Our data provides evidence of metabolic regulation under high cell density culturing conditions and demonstrates that cell growth arrest can be overcome. The acquired insights have the potential to not only enhance our understanding of cellular metabolism but also contribute to the development of superior cell lines for perfusion cultivation.
Original languageEnglish
JournalBiotechnology and Bioengineering
Volume121
Issue number4
Pages (from-to)1370-1382
ISSN0006-3592
DOIs
Publication statusPublished - 2024

Keywords

  • Chinese Hamster Ovary cells
  • bioprocessing
  • cell cycle arrest
  • monoclonal antibodies
  • perfusion

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