Calcium and magnesium dependence of phospholipase A2-catalyzed hydrolysis of phosphatidylcholine small unilamellar vesicles

Continuous Electrospray Ionization Mass Spectrometry Assay for Measuring Phospholipase Activity against Liposomes

Phospholipases have diverse roles in lipid and cell membrane biology. In animal venoms, they can have roles as neurotoxins or myotoxins that disrupt the integrity of cell membranes. In this work, we describe a temperature-controlled, continuous electrospray ionization mass spectrometry (ESI-MS) assay for measuring phospholipase A₂ activity against liposomes. The enzyme used in this assay was paradoxin, which is a neurotoxic trimeric phospholipase A₂ from inland taipan snake venom. Previously developed ESI-MS-based phospholipase assays have been discontinuous and analyzed hydrolysis of single lipid molecules by liquid chromatography ESI-MS. In this work, a continuous assay was developed against liposomes, a more complex substrate that more closely reflects the natural substrate for paradoxin. The assay confirmed the requirement for Ca²⁺ and allowed measurement of Michaelis-Menten-type parameters. The use of ESI-MS for lipid detection enabled nuanced insights into the effect of changing assay conditions not only on the enzyme but also on the liposome substrate. Changing the metal ion concentrations did not significantly change the liposomes but did affect enzymatic activity. Increasing temperature did not substantially affect the secondary structure of paradoxin but affected liposome size, resulting in increased enzymatic activity consistent with the disruption of the phosphatidylcholine membrane, increasing accessibility of sn-2 ester bonds. The continuous ESI-MS method described herein can be applied to other enzyme reactions, particularly those which utilize complex lipid substrates.

Development of a bis-pyrene phospholipid probe for fluorometric detection of phospholipase A2 inhibition

In this work, we report the design, synthesis, and application of a bis-pyrene phospholipid probe for detection of phospholipase A2 action through changes in pyrene monomer and excimer fluorescence intensities. Continuous fluorometric assays enabled detection of the activities of multiple PLA2 enzymes as well as the decrease in catalysis by PLA2 from honey bee venom caused by the inhibitor p-bromo phenacylbromide. Thin-layer chromatography and mass spectrometry analysis were also used to validate probe hydrolysis by PLA2. Mass spectrometry data also supported cleavage of the probe by phospholipase C and D enzymes, although changes in fluorescence were not observed in these cases. Nevertheless, the bis-pyrene phospholipid probe developed in this work is effective for detection of PLA2 enzyme activity through an assay that enables screening for inhibitor development.

Impact of aluminum on the oxidation of lipids and enzymatic lipolysis in monomolecular films at the air/water interface

There is evidence that serious pathologies are associated with aluminum (Al). In the present work, the influence of Al on enzymatic lipolysis was studied with the aim to get more insight into the possible link between the Al-induced membrane modification and the cytotoxicity of the trivalent cation (AlIII). Lipid monolayers were used as model membranes. The monomolecular film technique allowed monitoring the Al-dependent modifications of the lipid monolayer properties and enzyme kinetics. Two enzymes, namely, Candida rugosa lipase and a calcium (CaII)-dependent phospholipase A2 from porcine pancreas, were used to catalyze the lipolysis of triglyceride and phosphoglyceride monolayers, respectively. The results obtained show that Al modifies both the monolayer structure and enzymatic reaction rates. While the enzymes used in this study can be considered as probes detecting lipid membrane properties, it cannot be excluded that in physiological conditions modulation of the enzyme action by the Al-bound membranes is among the reasons for Al toxicity.

Activation of interfacial enzymes at membrane surfaces

A host of water-soluble enzymes are active at membrane surfaces and in association with membranes. Some of these enzymes are involved in signalling and in modification and remodelling of the membranes. A special class of enzymes, the phospholipases, and in particular secretory phospholipase A(2) (sPLA(2)), are only activated at the interface between water and membrane surfaces, where they lead to a break-down of the lipid molecules into lysolipids and free fatty acids. The activation is critically dependent on the physical properties of the lipid-membrane substrate. A topical review is given of our current understanding of the physical mechanisms responsible for activation of sPLA(2) as derived from a range of different experimental and theoretical investigations.

Changes in Ca2+ affinity upon activation of Agkistrodon piscivorus piscivorus phospholipase A2

Changes in the affinity of calcium for phospholipase A2 from Agkistrodon piscivorus piscivorus during activation of the enzyme on the surface of phosphatidylcholine vesicles have been investigated by site-directed mutagenesis and fluorescence spectroscopy. Changes in fluorescence that occur during lipid binding and subsequent activation have been ascribed to each of the three individual Trp residues in the protein. This was accomplished by generating a panel of mutant proteins, each of which lacks one or more Trp residues. Both Trp21, which is found in the interfacial binding region, and Trp119 show changes in fluorescence upon protein binding to small unilamellar zwitterionic vesicles or large unilamellar vesicles containing sufficient anionic lipid. Trp31, which is near the Ca2+ binding loop, exhibits little change in fluorescence upon lipid bilayer binding. A change in the fluorescence of the protein also occurs during activation of the enzyme. These changes arise from residue Trp31 as well as residues Trp21 and Trp119. The calcium dependence of the fluorescence change of Trp31 indicates that the affinity of the enzyme for calcium increases at least 3 orders of magnitude upon activation. These studies suggest either that a change in conformation of the enzyme occurs upon activation or that the increase in calcium affinity reflects formation of a ternary complex of calcium, enzyme, and substrate.

Characterization of the interaction of phospholipase A(2) with phosphatidylcholine-phosphatidylglycerol mixed lipids

The first requirement in the hydrolysis of phospholipid bilayers by phospholipase A(2) is the interaction of the enzyme with the bilayer surface. The catalytic ability of phospholipase A(2) has been shown to be extremely sensitive to the topology of the bilayer to which it binds and hydrolyzes. Phospholipid bilayer properties and composition such as unsaturation, charge, and the presence of reaction products are known regulators of the catalytic activity of phospholipase A(2) toward the phospholipids and influences the binding of enzyme to the membrane. We show in this paper that the effect of increased anionic lipid results in enhanced binding that can be described quantitatively in terms of a simple phenomenological model. However, the interaction with anionic lipid does not singularly dominate the thermodynamics of binding, nor can the lag phase observed in the time course of hydrolysis of large unilamellar vesicles simply be the result of limited interaction between the enzyme and the bilayer. Furthermore, we show that phospholipase A(2) from Akgistrodon piscivorus piscivorus can exist in at least two bilayer-bound states and that the absence of a fluorescence change upon mixing the enzyme with lipid bilayers does not necessarily indicate the absence of an interaction.

Structural changes in a secretory phospholipase A2 induced by membrane binding: a clue to interfacial activation?

Activation of phospholipase A2 (PLA2) upon binding to phospholipid assemblies is poorly understood. X-ray crystallography revealed little structural change in the enzyme upon binding of monomeric substrate analogs, whereas small conformational changes in PLA2 complexed with substrate micelles and an inhibitor were found by NMR. The structure of PLA2 bound to phospholipid bilayers is not known. Here we uncover by FTIR spectroscopy a splitting in the alpha-helical region of the amide I absorbance band of PLA2 upon binding to lipid bilayers. We provide evidence that a higher frequency component, which is only observed in the membrane-bound enzyme, is a property of more flexible helices. Formation of flexible helices upon interaction with the membrane is likely to contribute to PLA2 activation.

Activation of phosphatidylinositol-specific phospholipase C toward inositol 1,2-(cyclic)-phosphate

Phosphatidylinositol-specific phospholipase C (PI-PLC) from Bacillus thuringiensis catalyzes the hydrolysis of phosphatidylinositol (PI) in discrete steps: (i) an intramolecular phosphotransferase reaction to form inositol 1,2-(cyclic)-phosphate (cIP), followed by (ii) a cyclic phosphodiesterase activity that converts cIP to inositol 1-phosphate. Water-soluble cIP was used as the substrate to study the cyclic phosphodiesterase activity and interfacial behavior of PI-PLC. Different detergent micelles and phospholipid vesicles were used to examine if "interfacial activation" of the enzyme could occur toward a soluble substrate. Almost all detergents examined activated the enzyme at least 2-fold, with PC species yielding the largest increases in PI-PLC specific activity. Kinetic parameters were measured in the absence and presence of several representative detergents (e.g., Triton X-100 and diheptanoylphosphatidylcholine (diC7PC)). Gel filtration experiments showed that, under these conditions, the cIP did not partition to any measurable extent with these detergent micelles. The concentration at which half the maximum activation was observed occurred near the detergent CMC. Both Km and Vmax were altered by the presence of a surface: Km decreased to different degrees depending on the detergent, while Vmax increased substantially. The Km for cIP was 90 mM without detergent and decreased to 29 mM with diC7PC micelles added; Vmax increased almost 7-fold in the presence of diC7PC micelles. The enzyme efficiency (Vmax/Km) in the presence of diC7PC increased more than 21-fold, but it was still 20-fold lower than initial phosphotransferase activity for monomeric dihexanoylphosphatidylinositol. The poor efficiency of the cyclic phosphodiesterase activity is largely due to substrate binding affinity. The dependence of rate on substrate concentration exhibits cooperative behavior, especially without detergent. This cooperativity is discussed in terms of protein aggregation and ligand binding sites on the enzyme.

Relationships between bilayer structure and phospholipase A2 activity: interactions among temperature, diacylglycerol, lysolecithin, palmitic acid, and dipalmitoylphosphatidylcholine

Bilayers composed of phosphatidylcholine initially resist catalysis by phospholipase A2. However, after a latency period, they become susceptible when sufficient reaction products (lysolecithin and fatty acid) accumulate in the membrane. Temperatures near the main bilayer phase transition and saturated long-chain diacylglycerol in the bilayer modulate the effectiveness of the reaction products. The purpose of this study was to identify possible mechanisms for these effects of temperature and diacylglycerol. Various fluorescent probes were used to asses changes in the ability of the reaction products to perturb the bilayer and promote enzyme binding to he membrane surface. Temperature appeared to cause three effects. First, the degree of binding of enzyme at the end of the latency period was greatest near the phase transition temperature where the latency was shortest. Second, the bilayer was more sensitive to perturbation by reaction products near the transition. Third, the disturbance provoked by the products was confined to the membrane surface below the transition but affected deeper regions at higher temperature where the latency period was greater. The latter two effects of temperature required the presence of calcium. Diacylglycerol promoted lateral segregation of reaction products in the bilayer. This effect corresponded with the tendency of diacylglycerol to reduce the length of the latency period at temperature below the phase transition. Therefore, it appeared that temperature affects the latency period by alternating the binding of the enzyme and the depth and magnitude of the bilayer perturbation caused by reaction products. Alternatively, diacylglycerol may enhance the effectiveness of reaction products by inducing them to segregate in the bilayer and thus create local regions of increased impact on the bilayer surface.

Enhancement of Agkistrodon piscivorus piscivorus venom phospholipase A2 activity toward phosphatidylcholine vesicles by lysolecithin and palmitic acid: studies with fluorescent probes of membrane structure

The activity of phospholipase A2 from snake venom to hydrolyze bilayers of phosphatidylcholines is greatly enhanced by the presence of the hydrolysis products, lysolecithin and fatty acid, in the bilayer. The fluorescence of several probes of membrane structure was used to monitor changes in bilayer physical properties during vesicle hydrolysis. These changes were compared to emission spectra and fluorescence polarization results occurring upon direct addition of lysolecithin and/or fatty acid to the bilayer. The excimer to monomer ratio of 1,3-bis(1-pyrene)propane was insensitive to vesicle hydrolysis, suggesting that changes in the order of the phospholipid chains were not relevant to the effect of the hydrolysis products on phospholipase activity. The fluorescence of 6-propionyl-2-(dimethylamino)-naphthalene (Prodan) suggested that the polarity of the bilayer in the region of the phospholipid head groups increases as the hydrolysis products accumulate in the bilayer. The fluorescence of 6-dodecanoyl-2-(dimethylamino)naphthalene (Laurdan) confirmed that such effects were restricted to the bilayer surface. Furthermore, the lysolecithin appeared to be the product most responsible for these changes. These results suggested that lysolecithin increases the activity of phospholipase A2 during vesicle hydrolysis by disrupting the bilayer surface, making the phospholipid molecules more accessible to the enzyme active site.

Quantification of the interactions among fatty acid, lysophosphatidylcholine, calcium, dimyristoylphosphatidylcholine vesicles, and phospholipase A2

The rate of hydrolysis of phosphatidylcholine bilayers by soluble phospholipase A2 (PLA2) is greatly enhanced by the presence in the bilayer of a threshold mole fraction of the reaction products: fatty acid and lysophosphatidylcholine (lyso-PC). The threshold requirement of these products appears to vary as a function of vesicle and calcium concentration. To further identify the roles of myristic acid, lyso-PC, and calcium in promoting optimal PLA2 activity, we have quantified the various interactions among these components and dimyristoylphosphatidylcholine large unilamellar vesicles. The bilayer/water partition coefficient for myristic acid was obtained by competition of vesicles for the binding of the fatty acid to an acrylodan conjugate of an intestinal fatty acid binding protein as monitored by the acrylodan fluorescence emission spectrum. The partition coefficient for lyso-PC was obtained by a similar procedure using the tryptophan emission spectrum of bovine serum albumin. The effect of calcium concentration on these interactions was also quantified. These results were incorporated into an empirical model to describe the threshold requirements for these products in the bilayer. This information is vital for elucidating the mechanism of activation of PLA2 by the hydrolysis products.

Lipid bilayer heterogeneities and modulation of phospholipase A2 activity

The regulation of phospholipase A2 (PLA2) activity toward synthetic vesicular substrates is a model for the modulation c enzyme function by biological membranes. PLA2's catalytic rate toward membrane phospholipids can be modified by several order of magnitude by altering the membrane's composition and structure. The physical basis of this sensitivity is the subject of thi report. The results described here imply that the salient features of membrane-structure which modulate PLA2 activity include compositional phase separation; membrane curvature and, possibly, curvature-associated defects; and dynamic product inhibition due to limitations imposed by the rate of lateral diffusion of lipid in the membrane. Furthermore, it is shown that the effects of membrane structure on the catalytic rate are not exerted merely by enhancing association of PLA2 with the membrane surface: a membrane-bound inactive state is spectroscopically identified. Finally, these results are discussed in the context of some published models for the role of membrane structure in the regulation of membrane-bound enzymes.

Inhibition of yeast (1,3)-beta-glucan synthase by phospholipase A2 and its reaction products

Fungal (1,3)-beta-glucan synthases are sensitive to a wide range of lipophilic inhibitors and it has been proposed that enzyme activity is highly sensitive to perturbations of the membrane environment. Yeast membranes were exposed to phospholipases and various lipophilic compounds, and the resultant effects on glucan synthase activity were ascertained. Glucan synthase from Saccharomyces cerevisiae was rapidly inactivated by phospholipase A2 (PLA2), and to a lesser extent by phospholipase C. Inactivation was time and dose-dependent and was protected against by EDTA and fatty-acid binding proteins (bovine and human serum albumins). Albumins also partially protected against inhibition by papulacandin B. PLA2 reaction products were structurally characterized and it was shown that fatty acids and lysophospholipids were the inhibitory moieties, with no novel inhibitory compounds apparent. Glucan synthase was inhibited by a range of fatty acids, monoglycerides and lysophospholipids. Inhibition by fatty acids was non-competitive, and progressive binding of [14C]oleic acid correlated with activity loss. Fluorescence anisotropy studies using diphenylhexatriene (DPH) confirm that fatty acids increase membrane fluidity. These results are consistent with proposals suggesting that glucan synthase inhibition is due in part to non-specific detergent-like disruption of the membrane environment, in addition to direct interactions of lipophilic inhibitors with specific target sites on the enzyme complex.

Activity of phospholipase A2 on a fluorescent substrate incorporated into non-hydrolyzable phospholipid liposomes

The activity of phospholipase A2 (PLA2) on phospholipid liposomes depends on the physicochemical properties of the aggregated substrate, which are subject to continuous modification by the products released during hydrolysis. We propose here an experimental design that, by means of the incorporation of a fluorescent substrate at very low molar ratio (< or = 1:500) into a nonhydrolizable liposomal matrix of 1,2-dihexadecyl-sn-glycero-3-phosphocholine (DHPC), allows the study of hydrolysis by porcine pancreatic phospholipase A2, in virtual absence of physical perturbations of the lamellar phase, by the released products. We have been able to measure immediate hydrolysis of the fluorescent substrate 1,2-di-[omega(1'-pyreno)-decanoyl]-sn- glycero-3-phosphocholine when the sonicated liposomal matrix is in the gel phase. In the liquid crystalline state, in contrast, hydrolysis is very poor even after 80 min of adding the enzyme. Both in the gel and liquid-crystalline phases, incorporation of unlabeled PLA2 products activates the hydrolysis rate to comparable levels. It appears that the conformation adopted by the substrate immersed in the gel or liquid crystalline matrix is especially important in determining its susceptibility to hydrolysis in the absence of products.

Quantification of the interaction between lysolecithin and phospholipase A2

The rate of hydrolysis of phosphatidylcholine bilayers by phospholipase A2 may be either enhanced or inhibited by the presence of lysolecithin depending on the experimental conditions examined. To further understand the relationship of lysolecithin to phospholipase A2 activity, the binding of lysolecithin to phospholipase A2 from the venom of Agkistrodon piscivorus piscivorus was examined by fluorescence spectroscopy. The tryptophan emission intensity of the enzyme was enhanced by 70% upon addition of lysolecithin. The binding isotherm for lysolecithin to the phospholipase A2 estimated from the fluorescence change was biphasic, with a clear break in the curve occurring at the critical micelle concentration of the lysolecithin. Several observations suggested that the phospholipase A2 was capable of hydrolyzing the lysolecithin although at a rate far below that of phospholipid hydrolysis. These experiments were repeated using several other species of phospholipase A2, and the results were found to be general among the enzymes except the lys-49 isozyme from A. p. piscivorus which displayed neither the dependence on the critical micelle concentration for binding nor the ability to hydrolyze lysolecithin. These results were used as the basis for a quantitative analysis of enzyme fluorescence changes that occur during the time course of phospholipid hydrolysis and of the mechanism whereby lysolecithin inhibits the hydrolysis of phosphatidylcholine bilayers by phospholipase A2.

A critique of the role of the blood-brain barrier in the chemotherapy of human brain tumors

There is general agreement that most chemotherapy agents achieve only relatively low concentrations in the normal central nervous system, that the blood-brain barrier is variably disrupted in malignant brain tumors, and that the concentration of chemotherapy drugs in the brain adjacent to tumor is intermediate between concentrations achieved in brain tumors vs normal brain. However, there is substantial controversy regarding the role of the blood-brain barrier in resistance to chemotherapy of intracerebral tumors. Many chemotherapy agents achieve concentrations in brain tumors that are comparable to those in extracerebral tumors, and drugs that cross the intact blood-brain barrier only poorly may be active against intracerebral tumors. Furthermore, the hypothesis that the brain is a pharmacological sanctuary where metastases may grow while tumor is responding in other parts of the body may be flawed: there are only 2 or 3 types of malignancies (out of all those that are sensitive to chemotherapy) in which the risk of isolated central nervous system relapse is moderately high, and even in these 2 or 3, effective central nervous system prophylaxis has minimal or no impact on overall survival. Furthermore, drugs that cross the BBB do not appear to be more effective than other drugs at reducing the risk of brain metastases, and brain metastases at the time of diagnosis do not necessarily convey a worse prognosis than metastases to various other sites. While average drug concentrations in brain adjacent to tumor are lower than those within brain tumors, very small numbers of tumor cells may be capable of inducing local leakiness in blood vessels, and there is little information on drug concentrations achieved in individual tumor cells within the brain adjacent to tumor. Furthermore, any limitation of uptake of drugs into brain tumors could be at least partially due to increased tissue pressure within tumors rather than being due to blood-brain barrier phenomena. This distinction could be important, since strategies that one might use to increase drug delivery to brain tumors might differ depending on whether the reduced delivery were due to barrier phenomena vs blood flow phenomena. The role of the blood-brain barrier in resistance of intracerebral tumors to chemotherapy remains unclear: while it may well play some role (and perhaps even a major one), self-fulfilling prophecies and unintentional bias in data selection and interpretation may have previously made it appear more important than it actually is.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of lateral phase separation in the modulation of phospholipase A2 activity

Phospholipase A2-catalyzed hydrolysis of phosphatidylcholine large unilamellar vesicles is characterized by a period of slow hydrolysis followed by a rapid increase in the rate of hydrolysis. The temporal relationship between the burst of PLA2 activity and the lateral distribution of substrate and product lipids was examined by simultaneously recording product accumulation and the fluorescence of 1-pyrenyldecanoate, a fatty acid derivative sensitive to lipid distribution and lateral diffusion. The excimer: monomer ratio of the probe changes slowly prior to the burst in activity and then abruptly at the time of the burst. A partial phase diagram for the ternary codispersion of substrate and products (dipalmitoylphosphatidylcholine and 1:1 monopalmitoylphosphatidylcholine/palmitic acid) was constructed by differential scanning calorimetry and suggests gel/gel immiscibility in this system. Thus, the changes in pyrene fluorescence during the time course of hydrolysis appear to be due to lateral phase separation. The critical mole fraction of product both for lateral phase separation in the gel state and for elimination of the lag phase is approximately 0.083. The simultaneous recordings of PLA2 activity and pyrene fluorescence show that the lateral rearrangement of lipids begins prior to and continues during the rapid activation process of PLA2. Two possible effects of lateral phase separation are that concentration of the protein in the product-rich regions promotes putative dimerization or that formation of phase interface regions promotes enzyme activation.