Effects of temperature shift on cell cycle, apoptosis and nucleotide pools in CHO cell batch cultues
- PMID: 22358520
- PMCID: PMC3449885
- DOI: 10.1023/A:1007919921991
Effects of temperature shift on cell cycle, apoptosis and nucleotide pools in CHO cell batch cultues
Abstract
Temperature reduction in CHO cell batch culture may be beneficial in the production of recombinant protein and in maintenance of viability. The effects on cell cycle, apoptosis and nucleotide pools were studied in cultures initiated at 37°C and temperature shifted to 30 °C after 48 hours. In control cultures maintained at 37 °C, viable cells continued to proliferate until the termination of the culture, however, temperature reduction caused a rapid decrease in the percent of cells in S phase and accumulation of cells in G-1. This was accompanied by a concurrent reduction in U ratio (UTO/UDP-GNAc), previously shown to be a sensitive indicator of growth rate. Culture viability was extended following temperature shift, as a result of delayed onset of apoptosis, however, once initiated, the rate and manner of cell death was similar to that observed at 37 °C. All nucleotide pools were similarly degraded at the time of apoptotic cell death. Temperature reduction to 30 °C did not decrease the energy charge of the cells, however, the overall rate of metabolism was reduced. The latter may be sufficient to extend culture viability via a reduction in toxic metabolites and/or limitation of nutrient deprivation. However, the possibility remains that the benefits of temperature reduction in terms of both viability and productivity are more directly associated with cultures spending extended time in G-1.
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References
-
- Barnabé N, Butler M. Effect of temperature on nucleotide pools and monoclonal antibody production in a mouse hybridoma. Biotechnology and Bioengineering. 1994;44:1235–1245. - PubMed
-
- Bloemkolk JW, Gray MR, Merchant F, Mosmann TR. Effect of temperature on hybridoma cell cycle and MAb production. Biotechnology and Bioengineering. 1992;40:427–431. - PubMed
-
- de la Broise D, Noiseux M, Lemieux R, Massie B. Long term perfusion culture of hybridoma: a 'grow or die' cell cycle system. Biotechnology and Bioengineering. 1991;38:781–787. - PubMed
-
- Coco-Martin J., Oberink JW, van der Velden-de Groot TAM, Beuvery EC. The potential of flow cytometric analysis for the characterization of hybridoma cells in suspension cultures. Cytotechnology. 1992;8:65–74. - PubMed
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