Thioglycollate-elicited murine peritoneal macrophages produce significant quantities of TNF 2 to 4 h after induction with bacterial endotoxin, LPS. However, macrophages exposed to a second LPS stimulus are refractory and the amount of TNF detected in these supernatants is reduced 10- to 50-fold. The acquisition of the refractory state in vitro or in vivo requires the continued presence of LPS for a minimum of 6 to 8 h, is optimal by 20 h, and is reversible. Refractory macrophages incubated for an additional 48 h in the absence of LPS produce significant quantities of TNF after reexposure to endotoxin. Although LPS refractory macrophages do not release TNF in response to a secondary endotoxin challenge, riboprobe ribonuclease protection assays demonstrated amplification of TNF message, suggesting that post-transcriptional events are involved in the regulation of TNF production in endotoxin refractory macrophages. Immunoprecipitation studies revealed the accumulation of the 26-kDa TNF precursor in lysates of refractory macrophages, thus demonstrating a post-translational regulatory process. Although LPS refractory macrophages do not release TNF in response to a second LPS stimulus, ingestion of zymosan by these cells results in the release of significant quantities of TNF. Furthermore, LPS-refractory macrophages do not demonstrate a reduction in other effector functions including Fc-mediated erythrophagocytosis. Therefore, the LPS refractory state is a metabolically dependent post-translational regulatory process, which requires continuous LPS exposure, is specific in which macrophage effector functions are inhibited, and is reversible with further incubation or by non-LPS-related stimuli.