Biophysical properties of cytidine diphosphate diacylglycerol in solution.

The physical properties of CDP diacylglycerol derived from egg phosphatidylcholine are very different from those of the common glycerophospholipids, such as phosphatidylcholine. Gently dispersed in buffer (5 mM phosphate, 0.15 M NaCl, pH 7.4), the liponucleotide initially forms an opalescent suspension of spherical vesicles, up to 50 micron in diameter, which appear to be unilamellar. These large vesicles are unstable and, independently of initial concentration, unstirred suspensions are no longer turbid after being incubated for about 1 h at room temperature. The passage of samples through Sepharose and Sephadex at increasing time intervals after the first hour reveals a continuing but slow diminution in size until, at about two days, a final peak is obtained which remains invariant for longer times. Chromatography of these ultimate stable micelles on Sephadex G-200 gives a Stokes radius of 4.2 nm. Their sedimentation coefficient extrapolated to zero concentration is 6.1 S. These numbers, combined with a partial specific volume of 0.835 ml X g-1, give an anhydrous mass of 155 000 Da and an aggregation number of 158. Although the data suggest the particles to be spherical, other compact forms cannot be excluded. Proton NMR at 220 MHz shows time-dependent spectral changes which are consistent with the slow structural transformation observed by gel-filtration chromatography, and indicate that the sugar and cytosine groups in the ultimate micelles apparently are motionally restricted. The critical micelle concentration is near 6 microM, but micelle-free molecule equilibration requires at least 7 days at a total concentration of 89 microM. Sonication considerably decreases the time required for the vesicle-micelle transformation and the micelle-free molecule equilibration. Some implications for enzymology are discussed.