Influence of Ethanol and Phosphatidylethanol on the Activity of Pancreatic Phospholipase A2

Hydrolysis of dioleoylphosphatidylethanol (DOPEt) and dioleoylphosphatidylcholine (DOPC) catalyzed by phospholipase A₂ (PLA₂) from porcine pancreas has been studied in single-component and binary liposomes in the absence and in the presence of ethanol. DOPEt (an anionic phospholipid) was found to increase the rate of hydrolysis of zwitterionic DOPC in liposomes under the action of PLA₂.     

Modification of the tetrodotoxin receptor in Electrophorus electricus by phospholipase A2

The effects of phospholipase A₂ treatment on the tetrodotoxin receptors in Electrophorus electricus was studied. (1) The binding of [³H]tetrodotoxin to electroplaque membranes was substantially reduced by treatment of the membranes with low concentrations of phospholipase A₂ from a number of sources, including bee venom, Vipera russelli and Crotalus adamanteus and by $\text{β-}\text{bungarotoxin}$. (2) Phospholipase A₂ from bee venom and from C. adamanteus both caused extensive hydrolysis of electroplaque membrane phospholipids although the substrate specificity differed. Analysis of the phospholipid classes hydrolyzed revealed a striking correlation between loss of toxin binding and hydrolysis of phosphatidylethanolamine but not of phosphatidylserine. (3) The loss of toxin binding could be partially reversed by treatment of the membranes with bovine serum albumin, conditions which are known to remove hydrolysis products from the membrane. (4) Equilibrium binding studies on the effects of phospholipase A₂ treatment on [³H]tetrodotoxin binding showed that the reduction reflected loss of binding sites and not a change in affinity. (5) These results are interpreted in terms of multiple equilibrium states of the tetrodotoxin-receptors with conformations determined by the phospholipid environment.     

The effect of hexadecylphosphocholine on the degradation of mitochondrial phospholipids

Hexadecylphosphocholine (HePC) is known as antitumor agent but the mechanism has not yet been understood. In rat liver mitochondria its effect on phospholipid transformation has been studied by quantitative HPTLC and phosphorus determination. From the results it can be concluded that HePC influences the activities of phospholipase A₂, phospholipase C, phospholipase D, and lysophospholipase A. The phospholipid transformation as well as the influence of HePC are affected by exogenous calcium ions. In the presence of calcium HePC has been found to inhibit enzyme activities, whereas in the absence of exogenous calcium ions enzymatic phospholipid transformations are activated or inhibited depending on HePC concentrations.     

Effect of purified phospholipases on the binding of tetrodotoxin to axon plasma membrane

Summary The role of phospholipids in the binding of [³H] tetrodotoxin to garfish olfactory nerve axon plasma membrane was studied by the use of purified phospholipases. Treatment of the membranes with low concentrations of either phospholipase A₂ (Crotalus adamanteus andNaja naja) or phospholipase C (Bacillus cereus andClostridium perfringens) resulted in a marked reduction in tetrodotoxin binding activity. A 90% reduction in the activity occurred with about 45% hydrolysis of membrane phospholipids by phospholipase A₂, and with phospholipase C the lipid hydrolysis was about 60–70% for a 70–80% reduction in the binding activity. Phospholipase C fromB. cereus andCl. perfringens had similar inhibitory effects. Bovine serum albumin protected the tetrodotoxin binding activity of the membrane from the inhibitory effect of phospholipase A₂ but not from that of phospholipase C. In the presence of albumin about 25% of the membrane phospholipids remained unhydrolyzed by phospholipase A₂. It is suggested that these unhydrolyzed phospholipids are in a physical state different from the rest of the membrane phospholipids and that these include the phospholipids which are directly related to the tetrodotoxin binding component. It is concluded that phospholipids form an integral part of the tetrodotoxin binding component of the axon membrane and that the phospholipase-caused inhibition of the binding activity is due to effects resulting from alteration of the phospholipid components.     

Modulation of the beta-adrenergic response in cultured rat heart cells

Incubation of rocker-cultured neonatal rat heart cells with 3 mM L(+)-lactate led to a sharp increase in the sensitivity of cardiomyocytes to the beta-adrenergic agonist isoprenaline, as measured by their chronotropic response. This effect was accompanied by a reduction in the arachidonic acid content of the total phospholipids. The phospholipase A₂-activator melittin as well as free arachidonic acid induced this supersensitivity to the same degree. On the other hand, the L(+)-lactate-evoked supersensitivity could be blocked by the phospholipase A₂ inhibitors mepacrine and n-bromophenacyl-bromide, suggesting an involvement of phospholipase A₂ in the process of beta-adrenergic sensitization. The sensitizing action of arachidonic acid was blocked by the lipoxygenase inhibitors esculetin and nordihydroguaiaretic acid, but not by the cyclooxygenase inhibitor indomethacin. Supersensitivity was likewise evoked by 15-S-hydroxyeicosatetraenoic acid (15-S-HETE), but not by 5-S-HPETE or 5-S-HETE. These findings suggest that the phospholipase A₂-15-lipoxygenase pathway plays a role in the induction of beta-adrenergic supersensitivity in the cultured cardiomyocytes and point to a new physiological role of the lipoxygenase product 15-S-HETE.Abbreviations NDGA nordihydroguaiaretic acid - HETE hydroeicosatetraenoic acid - HPETE hydroperoxyeicosatetraenoic acid     

Role of membrane oxidation in controlling the activity of human group IIa secretory phospholipase A2 toward apoptotic lymphoma cells

The membranes of healthy lymphocytes normally resist hydrolysis by secretory phospholipase A₂. However, they become susceptible during the process of apoptosis. Previous experiments have demonstrated the importance of certain physical changes to the membrane during cell death such as a reduction in membrane lipid order and exposure of phosphatidylserine on the membrane surface. Nevertheless, those investigations also showed that at least one additional factor was required for rapid hydrolysis by the human group IIa phospholipase isozyme. This study was designed to test the possibility that oxidation of membrane lipids is the additional factor. Flow cytometry and confocal microscopy with a fluorescent probe of oxidative potential suggested that oxidation of the plasma membrane occurs during apoptosis stimulated by thapsigargin. When oxidative potential was high, the activity of human group IIa secretory phospholipase A₂ was enhanced 30- to 100-fold compared to that observed with conditions sufficient for maximal hydrolysis by other secretory phospholipase A₂ isoforms. Direct oxidation of cell membranes with either of two oxidizing agents also stimulated hydrolysis by secretory phospholipase A₂. Both oxidizers caused externalization of phosphatidylserine, but a change in lipid order did not always occur. These results demonstrated that membrane oxidation strongly stimulates human group IIa secretory phospholipase A₂ activity toward apoptotic cells. Interestingly, the change in membrane order, previously thought to be imperative for high rates of hydrolysis, was not required when membrane lipids were oxidized. Whether phosphatidylserine exposure is still necessary with oxidation remains unresolved since the two events could not be deconvoluted.     

Phospholipase A2 activity towards phosphatidylcholine in mixed micelles: surface dilution kinetics and the effect of thermotropic phase transitions

Phospholipase A₂ will act on dipalmitoyl phosphatidylcholine as substrate when the phospholipid is part of a mixed micelle with Triton X-100 at a molar ratio of Triton to phospholipid of 2:1 or greater. Kinetic studies at high molar ratios of Triton X-100 to phospholipid are reported and show that the binding of phospholipase A₂ to substrate depends on the total concentration of Triton X-100 and phospholipid, but that the rate of enzymatic catalysis decreases proportionally to the Triton X-100 concentration. These results are interpreted in terms of a model involving surface dilution kinetics. The relationship of this model to that of competitive inhibition is discussed. In addition, the activity of phospholipase A₂ towards dipalmitoyl phosphatidylcholine and dimyristoyl phosphatidylcholine at different temperatures is reported, and the results show a direct effect of the thermotropic phase transition of dipalmitoyl phosphatidylcholine on enzymatic activity.     

Esterification of monohydroxyfatty acids into the lipids of a macrophage cell line

Cells of a mouse macrophage-like tumor cell line, J774.2, were incubated with 0.6μM radiolabeled mono- and di-hydroxyfatty acids. Monohydroxyfatty acid products of the neutrophil and platelet lipoxygenase pathways (5-HETE, 15-HETE, and 12-HETE) were rapidly taken up (42–64% of the counts cell associated at 1 min) and esterified into triglycerides and phospholipids. 5-HETE and 12-HETE were found in triglycerides and distributed among phospholipid classes while 50% of added 15-HETE was esterified into phosphatidyl inositol. Treatment of phospholipids from cells incubated with 5-HETE, 12-HETE, and 15-HETE with phospholipase A₂ resulted in release of the respective monohydroxyfatty acid. HHT, a monohydroxyfatty acid product of the cyclooxygenase pathway, was taken up and esterified more slowly than the lipoxygenase products. In addition, HHT was not released when the phospholipids from cells incubated with HHT were treated with phospholipase A₂. LTB₄, a dihydroxyfatty acid product of neutrophil lipoxyegnase, was not taken up by J774.2 cells. The unique patterns of uptake and intracellular distribution of the different monohydroxyfatty acids suggests that the enzymes involved in the esterification of these compounds have substrate specificity and may also relate to the specific biologic effects of the compounds.     

Manoalide,a Phospholipase A2 Inhibitor,Inhibits Arachidonate Incorporation and Turnover in Brain Phospholipids of the Awake Rat

The Fatty Acid method was used to determine whether incorporation of plasma radiolabeled arachidonic acid into brain phospholipids is controlled by phospholipase A₂. Awake rats received an i.v. injection of a phospholipase A₂ inhibitor, manoalide (10 mg/kg), and then were infused i.v. with [1-¹⁴C]arachidonate or [³H]arachidonate. Animals were killed after infusion by microwave irradiation, and tracer distribution was analyzed in brain phospholipid, neutral lipid and acyl-CoA pools. Calcium-independent phospholipase A₂ activity in brain homogenate was reduced by manoalide, whereas phospholipase C activity was unaffected. At 60 min but not at 20 or 40 min after its injection, manoalide had significantly decreased by 50% incorporation of unesterified arachidonate into and turnover within brain phospholipids, taking into account dilution of the brain arachidonoyl-CoA pool by recycled arachidonate. Manoalide also increased by 100% the net rate of unesterified arachidonate incorporation into brain triacylglycerol. This study indicates that manoalide can be used to inhibit brain phospholipase A₂ in vivo, and that phospholipase A₂ plays a critical role in arachidonate turnover in brain phospholipids and neutral lipids.     

Phospholipid signalling and lipid-derived second messengers in plants

Phospholipid signalling is mediated by phospholipid breakdown products generated by phospholipases. The enzymes from animals and plants generating known or potential lipid-derived second messengers are compared. Plants possess a phospholipase C and a phospholipase A₂ both of which are agonist-activated. These agonists (auxin, elicitors, perhaps others) bind to the external surface of the plasma membrane. The target enzyme for potential plant lipid-derived second messengers is lipid-activated protein kinase but the possibility that other enzymes may be also lipid-modulated should not be precluded.Abbreviations DAG diacylglycerol - CDPK calmodulin-like domain protein kinase - PLA2 phospholipase A₂ - PLC phospholipase C - PLD phospholipase D - PKC protein kinase C - PS phosphatidylserine     

Lipid-protein interactions in mitochondria. The effect of protein interaction on susceptibility of phospholipids to phospholipase A2 and C hydrolysis.

Phospholipase A₂ (Naja naja) and phospholipase C (from either Clostridium welchii or Bacillus cereus) have been tested on phospholipid dispersions and natural or reconstituted membranes; notwithstanding the different substrate specificities, the different enzymes gave comparable behaviors, suggesting that the results were the expression of sterical features in the lipid bilayers, i.e., availability of the phospholipids to enzymatic attack. The hydrolysis of phospholipids (Asolectin) in sonic protein-free vesicles is hindered by ionic interaction with basic proteins (cytochrome c or lysozyme). On the other hand binding of Asolectin to lipid-depleted mitochondria to obtain reconstituted mitochondria does not prevent phospholipase action on the phospholipids; similarly, phospholipids are hydrolyzed at maximal rates in natural membranes (mitochondria or submitochondrial particles). Surprisingly, ionic interaction of RM or natural membranes with basic proteins does not prevent phospholipase hydrolysis of the membrane phospholipids. The interpretation of this phenomenon may be related to the heterogeneity of phospholipid distribution in protein-containing membranes.     

Further studies on the mechanism of action of substance P in rat brain,involving selective phosphatidylinositol hydrolysis

We have suggested that substance P, in cerebral cortex, causes a phosphatidylinositol (PI) breakdown by a dual mechanism suggesting the involvement of either phospholipase A₂ or phospholipase C. We have presently characterized further these effects. Substance P (65 pM) provoked an increase in lysoPI concomitant with a decrease in PI level. This finding confirms the involvement of phospholipase A₂ activation. To study the involvement of phospholipase C in the action of higher doses (0.65 M) of the peptide, we used pulse-chase experiments (where phospholipid depletion was monitored) and short-term³²P-labeled slices (where phospholipid synthesis was studied). Substance P evoked an acceleration of both hydrolysis and resynthesis of PI as early as 15 s. A prolonged exposure (30 min) resulted in stimulation of PI hydrolysis without subsequent resynthesis. The peptide did not cause any effect on inositol 1,4-bisphosphate and inositol 1,4,5-trisphosphate. These alterations in PI metabolism take place simultaneously with a generation of diacylglycerol which showed two maxima at both indicated times.     

Induced accumulation of triterpenoids in Scutellaria baicalensis suspension cultures using a yeast elicitor

When growth-phase cell suspension cultures of Scutellaria baicalensis were treated with 50 g of yeast elicitor preparation ml^–1, both oleanolic acid and ursolic acid transiently increased in the culture medium rather than in the cells. The maximal triterpenoid concentration was 13.7 mg l^–1 media approx. 35 h after treatment, whereas the maximum concentration was 2.1 mg l^–1 media after about 20 h following treatment with methyl jasmonate. Elicitor treatment also doubled phospholipase A₂ activity (25 pmol mg^–1 min) and the simultaneous treatment of aristolochic acid, a phospholipase A₂ inhibitor, inhibited triterpenoids accumulation as well as phospholipase A₂ activity.     

Membrane phospholipid catabolism and Ca2+ activity in control of senescence

Leshem, Y. Y. 1987. Membrane phospholipid catabolism and Ca²⁺ activity in control of senescence. A key role in the regulation of plant development and senescence appears to be a finely balanced equilibrium between membrane phospholipid catabolism on the one hand, and synthesis and remodelling on the other. In the catabolic “phosphatidyl-linoleyl(-enyl) cascade”, entering of Ca²⁺ into the cytosol triggers the catabolic process by binding to calmodulin and activating phospholipase A₂, (EC 3.1.1.4). The latter proceeds to release linoleic or linolenic acid from the sn-2 (stereospecific numbering) location of intact phospholipid, thus providing substrate for lipoxygenase (EC 1.13.11.12). The action of lipoxygenase then generates a series of oxy-free radicals, ethylene, endogenous Ca²⁺ ionophores, malondialdehyde and jasmonic acid. These may recycle to the membrane, causing the entry of more Ca²⁺ and induction of a further, identical catabolic cycle. With increased cycling, membranes become progressively senescent and undergo biophysical changes altering microviscosity, fluidity, phase configurations of membrane phospholipids and transition temperatures. The cascade does not appear to be specific for the phospholipid substrate, and it is envisaged that besides phospholipase A₂, both phospholipase B (EC 3.1.1.5) and lipolytic acylhydrolase could participate in the process. A parallel process counteracting the above, is membrane remodelling and turnover, proceeding initially by the same Ca²⁺- and possibly calmodulin-triggering, but leading via phospholipase C (EC 3.1.4.10) action and diacylglycerol formation to protein kinase activation and proton pump recharging. It is speculated that auxin and cytoki-nin, albeit by different pathways, induce this route, for which membrane phospho-inositides may be the preferred membrane-associated phospholipid substrate.     

Phospholipase A2 inactivation of microsomal 17β-hydroxysteroid oxidoreductase: Rates of phospholipid hydrolysis and enzyme inactivation,effects of hydrolysis products and properties of the phospholipase A2-treated enzyme

Exposure of guinea pig liver microsomes to phospholipase A₂ resulted in the nearly complete loss of 17β-hydroxy-steroid oxidoreductase (17β-HSD) activity, the time course of which correlated with phospholipid hydrolysis and lysolecithin formation. Lysolecithin and unsaturated fatty acids added to microsomes also inactivated 17β-HSD indicating that they may contribute to the inactivation by phospholipase A₂.If exposure to lysolecithin and fatty acids was minimized by including serum albumin in the reaction mixture, phospholipids were rapidly hydrolyzed; but in this case the extent of 17β-HSD inactivation was less and the rate of loss was significantly slower. The data suggest that phospholipid hydrolysis $\text{per se}$ results in a destabilization of 17β-HSD resulting in the subsequent activity loss.The inactivation of 17β-HSD by lysolecithin and fatty acids has not been reported previously and is suggestive of a possible control mechanism $\text{in vivo}$.     

Effects of phospholipase A2 treatment of human erythrocyte membranes on the rates of spectrin-actin dissociation

This work examines the extent to which alterations in the composition of the phospholipid bilayer of the erythrocyte membrane influences the stability of the association of the ‘cytoskeletal network’ to the rest of the membrane. Rates of spectrin-actin dissociation at low ionic strength were used as a measure of the stability, and composition of the phospholipid bilayer was altered by the action of the enzyme phospholipase A₂. Hydrolysis of all the phosphatidylcholine of the outer leaflet of the bilayer had no effect on dissociation rates, whether or not the hydrolysis products were extracted with albumin. Hydrolysis of inner leaflet phospholipids increased the rates by up to 2-fold if the hydrolysis products were not extracted; for ?50% hydrolysis, the rates were unaffected if the hydrolysis products were extracted. The moderate magnitudes of the increases in dissociation rates indicate that interactions between the ‘cytoskeletal network’ and the phospholipid bilayer are not a decisive factor in maintaining the stability of the membrane, at least under low ionic strength conditions.     

Effect of phospholipase D on micellar phospholipids and the role of calcium ions]

The rates of the reaction products formation under simultaneous phospholipase D effect on phosphatidyl ethanolamine and phosphatidyl choline were studied. The hydrolysis of cephalin, unlike the phospholipase D effect on lecithin, does not require Ca2+ ions. Ca2+ does not affect the enzymatic degradation of lecithin and inhibits the reaction with cephalin in "inorganized" phospholipid emulsions. The hydrolysis of micellar phospholipids by phospholipase D (in the presence of the anionic detergent sodium dodecyl sulfate) is accelerated by Ca2+ ions for both substrates. The apparent Km value is equal to 1.5 mM and does not depend on the phospholipid type. In contrast, the value of kcat for lecithin is twice as high as that for cephalin. It was demonstrated that the phase state of the phospholipids and the chemical nature of the alcohol residue in the phospholipid molecule are essential for the substrate specificity of phospholipase D.     

Polarographic assay for phospholipase A2

A rapid, specific, and quantitative assay for phospholipase A₂ from Naja naja venom has been devised, in which phospholipid hydrolysis is measured as soybean lipoxidase-catalyzed oxygen incorporation into the ensuing unsaturated fatty acids. Under conditions where phospholipid was limiting, a linear relationship developed between the extent of oxygen uptake and the amount of egg lecithin metabolized. When phospholipase was rate limiting, the initial rate of oxygen consumption was a linear function of phospholipase concentration over a 14-fold range from 30 to 420 ng/ml. This linear relationship did not exist at higher phospholipase levels, probably due to the micellar nature of the phospholipid. Since this assay can readily detect as little as 17 ng/ml of phospholipase A₂ (Naja naja venom) and is insensitive to most potential interfering materials, it should be useful in a variety of applications.     

Use of phospholipase A to compare phospholipid organization in synaptic membranes,myelin, and liposomes

Summary The pattern of fatty acid release from rat synaptic membranes in the presence of phospholipase A₂ (Vipera russelli) was compared to that from liposomes comprised of phospholipids. Phospholipase A₂ more readily attacked myelin and synaptic membranes than liposomes prepared from total phospholipids derived from myelin. Although hydrolysis of liposomal phospholipids occurred in the absence of added calcium, the presence of 2mm CaCl₂ or 2% bovine serum albumin significantly enhanced the phospholipase attack of liposomes, but not synaptic membranes or myelin. Phospholipase exhibited a marked preference for phospholipids containing docosahexaenoic acid (226) in the synaptic membranes, while with liposomes the pattern of released fatty acid reflected the fatty acid composition in the two-position of the phospholipids. Although either calcium or albumin markedly increased the phospholipase hydrolysis of liposomes, neither affected the hydrolysis of synaptic membranes or the pattern of fatty acid release from liposomes. It was concluded that the nonlipid constituents, particularly the proteins, of biomembranes were responsible for the organization of the phospholipids and accounted for the observed differences between liposomes and synaptic membranes with respect to enzymic accessibility.     

Phospholipases A2 in Ischemic and Toxic Brain Injury

Phospholipases A₂ (PLA₂s) regulate hydrolysis of fatty acids, including arachidonic acid, from the sn-2 position of phospholipid membranes. PLA₂ activity has been implicated in neurotoxicity and neurodegenerative processes secondary to ischemia and reperfusion and other oxidative stresses. The PLA₂s constitute a superfamily whose members have diverse functions and patterns of expression. A large number of PLA₂s have been identified within the central nervous systems of rodents and humans. We postulated that group IV large molecular weight, cytosolic phospholipase A₂ (cPLA₂) has a unique role in neurotoxicity associated with ischemic or toxin stress. We created mice deficient in cPLA₂ and tested this hypothesis in two injury models, ischemia/reperfusion and MPTP neurotoxicity. In each model cPLA₂ deficient mice are protected against neuronal injury when compared to their wild type littermate controls. These experiments support the hypothesis that cPLA₂ is an important mediator of ischemic and oxidative injuries in the brain.