The TF-1 human erythroleukemic cell line exhibits opposing physiological responses toward tumor necrosis factor-␣ (TNF) treatment, dependent upon the mitotic state of the cells. Mitotically active cells in log growth respond to TNF by rapidly undergoing apoptosis whereas TNF exposure stimulates cellular proliferation in mitotically quiescent cells. The concentrationdependent TNF-induced apoptosis was monitored by cellular metabolic activity and confirmed by both DNA epifluorescence and DNA fragmentation. Moreover, these responses could be detected by measuring extracellular acidification activity, enabling rapid prediction (within ϳ 1.5 h of TNF treatment) of the fate of the cell in response to TNF. Growth factor resupplementation of quiescent cells, resulting in reactivation of cell cycling, altered TNF action from a proliferative stimulus to an apoptotic signal. Expression levels of the type II TNF receptor subtype (p75TNFR) were found to correlate with sensitivity to TNF-induced apoptosis. Pretreatment of log growth TF-1 cells with a neutralizing antip75TNFR monoclonal antibody inhibited TNF-induced apoptosis by greater than 80%. Studies utilizing TNF receptor subtype-specific TNF mutants and neutralizing antisera implicated p75TNFR in TNF-dependent apoptotic signaling. These data show a bifunctional physiological role for TNF in TF-1 cells that is dependent on mitotic activity and controlled by the p75TNFR.Cells have the capability of responding to a multitude of signals that it encounters in its extracellular environment. One such signal with widespread pleiotropic actions is the cytokine tumor necrosis factor-␣ (TNF) 1 (1). TNF has been shown to modulate proliferation, differentiation, and apoptotic or necrotic cell death in a number of different cell types (2-4). These disparate responses to TNF are mediated by TNF binding to specific cell surface receptors. Two distinct TNF receptors, type I (p55TNFR) and type II (p75TNFR) (M r 55,000 -60,000 and 70,000 -80,000 in human cells, respectively), have been identified (5, 6), although it remains unclear which of the many responses reported for TNF can be attributed to a specific receptor subtype (4). Moreover, the precise signal transduction pathways for each of these receptor subtypes have yet to be fully delineated. One action of TNF, the induction of apoptosis, is characterized by a discrete set of cellular events regulated by gene expression (7,8). The physiological events accompanying apoptosis include condensation of the chromatin, degradation of DNA through the activation of endogenous nucleases, and dissolution of the cell into small membrane-bound apoptotic vesicles (9, 10). In vivo, these vesicles are phagocytosed by macrophages or other phagocytic cells. Cell death by apoptosis is essential in many physiological processes, including embryonic development of the nervous system (11), oncogenic pathology (12), and clonal selection of hematopoietic cells (13).Conversely, TNF has also been shown to stimulate cellular proliferation in a variety of systems...
