Gupta Shivani, Shah Bhavana, Fung Coral Shek, Chan Pik Kay, Wakefield Devin L, Kuhns Scott, Goudar Chetan T, Piret James M
Amgen, Inc., San Francisco, CA, United States.
Michael Smith Laboratories, and Department of Chemical and Biological Engineering, University of British Columbia, Vancouver, BC, Canada.
Front Bioeng Biotechnol. 2023 Feb 16;11:1113994. doi: 10.3389/fbioe.2023.1113994. eCollection 2023.
Since 2015 more than 34 biosimilars have been approved by the FDA. This new era of biosimilar competition has stimulated renewed technology development focused on therapeutic protein or biologic manufacturing. One challenge in biosimilar development is the genetic differences in the host cell lines used to manufacture the biologics. For example, many biologics approved between 1994 and 2011 were expressed in murine NS0 and SP2/0 cell lines. Chinese Hamster ovary (CHO) cells, however, have since become the preferred hosts for production due to their increased productivity, ease of use, and stability. Differences between murine and hamster glycosylation have been identified in biologics produced using murine and CHO cells. In the case of monoclonal antibodies (mAbs), glycan structure can significantly affect critical antibody effector function, binding activity, stability, efficacy, and half-life. In an attempt to leverage the intrinsic advantages of the CHO expression system and match the reference biologic murine glycosylation, we engineered a CHO cell expressing an antibody that was originally produced in a murine cell line to produce murine-like glycans. Specifically, we overexpressed cytidine monophospho-N-acetylneuraminic acid hydroxylase (CMAH) and N-acetyllactosaminide alpha-1,3-galactosyltransferase (GGTA) to obtain glycans with N-glycolylneuraminic acid (Neu5Gc) and galactose-α-1,3-galactose (alpha gal). The resulting CHO cells were shown to produce mAbs with murine glycans, and they were then analyzed by the spectrum of analytical methods typically used to demonstrate analytical similarity as a part of demonstrating biosimilarity. This included high-resolution mass spectrometry, biochemical, as well as cell-based assays. Through selection and optimization in fed-batch cultures, two CHO cell clones were identified with similar growth and productivity criteria to the original cell line. They maintained stable production for 65 population doubling times while matching the glycosylation profile and function of the reference product expressed in murine cells. This study demonstrates the feasibility of engineering CHO cells to express mAbs with murine glycans to facilitate the development of biosimilars that are highly similar to marketed reference products expressed in murine cells. Furthermore, this technology can potentially reduce the residual uncertainty regarding biosimilarity, resulting in a higher probability of regulatory approval and potentially reduced costs and time in development.
自2015年以来,美国食品药品监督管理局(FDA)已批准了34种以上的生物类似药。生物类似药竞争的新时代刺激了专注于治疗性蛋白质或生物制品生产的技术重新发展。生物类似药开发中的一个挑战是用于生产生物制品的宿主细胞系的基因差异。例如,1994年至2011年间批准的许多生物制品是在小鼠NS0和SP2/0细胞系中表达的。然而,由于其更高的生产力、易用性和稳定性,中国仓鼠卵巢(CHO)细胞此后已成为首选的生产宿主。在使用小鼠和CHO细胞生产的生物制品中,已鉴定出小鼠和仓鼠糖基化之间的差异。就单克隆抗体(mAb)而言,聚糖结构可显著影响关键的抗体效应功能、结合活性、稳定性、功效和半衰期。为了利用CHO表达系统的固有优势并匹配参考生物制品的小鼠糖基化,我们对一个表达最初在小鼠细胞系中产生的抗体的CHO细胞进行了工程改造,使其产生类似小鼠的聚糖。具体而言,我们过表达了胞苷单磷酸-N-乙酰神经氨酸羟化酶(CMAH)和N-乙酰乳糖胺α-1,3-半乳糖基转移酶(GGTA),以获得带有N-羟乙酰神经氨酸(Neu5Gc)和半乳糖-α-1,3-半乳糖(α-半乳糖)的聚糖。结果表明,所得的CHO细胞产生了带有小鼠聚糖的单克隆抗体,然后通过通常用于证明分析相似性的一系列分析方法对其进行分析,以此作为证明生物相似性的一部分。这包括高分辨率质谱分析、生化分析以及基于细胞的检测。通过在分批补料培养中进行筛选和优化,鉴定出了两个CHO细胞克隆,它们具有与原始细胞系相似的生长和生产力标准。它们在65个群体倍增时间内保持稳定生产,同时匹配在小鼠细胞中表达的参考产品的糖基化谱和功能。这项研究证明了对CHO细胞进行工程改造以表达带有小鼠聚糖的单克隆抗体的可行性,这有助于开发与在小鼠细胞中表达的市售参考产品高度相似的生物类似药。此外,这项技术可能会降低生物相似性方面的残留不确定性,从而提高获得监管批准的可能性,并可能降低开发成本和时间。
