Model-Driven Engineering of N‑Linked Glycosylation in Chinese Hamster Ovary Cells
datasetposted on 18.10.2019, 14:08 by Christopher S. Stach, Meghan G. McCann, Conor M. O’Brien, Tung S. Le, Nikunj Somia, Xinning Chen, Kyoungho Lee, Hsu-Yuan Fu, Prodromos Daoutidis, Liang Zhao, Wei-Shou Hu, Michael Smanski
Chinese hamster ovary (CHO) cells are used for industrial production of protein-based therapeutics (i.e., “biologics”). Here we describe a method for combining systems-level kinetic models with a synthetic biology platform for multigene overexpression to rationally perturb N-linked glycosylation. Specifically, we sought to increase galactose incorporation on a secreted Immunoglobulin G (IgG) protein. We rationally design, build, and test a total of 23 transgenic cell pools that express single or three-gene glycoengineering cassettes comprising a total of 100 kilobases of engineered DNA sequence. Through iterative engineering and model refinement, we rationally increase the fraction of bigalactosylated glycans five-fold from 11.9% to 61.9% and simultaneously decrease the glycan heterogeneity on the secreted IgG. Our approach allows for rapid hypothesis testing and identification of synergistic behavior from genetic perturbations by bridging systems and synthetic biology.
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protein-based therapeutics100 kilobasesbiology platformincrease galactose incorporationcell poolsCHObigalactosylated glycansGlycosylationIgGidentificationglycan heterogeneityapproachmethodmodel refinementi.eiterative engineeringChinese Hamster Ovary Cellsperturb N-linked glycosylationthree-gene glycoengineering cassettesperturbationsystems-levelfractionImmunoglobulin GModel-Driven Engineeringmultigene overexpressionhamster ovaryhypothesis testingbiologicDNA sequence