The neurotrophic role of acetylcholine (ACh) in the denervation-dependent decline of muscle resting membrane potential (RMP) was evaluated. Freshly dissected rat hemidiaphragms with short or long (2 cm) nerve stumps attached ("-N" and "+N" preparations, respectively) were incubated in organ culture in the presence or absence of the nicotinic blockers, alpha-bungarotoxin (alpha-BTX) or d-tubocurarine (curare). Subsequently, RMPs and miniature endplate potentials (MEPPs) of the junctional region were measured. Spontaneous MEPPs disappeared with a half-life of 12 and 20 hr in -N and +N preparations, respectively. A 10- to 15-mV depolarization of RMP was observed between 15 and 20 hr in -N muscles and between 24 and 28 hr in +N muscles. This time course of disappearance of spontaneous potentials and of membrane depolarization agrees well with that observed in vivo. Although nicotinic transmission was blocked from the initiation of the incubation period in alpha-BTX- or curare-treated muscles, no acceleration of RMP decline in -N muscles in vitro was observed. Moreover, in +N preparations the effect of the nerve stump in delaying RMP depolarization persisted despite the continuous presence of alpha-BTX or curare. Since excess ACh triggers a lysosomal proteolytic response at the nerve-muscle junction and since this may occur early in denervation, the possible role of a nicotinic-induced proteolytic mechanism was tested in vitro with the potent protease inhibitor leupeptin. This inhibitor did not delay or prevent the denervation-dependent alterations.(ABSTRACT TRUNCATED AT 250 WORDS)