Strategies to modulate BHK cell proliferation by the regulation of IRF-1 expression

Abstract

Activation of the constitutively expressed interferon-regulatory-factor-1/estrogen receptor fusion protein (IRF-1-hER) in BHK cells was accomplished through the addition of estradiol to the culture medium, which enabled IRF-1 to gain its transcriptional activator function and inhibit cell growth. With the addition of 100 nM estradiol at the beginning of the exponential phase of a cell suspension culture, IRF-1 activation led to a rapid cell growth inhibition but also to a significant decrease in cell viability. To apply this concept in industry, a reduction of the time span of estradiol exposure is required. Cycles of estradiol addition and removal were performed in 2-l stirred tank bioreactors operated under perfusion, where an initial step addition of 100 nM estradiol was performed, followed, after 48–72 h, by a slow dilution with estradiol-free fresh medium (perfusion rate varying between 0.7 and 1.4 per day). Cell growth inhibition was successfully achieved for three consecutive cycles. Diluting the estradiol by perfusing medium without estradiol to concentrations lower than 10 nM led to cell growth and viability recovery independently of the perfusion rate used. These observations permitted the definition of operational strategies for regulated IRF-1 BHK cell growth by pulse estradiol addition, followed by a period of 48 h in the presence of estradiol and by fast perfusion to estradiol concentrations lower than 10 nM. Cell growth response to IRF-1 activation and following estradiol removal by perfusion was also evaluated with an IRF-1-hER regulated clone expressing constitutively Factor VII, where the time of estradiol exposure and perfusion rate were varied. This clone presented a stronger response to IRF-1 activation without an increase in Factor VII specific productivity after cell growth inhibition; this clearly indicates that the stationary phase obtained is clone dependent. This work proves that it is possible to modulate the IRF-1 effect for cell growth control by the manipulation of cycles of addition and removal of estradiol, potentially representing a new generation of culture procedures for controlled growth production purposes.