Yuchen Yang, Neil C Dalvie, Joseph R Brady, Christopher A Naranjo, Timothy Lorgeree, Sergio A Rodriguez-Aponte, Ryan S Johnston, Mary K Tracey, Carmen M Elenberger, Eric Lee, Mark Tié, Kerry R Love, J Christopher Love
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引用次数: 0
摘要
单克隆抗体(mAbs)是利用中国仓鼠卵巢(CHO)细胞的成熟工艺制造的一类主要生物制药。使用 Komagataella phaffii 等替代宿主进行下一代生物制造可以提高这些药物的可及性,实现可持续发展的广泛社会目标,并为加速新产品开发提供经济优势。然而,由 K. phaffii 生产的抗体可能会表现出独特的分子质量属性,如依赖于宿主的、与产品相关的变体,这可能会引起临床使用的潜在问题。我们在此展示了对基于人类 IgG1 同工型的糖基化抗体氨基酸序列的保守修饰,这些修饰可使 K. phaffii 分泌的产品相关变异最小化。2-3 个氨基酸变化的组合减少了六种不同的商业 mAbs 的糖基化版本的差异。在 K. phaffii 和 CHO 细胞中表达经过修饰的 NIST mAb 序列显示出相似的生物物理特性和分子变化。这些结果为生产可由酵母或哺乳动物细胞交替表达的高质量 mAb 提供了一条途径。改进蛋白质的分子设计,使一系列具有良好特性的生物制药的生产策略成为可能,这将加速全球生物制药的普及和创新。
Adaptation of Aglycosylated Monoclonal Antibodies for Improved Production in Komagataella phaffii.
Monoclonal antibodies (mAbs) are a major class of biopharmaceuticals manufactured by well-established processes using Chinese Hamster Ovary (CHO) cells. Next-generation biomanufacturing using alternative hosts like Komagataella phaffii could improve the accessibility of these medicines, address broad societal goals for sustainability, and offer financial advantages for accelerated development of new products. Antibodies produced by K. phaffii, however, may manifest unique molecular quality attributes, like host-dependent, product-related variants, that could raise potential concerns for clinical use. We demonstrate here conservative modifications to the amino acid sequence of aglycosylated antibodies based on the human IgG1 isotype that minimize product-related variations when secreted by K. phaffii. A combination of 2-3 changes of amino acids reduced variations across six different aglycosylated versions of commercial mAbs. Expression of a modified sequence of NIST mAb in both K. phaffii and CHO cells showed comparable biophysical properties and molecular variations. These results suggest a path toward the production of high-quality mAbs that could be expressed interchangeably by either yeast or mammalian cells. Improving molecular designs of proteins to enable a range of manufacturing strategies for well-characterized biopharmaceuticals could accelerate global accessibility and innovations.
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