Michael W. Laird scite author profile

In the biopharmaceutical industry, therapeutic monoclonal antibodies are primarily produced in mammalian cell culture systems. During the scale-up of a monoclonal antibody production process, we observed excessive mechanical cell shear as well as significant reduction of the antibody's interchain disulfide bonds during harvest operations. This antibody reduction event was catastrophic as the product failed to meet the drug substance specifications and the bulk product was lost. Subsequent laboratory studies have demonstrated that cells subjected to mechanical shear release cellular enzymes that contribute to this antibody reduction phenomenon (manuscript submitted; Kao et al., 2009). Several methods to prevent this antibody reduction event were developed using a lab-scale model to reproduce the lysis and reduction events. These methods included modifications to the cell culture media with chemicals (e.g., cupric sulfate (CuSO(4))), pre- and post-harvest chemical additions to the cell culture fluid (CCF) (e.g., CuSO(4), EDTA, L-cystine), as well as lowering the pH and air sparging of the harvested CCF (HCCF). These methods were evaluated for their effectiveness in preventing disulfide bond reduction and their impact to product quality. Effective prevention methods, which yielded acceptable product quality were evaluated for their potential to be implemented at manufacturing-scale. The work described here identifies numerous effective reduction prevention measures from lab-scale studies; several of these methods were then successfully translated into manufacturing processes.

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Tethering of CpxP to the inner membrane prevents spheroplast induction of the Cpx envelope stress response

Raivio

Laird²,

Joly³

et al. 2000

Molecular Microbiology

106

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SummaryThe Cpx envelope stress response of Escherichia coli is controlled by a two-component regulatory system that senses misfolded proteins in extracytoplasmic compartments and responds by inducing the expression of envelope protein folding and degrading factors. We have proposed that in the absence of envelope stress the pathway is maintained in a downregulated state, in part through interactions between the periplasmic inhibitor molecule CpxP and the sensing domain of the histidine kinase CpxA. In this study, we show that depletion of the periplasmic contents of the cell by spheroplast formation does indeed lead to induction of the Cpx envelope stress response. Further, removal of CpxP is an important component of this induction because tethering an MBP±CpxP fusion protein to the spheroplast inner membranes prevents full activation by this treatment. Spheroplast formation has previously been demonstrated to induce the expression of a periplasmic protein of unknown function, Spy. Analysis of spy expression in response to spheroplast formation by Western blot analysis and by lacZ operon fusion in various cpx mutant backgrounds demonstrated that spy is a member of the Cpx regulon. Interestingly, although the only known spy homologue is cpxP, Spy does not appear to perform the same function as CpxP as it is not involved in inhibiting the Cpx envelope stress response. Rather, deletion of spy leads to activation of the s E stress response. Because the s E response is specifically affected by alterations in outer membrane protein biogenesis, we think it possible that Spy may be involved in this process.

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Bacillus anthracisEdema and Lethal Toxin Have Different Hemodynamic Effects but Function Together to Worsen Shock and Outcome in a Rat Model

Cui

et al. 2007

J INFECT DIS

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Mechanism of antibody reduction in cell culture production processes

Kao

Hewitt

Trexler-Schmidt³

et al. 2010

Biotech & Bioengineering

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We recently observed a significant disulfide reduction problem during the scale-up of a manufacturing process for a therapeutic antibody using a CHO expression system. Under certain conditions, extensive reduction of inter-chain disulfide bonds of an antibody produced by CHO cell culture may occur during the harvest operations and/or the protein A chromatography step, resulting in the observation of antibody fragments (light chain, heavy chain, and various combination of both) in the protein A pools. Although all conditions leading to disulfide reduction have not been completely identified, an excessive amount of mechanical cell lysis generated at the harvest step appears to be an important requirement for antibody reduction (Trexler-Schmidt et al., 2010). We have been able to determine the mechanism by which the antibody is reduced despite the fact that not all requirements for antibody reduction were identified. Here we present data strongly suggesting that the antibody reduction was caused by a thioredoxin system or other reducing enzymes with thioredoxin-like activity. The intracellular reducing enzymes and their substrates/cofactors apparently were released into the harvest cell culture fluid (HCCF) when cells were exposed to mechanical cell shear during harvest operations. Surprisingly, the reducing activity in the HCCF can last for a long period of time, causing the reduction of inter-chain disulfide bonds in an antibody. Our findings provide a basis for designing methods to prevent the antibody reduction during the manufacturing process.

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Effect of Individual Fc Methionine Oxidation on FcRn Binding: Met252 Oxidation Impairs FcRn Binding More Profoundly than Met428 Oxidation

Gao¹,

Ji²,

Veeravalli

et al. 2015

Journal of Pharmaceutical Sciences

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Michael W. Laird

Identification and prevention of antibody disulfide bond reduction during cell culture manufacturing

Tethering of CpxP to the inner membrane prevents spheroplast induction of the Cpx envelope stress response

Bacillus anthracisEdema and Lethal Toxin Have Different Hemodynamic Effects but Function Together to Worsen Shock and Outcome in a Rat Model

Mechanism of antibody reduction in cell culture production processes

Effect of Individual Fc Methionine Oxidation on FcRn Binding: Met252 Oxidation Impairs FcRn Binding More Profoundly than Met428 Oxidation

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