Studies on base-exchange reactions of phospholipids in rat brain particles and a "solubilized" system.

A filtration-method on Millipore-membranes for the assay of the base-exchange reaction was described. Its advantage over the usual procedure based upon the extraction and the washing of lipids was discussed with the viewpoint of processing many samples, which would be indispensable for purifying the enzyme.The reaction showed an absolute dependency for calcium ion with different optimal concentrations for each of the three bases, a sensitivity to inhibition by high ionic strength, and a pH optimum around 9.0. Exogenously added phospholipid, asolectin, gave a slight stimulation for ethanolamine and l-serine incorporation at a low concentration while choline incorporation was essentially inhibited at all concentrations examined. In heat-denaturation experiments with the particulate and soluble the incorporation of choline into lipid was more sensitive than that of ethanolamine and l-serine. A developmental study showed that brain particles sedimenting between 10,000 and 35,000g prepared from rats aged 22–27 days readily incorporated ethanolamine, l-serine, and choline into their corresponding phosphatidyl compound.Several procedures for solubilization of the “base-exchange” enzyme were examined. The most effectively solubilized preparation was obtained by the use of an ionically balanced detergent, Miranol H2M. This preparation showed a marked dependency on exogenously added phospholipids for its maximal enzymic activity, had a pH optimum at around 7.2, and had an absolute requirement for Ca²⁺. This particular detergent at a concentration of 1% ($\text{w}\text{v}$) solubilized approximately 50% of the protein, and about 30% of the phospholipids, 40% of the cerebrosides, and only 11% of the cholesterol originally present in the particles. The relative proportions of different phospholipids solubilized by the detergent were, however, similar to those present in the original particles.The base-exchange reaction catalyzed by the solubilized enzyme was found to be highly sensitive to ionic strength, and the inhibitory effect of a specific monovalent cation paralleled its ionic size. Substantial differences in the K_m value for each of the substrates with only slight differences in V were observed.The choice of solubilizing agents in relation to these properties and to the maintenance of the activity of the base-exchange reaction was discussed.