Therapeutic bispecific antibodies are formed by assembly of multichain polypeptides. In general, a bispecific antibody has two different light chains and two different heavy chains that fold and correctly pair via engineered interchain interactions. Because of some incorrect assembly, product-related impurities can be prevalent (e.g., half molecules, mispaired light chains, homodimers), requiring its removal during subsequent purification. In this study, we investigated the modulation of impurity levels in a stable Chinese hamster ovary cell line X expressing a bispecific antibody A formed by two light chains (LC1 and LC2) and two heavy chains (HC1 and HC2) that assembled intracellularly into a heterodimer (LC1-HC1 + LC2-HC2) via engineered charged residues. Cell line X exhibited the best volumetric productivity, growth, and viability in culture compared with other clones but also showed higher levels of half antibody species (>10%); therefore, to minimize process yield loss, better understanding, and control of impurity formation was pursued. We found this cell line decreased half antibody levels from 16% to 1% when temperature changed from 36°C to 32.5°C or 31.5°C. However, lower temperature also increased high-molecular-weight (HMW) species from 4% to 12%. To determine the impurity species composition, we characterized enriched fractions with half antibody or HMW. Intact mass spectrometry analysis revealed half antibody was LC2-HC2, whereas HMW was a mixture with ~50% as LC1-HC1 homodimer. Results suggested LC2-HC2 was easily folded and could be secreted as half antibody, especially at 36°C. On the contrary, LC1-HC1 was more susceptible to misfold or aggregate, a phenomenon more acute for cell line X at lower culture temperature because of 60% increased LC1 and HC1 messenger RNA levels. Although temperature modulation was cell line X-specific, the propensity of LC2-HC2 to form half antibodies and LC1-HC1 to aggregate appeared in other cell lines also expressing bispecific antibody A, suggesting an amino-acid sequence-dependent mechanism. In summary, impurity formation in cell line X was temperature-dependent and was influenced by different molecule characteristics between the LC1-HC1 and LC2-HC2 parts. Ultimately, we selected a biphasic cell culture process with a growth phase followed by a lower temperature phase to improve product quality and purification yield.
Keywords: culture temperature; hetero-IgG; high-molecular weight; homodimer; product-related impurity.
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