Relationship of depolarization to phosphorus metabolism and transport in excitable tissues

Abstract

In the presence of Ringer solution containing a high concentration of potassium ions, the incorporation of orthophosphate-P³² into ATP and other organophosphates of the desheathed sciatic nerve or spinal ganglia of bullfrog was inhibited over 75%. The inhibition in calcium-free Ringer solution containing EDTA was somewhat less. With increasing external K⁺ there was a good correlation between the decrease in the resting potential of spinal ganglion cells and the inhibition of P³² incorporation into ATP and phosphocreatine. Since oxidative phosphorylation or carbohydrate metabolism was not inhibited by high K⁺, it was concluded that the K⁺ interfered with the transport mechanisms involved in orthophosphate-P³² exchange across the nerve membrane. P_i transport was believed to involve the following three chain-linked reactions: 1) carrier + P ⇌ carrier P; 2) carrier P ⇌ carrier + P_i; 3) P_i + ADP ⇌ ATP, where the first two reactions occurred in the membrane and the third within mitochondria. Reaction I or II was presumed to be K⁺ sensitive. The possible mechanisms involved in such an inhibition are discussed in terms of present-day theories relating to bioelectric phenomena.