Abstract
A [Na+]-gradient-dependent Ca2+ transporter from brain synaptic plasma membranes has been isolated, purified, and reconstituted into brain phospholipid vesicles. The purification was achieved by sucrose-gradient centrifugation after solubilization of the synaptic membranes in cholate in the presence of a 30-fold excess (by weight) of added brain phospholipids and [Na+]-gradient-dependent Ca2+ loading of the reconstituted vesicles. A 128-fold increase in specific activity of [Na+]-gradient-dependent Ca2+ uptake per mg of protein has been obtained. The purified and reconstituted vesicles took up Ca2+ only in response to an outward-oriented [Na+] gradient. The Ca2+ uptake could be inhibited by dissipation of the [Na+] gradient with nigericin. Successful purification was based on the initial [Na+]-gradient dependency of the Ca2+-transport process, the magnitude of the [Na+]-gradient-dependent uptake, and the presence of purified brain phospholipids. Analysis of the sucrose-gradient-purified reconstituted vesicles on NaDodSO4/polyacrylamide gels showed that the activity coincided with enriched appearance of a 70,000-Da protein.