Inhibition by ATP of Hippocampal Synaptic Transmission Requires Localized Extracellular Catabolism by Ecto-Nucleotidases into Adenosine and Channeling to Adenosine A1Receptors

Abstract

ATP analogs substituted in the γ-phosphorus (ATPγS, β,γ-imido-ATP, and β,γ-methylene-ATP) were used to probe the involvement of P₂ receptors in the modulation of synaptic transmission in the hippocampus, because their extracellular catabolism was virtually not detected in CA1 slices. ATP and γ-substituted analogs were equipotent to inhibit synaptic transmission in CA1 pyramid synapses (IC₅₀ of 17–22 μm). The inhibitory effect of ATP and γ-phosphorus-substituted ATP analogs (30 μm) was not modified by the P₂ receptor antagonist suramin (100 μm), was inhibited by 42–49% by the ecto-5′-nucleotidase inhibitor and α,β-methylene ADP (100 μm), was inhibited by 74–85% by 2 U/ml adenosine deaminase (which converts adenosine into its inactive metabolite-inosine), and was nearly prevented by the adenosine A₁ receptor antagonist 1,3-dipropyl-8-cyclopentylxanthine (10 nm). Stronger support for the involvement of extracellular adenosine formation as a main requirement for the inhibitory effect of ATP and γ-substituted ATP analogs was the observation that an inhibitor of adenosine uptake, dipyridamole (20 μm), potentiated by 92–124% the inhibitory effect of ATP and γ-substituted ATP analogs (10 μm), a potentiation similar to that obtained for 10 μm adenosine (113%). Thus, the present results indicate that inhibition by extracellular ATP of hippocampal synaptic transmission requires localized extracellular catabolism by ecto-nucleotidases and channeling of the generated adenosine to adenosine A₁ receptors.