Physical properties of the transmembrane signal molecule, sn-1-stearoyl 2-arachidonoylglycerol. Acyl chain segregation and its biochemical implications.

sn-1,2-diacylglycerol (DAG), a key intermediate in lipid metabolism, activates protein kinase C and is a fusogen. Phosphoinositides, the main sources of DAG in cell signaling, contain mostly stearoyl and arachidonoyl in the sn-1 and -2 positions, respectively. The polymorphic behavior of sn-1-stearoyl-2-arachidonoylglycerol (SAG) was studied by differential scanning calorimetry, x-ray powder diffraction, and solid state magic angle spinning (MAS) (13)C NMR. Three alpha phases were found in the dry state. X-ray diffraction indicated that the acyl chains packed in a hexagonal array in the alpha phase, and the two sub-alpha phases packed with pseudo-hexagonal symmetry. In the narrow angle range strong diffractions of approximately 31 and approximately 62 A were present. High power proton-decoupled MAS (13)C NMR of isotropic SAG gave 16 distinct resonances of the 20 arachidonoyl carbons and 5 distinct resonances of the 18 stearoyl carbons. Upon cooling, all resonances of stearoyl weakened and vanished in the sub-alpha(2) phase, whereas arachidonoyl carbons from 8/9 to 20 gave distinct resonances in the frozen phases. Remarkably, the omega-carbon of the two acyl chains had different chemical shifts in alpha, sub-alpha(1), and sub-alpha(2) phases. Large differences in spin lattice relaxation of the stearoyl and arachidonoyl methene and methyl groups were demonstrated by contact time (cross-polarization) MAS (13)C NMR experiments in the solid phases alpha, sub-alpha(1), and sub-alpha(2). This shows that stearoyl and arachidonoyl in SAG have different environments in the solid states (alpha, sub-alpha(1), and sub-alpha(2) phases) and may segregate during cooling. The NMR and long spacing x-ray diffraction results suggest that SAG does not pack in a conventional double layer with the two acyls in a hairpin fashion. Our findings thus provide a physicochemical basis for DAG hexagonal phase domain separation within membrane bilayers.

Glycerophospholipid metabolism: back to the future.

It has become customary to regard the various glycerophospholipids as quite similar, and the acyl groups are considered to have little influence on the behaviour of the lipids in membranes or metabolism. Nevertheless, a number of recent observations by the authors and others indicate a high degree of metabolic compartmentation and substrate specificity with regard to the acyl substituents (acyl specificity) of glycerophospholipid metabolising enzymes in intact cells. 1. [32P]Orthophosphate and [3H]glycerol are incorporated into phosphatidylcholine (PC) and phosphatidylethanolamine (PE) of platelets and Swiss 3T3 fibroblasts with a [32P]/[3H]-ratio several fold lower than in glycerol-3-phosphate, phosphatidic acid (PA) and phosphatidylinositol (PI), suggesting distinct metabolic separation (probably by cellular compartmentation) of the glycerol and choline (or ethanolamine) branches of de novo phospholipid biosynthesis. 2. In fibroblasts the [32P]/[3H]-ratio varied 50-fold among the molecular species of PC, PE, PI and PA, which indicates that the enzymes involved in these conversions have some degree of acyl specificity. 3. In vitro assays for lipid-converting enzymes employ detergents, which affect acyl specificity of the enzymes (lipid kinases) both by their chemical nature and concentrations. 4. Thrombin stimulation of platelets causes formation of a multitude of diacylglycerol (DAG) molecular species, but only one major molecular species of PA is formed indicating that the DAG kinase may have distinct acyl specificity in the intact cell. 5. However, this specificity could also result from the net reactions of DAG kinase(s) and PA phosphohydrolase(s), which would constitute an ATP-utilising, paired regulation of the molecular species of PA and the inositol lipids on one hand, and PC, PE phosphatidylserine and triacylglycerol on the other. These findings indicate a high complexity of glycerophospholipid metabolism and a distinct acyl specificity in intact cells that are not apparent from studies in vitro. A major challenge for future research in this area is to bridge the apparent discrepancy between in vivo and in vitro observations regarding glycerophospholipid metabolism, an endeavour that will require more knowledge about the physical chemistry of naturally occurring molecular species than is available today. The most prevailing appreciation of glycerophospholipids among biological scientists to-day is that they can be distinguished functionally, topographically and metabolically only by their head groups and that they form the bilayer in biological membranes. Most of us know that the fatty acid in the sn-2 position is unsaturated and have been indoctrinated that the higher the degree of unsaturation, the greater the fluidity of the membrane.(ABSTRACT TRUNCATED AT 400 WORDS)