Post‐tetanic hyperpolarization, sodium‐potassium‐activated adenosine triphosphatase and high energy phosphate levels in garfish olfactory nerve.

Abstract

1. While much is now known about the Na-K-ATPase and the posttetanic hyperpolarization of nervous tissue, they have yet to be studied together in the same preparation. 2. The post-tetanic hyperpolarization was studied in desheathed garfish olfactory nerve. The rate constant of decay of the post-tetanic hyperpolarization was determined by monitoring difference potentials after stimulation at 1/sec for 2-3 min. 3. In membrane fractions prepared from these nerves, the ouabain-sensitive ATPase activity (Na-K-ATPase) was determined by spectrophotometric measurements. 4. Both the post-tetanic hyperpolarization and the Na-K-ATPase showed a similar sigmoidal dependence on K+ concentration. The sequence of cation specificities measured at the K-site of the enzyme was the same as that determined by post-tetanic hyperpolarization measurements in whole nerve. 5. The rate constants of the enzyme showed a dependence on Na+ concentration that paralleled the way in which the post-tetanic hyperpolarization rate constants varied as a function of the number of impulses. When Na+ was completely replaced by Li+, neither enzyme activity nor post-tetanic hyperpolarization could be measured. 6. The pH optimum for enzyme activity was between pH 7-0 and 7-8, while the optimal pH for post-tetanic hyperpolarization was above pH 8-0. 7. Metabolite levels in preparations of this nerve studied in vitro correspond to levels found in vivo. 8. High energy phosphate levels were measured fluorometrically in extracts of nerve samples that had been stimulated in air at 1/sec for various intervals. 9. During the first 2 min of stimulation, there was a significant accumulation of inorganic phosphate, and the ATP/ADP.Pi ratio dropped appreciably. 10. The accumulation of ATPase products was commensurate with the approach of post-tetanic hyperpolarization rate constants to their maximum level. This provides direct evidence for an ATPase functioning in active Na+ transport in nerve. 11. The garfish Na-K-ATPase is sensitive to the ATP/ADP ratio of the incubating medium, but is relatively insensitive to orthophosphate, Pi. The fall in post-tetanic hyperpolarization rate constants observed with continued nerve stimulation may have been partially due to the falling ATP/ADP ratio measured in nerve under similar conditions.