Amy Shen

Animal cell culture technology has advanced significantly over the last few decades and is now generally considered a reliable, robust and relatively mature technology. A range of biotherapeutics are currently synthesized using cell culture methods in large scale manufacturing facilities that produce products for both commercial use and clinical studies. The robust implementation of this technology requires optimization of a number of variables, including 1) cell lines capable of synthesizing the required molecules at high productivities that ensure low operating cost; 2) culture media and bioreactor culture conditions that achieve both the requisite productivity and meet product quality specifications; 3) appropriate on-line and off-line sensors capable of providing information that enhances process knowledge; and 4) good understanding of culture performance at different scales to ensure smooth scale-up. Successful implementation also requires appropriate strategies for process development, scale-up and process characterization and validation that enable robust operation that is compliant with current regulations. This review provides an overview of the state-of-the art technology in key aspects of cell culture, e.g., engineering of highly productive cell lines and optimization of cell culture process conditions. We also summarize the current thinking on appropriate process development strategies and process advances that might affect process development.

The presence or absence of core fucose in the Fc region N-linked glycans of antibodies affects their binding affinity toward FcγRIIIa as well as their antibody-dependent cell-mediated cytotoxicity (ADCC) activity. However, the quantitative nature of this structure-function relationship remains unclear. In this study, the in vitro biological activity of an afucosylated anti-CD20 antibody was fully characterized. Further, the effect of fucose reduction on Fc effector functions was quantitatively evaluated using the afucosylated antibody, its "regular" fucosylated counterpart and a series of mixtures containing varying proportions of "regular" and afucosylated materials. Compared with the "regular" fucosylated antibody, the afucosylated antibody demonstrated similar binding interactions with the target antigen (CD20), C1q and FcγRIa, moderate increases in binding to FcγRIIa and IIb, and substantially increased binding to FcγRIIIa. The afucosylated antibodies also showed comparable complement-dependent cytotoxicity activity but markedly increased ADCC activity. Based on EC 50 values derived from dose-response curves, our results indicate that the amount of afucosylated glycan in antibody samples correlate with both FcγRIIIa binding activity and ADCC activity in a linear fashion. Furthermore, the extent of ADCC enhancement due to fucose depletion was not affected by the FcγRIIIa genotype of the effector cells.

A systematic analytical approach combining tryptic and chymotryptic peptide mapping with a Mascot Error Tolerant Search (ETS) has been developed to detect and identify low level protein sequence variants, i.e., amino acid substitutions, in recombinant monoclonal antibodies. The reversed-phase HPLC separation with ultraviolet (UV) detection and mass spectral acquisition parameters of the peptide mapping methods were optimized by using a series of model samples that contained low levels (0.5-5.0%) of recombinant humanized anti-HER2 antibody (rhumAb HER2) along with another unrelated recombinant humanized monoclonal antibody (rhumAb A). This systematic approach's application in protein sequence variant analysis depends upon time and sensitivity constraints. An example of using this approach as a rapid screening assay is described in the first case study. For stable CHO clone selection for an early stage antibody project, comparison of peptide map UV profiles from the top four clone-derived rhumAb B samples quickly detected two sequence variants (M83R at 5% and P274T at 42% protein levels) from two clones among the four. The second case study described in this work demonstrates how this approach can be applied to late stage antibody projects. A sequence variant, L413Q, present at 0.3% relative to the expected sequence of rhumAb C was identified by a Mascot-ETS for one out of four top producers. The incorporation of this systematic sequence variant analysis into clone selection and the peptide mapping procedure described herein have practical applications for the biotechnology industry, including possible detection of polymorphisms in endogenous proteins.

One of the major goals in cell culture process development for therapeutic antibody production is to develop methods to reach high titer in classical fed-batch processes. This goal is often achieved through the optimizations of expression vector, cell line, media and cell culture process controls to increase cell specific productivity, viable cell density, and culture longevity. During process optimization for a selected production cell line, cell specific productivity (qP) can vary significantly with culture conditions. Therefore, identifying strategies to maintain maximal specific productivity throughout the entire fed-batch culture and to eliminate cellular/process bottlenecks that prevent high levels of antibody production would be crucial for further advancements in this area. In this work, specific productivity was increased and maintained at high level throughout the course of the culture by the optimization of feed media and feeding strategy. Through the enhancement of nutrient feeding, final titer was increased by 2.5-fold from the platform fed-batch process and reached 7.5 g/L. In addition, further insight upon possible cellular bottlenecks in high yield antibody production was obtained by comparing the levels of heavy chain (HC) and light chain (LC) mRNA and the levels of intracellular antibody between the non-optimized and optimized feeding processes. The mRNA levels of the two processes were measured and exhibited no significant difference suggesting that transcription is not the bottleneck. When intracellular antibody level was studied, the relatively constant level of HC, LC, and intact antibody between days 9 and 14 suggested that translation could be the rate-limiting step under the non-optimized nutrient feeding condition due to the dramatic drop of qP to roughly zero which correlated with the depletion of tyrosine as one of the key amino acids for protein synthesis. Finally, accumulation of unassembled HC but not intact antibody was observed at days 14-18 under the enhanced feeding condition, implying that folding and assembly may be the bottleneck toward the end of the culture.