Metabolism of N-acylethanolamine phospholipids by a mammalian phosphodiesterase of the phospholipase D type

Membrane-associated phospholipase D activity in rat sciatic nerve

Rat sciatic nerve contains a membrane-bound phospholipase D that catalyzes the hydrolysis of exogenous phosphatidylcholine (PC) to phosphatidic acid (PA) and choline. The enzyme is associated with a particulate fraction consisting primarily of microsomes and myelin. This fraction also contains phosphatidate phosphohydrolase activity leading to the production of diacylglycerols (DAG). The phosphohydrolase activity can be completely inhibited by NaF. Hydrolysis of exogenous PC requires detergent and is linear up to about 40 micrograms of protein at a pH optimum of 6.5. In the absence of NaF, the sum of PA and DAG increases linearly for 40 min, whereas in its presence, PA production is linear for only 15 min. At optimum conditions, PC hydrolysis proceeds at 15 nmol/h/mg of protein. Addition of increasing amounts of ethanol to the incubation system leads to the generation of increasing amounts of phosphatidylethanol, indicating transphosphatidylation activity. At an ethanol concentration of 0.4 M, phosphatidylethanol represents about one-half of the reaction products generated at approximately the same rate of enzymic activity observed in the absence of ethanol. Higher ethanol concentrations are inhibitory.

Phospholipase D activity in subcellular membranes of rat ventricular myocardium

The phospholipase D (PL D), which catalyzes the formation of phosphatidic acid (PA), was studied in rat myocardium using 14C-labelled phosphatidylcholine (PC) as an exogenous substrate. Subcellular distribution experiments indicated the presence of PL D in particulate fractions only. Different procedures for the isolation of purified cardiac subcellular organelles showed the presence of PL D in sarcolemma (SL), sarcoplasmic reticulum (SR) and mitochondria with 14-, 11- and 5-fold enrichment when compared to the homogenate value, respectively. The activity of SL PL D was observed over a narrow acid pH range with an optimum at 6.5, and it showed a high specificity for PC while phosphatidylethanolamine and phosphatidylinositol showed a low rate of hydrolysis. Under optimal conditions, PA formation was linear for a 90-min period of incubation and the reaction rate was constant for 10 to 100 micrograms SL protein in the assay medium. The SR PL D displayed properties similar to those seen with the SL PL D. In membrane fractions PL D was also found to catalyze a transphosphatidylation reaction for the synthesis of phosphatidylglycerol. Assessment of the intramembranal levels of radioactive 1,2-diacylglycerol (DAG) in the absence or presence of KF suggested the presence of an active PA phosphohydrolase activity. This study indicates that a PC-specific PL D activity is localized in different membrane systems of the myocardium and may be associated with PA phosphohydrolase to act in a coordinated manner. The functional significance of PL D-dependent formation of PA in cardiac membranes is discussed.

Phospholipase D in cell signalling and its relationship to phospholipase C

Phospholipases C and D are phosphodiesterases which act on phospholipid head groups. Although the presence of these enzymes in living organisms has long been known, it is only recently that their role in cell signal transduction has been appreciated. The new developments on phospholipases D (PLD) are especially noteworthy, since these enzymes catalyze a novel pathway for second messenger generation. In a variety of mammalian cell systems, several biological or chemical agents have recently been shown to stimulate PLD activity. Depending on the system, activation of PLD has been suggested to be either dependent on, or independent of, Ca2+ and protein kinase C. PLD primarily hydrolyses phosphatidylcholine (PC) but phosphatidylinositol and phosphatidylethanolamine have also been reported as substrates. Different forms of endogenous PLD may also exist in cells. Exogenous addition of PLD causes alterations in cellular functions. In many instances, Ca2+ mobilizing agonists may stimulate both PLC and PLD pathways. Interestingly, several metabolites of these two enzymes are second messengers and are common to both pathways (e.g. phosphatidic acid, diglyceride). This has raised the issue of the interrelationship between these pathways. The regulation of either PLC or PLD by cellular components, e.g. guanine nucleotide binding proteins or protein kinases, is under intense investigation. These recent advances are providing novel information on the significance of phospholipase C and D mediated phospholipid turnover in cellular signalling. This review highlights some of these new discoveries and emerging issues, as well as challenges for future research on phospholipases.

Biochemical characterization of phospholipase D activity from human neutrophils

We have found a phospholipase D activity in the postnuclear fraction of human neutrophils, employing phosphatidylinositol as exogenous substrate. This phospholipase D activity was assessed by both phosphatidate formation and by free inositol release in the presence of 15 mM LiCl in the reaction mixture and in the absence of Mg2+ ions to prevent inositol-1-phosphate phosphatase activity. To assess further the phospholipase D activity, we studied its capacity to catalyze a transphosphatidylation reaction, as a unique feature of the enzyme. It was detected as [14C]phosphatidylethanol formation when the postnuclear fraction was incubated with [14C]phosphatidylinositol in the presence of ethanol. The phospholipase D showed a major optimum pH at 7.5 and a minor one at pH 5.0. Neutral and acid phospholipase D activities were differentially located in subcellular fractionation studies of resting neutrophils, namely in the cytosol and in the azurophilic granules, respectively. Neutral phospholipase D required Ca2+ ions to the active, whereas the acid enzyme activity was Ca2(+)-independent. The neutral phospholipase D activity showed a certain specificity for phosphatidylinositol, as it was able to hydrolyze phosphatidylinositol at a much higher rate than phosphatidylcholine, in the absence and in the presence of different detergents. This neutral phospholipase D activity behaved as a protein of high molecular mass (350-400 kDa) by gel filtration chromatography. Moreover, neutral phospholipase D activity was detected in the postnuclear fraction of human monocytes, by measuring free inositol release from phosphatidylinositol as exogenous substrate, under the same experimental conditions as those used with neutrophils. The enzyme displayed similar specific activities in both cell types as well as the same degree of activation after cell stimulation with the calcium ionophore A23187. These results demonstrate the existence of two phospholipase D activities with different pH optima and intracellular location in human neutrophils. Furthermore, these results suggest that this phospholipase D can play a role in signal-transducing processes during cell stimulation in human phagocytes.

Effects of long-chain N-acylethanolamines on lipid peroxidation in cardiac mitochondria

A long-chain N-acylethanolamine (N-oleoyl-2-aminoethanol) is shown to inhibit the production of thiobarbituric acid-reactive substances in rat heart mitochondria treated with Fe2+ or Fe3+/ADP. The inhibition is concentration-dependent in the range 50-150 microM of the agent and can be nearly complete depending on the type and amount of the free radical-generating system. Structural analogues of N-acylethanolamine are inhibitory as well, but neither oleic acid nor ethanol-amine has measurable effects. N-Oleoyl-2-aminoethanol affects peroxidation of linoleic acid micelles only minimally and has no effect on deoxyribose peroxidation.

N-Acylation of ethanolamine phospholipids by acyl transfer does not involve hydrolysis

N-Acylethanolamine phospholipids occur in infarcted but not in normal canine myocardium. Their synthesis is catalyzed by a membrane-bound, Ca2+-requiring N-acyltransferase (transacylase) which transfers acyl groups from the sn-1 position of various phospholipids including phosphatidylethanolamine to the amino group of ethanolamine phospholipids. When dog heart mitochondria are incubated in media containing Ca2+ and H2(18)O, the resulting N-acylethanolamine phospholipids do not accumulate 18O in either the amide or 1-O-acyl groups. The results indicate that acyl transfer occurs without hydrolysis, most likely through an acyl-enzyme complex which may be covalently linked.

A glycan-phosphatidylinositol-specific phospholipase D in human serum

A group of proteins anchored to the cell by phosphatidylinositol (PI) has recently been identified. The significance of this new class of membrane anchor is unknown; one possibility is that it facilitates release of the molecule by phospholipases. In fact, phospholipase C enzymes specific for the complex carboxyl-terminal glycolipids of these proteins have been isolated from African trypanosomes and from hepatocyte plasma membranes. This study reports the discovery of a glycan-PI-specific phospholipase D in human serum that cleaves both the membrane form of the variant surface glycoprotein of African trypanosomes and its glycolipid precursor, but not phosphatidylethanolamine, phosphatidylcholine, or phosphatidylinositol. Decay-accelerating factor, another PI-anchored molecule, is also cleaved by the enzyme and converted from a hydrophobic to a soluble protein. The enzyme is Ca2+-dependent, heat labile, and not affected by the inhibitor of serine proteases, phenylmethylsulfonylfluoride. Its function is not known, but the present findings indicate that it participates in the metabolism of glycolipid-anchored membrane proteins.

Hydrolysis of N-acylated glycerophospholipids by phospholipases A2 and D: a method of identification and analysis

We have previously identified N-acylethanolamine phospholipids in infarcted dog heart and in normal fish brain by chemical and enzymatic degradation. We now report that hydrolysis with phospholipase D from Streptomyces chromofuscus removes N-acylethanolamine from N-acylethanolamine phospholipids and lyso N-acylethanolamine phospholipids, or N-acylserine from lyso N-acylserine phospholipids. At acidic pH, a phosphatase present in the phospholipase D preparation further hydrolyzes the resulting phosphatidic acid (PA) or lyso-PA to diacyl- or monoacylglycerol. Because N-acylserine phospholipids are a poor substrate for the phospholipase D, pretreatment with phospholipase A2 (Trimeresurus flavoviridis venom) is used to remove the 2-O-acyl group. Thus, both types of N-acylated phospholipids can be analyzed by consecutive phospholipase A2 and phospholipase D treatment. Reaction products, i.e., free fatty acids, monoacylglycerols and N-acylethanolamine or N-acylserine, are separable by thin-layer chromatography. Both N-acyl components can be further characterized by conversion to the t-butyldimethylsilyl derivatives. The method was used to identify and analyze the N-acylserine phospholipids of bovine brain.

N-acylethanolamine phospholipid metabolism in normal and ischemic rat brain

N-Acylethanolamine phospholipids accumulate in rat brain during post-decapitative ischemia. Small amounts of these phospholipids consisting primarily of diacyl and alkenylacyl species can be detected within 15 min of ischemia and they increase linearly for 60 min. This ischemia-induced synthesis is more pronounced in developing rat brain (approx. 5.0 nmol/h per mumol lipid P) than in adult brain (0.4 nmol). Pulse labeling experiments with subcellular preparations of 10-day-old rat brain indicate a precursor-product relationship between ethanolamine phospholipids and their N-acyl analogs. N-Acylation of endogenous substrates occurs with both microsomes and mitochondria, exhibits a pH optimum of 10 and requires 1 mM Ca2+ for maximal (0.2 mM Ca2+ for half maximal) activity. Cell-free preparations of both developing and adult rat brain contain a phosphodiesterase which hydrolyzes N-acylphosphatidylethanolamine to phosphatidic acid and N-acylethanolamine. The latter is further hydrolyzed to fatty acid and ethanolamine by an amidohydrolase. [1-3H]Ethanolamine, injected intracerebrally or intraperitoneally into 13- and 18-day-old rats, is incorporated into brain ethanolamine phospholipids. Since small amounts of radioactivity are also associated with N-acylethanolamine phospholipids 5 and 24 h after injection of the substrate, it appears that these phospholipids may occur at a very low level as a natural lipid constituent of rat brain.

Occurrence of N-acylethanolamine phospholipids in fish brain and spinal cord

N-Acylethanolamine phospholipids were identified in the central nervous system of the fresh water fish, pike (Esox lucius) and carp (Cyprinus carpio), at levels ranging from 0.1 to 0.9% of total phospholipid. The N-acylethanolamine phospholipids of carp brain were isolated and characterized by chemical, biochemical and spectroscopic methods. Two major species, 1,2-diacyl-sn-glycero-3-phospho(N-acyl)ethanolamines (approx. 30%) and 1-O-(1'-alkenyl)-2-acyl-sn-glycero-3-phospho(N-acyl)ethanolamines (approx. 70%) were identified. The N-acyl groups of each species consisted primarily of 16:0 (approx. 60%) but also contained 16:1, 18:0 and 18:1 (approx. 10% each) and a number of trace constituents. The N-acylethanolamine phospholipids had O-acyl and O-alkenyl group compositions similar but not identical to those of the ethanolamine phospholipids of the same tissue. N-Acylethanolamine phospholipids were present in all subcellular fractions of carp brain, except mitochondria.

Comparison of the hydrolysis of phosphatidylethanolamine and phosphatidyl(N-acyl)ethanolamine in Dictyostelium discoideum amoebae

In Dictyostelium discoideum, (N-acyl)ethanolamine glycerophospholipids disappear as the amoebae aggregate, whereas the amount of ethanolamine glycerophospholipids remains relatively constant, suggesting that each type of ethanolamine-containing phospholipid might have a separate metabolic pathway. To study their metabolism, phosphatidylethanolamine and phosphatidyl(N-acyl)ethanolamine containing either [14C]ethanolamine or a 14C-labeled sn-2 fatty acyl group were incubated with D. discoideum homogenates, and the conversion of the substrates into radioactive products was monitored. At pH values 3.8 and 4.5, phosphatidyl(N-acyl)ethanolamine was hydrolyzed by a phospholipase A1 to form the sn-2 acyl form of the lipid. Only minor hydrolysis occurred at pH values of 5.2 or higher. (N-acyl)Ethanolamine was also released by a phospholipase D type activity at 0.1 the rate of the lysophospholipid formation. Phosphatidyl(N-acyl)ethanolamine was not hydrolyzed to form phosphatidylethanolamine or water soluble components. At pH 7.2 and at the low pH range of 3.8-4.5, phosphatidylethanolamine was hydrolyzed to lysophosphatidylethanolamine, which was then further degraded to water-soluble components. At pH 7.2, a phospholipase A2 initially hydrolyzed the phosphatidylethanolamine, whereas at the low pH range a phospholipase A1 was the most active enzyme. Although both types of ethanolamine-containing phospholipid were hydrolyzed by a phospholipase A1 at the low pH range, phosphatidylethanolamine hydrolysis was more sensitive to inhibition by Trition X-100, and phosphatidylethanolamine was hydrolyzed to water-soluble components, whereas phosphatidyl(N-acyl)ethanolamine was not. At pH 7.2, phosphatidylethanolamine was hydrolyzed, but phosphatidyl(N-acyl)ethanolamine was not hydrolyzed at all. These results indicate that there are separate routes of degradation for the two types of ethanolamine-containing phospholipid in D. discoideum.

Properties of canine myocardial phosphatidylethanolamine N-acyltransferase

Dog heart contains a membrane bound N-acyltransferase (transacylase) which transfers acyl groups from the sn-1 position of membrane phospholipids to the amino group of ethanolamine phospholipids in the presence of millimolar Ca2+ concentrations. Using crude membrane preparations, we found this N-acyltransferase activity to be heat sensitive and inhibited by sulfhydryl reagents. Pretreatment of a membrane fraction with trypsin reduced N-acyltransferase activity to 60% while pretreatment with trypsin and Triton X-100 together reduced it to 30% of the control value. At pH 8.0 both Sr2+ and Mn2+ could fully substitute for Ca2+ with respect to optimum ion concentration and molecular species of the product formed in dog heart membranes from endogenous substrates. Ba2+ was equally effective in achieving N-acylation of ethanolamine phospholipids while other divalent cations were less effective or ineffective. The reaction exhibited a pH optimum of 8.5 to 9.0 with both Ca2+ and Sr2+ while Mn2+ precipitated above pH 8.0 resulting in decreased N-acylation activity. Both phosphatidylcholine and 1-acyl lysophosphatidylcholine could serve as acyl donors. Triton X-100 at a concentration of 0.1% stimulated acyl transfer from exogenous phosphatidylcholine but inhibited acyl transfer from lysophosphatidylcholine.

Catabolism of N-acylethanolamine phospholipids by dog brain preparations

N- Acylphosphatidylethanolamine , incubated with dog brain homogenate or microsomes, was hydrolyzed to phosphatidic acid and N-acylethanolamine by a phosphodiesterase of the phospholipase D type. In the absence of F-, phosphatidic acid was further hydrolyzed to diacylglycerol and Pi while N-acylethanolamine was hydrolyzed by an amidase to fatty acid and ethanolamine. The phosphodiesterase showed an alkaline pH optimum and was also active towards N- acetylphosphatidylethanolamine , N-acyl-lysophosphatidylethanolamine, and glycerophospho (N-acyl)ethanolamine but showed little activity toward phosphatidylethanolamine and phosphatidylcholine. Ca2+ stimulated slightly at low concentrations but inhibited at higher concentrations. Triton X-100 stimulated the hydrolysis of N- acylphosphatidylethanolamine , inhibited that of N-acyl-lysophosphatidylethanolamine and glycerophospho (N-acyl)ethanolamine, and had no effect on phosphatidylethanolamine or phosphatidylcholine hydrolysis. The N-acylethanolamine hydrolase (amidase) was also present in the microsomal fraction and exhibited a pH optimum of 10.0. In addition to hydrolysis by the phosphodiesterase, N- acylphosphatidylethanolamine was also catabolized by microsomal phospholipases A1 and/or A2 to N-acyl-lysophosphatidylethanolamine, some of which was further hydrolyzed to glycerophospho (N-acyl)ethanolamine.