Pregnenolone binds to microtubule-associated protein 2 and stimulates microtubule assembly

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The National Academy of Sciences

RESUMO

Fetal or adult rat-brain cytosol and fetal rat-brain microtubules contain a high-affinity, low-capacity pregnenolone-binding protein. The equilibrium dissociation constant is in the 30–50 nM range. The best competitors (in decreasing order) are pregnenolone sulfate, progesterone, Δ5-pregnene-3β,20α-diol, and 3β-hydroxy-5α-pregnan-20-one. It was hypothesized that the pregnenolone-binding protein pertained to microtubule-associated proteins (MAPs). Indeed, partial purification of fetal brain cytosol by fast pressure liquid chromatography with sequential ion-exchange and gel-filtration columns yielded two fractions, one of very high molecular mass, >200 kDa, and the other of 40–60 kDa, enriched in [3H]pregnenolone-binding activity and in proteins immunolabeled with monoclonal anti-tubulin and anti-MAP2 antibodies. Because many proteins are associated with microtubules, binding assays were repeated with purified calf-brain tubulin, MAP2, and Tau protein. Only the MAP2 fraction showed saturable [3H]pregnenolone binding with an affinity very close to that of rat-brain microtubules, but with a much larger concentration of binding sites (16 pmol/mg MAP2), which was increased more than 8-fold after copolymerization of MAP2 with tubulin. Finally, steroid effects on microtubule-assembly kinetics were assayed. Pregnenolone induced a large, dose-related increase of both the rate and extent of MAP2-induced tubulin assembly, whereas progesterone, inactive per se, counteracted the stimulatory effect of pregnenolone. Electron microscopic analysis confirmed that pregnenolone-increased assembly of microtubules produced a completely normal structure. The stimulatory effect on MAP2–tubulin interaction was also observed in fetal rat-brain neuron cultures. Therefore, we propose a mechanism of neurosteroid action, the control of microtubule or, more generally, of neural cytoskeleton dynamics, with potential roles in brain development, plasticity, and aging.

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