Chemical caspase inhibitors enhance cell culture viabilities and protein titer.

Mammalian cell cultures are integral to the production of therapeutic and diagnostic proteins. A common problem encountered in culturing these cell lines, however, is a loss in viability at later stages of the cell culture process. In this study the effects of three newly synthesized chemical caspase inhibitors were investigated for their capacity to inhibit cell death. Findings show that these protease inhibitors were successful in prolonging cellular viabilities among anchorage-dependent CHO-K1 and HEK-293 cells lines. Cells treated with one inhibitor, 7312, performed as well or better when compared with the commercially known caspase inhibitor, zVAD.fmk. Suspension CHO cells producing an IgG were used to investigate the capacity of 7312 to improve protein production. Treatment of cells with 7312 increased integrated cell densities by 33% with treated cells having a higher maximum cell density and higher viability. As a result, monoclonal antibody titers increased by 20% and higher in spinner flask experiments. Increasing productivity in mammalian cell cultures has key implications for the pharmaceutical and biotechnology sectors, which are presently focused on developing methods to enhance cell performance in bioreactor environments.

Inhibiting the apoptosis pathway using MDM2 in mammalian cell cultures.

The ability to regulate apoptosis in mammalian cell cultures represents one approach to developing more economical and efficient processes. Genetic modification of cells using anti-apoptotic genes is one method that may be used to improve cellular performance. This study investigates a method to inhibit upstream apoptosis pathways through the overexpression of MDM2, an E3 ubiquitin ligase for p53. Both 293 and CHO cells expressing MDM2 were examined under both batch and spent media conditions. For batch cultures, MDM2 overexpression increased viable cell densities and viabilities over control cells with the largest enhancements observed in CHO cells. When CHO cells were passaged without medium exchange, cells expressing MDM2 reached a viable cell density that was nearly double the control and survived for an extra day in culture. When exposed to spent media initially, both 293-MDM2 and CHO-MDM2 cells continued to grow for 2 days while the control cells stopped growing after the first day. DNA analysis using flow cytometry confirmed that while CHO controls were found to be undergoing DNA fragmentation, CHO-MDM2 cells exhibit DNA degradation at a much slower rate. When compared to Bcl-2-expressing cells, MDM2 expression showed greater protection against apoptosis in passaged culture, spent medium, and following transient p53 overexpression. However, expression of the RING sequence of MDM2 responsible for E3 ligase activity without the other components of the protein was found to be toxic to 293 cells in culture. These results suggest that the overexpression of heterologous MDM2 represents a promising method to delay apoptosis in mammalian cell cultures.