Responses of CHO cell lines to increased pCO2 at normal (37°C) and reduced (33°C) culture temperatures

The correlation between dissolved carbon dioxide (pCO(2)) and cell growth, cell metabolism, productivity and product quality has often been reported. However, since pCO(2) values in bioprocesses always vary concurrently with other bioprocess variables, it is very difficult to distinguish only the effect of pCO(2). The aim of our work was to investigate further the specific effect of pCO(2) and cell response on a proteome level. Proteome responses of three different CHO-Der3 cell lines in the exponential growth phase at normal (37 degrees C) and reduced (33 degrees C) culture temperatures, with normal (10%) and increased (20%) pCO(2), were studied by comparative proteomic analysis (2D-DIGE). Cell viability and cell density, and the concentration of glucose, glutamine and lactate monitored over 72-h cultures showed that elevated pCO(2) did not affect cell viability or productivity at either culture temperature, while metabolic activity was reduced. The specific metabolic profile also indicated altered glucose metabolism toward a less efficient anaerobic metabolism. Two-way ANOVA of proteomic data discriminated many more pCO(2)-specific changes in protein abundance (p < 0.01) at 33 degrees C than at 37 degrees C and PCA analysis was able to distinguish clusters distinguishing cell lines and culture conditions at low temperature and elevated pCO2, indicating substantial proteome changes under these culture conditions. Cell sensitivity to increased pCO(2) at the lower temperature was further confirmed by a significantly increased abundance of twelve proteins involved in anti-oxidative mechanisms and increased abundance of six proteins involved in glycolysis, including L-lactate dehydrogenase. Proteomic results support the metabolic data and the proposed pCO(2) invoked metabolic switch toward anaerobic pathways. Anti-oxidative mechanisms, together with the anaerobic metabolism, allow the cells to detoxify while maintaining sufficient energy levels to preserve their vitality and functionality. This study provides further insight into the proteome responses of CHO cell lines to increased pCO(2) at the two culture temperatures. (C) 2015 Elsevier B.V. All rights reserved.