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Combining Regulated and Constitutive Protein Expression Significantly Boosts Protein Expression by Increasing Productivity without Affecting CHO Cell Growth.

Cynthia LamJoseph CarverDomingos NgDejin ZhanDanming TangThara KandamkalamBrad SnedecorGavin BarnardAmy ShenShahram Misaghi
Published in: Biotechnology progress (2023)
Chinese hamster ovary (CHO) cells are commonly used for expression of therapeutic proteins. To increase the titer output of CHO production cultures either specific productivity (Qp), growth, or both need to be increased. Generally, Qp and growth are inversely correlated and cell lines with high Qp have slower growth and vice versa. During the cell line development (CLD) process, the faster growing cells tend to take over the culture and represent the majority of the isolated clones post single cell cloning. In this study, combinations of regulated and constitutive expression systems were used to supertransfect targeted integration (TI) cell lines expressing the same antibody either constitutively or under regulated expression. Clone screening with a hybrid expression system (inducible + constitutive) allowed identification and selection of higher titer clones under uninduced conditions, without a negative impact on cell growth during clone selection and expansion. Induction of the regulated promoter(s) during the production phase increased the Qp without negatively affecting growth, resulting in approximately 2-fold higher titers (from 3.5 g/L to 6-7 g/L). This was also confirmed using a 2-site TI host where the gene of interest was expressed inducibly from site-1 and constitutively from site-2. Our findings suggest that such a hybrid expression CLD system can be used to increase production titers, providing a novel approach for expression of therapeutic proteins with high titer market demands. This article is protected by copyright. All rights reserved.
Keyphrases
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