Identification of minor metabolites of phospholipid signal molecules in [(32)P]P(i)-labelled platelets

Incubation of blood platelets with (32)P-labelled inorganic phosphate for 60 min leads to incorporation of radioisotope mainly into phosphatidylinositol (PI), phosphatidylinositol-4-phosphate (PIP) and phosphatidyl-4,5-bisphosphate (PIP(2)) in resting platelets and into phosphatidic acid (PA) in activated platelets. Small amounts of other important phosphoinositide isomers also become labelled following platelet activation, among them the 3-phosphorylated derivatives. In addition, several other faintly labelled spots are visible on TLC separations. Three of these lipids have now been identified as lysophosphatidylinositol (lysoPI), lysophosphatidic acid (lysoPA) and CDP-diacylglcerol (CDP-DAG).[(32)P]LysoPI was present in resting and activated platelets, whereas [(32)P]lysoPA and [(32)P]CDP-DAG were observed only upon platelet activation. The phosphoinositide cycle turns over without accumulation of [(32)P]PA and [(32)P]CDP-DAG in resting platelets. A large increase (as much as 40-fold) in the steady-state level of [(32)P]PA is seen in thrombin-activated platelets. A slight increase in the steady-state levels of [(32)P]CDP-DAG is accompanied by a similar increase in [(32)P]PI and larger increases in [(32)P]PIP and [(32)P]PIP(2) (about 50%), which is indicative of a general increase in flux in the PPI cycle. Elevation of CDP-DAG levels is probably only a reflection of increased flux, whereas lysoPA and lysoPI have been reported to have diverse signalling functions in various cells.

Substrate-induced membrane association of phosphatidylserine synthase from Escherichia coli

To better establish the intracellular location of the phosphatidylserine synthase of Escherichia coli and hence better understand how it is regulated in the cell, we compared the size, function, and binding properties of the enzyme made in vitro with the enzyme found in cell lysates and with the purified enzyme. The enzyme made either in vivo or in an active form in vitro was found primarily associated with the ribosomal fraction of the cell and had the same apparent molecular mass as the purified enzyme. These results were unaffected by the presence of protease inhibitors. Addition of unsupplemented E. coli membranes or membranes supplemented with phosphatidylethanolamine did not affect the subcellular distribution of the enzyme in these experiments. However, addition of membranes supplemented with either the lipid substrate, CDP-diacylglycerol, or the lipid product, phosphatidylserine, resulted in membrane association by the enzyme rather than ribosomal association. Addition of membranes supplemented with acidic lipids also brought about membrane association, but this association was primarily ionic since it was disrupted by high salt concentrations. These results strongly suggest that the ribosomal location of this enzyme is not the result of some modification event occurring after cell lysis and that the normal functioning of the enzyme involves membrane association which is primarily induced by the presence of a membrane-associated substrate.

Enzymes of phospholipid synthesis: axonal versus Schwann cell distribution

Using quantitative EM autoradiography to localize sites of incorporation of tritiated inositol and choline into mouse sciatic nerve, we observed a substantial axon-based phosphatidylinositol synthesis, but no axonal phosphatidylcholine synthesis. In the present communication we provide biochemical evidence for the axonal transport of CDP-diglyceride:inositol transferase (EC 2.7.8.11), the terminal enzyme in de novo phosphatidylinositol biosynthesis. Axonal transport of 1,2-diacyl-glycerol:CDP-choline choline phosphotransferase (EC 2.7.8.2), required for de novo phosphatidylcholine synthesis, was not apparent in these studies. During subcellular fractionation activities for the synthesis of phosphatidylinositol by inositol transferase (IT) and phosphatidylcholine by choline phosphotransferase (CPT) were recovered in crude microsomal fraction of rat sciatic nerve. However, CPT was much more highly enriched in the microsome fraction than IT, which may be an indication of the different subcellular localizations of these enzymes. Following ligation, we detected localized increases in the activities of both enzymes in 5 (and 3) mm segments taken immediately proximal and distal to the ligature. Both activities increased in a linear fashion in the proximal segments over the ensuing 72 h period. It took about 40 h (IT) and 56 h (CPT) for the activities in the segments proximal to the ligature to double compared to unligated contralateral (control) nerves. The time-dependent accumulation of IT was primarily due to axonal transport, while that of CPT was largely a result of increased enzyme activity in local Schwann cells. Evidence came from double ligation studies, where a proximal ligature, acting to restrict orthograde axonal transport, reduced accumulation in a distal ligature by 80% for IT, but only 28% for CPT. Conversely, blockage of the Schwann cell response with actinomycin D, reduced accumulation of CPT by 83% and IT by only 36%. Finally, light microscopic autoradiography was used to show that in the segment proximal to the ligature, tritiated inositol incorporation into lipid was primarily axonal, whereas that of tritiated choline remained primarily associated with Schwann cells.

Isolation and characterization of cytidine diphosphate diglyceride from beef liver

Cytidine diphosphate diglyceride was isolated from beef liver by a combination of silicic acid column, DEAE-cellulose column, and this layer chromatography. The product (5.8 to 17.4 mumol/kg of liver) contained cytidine/phosphate/fatty acids in the molar proportions 1.05/2.0/2.05 (theoretical, 1.0/2.0/2.0) (average for three preparations). The liponucleotide was split quantitatively by a partially purified hydrolase from Escherichia coli, specific for CDP-diglyceride, (Raetz, C. R. H., Hirschberg, C. B., Dowhan, W., Wickner, W. T., and Kennedy, E. P. (1972) J. Biol. Chem. 247, 2245-2247) into phosphatidic acid and a water-soluble nucleotide that was chromatographically identical with CMP. No dCMP was located in these hydrolysates. The liver liponucleotide was more effective than a synthetic preparation of CDP-diglyceride in promoting the formation of phosphatidylinositol with guinea pig brain microsomes. The fatty acid composition of CDP-diglyceride was compared with metabolically related phospholipids from beef liver. The liponucleotide had a similar composition to phosphatidylinositol, characterized by a high level of stearate and with arachidonate as the major unsaturated fatty acid. The content of arachidonate in both lipids was significantly higher than that in phosphatidic acid. The profile of fatty acids of cardiolipin was quite unlike that of CDP-diglyceride. These findings suggest several alternatives for the metabolic origins of beef liver CDP-diglyceride: (a) CDP-diglyceride is formed from an atypical pool of phosphatidic acid, (b) the enzyme is selective for arachidonoyl-containing species of phosphatidic acid, (c) the liponucleotide may also be derived from phosphatidylinositol by the back-reaction of CDP-diglyceride: inositol phosphatidyltransferase.