Apoptosis-mediated regulation of recombinant human granulocyte colony-stimulating factor production by genetically engineered fibroblasts.

We investigated the feasibility of an inducible apoptosis system to regulate cells genetically engineered for ectopic cytokine production. In a previous study, cDNA encoding the ligand-binding domain of the rat estrogen receptor was fused to the sequence for murine Fas transmembrane and cytoplasmic regions, and expression of the fusion protein (MfasER) in L929 fibroblasts resulted in estrogen-dependent apoptosis. We applied this MfasER/estrogen strategy to apoptosis-mediated regulation of cytokine production, using the human granulocyte colony-stimulating factor (G-CSF) as a model. Upon estrogen treatment, the G-CSF producers expressing MfasER showed an apoptotic phenotype and died in several hours, with termination of G-CSF production. This estrogen-induced apoptosis was not influenced by whether the target cells were proliferating or resting, unlike a conventional suicide system involving the herpes simplex virus 1 thymidine kinase (HSVtk). That is, estrogen induced prompt and extensive apoptosis in the resting cells which expressed MfasER, while ganciclovir treatment induced only partial reduction of the resting cells which expressed HSVtk. These results imply the feasibility of apoptosis-mediated regulation of cytokine production by genetically modified cells for supplement gene therapy.