Metabolism of choline in brain of the aged CBF‐1 mouse

Abstract

In order to quantify the changes that occur in the cholinergic central nervous system with aging, we have compared acetylcholine (Ach) formation in brain cortex slice preparations from 2‐year‐old aged CBF‐1 mouse brains and compared the findings with those in 2–4‐month‐old young adult mouse brain slices. Incorporation of exogenous radioactively labelled choline (31 nM [³H] choline) into acetyl choline in incubated brain slices was linear with time for 90 min. Percentage of total choline label distributed into Ach remained constant from 5 min after starting the incubation to 90 min. In contrast, distribution of label into intracellular free choline (Ch) and phosphorylcholine (Pch) changed continuously over this period suggesting that the Ch pool for Ach synthesis in brain cortex is different from that for Pch synthesis. Incorporation of radioactivity into Ach was not influenced by administration of 10 μM eserine, showing that the increment of radioactivity in Ach reflects rate of Ach formation, independently from degradation by acetylcholine esterases. Under our experimental conditions, slices from cortices of aged 24‐month‐old mouse brain showed a significantly greater (27%) incorporation of radioactivity into intracellular Ach than those from young, 2–4‐month‐old, brain cortices. Inhibitors of Arch release, 1 mM ATP or GABA, had no effect. Since concentration of radioactive precursor in the incubation medium was very low (31 nM), the Ch pool for Ach synthesis in slices was labelled without measurably changing the size of the endogenous pool. These data suggest a compensatory acceleration of Ach synthesis or else a smaller precursor pool specific for Ach synthesis into which labelled Ch migrated in aged brain. We also measured in detail the incorporation of [³H]CH into choline phospholipids: phosphatidyl choline, lysophosphatidyl choline, and sphingomyelin of young and old mouse brain. We could not detect any difference between young and old mouse brain cortical slices, suggesting that the difference in Ach synthesis that we have observed may reflect a specific alteration with aging in the metabolic mechanism for Ach synthesis.