Since it was been reported that the depolarization-induced ACh release is inhibited by activation of presynaptic A₁-adenosine heteroreceptor in hippocampus, a large body of experimental data on the post-receptor mechanism of this process has been accumulated. But, the post-receptor mechanism of presynaptic A₁-adenosine receptor on the ACh release has not been clearly elucidated yet. Therefore, it was attempted to clarify the post-receptor mechanisms of the A₁-adenosine receptor-mediated control of ACh release in this study. Slices from rat hippocampus were equilibrated with ³H-choline and the release of the labelled products was evoked by electrical stimulation (3 Hz, 5 VCm^-1, 2ms, rectangular pulses), and the influence of various agents on the evoked tritium-outflow was investigated. Adenosine, in concentrations ranging from 0.3 ~ 300μM, decreased the ACh release in a dose-dependent manner, without affecting the basal rate of release. The adenosine effects were significantly inhibited by DPCPX (2μM), a selective A₁-receptor antagonist. The responses to N-ethylmaleimide (10&30μM), a SH-alkylating agent of G-protein, were characterized by increments of the evoked ACh-release and the basal release, and the adenosine effects were completely abolished by NEM pretreatment. PDB (1 ~ 10μM), a specific protein kinase C (PKC) activator, increased, whereas PMB (0.03 ~ 1 mg), a PKC inhibitor, decreased the evoked ACh-release, and the adenosine effects were not affected by these agents. Nifedipine (1μM), a Ca²⁺ -channel blocker of dihydropyridine analogue, significantly inhibited the adenosine effect, but glibenclamide, a K⁺-channel blocker, did not. Finally, 8-bromo cyclic AMP (100 & 300μM), a membrane-permeable analogue of cAMP, did not alter the ACh release, but adenosine effects were inhibited by pretreatment with large dose of 8-br-cAMP (300μM). These results indicate that the decrement of the evoked ACh-release by A₁-adenosine receptor is mediated by the G-protein, and nifedipine-sensitive Ca²⁺-channel and adenylate cyclase system are coupled partly to this effect, and that protein kinase C and glibenclamide-sensitive K⁺-channel are not involved in this process.