DEPLETION OF THE MITOCHONDRIAL ELECTRON-TRANSPORT ABROGATES THE CYTOTOXIC AND GENE-INDUCTIVE EFFECTS OF TNF

Tumor necrosis factor (TNF) has cytotoxic and gene-inductive activities on several cell types. Previous studies on L929 fibrosarcoma cells have revealed that the mitochondrial electron transport system plays a key role in inducing TNF cytotoxicity, presumably by the formation of reactive oxygen intermediates (ROI). Here we report that mitochondria-derived intermediates are not only cytotoxic but, in addition, function as signal transducers of TNF-induced gene expression. The activation of NFchiB, which fulfills an important role in TNF-induced gene transcription, could be blocked by interference with the mitochondrial electron transport system. Furthermore, antimycin A, a mitochondrial inhibitor that increases the generation of ROI, potentiated TNF-triggered NFchiB activation. The dual role of mitochondria-derived intermediates in cytotoxicity and immediate-early gene induction of TNF was further substantiated by isolating L929 subclones which lacked a functional respiratory chain. This depletion of the mitochondrial oxidative metabolism resulted in resistance towards TNF cytotoxicity, as well as in inhibition of NFchiB activation and interleukin-6 gene induction by TNF. These findings suggest that mitochondria are the source of second messenger molecules and serve as common mediators of the TNF-cytotoxic and gene-regulatory signaling pathways.