The size and curvature of anionic covesicle substrate affects the catalytic action of cytosolic phospholipase A2.

Cytosolic phospholipase A2 (cPLA2) is normally located in the cytosol, but in response to cellular activation the enzyme binds to the membrane at the lipid/water interface where it catalyzes the hydrolysis of the sn-2 ester of arachidonate-containing phospholipids. Synthetic phospholipid vesicle systems have been used in kinetic and mechanistic analyses of cPLA2, but these systems result in a rapid loss of enzyme activity. In the present research, covesicles of 1,2-dimyristoyl-sn-glycero-3-phosphomethanol (DMPM) containing 相似文献   

Interfacial catalysis by phospholipase A2: substrate specificity in vesicles.

The binding equilibrium of phospholipase A2 (PLA2) to the substrate interface influences many aspects of the overall kinetics of interfacial catalysis by this enzyme. For example, the interpretation of kinetic data on substrate specificity was difficult when there was a significant kinetic contribution from the interfacial binding step to the steady-state catalytic turnover. This problem was commonly encountered with vesicles of zwitterionic phospholipids, where the binding of PLA2 to the interface was relatively poor. The action of PLA2 on phosphatidylcholine (PC) vesicles containing a small amount of anionic phospholipid, such as phosphatidic acid (PA), was studied. It was shown that the hydrolysis of these mixed lipid vesicles occurs in the scooting mode in which the enzyme remains tightly bound to the interface and only the substrate molecules present on the outer monolayer of the target vesicle became hydrolyzed Thus the phenomenon of scooting mode hydrolysis was not restricted to the action of PLA2 on vesicles of pure anionic phospholipids, but it was also observed with vesicles of zwitterionic lipids as long as a critical amount of anionic compound was present. Under such conditions, the initial rate of hydrolysis of PC in the mixed PC/PA vesicles was enhanced more than 50-fold. Binding studies of PLA2 to vesicles and kinetic studies in the scooting mode demonstrated that the enhancement of PC hydrolysis in the PC/PA covesicles was due to the much higher affinity of the enzyme toward covesicles compared to vesicles of pure PC phospholipids. A novel and technically simple protocol for accurate determination of the substrate specificity of PLA2 at the interface was also developed by using a double-radiolabel approach. Here, the action of PLA2 in the scooting mode was studied on vesicles of the anionic phospholipid 1,2-dimyristoyl-sn-glycero-3-phosphomethanol that contained small amounts of 3H- and 14C-labeled phospholipids. From an analysis of the 3H and 14C radioactivity in the released fatty acid products, the ratio of substrate specificity constants (kcat/KMS) was obtained for any pair of radiolabeled substrates. These studies showed that the PLA2s from pig pancreas and Naja naja naja venom did not discriminate between phosphatidylcholine and phosphatidylethanolamine phospholipids or between phospholipids with saturated versus unsaturated acyl chains and that the pig enzyme had a slight preference for anionic phospholipids (2-3-fold). The described protocol provided an accurate measure of the substrate specificity of PLA2 without complications arising from the differences in binding affinities of the enzyme to vesicles composed of pure phospholipids.     

Substrate specificities and properties of human phospholipases A2 in a mixed vesicle model.

Studies of the specificity of phospholipases A2 (PLA2s) for different substrates have usually been carried out in vesicles or mixed micelles, where differences in shape, size, or charge of vesicles formed with different phospholipids may give misleading results. Another factor is binding of the enzyme to the phospholipid surface, which has recently been addressed using vesicles of an anionic phospholipid, dimyristoyl-sn-glycero-3-phosphomethanol (DMPM) to which some extracellular PLA2s were shown to bind with a very high affinity (Jain, M. K., and Berg, O. G. (1989) Biochem. Biophys. Acta 1002, 127-156). In the present report we have used a similar system to study the substrate preferences of two human PLA2s that are thought to be physiologically relevant in the metabolism of arachidonic acid: a recombinant form of the human synovial fluid (14 kDa) PLA2 and the cytosolic (85 kDa) PLA2 found in monocytic cells. It is shown that both human enzymes bind tightly to DMPM vesicles and follow the basic characteristics of processive hydrolysis in this model using analysis of progress curves and substrate competition experiments. Mixed vesicles containing DMPM with small amounts (3-5 mol%) of other phospholipids have been used to study the substrate selectivity of the two human isoenzymes. The synovial fluid PLA2 shows a clear preference (approximately 7-fold) for sn-glycero-3-phosphoethanolamine over sn-glycero-3-phosphocholine. Within glycerophosphocholines, this enzyme displays little preference for the sn-2 fatty acyl group, and a slight preference for phospholipids with sn-1-acyl versus sn-1-alkyl substituents. In contrast, the cytosolic PLA2 shows a marked selectivity for arachidonoyl in the sn-2 position and only minor differences in selectivity for the polar head group in the sn-3 position. This enzyme does not distinguish between sn-1-acyl and sn-1-alkyl subclasses of glycerophosphocholines.     

Competitive, reversible inhibition of cytosolic phospholipase A2 at the lipid-water interface by choline derivatives that partially partition into the phospholipid bilayer.

Cytosolic phospholipase A2 (cPLA2) catalyzes the selective release of arachidonic acid from the sn-2 position of phospholipids and is believed to play a key cellular role in the generation of arachidonic acid. When assaying the human recombinant cPLA2 using membranes isolated from [3H]arachidonate-labeled U937 cells as substrate, 2-(2'-benzyl-4-chlorophenoxy)ethyl-dimethyl-n-octadecyl-ammonium chloride (compound 1) was found to inhibit the enzyme in a dose-dependent manner (IC50 = 5 microM). It was over 70 times more selective for the cPLA2 as compared with the human nonpancreatic secreted phospholipase A2, and it did not inhibit other phospholipases. Additionally, it inhibited arachidonate production in N-formyl-methionyl-leucyl-phenylalanine-stimulated U937 cells. To further characterize the mechanism of inhibition, an assay in which the enzyme is bound to vesicles of 1,2-dimyristoyl-sn -glycero-3-phosphomethanol containing 6-10 mol % of 1-palmitoyl-2-[1-14C]arachidonoyl-sn-glycero-3-phosphocholine was employed. With this substrate system, the dose-dependent inhibition could be defined by kinetic equations describing competitive inhibition at the lipid-water interface. The apparent equilibrium dissociation constant for the inhibitor bound to the enzyme at the interface (KI*app) was determined to be 0.097 +/- 0.032 mol % versus an apparent dissociation constant for the arachidonate-containing phospholipid of 0.3 +/- 0.1 mol %. Thus, compound 1 represents a novel structural class of inhibitor of cPLA2 that partitions into the phospholipid bilayer and competes with the phospholipid substrate for the active site. Shorter n-alkyl-chained (C-4, C-6, C-8) derivatives of compound 1 were shown to have even smaller KI*app values. However, these short-chained analogs were less potent in terms of bulk inhibitor concentration needed for inhibition when using the [3H]arachidonate-labeled U937 membranes as substrate. This discrepancy was reconciled by showing that these shorter-chained analogs did not partition into the [3H]arachidonate-labeled U937 membranes as effectively as compound 1. The implications for in vivo efficacy that result from these findings are discussed.     

Studies of the role of group VI phospholipase A2 in fatty acid incorporation, phospholipid remodeling, lysophosphatidylcholine generation, and secretagogue-induced arachidonic acid release in pancreatic islets and insulinoma cells.

An 84-kDa group VI phospholipase A2 (iPLA2) that does not require Ca2+ for catalysis has been cloned from Chinese hamster ovary cells, murine P388D1 cells, and pancreatic islet beta-cells. A housekeeping role for iPLA2 in generating lysophosphatidylcholine (LPC) acceptors for arachidonic acid incorporation into phosphatidylcholine (PC) has been proposed because iPLA2 inhibition reduces LPC levels and suppresses arachidonate incorporation and phospholipid remodeling in P388D1 cells. Because islet beta-cell phospholipids are enriched in arachidonate, we have examined the role of iPLA2 in arachidonate incorporation into islets and INS-1 insulinoma cells. Inhibition of iPLA2 with a bromoenol lactone (BEL) suicide substrate did not suppress and generally enhanced [3H]arachidonate incorporation into these cells in the presence or absence of extracellular calcium at varied time points and BEL concentrations. Arachidonate incorporation into islet phospholipids involved deacylation-reacylation and not de novo synthesis, as indicated by experiments with varied extracellular glucose concentrations and by examining [14C]glucose incorporation into phospholipids. BEL also inhibited islet cytosolic phosphatidate phosphohydrolase (PAPH), but the PAPH inhibitor propranolol did not affect arachidonate incorporation into islet or INS-1 cell phospholipids. Inhibition of islet iPLA2 did not alter the phospholipid head-group classes into which [3H]arachidonate was initially incorporated or its subsequent transfer from PC to other lipids. Electrospray ionization mass spectrometric measurements indicated that inhibition of INS-1 cell iPLA2 accelerated arachidonate incorporation into PC and that inhibition of islet iPLA2 reduced LPC levels by 25%, suggesting that LPC mass does not limit arachidonate incorporation into islet PC. Gas chromatography/mass spectrometry measurements indicated that BEL but not propranolol suppressed insulin secretagogue-induced hydrolysis of arachidonate from islet phospholipids. In islets and INS-1 cells, iPLA2 is thus not required for arachidonate incorporation or phospholipid remodeling and may play other roles in these cells.     

Arachidonate cannot be released directly from diacyl-sn-glycero-3-phosphocholine in thrombin-stimulated platelets.

The origin of the arachidonate released from platelets on stimulation with thrombin was investigated by comparing the specific activities of released arachidonate and of arachidonoyl-containing phospholipids using rat platelets prelabelled with arachidonate. Quantification of the released arachidonate was determined in the presence of BW 755 C, a dual cyclo-oxygenase/lipoxygenase inhibitor, which was found not to modify the arachidonate mobilization between the platelet phospholipids. The phospholipid molecular species were analysed by h.p.l.c. of diradylglycerol benzoate derivatives of diacyl, alkylacyl and alkenylacyl classes. The labelled/unlabelled arachidonate ratio varied greatly in the phospholipids depending on whether an ether or acyl bond was present in sn-1 position of the glycerol, on the length and degree of unsaturation of this fatty chain and on the polar head group. Between 15 s and 5 min of stimulation by thrombin, the released arachidonate kept a constant specific activity which was considerably lower than the specific activity of diacyl-GPC. The specific activity of the released arachidonate was intermediate between the specific activities of the 16:0-20:4 and 18:0-20:4 species of diacyl-GPI and diacyl-GPE, and corresponded to the mean specific activity of alkylacyl-GPC. The data indicate that the released arachidonate cannot come directly from diacyl-GPC, and that two phospholipids in particular can act as direct precursors of the released arachidonate. These are (1) the alkylacyl-GPC and (2) the diacyl-GPE whose hydrolysis would induce an arachidonate transfer from diacyl-GPC.     

Phospholipid metabolism in human neutrophils activated by N-formyl-methionyl-leucyl-phenylalanine. Degranulation is not required for release of arachidonic acid: studies with neutrophils and neutrophil-derived cytoplasts.

Neutrophils respond to chemoattractants by aggregating, degranulating, remodelling of phospholipids and releasing arachidonic acid. To determine whether ligand-induced remodelling of phospholipids depends on redistribution of intracellular organelles (degranulation), we compared phospholipid remodelling of human neutrophils with that of neutrophil-derived cytoplasts. Cytoplasts, organelle-depleted vesicles of cytosol surrounded by plasmalemma, cannot degranulate. Without a stimulus, [3H]arachidonate was incorporated preferentially into phosphatidylinositol (PI) and phosphatidylcholine (PC). Exposure of cytoplasts and neutrophils prelabelled with [3H]arachidonate or [14C]glycerol to fMet-Leu-Phe (10(-7) M) induced rapid changes in distribution of label and mass of individual phospholipids: [3H]arachidonate in phosphatidic acid (PA) increased 500% (120 s), [14C]glycerol incorporation and mass of PA approached 200% of unstimulated values, and [3H]arachidonate in PI decreased continuously; these data are compatible with activity of a PI/PA cycle. However, the mass of PI in both preparations and [14C]glycerol label in intact neutrophils increased initially (5 s), suggesting net synthesis and mobilization of more than one pool of PI. Heterogeneity of PC pools was also observed: [3H]arachidonate was lost from PC immediately upon addition of stimulus, whereas mass and [14C]glycerol values increased. Thus, net phospholipid synthesis, redistribution of arachidonate and activation of the PI/PA cycle are immediate responses of the neutrophil to receptor occupancy by chemoattractants. Furthermore, the similarity in response to fMet-Leu-Phe of neutrophils and granule-free cytoplasts indicates that these processes are independent of degranulation.     

A facile purification procedure of phospholipase D from cabbage and its characterization.

Phospholipase D (PLD), an enzyme predestined for the preparation of new phospholipids, was isolated from cabbage and purified in a highly efficient way by using a combination of hydrophobic chromatography and a specific calcium effect. In the presence of calcium ions (50mM), PLD is bound from the crude enzyme solution to Octyl-Sepharose and subsequently selectively eluted by removing the calcium ions. The obtained enzyme is electrophoretically pure (95%), its molecular mass and isoelectric point were determined to be 87,000 Da and 4.7, respectively. The purified enzyme was kinetically characterized by use of mixed phosphatidylcholine-SDS micelles as well as the short-chain lecithins 1,2-dihexanoyl- and 1,2-diheptanoyl-sn-glycero-3-phosphocholine as substrates. A hyperbolic upsilon/[S]-characteristic was obtained for the mixed micellar system, whereas the upsilon/[S] curves of the short-chain lecithins reflect the dependence of velocity on the physical state of the substrate. A small velocity increase was observed up to a critical substrate concentration near the critical micelle concentration, from where the velocity increases hyperbolically.     

Synthesis of sn-1 functionalized phospholipids as substrates for secretory phospholipase A2

Secretory phospholipase A2 (sPLA2) represents a family of small water-soluble enzymes that catalyze the hydrolysis of phospholipids in the sn-2 position liberating free fatty acids and lysophospholipids. Herein we report the synthesis of two new phospholipids (1 and 2) with bulky allyl-substituents attached to the sn-1 position of the glycerol backbone. The synthesis of phospholipids 1 and 2 is based upon the construction of a key aldehyde intermediate 3 which locks the stereochemistry in the sn-2 position of the final phospholipids. The aldehyde functionality serves as the site for insertion of the allyl-substituents by a zinc mediated allylation. Small unilamellar liposomes composed of phospholipids 1 and 2 were subjected to sPLA2 activity measurements. Our results show that only phospholipid 1 is hydrolyzed by the enzyme. Molecular dynamics simulations revealed that the lack of hydrolysis of phospholipid 2 is due to steric hindrance caused by the bulky side chain of the substrate allowing only limited access of water molecules to the active site.     

Regulatory aspects of mitochondrial phospholipase A2 from rat liver: effects of proteins, phospholipids and calcium ions

This paper deals with the search for specific inhibitors or activators of the mitochondrial phospholipase A2. Convincing evidence for the existence of proteins in the mitochondrial or cytosolic fraction that function as specific regulators of this enzyme was not obtained. The enzymatic activity appeared to be inhibited at low substrate concentrations by lipocortin isolated from human monocytes. However, at higher substrate concentrations, the inhibition disappeared, suggesting either that lipocortin sequestered the phospholipid substrate or that the putative inactive complex of enzyme and lipocortin dissociated in the presence of excess phospholipids. The hydrolysis of the neutral phospholipid phosphatidylethanolamine was stimulated by the presence of cardiolipin and phosphatidylglycerol. It is unlikely that this is caused merely by the negative charge of these phospholipids, since other negatively charged phospholipids did not show this effect. Using a phospholipid extract from mitochondria as substrate, the enzymatic activity as a function of the Ca2+ concentration was determined. Only one enzyme activity plateau was observed. The calculated KCa2+ value of 0.05 mM suggests that the mitochondrial phospholipase A2 could be regulated strictly by the modulation of the free Ca2+ concentration in vivo. The two activity plateaus observed previously upon variation of the Ca2+ concentration using phosphatidylethanolamine as substrate could be explained by a Ca2+-induced transition of the phospholipid structure.     

Probing the role of substrate conformation in phospholipase A2 action on aggregated phospholipids using constrained phosphatidylcholine analogues

Phospholipase A2s hydrolyze aggregated phospholipid substrates much more rapidly than dispersed monomeric ones. Whether this is a consequence of interface-associated conformational changes of the enzyme or of the substrate, or of both, remains a key question in lipid enzymology. This problem is addressed herein using a rationally designed probe of substrate conformation. (1,3/2)-1-O-(phosphorylcholine)-2,3-O-dihexanoylcyclopentane-1,2,3 -triol is a novel short chain phosphatidylcholine analogue in which the glycerol-like backbone is part of a five-membered ring and therefore covalently constrained within a small defined range of conformations. To the extent that the constrained analogue resists aggregation-associated conformational changes, it provides a means for assessing the contribution of such changes to phospholipase A2 action on aggregated phospholipids. The monomeric (-)-cyclopentanoid analogue is a substrate for phospholipase A2s from Naja naja naja venom. However, when this constrained phospholipid is aggregated, its hydrolysis rate is not enhanced, in contrast to its unconstrained counterpart, 1,2-dihexanoyl-sn-glycero-3- phosphorylcholine. This lack of activation was not caused by a failure of the enzyme to bind the micellar, constrained analogue. While the constrained analogue does not show interfacial activation, it does show the activation of phosphatidylethanolamine hydrolysis typical of phosphorylcholine-containing lipids. Hence, these results strongly support the contention that specific packing-induced conformations of aggregated substrate play a substantial role in the large interfacial activations observed with phospholipase A2.     

Photo-induced inactivation and uncoupling of gonadotropin receptors in rat ovarian plasma membrane

Extraction of membranes of Lactobacillus plantarum with Triton X-100/glycerol solubilized up to 80% of the undecaprenol kinase activity. Fractionation of the extract by gel chromatography separated endogenous phospholipid from the enzyme but simultaneously inactivated the enzyme. The kinase was reactivated by reconstitution with various synthetic phosphatidylcholines and purified L. plantarum phospholipids. Ditetradecanoylphosphatidylcholine and lysylphosphatidylglycerol were the best activators. Furthermore, the optimal environment for enzyme stimulation was provided by different defined molar ratios of Triton X-100/phospholipid. The ratios for the phospholipids tested ranged from 1.25 to 6.3. Similar substrate specificity and kinetic constants were observed for both the solubilized and reconstituted enzymes suggesting that no fundamental changes in the enzyme activity occurred during the delipidation-reconstitution process.     

Substrate Efflux Propensity Plays a Key Role in the Specificity of Secretory A-type Phospholipases

To better understand the principles underlying the substrate specificity of A-type phospholipases (PLAs), a high throughput mass spectrometric assay was employed to study the effect of acyl chain length and unsaturation of phospholipids on their rate of hydrolysis by three different secretory PLAs in micelles and vesicle bilayers. With micelles, each enzyme responded differently to substrate acyl chain unsaturation and double bond position, probably reflecting differences in the accommodative properties of their substrate binding sites. Experiments with saturated acyl positional isomers indicated that the length of the sn2 chain was more critical than that of the sn1 chain, suggesting tighter association of the former with the enzyme. Only the first 9–10 carbons of the sn2 acyl chain seem to interact intimately with the active site. Strikingly, no discrimination between positional isomers was observed with vesicles, and the rate of hydrolysis decreased far more with increasing chain length than with micelles, suggesting that translocation of the phospholipid substrate to the active site is rate-limiting with bilayers. Supporting this conclusion, acyl chain structure affected hydrolysis and spontaneous intervesicle transfer, which correlates with lipid efflux propensity, analogously. We conclude that substrate efflux propensity plays a more important role in the specificity of secretory PLA₂s than commonly thought and could also be a key attribute in phospholipid homeostasis in which (unknown) PLA₂s are key players.     

Platelet-derived growth factor stimulates synthesis of 1,2-diacylglycerol from monoacylglycerol in Balb/c 3T3 cells.

1,2-Diacylglycerol (1,2,-DAG) plays an important role in the protein kinase C-mediated signal-transduction system. Several reports have shown that 1,2-DAG is generated through various pathways other than classical phospholipid hydrolysis. We observed a rapid incorporation of [3H]myristate into 1,2-DAG in platelet-derived-growth-factor (PDGF)-treated Balb/c 3T3 cells. [14C]Palmitate was similarly incorporated into 1,2-DAG. The effect of PDGF, which was inhibited by cycloheximide, became maximal after 60 min treatment with PDGF, and disappeared 300 min after removal of PDGF. Treatment with triacylglycerol lipase revealed that labelled saturated fatty acid was incorporated into the sn-1 position. PDGF barely stimulated incorporation of [3H]glycerol or [14C]glucose into 1,2-DAG. Incorporation of [3H]myristate into 1,2-DAG preceded that into triacyglycerol and phospholipids. These results suggest that synthesis of 1,2-DAG from monoacylglycerol is enhanced in PDGF-treated cells. However, there is no significant difference in the activity of monoacylglycerol acyltransferase measured in vitro in quiescent and PDGF-treated cells. The reason for this discrepancy is discussed.     

Differential activation of membrane phospholipid turnover by compound 48/80 and ionophore A23187 in rat mast cells

Membrane phospholipid turnover was investigated during histamine release from rat mast cells. Addition of calcium ionophore A23187 (0.5 microgram/ml) to mast cells prelabeled with [3H]glycerol induced the rapid and progressive increase in phosphatidic acid (PA) and 1,2-diacylglycerol (DG), which was concomitant with the small rise in phosphatidylinositol (PI). Loss of the level in triacylglycerol (TG) was very marked. Polyamine compound 48/80 (5 micrograms/ml) was shown to cause rises in PA, 1,2-DG, and PI without any significant changes in TG. Both stimuli increased incorporation of exogenous [3H]glycerol into phospholipids, indicating the involvement of de novo synthesis in phospholipid metabolism. Studies with [3H]arachidonic acid-labeled mast cells showed an enhanced liberation of radioactive arachidonate and metabolites upon histamine release. There were associated decreases of radioactivity in phosphatidylcholine (PC) and TG when exposed to A23187, while phosphatidylethanolamine (PE) was degraded as a result of 48/80 activation. The transient increases of [3H]arachidonoyl-1,2-DG and PA were caused by 48/80, while A23187 showed a gradual rise in the radioactivity in these two lipid fractions. These findings reflect activation of phospholipase C. When mast cells were activated by low concentrations of A23187 (0.1 microgram/ml) and 48/80 (0.5 microgram/ml), different behaviors of PI metabolism were observed. An early degradation of PI and a subsequent formation of 1,2-DG and PA suggest that the lower concentrations of these agents stimulate the PI cycle initiated by PI breakdown rather than de novo synthesis. These results demonstrate that marked and selective changes in membrane phospholipid metabolism occur during histamine release from mast cells, and that these reactions seem to be controlled by the coordination of degradation and biosynthesis, depending on the type and the concentration of stimulants. A23187 stimulates arachidonate release perhaps via the cleavages of PC and TG, whereas 48/80 liberates arachidonate from PE.     

Monolayers of long chain lecithins at the air/water interface and their hydrolysis by phospholipase A2

The behavior of phosphatidylcholine monolayers at the air/water interface was studied by measuring their surface isotherm, surface potential, surface viscosity, and rate of hydrolysis by the dimeric phospholipase A2 from the venom of Crotalus atrox. The monolayers showed typical liquid-expanded behavior. In this phase, the surface potential was linearly dependent on surface concentration and extrapolated at zero concentration to a value characteristic of a liquid hydrocarbon/water interface. The rate of the reaction was measured by monitoring changes in area at constant surface pressure for 1,2-dioctanoyl- and 1,2-didecanoyl-3-sn-phosphatidylcholines, and by monitoring changes in surface potential for 1,2-dimyristoyl-, 1,2-dipalmitoyl-, 1-palmitoyl-2-oleoyl-, and 1-oleoyl-2-palmitoyl-sn-glycero-3-phosphocholines. The enzymatic hydrolysis is first order with respect to the enzyme-calcium complex which forms with a Kd = 1.5 mM. A mechanism is proposed to account for the dependency of the reaction rates on the surface concentration of the substrate. We postulate that the rate-limiting step is the decomposition of a quaternary complex formed from two phospholipid molecules, one calcium ion and one dimeric enzyme. The rate is independent of the surface pressure per se; addition of inert lipids to a monolayer at constant area, and hence constant surface concentration of the substrate, increases the surface pressure without changing the surface density of the substrate yielding maximal enzymatic rate. The enzyme is specific for loosely packed substrate molecules in the liquid-expanded state: transition into the liquid-condensed state or compression of the liquid-expanded layer beyond 80 A2/phospholipid strongly inhibits the enzymatic reaction. Our results show that surface recognition is a direct consequence of a bifunctional active site since it is only at a phospholipid surface that the distance between two substrate molecules is optimal for forming a catalytically competent enzyme-Ca2+-(substrate)2 complex.     

Complete retention of phospholipid acyl groups by mammalian cells in culture.

Radiolabeled phosphate, acetate, and glycerol are incorporated into strain L-fibroblast phospholipids. The acetate and glycerol specifically label the fatty acid and glycerol moieties, respectively, of the phospholipids. To study the metabolic fate of the various moieties of phospholipids, cells incubated with the above radiolabeled compounds were transferred to unlabeled medium, and the rate at which phospholipid radioactivity per 10(6) cells decreased was determined. The rate of decrease expected on the basis of cell division alone was estimated either by monitoring increases in cell number, or by measuring the rate at which radiolabeled DNA per 10(6) cells decreased. Both phospholipid phosphorus and glycerol are lost at a rate greater than can be accounted for by cell division alone. By contrast, nearly all phospholipid acyl chains were retained by the cell to the same extent as radiolabeled DNA. While presence of nonradioactive glycerol in the medium increased the rate at which glycerol was lost from phospholipid, the addition of exogenous fatty acid was without effect on the retention of phospholipid acyl groups. The acyl-glycerol bond of phosphatidylcholine is metabolically more labile than that of phosphatidylethanolamine. Together the data suggest that although L-fibroblast phospholipids undergo deacylation-reacylation reactions, the acyl chains do not equilibrate with either extracellular or intracellular pools of unesterified fatty acid.     

On the substrate specificity of rat liver phospholipase A1

The substrate specificity of purified phospholipase A1 was studied using mixed micelles of phospholipid and Triton X-100. The kinetic analysis employed determined Vmax, Ks (a dissociation constant for the phospholipase A1-mixed micelle complex), and Km (the Michaelis constant for the catalytic step which reflects the binding of the enzyme to the substrate in the interface). The order of Vmax values was phosphatidic acid greater than phosphatidylethanolamine greater than phosphatidylcholine greater than phosphatidylserine. The order of Ks values was phosphatidylcholine greater than phosphatidylethanolamine greater than phosphatidic acid greater than phosphatidylserine; the order of Km values was phosphatidic acid greater than phosphatidylethanolamine = phosphatidylserine greater than phosphatidylcholine. When present together, phosphatidylcholine inhibited the hydrolysis of phosphatidylethanolamine but phosphatidylethanolamine did not affect the hydrolysis of phosphatidylcholine. Sphingomyelin, phosphatidylcholine plasmalogen, and phosphatidylethanolamine plasmalogen had no effect on the hydrolysis of phosphatidylethanolamine. The effects of the reaction products, lysolipids and/or fatty acids, were also considered for their influence on phosphatidylethanolamine hydrolysis catalyzed by phospholipase A1. Free fatty acid was found to inhibit, whereas lysophospholipids stimulated hydrolysis of phosphatidylethanolamine. In a mixture of 1,2- and 1,3-diacylglycerides in mixed micelles, only the acyl chain at the sn-1 position of the 1,2 compound was hydrolyzed. Surface charge did not modulate the hydrolysis of phosphatidylcholine vesicles or mixed micelles. In conclusion, it is hypothesized that steric hindrance at position 3 of the glycerol regulates substrate binding in the active site and that an acyl group in position 1 is favored over a vinyl ether linkage for binding.     

Ether lipid metabolism. Incorporation of O-hexadecyl ethanediol into rat brain lipids.

1-O-[1'-14C]Hexadecyl ethanediol was administered intracerebrally to myelinating rat brain, and incorporation of radioactivity into brain lipids was followed over a 48-h period: (1) O-Hexadecyl ethanediol was metabolized primarily through oxidative ether bond cleavage, and much of the label was recovered in phospholipid acyl groups. (2) Substantial amounts of radioactivity were also found in choline and ethanolamine phospholipids having an O-hexadecyloxyethyl glycerol backbone. This means that alkyl ethanediol was used in glycerol ether biosynthesis as are long-chain primary alcohols. (3) Acidic hydrolysis of the ethanolamine glycerophosphatide fraction yielded also labeled hexadecanol which may indicate desaturation of 1-O-hexadecyloxyethyl 2-acyl glycerophosphoryl ethanolamine to the plasmalogen analogue. (4) Small amounts of the substrate were oxidized to O-hexadecyl glycolic acid and incorporated into the phospholipids. The substrate did not serve as precursor of O-hexadecyl ethanediol phosphorylcholine or phosphorylethanolamine in the brain.