Microtubule assembly in developing mammalian brain

Abstract

Microtubule protein was measured in mouse brain homogenates by quantitative colchicine binding. Neonatal animals contained more than twice the amount of brain tubulin as adult mice. The percentage of colchicine-binding protein which was polymerized was determined by extracting brain at room temperature into a medium designed to stabilize intact microtubules. Under identical conditions and tubulin concentrations, neonatal brain tubulin (colchicine-binding activity) had a greater proportion of the total extracted in an apparently polymerized state (pelletable by centrifugation) than did adult brain. A slight variation in the ratio of assembled to unassembled tubulin was observed with varying protein concentration (volume of extract), indicating that the values obtained may not reflect exactly the in vivo situation, because a rapid equilibration takes place upon homogenization. At all protein concentrations, the neonatal brain extracts contained a significantly greater proportion of assembled tubulin than did adult brain. This proportion began to fall at 5 days postnatal and reached the adult level at 30 days. The tubulin assembled/not assembled ratios were not altered by addition of nucleoside triphosphates, additional EGTA, or sulfhydryl protecting agents, and did not vary with preparation times of 30–90 min. The colchicine-binding reaction and decay of colchicine-binding activity with time were similar in extracts of different aged mouse brains, with neonatal slightly more stable than adult. Pools of tubulin from any age which were soluble at room temperature (unpolymerized) could not repolymerize well in vitro when incubated with GTP at 37 °C, whereas pools of tubulin which were sedimentable at room temperature (polymerized) could be redissolved at 0 °C and readily reassembled at 37 °C. The neonatal extract tubulin was thus more polymerization competent than the adult extracts; this correlates with a greater proportion of assembled tubulin in extracts at room temperature and possibly in vivo.