Formation of transient highly-charged mAb clusters strengthens interactions with host cell proteins and results in poor clearance of host cell proteins by protein A chromatography

• Published in: Journal of Chromatography A Vol. 1679; p. 463385
• Main Authors: Luo, Haibin, Du, Qun, Qian, Chen, Mlynarczyk, Michelle, Pabst, Timothy M., Damschroder, Melissa, Hunter, Alan K., Wang, William K.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 30.08.2022
• Subjects: Downstream process development; Host cell protein; Hydrodynamic radius; Monoclonal antibody; Reversible cluster; Downstream process development; Hydrodynamic radius; Monoclonal antibody; Host cell protein; Reversible cluster
• ISSN: 0021-9673
• DOI: 10.1016/j.chroma.2022.463385

•Only small subset (10%) of mAbs exhibited significant HCP copurification issue.•High-HCP mAbs share many common HCPs and similar copurification mechanism.•HCP copurification correlates with mAb's self-association propensity.•Mab-clustering strengthens interactions between mAb with HCPs.•Breaking mAb-clusters effectively prevents HCP copurification. Protein A chromatography with a high salt wash usually leads to robust clearance of host cell proteins (HCPs) in most recombinant monoclonal antibodies (mAbs), but a small subset of recalcitrant mAbs show significant HCP copurification. In this study, we carried out systematic studies using 4 different mAbs to explore the HCP copurification mechanism. HCP identification results revealed that the 3 high-HCP mAbs had many common HCPs which do not copurify with the low-HCP mAb, suggesting a similar mechanism is at play. Through wash evaluation, surface patch analysis, chain-swapping, domain evaluation, and structure-guided mutations, several charged residues in each mAb were found which correlated with HCP copurification. Surprisingly, these residues are also critical for self-association propensity. We observed an inverse correlation between diffusion interaction parameter and HCP copurification. Each of the high-HCP mAbs could form dynamic clusters consisting of 3∼6 mAb molecules. Therefore, a mAb cluster can exhibit higher net positive charges on the order of 3 to 6, compared with the individual mAb. In Protein A chromatography, high-HCP mAbs had elution tailing which contained high level of HCPs. Addition of Arginine-HCl or point mutations preventing cluster formation effectively reduced HCP copurification and elution tailing. Based on these results, we propose a novel HCP-copurification mechanism that formation of mAb clusters strengthens charge-charge interactions with HCPs and thus compromises HCP removal by Protein A chromatography. Besides arginine, histidine under acidic pH conditions prevented cluster formulation and resulted in effective HCP removal. Finally, structure-guided protein engineering and solution screening by using cluster size as indicator are useful tools for managing mAbs with high-HCP issues.