Emerging roles of secreted phospholipase A2 enzymes: Lessons from transgenic and knockout mice

Among the emerging phospholipase A₂ (PLA₂) superfamily, the secreted PLA₂ (sPLA₂) family consists of low-molecular-mass, Ca²⁺-requiring extracellular enzymes with a His-Asp catalytic dyad. To date, more than 10 sPLA₂ enzymes have been identified in mammals. Individual sPLA₂s exhibit unique tissue and cellular localizations and enzymatic properties, suggesting their distinct pathophysiological roles. Despite numerous enzymatic and cell biological studies on this enzyme family in the past two decades, their precise in vivo functions still remain largely obscure. Recent studies using transgenic and knockout mice for several sPLA₂ enzymes, in combination with lipidomics approaches, have opened new insights into their distinct contributions to various biological events such as food digestion, host defense, inflammation, asthma and atherosclerosis. In this article, we overview the latest understanding of the pathophysiological functions of individual sPLA₂ isoforms fueled by studies employing transgenic and knockout mice for several sPLA₂s.     

In silico and in vitro characterization of phospholipase A2 isoforms from soybean (Glycine max)

At the present, no secreted phospholipase A₂ (sPLA₂) from soybean (Glycine max) was investigated in detail. In this work we identified five sequences of putative secreted sPLA₂ from soybean after a BLAST search in G. max database. Sequence analysis showed a conserved PA2c domain bearing the Ca²⁺ binding loop and the active site motif. All the five mature proteins contain 12 cysteine residues, which are commonly conserved in plant sPLA₂s. We propose a phylogenetic tree based on sequence alignment of reported plant sPLA₂s including the novel enzymes from G. max. According to PLA₂ superfamily, two of G. max sPLA₂s are grouped as XIA and the rest of sequences as XIB, on the basis of differences found in their molecular weights and deviating sequences especially in the N- and C-terminal regions of the isoenzymes. Furthermore, we report the cloning, expression and purification of one of the putative isoenzyme denoted as GmsPLA₂-XIA-1. We demonstrate that this mature sPLA₂ of 114 residues had PLA₂ activity on Triton:phospholipid mixed micelles and determine the kinetic parameters for this system. We generate a model based on the known crystal structure of sPLA₂ from rice (isoform II), giving first insights into the three-dimensional structure of folded GmsPLA₂-XIA-1. Besides describing the spatial arrangement of highly conserved pair HIS-49/ASP-50 and the Ca⁺² loop domains, we propose the putative amino acids involved in the interfacial recognition surface. Additionally, molecular dynamics simulations indicate that calcium ion, besides its key function in the catalytic cycle, plays an important role in the overall stability of GmsPLA₂-XIA-1 structure.     

Inhibition of secretory phospholipase A2 enzyme by bilirubin: A new role as endogenous anti-inflammatory molecule

Bilirubin is a powerful antioxidant that suppresses the inflammatory process. However its interaction with proinflammatory PLA₂ enzyme is not known. Inhibition of several secretory phospholipase A₂ (sPLA₂) enzyme activities by bilirubin was studied using ¹⁴C-oleate labeled Escherichia coli as substrate. Bilirubin inhibits purified sPLA₂ enzyme from Vipera russellii and Naja naja venom and partially purified sPLA₂ enzymes from human ascitic fluid, pleural fluid and normal serum in a dose dependent manner. IC₅₀ values calculated for these enzymes ranges from 1.75 to 10.5 μM. Inflammatory human sPLA₂ enzymes are more sensitive to inhibition by bilirubin than snake venom sPLA₂s. Inhibition of sPLA₂ activity by bilirubin is independent of calcium concentration. Increasing substrate concentration (upto 180 nmol) did not relieve the inhibition of sPLA₂ by bilirubin and it is irreversible. Bilirubin quenched the relative fluorescence intensity of sPLA₂ in a dose dependent manner in the same concentration range at which in vitro sPLA₂ inhibition was observed. In the presence of bilirubin, apparent shift in the far UV-CD spectra of sPLA₂ was observed, indicating a direct interaction with the enzyme. Inhibition of sPLA₂ induced mouse paw edema by bilirubin confirms its sPLA₂ inhibitory activity in vivo also. These findings indicate that inhibition of sPLA₂ by bilirubin is mediated by direct interaction with the enzyme and bilirubin may act as an endogenous regulator of sPLA₂ enzyme activity.     

Emerging roles of secreted phospholipase A2 enzymes: An update

Phospholipase A₂ (PLA₂) enzymes catalyze the hydrolysis of the sn-2 position of glycerophospholipids to produce free fatty acids and lysophospholipids. More than one third of the mammalian PLA₂ enzymes belong to the secreted PLA₂ (sPLA₂) family, which consists of low molecular mass, Ca²⁺-requiring enzymes with a His–Asp catalytic dyad. Individual sPLA₂ enzymes exhibit unique tissue and cellular localizations and specific enzymatic properties, suggesting their distinct biological roles. The past decade has met a new era of the sPLA₂ research field toward deciphering their in vivo functions by developing several specific tools and methods. These include i) the production of transgenic and knockout mouse lines for several sPLA₂s, ii) the development of specific analytical tools including the production of large amounts of recombinant sPLA₂ proteins, and iii) applying mass spectrometry lipidomics to unveil their specific enzymatic properties occurring in vivo. It is now obvious that individual sPLA₂s are involved in diverse biological events through lipid mediator-dependent and -independent processes, act redundantly or non-redundantly in the context of physiology and pathophysiology, and may represent potential drug targets or novel bioactive molecules in certain situations. In this review, we will highlight the newest understanding of the biological roles of sPLA₂s in the past few years.     

Expression and Induction of Secretory Phospholipase A Group IB in Brain

Summary Secretory phospholipases A₂ (sPLA₂) form a diverse family of enzymes involved in physiologicand pathologic processes. Common among all sPLA₂ is the ability to cleave acyl groups of phospholipids at 2_C of the glycerol backbone, thereby releasingfatty acid and a lysophospholipid. Several sPLA₂ have been cloned and characterized in various tissues.Furthermore, receptors have been identified. In the nervous system sPLA₂ groups IIA, IIE, IIF, V, and XII have been identified, and binding sites for sPLA₂ group IB (sPLA₂-IB) have been found. Here, we report sPLA₂-IB in rat and human brain as well as in neurons in primary culture. The distribution of sPLA₂-IB seems to be mainly neuronal, with the highest abundance occurring in the cerebral cortex and hippocampus. We also find that genes encoding sPLA₂-IB are induced by kainic acid and by electroshock-induced convulsions.Based on the present results we suggest that sPLA₂-IB may be a neuronal intercellular signalling modulator.     

Phospholipase A2-like activity of human bocavirus VP1 unique region

Human bocavirus (HBoV) is a new parvovirus first discovered in 2005, which is associated with acute respiratory infection. Analysis of sequence homology has revealed that a putative phospholipase A₂ (PLA₂) motif exists in the VP1 unique region of HBoV. However, little is known about whether the VP1 unique region of HBoV has PLA₂ enzymatic activity and how these critical residues contribute to its PLA₂ activity. To address these issues, the VP1 unique region protein and four of its mutants, were expressed in Eschericha coli. The purified VP1 unique protein (VP1U) showed a typical Ca²⁺-dependent secreted PLA₂-like (sPLA₂) activity, which was inhibited by sPLA₂-specific inhibitors in a time-dependent manner. Mutation of one of the amino acids (21Pro, 41His, 42Asp or 63Asp) in VP1U almost eliminated the sPLA₂ activity of HBoV VP1U. These data indicate that VP1U of HBoV has sPLA₂-like enzymatic activity, and these residues are crucial for its sPLA₂-like activity. Potentially, VP1U may be a target for the development of anti-viral drugs for HBoV.     

Phospholipase A2 Sensitive Liposomes for Delivery of Small Interfering RNA (siRNA)

Small interfering RNA (siRNA) is potent and highly specific for gene silencing and there is currently a lot of enthusiasm for developing siRNA into a drug. However, for most therapeutic applications of siRNA, delivery systems are needed. These delivery systems have multiple requirements and should on one hand ideally be stable carriers protecting the siRNA from degradation and on the other hand assist the siRNA in overcoming membrane barriers for intracellular delivery to the cytosol. Long-circulating liposomes, which are sensitive to secretory phospholipase A₂ (sPLA₂) are feasible delivery systems for systemic administration of drugs due to their passive targeting to pathological tissue via the enhanced permeability and retention (EPR) effect and their site-specific, enzyme-triggered release of encapsulated drug in response to sPLA₂ which exists locally at elevated levels at, e.g,. sites of inflammation. However, recent data suggest that endosomal membrane destabilizing approaches could be addressed to design sPLA₂-sensitive liposomes as successful delivery systems for siRNA to the RNA interference pathway in the cytoplasm upon systemic administration.     

Expression of phospholipases A2 in primary human lung macrophages: Role of cytosolic phospholipase A2-α in arachidonic acid release and platelet activating factor synthesis

Macrophages are a major source of lipid mediators in the human lung. Expression and contribution of cytosolic (cPLA₂) and secreted phospholipases A₂ (sPLA₂) to the generation of lipid mediators in human macrophages are unclear. We investigated the expression and role of different PLA₂s in the production of lipid mediators in primary human lung macrophages. Macrophages express the alpha, but not the zeta isoform of group IV and group VIA cPLA₂ (iPLA₂). Two structurally-divergent inhibitors of group IV cPLA₂ completely block arachidonic acid release by macrophages in response to non-physiological (Ca²⁺ ionophores and phorbol esters) and physiological agonists (lipopolysaccharide and Mycobacterium protein derivative). These inhibitors also reduce by 70% the synthesis of platelet-activating factor by activated macrophages. Among the full set of human sPLA₂s, macrophages express group IIA, IID, IIE, IIF, V, X and XIIA, but not group IB and III enzymes. Me-Indoxam, a potent and cell impermeable inhibitor of several sPLA₂s, has no effect on arachidonate release or platelet-activating factor production. Agonist-induced exocytosis is not influenced by cPLA₂ inhibitors at concentrations that block arachidonic acid release. Our results indicate that human macrophages express cPLA₂-alpha, iPLA₂ and several sPLA₂s. Cytosolic PLA₂-alpha is the major enzyme responsible for lipid mediator production in human macrophages.     

Inhibition of sPLA2 enzyme activity by cell-permeable antioxidant EUK-8 and downregulation of p38, Akt,and p65 signals induced by sPLA2 in inflammatory mouse paw edema model

The arachidonic acid (AA) metabolic pathway, plays a vital role in the production of eicosanoids by the action of pro-inflammatory secretory phospholipase A₂ (PLA₂). Release of eicosanoids is known to be involved in many inflammatory diseases. Identification of the inhibitory molecules of this AA pathway enzyme along with the regulation of intracellular signaling cascades may be a finer choice to develop as a powerful anti-inflammatory drug. In this regard, we have screened few cell-permeable antioxidant molecules Tempo, Mito-TEMPO, N,N'-Bis(salicylideneamino)ethane-manganese(II) (EUK)-134, and EUK-8 against pro-inflammatory sPLA₂s. Among these, we found EUK-8 is a potent inhibitor with its IC₅₀ value ranges 0.7–2.0 µM for sPLA₂s isolated from different sources. Furthermore, docking studies confirm the strong binding of EUK-8 towards sPLA₂. In vivo effect of EUK-8 was studied in HSF-sPLA₂-induced edema in mouse paw model. In addition to neutralizing the edema, EUK-8 significantly reduces the phosphorylation level of inflammatory proteins such as p38 member of MAPK pathway, Akt, and p65 along with the suppression of pro-inflammatory cytokine (interleukin-6) and chemokine (CXCL1) in edematous tissue. This shows that EUK-8 not only inhibits the sPLA₂ activity, it also plays an important role in the regulation of sPLA₂-induced cell signaling cascades. Apart from the sPLA₂ inhibition, we also examine the regulatory actions of EUK-8 with other downstream enzymes of AA pathway such as 5-LOX assay in human polymorphonuclear leukocytes (PMNs) and COX-2 expression in carrageenan-λ induced paw edema. Here EUK-8 significantly inhibits 5-LOX enzyme activity and downregulates COX-2 expression. These data indicate that EUK-8 found to be a promising multitargeted inhibitory molecule toward inflammatory pathway. In conclusion, mitochondrial targeted antioxidant EUK-8 is not only the powerful antioxidant, also a potent anti-inflammatory molecule and may be a choice of molecule for pharmacological applications.     

On the Role of Protein Disulfide Isomerase in the Retrograde Cell Transport of Secreted Phospholipases A2

Following the finding that ammodytoxin (Atx), a neurotoxic secreted phospholipase A₂ (sPLA₂) in snake venom, binds specifically to protein disulfide isomerase (PDI) in vitro we show that these proteins also interact in living rat PC12 cells that are able to internalize this group IIA (GIIA) sPLA₂. Atx and PDI co-localize in both differentiated and non-differentiated PC12 cells, as shown by fluorescence microscopy. Based on a model of the complex between Atx and yeast PDI (yPDI), a three-dimensional model of the complex between Atx and human PDI (hPDI) was constructed. The Atx binding site on hPDI is situated between domains b and b’. Atx interacts hPDI with an extensive area on its interfacial binding surface. The mammalian GIB, GIIA, GV and GX sPLA₂s have the same fold as Atx. The first three sPLA₂s have been detected intracellularly but not the last one. The models of their complexes with hPDI were constructed by replacement of Atx with the respective mammalian sPLA₂ in the Atx—hPDI complex and molecular docking of the structures. According to the generated models, mammalian GIB, GIIA and GV sPLA₂s form complexes with hPDI very similar to that with Atx. The contact area between GX sPLA₂ and hPDI is however different from that of the other sPLA₂s. Heterologous competition of Atx binding to hPDI with GV and GX sPLA₂s confirmed the model-based expectation that GV sPLA₂ was a more effective inhibitor than GX sPLA₂, thus validating our model. The results suggest a role of hPDI in the (patho)physiology of some snake venom and mammalian sPLA₂s by assisting the retrograde transport of these molecules from the cell surface. The sPLA₂–hPDI model constitutes a valuable tool to facilitate further insights into this process and into the (patho)physiology of sPLA₂s in relation to their action intracellularly.     

Group IID,IIE, IIF and III secreted phospholipase A2s

Among the 11 members of the secreted phospholipase A₂ (sPLA₂) family, group IID, IIE, IIF and III sPLA₂s (sPLA₂-IID, -IIE, -IIF and -III, respectively) are “new” isoforms in the history of sPLA₂ research. Relative to the better characterized sPLA₂s (sPLA₂-IB, -IIA, -V and -X), the enzymatic properties, distributions, and functions of these “new” sPLA₂s have remained obscure until recently. Our current studies using knockout and transgenic mice for a nearly full set of sPLA₂s, in combination with comprehensive lipidomics, have revealed unique and distinct roles of these “new” sPLA₂s in specific biological events. Thus, sPLA₂-IID is involved in immune suppression, sPLA₂-IIE in metabolic regulation and hair follicle homeostasis, sPLA₂-IIF in epidermal hyperplasia, and sPLA₂-III in male reproduction, anaphylaxis, colonic diseases, and possibly atherosclerosis. In this article, we overview current understanding of the properties and functions of these sPLA₂s and their underlying lipid pathways in vivo.     

Snake venoms as a source of compounds modulating sperm physiology: Secreted phospholipases A2 from Oxyuranus scutellatus scutellatus impact sperm motility,acrosome reaction and in vitro fertilization in mice

The goal of this study was to identify new compounds from venoms able to modulate sperm physiology and more particularly sperm motility. For this purpose, we screened the effects of 16 snake venoms cleared of molecules higher than 15 kDa on sperm motility. Venoms rich in neurotoxins like those from Oxyuranus scutellatus scutellatus or Daboia russelii, were highly potent inhibitors of sperm motility. In contrast, venoms rich in myotoxins like those from Echis carinatus, Bothrops alternatus and Macrovipera lebetina, were inactive. From the main pharmacologically-active fraction of the Taipan snake O. scutellatus s., a proteomic approach allowed us to identify 16 different proteins, among which OS1 and OS2, two secreted phospholipases A2 (sPLA₂). Purified OS1 and OS2 mimicked the inhibitory effect on sperm motility and were likely responsible for the inhibitory effect of the active fraction. OS1 and OS2 triggered sperm acrosome reaction and induced lipid rearrangements of the plasma membrane. The catalytic activity of OS2 was required to modulate sperm physiology since catalytically inactive mutants had no effect. Finally, sperm treated with OS2 were less competent than control sperm to initiate in vitro normal embryo development. This is the first report characterizing sPLA₂ toxins that modulate in vitro sperm physiology.     

Comparison of the activities of wild type and mutant enhancing factor/mouse secretory phospholipase A2 proteins

Enhancing factor (EF) protein, an isoform of secretory phospholipase A₂ (PLA₂), was purified as a modulator of epidermal growth factor from the small intestine of the Balb/c mouse. It was for the first time that a growth modulatory property of sPLA₂ was demonstrated. Deletion mutation analysis of EF cDNA carried out in our laboratory showed that enhancing activity and phospholipase activity are two separate activities that reside in the same molecule. In order to study the specific amino acids involved in each of these activities, two site-directed mutants of EF were made and expressedin vitro. Comparison of enhancing activity as well as phospholipase A₂ activity of these mutant proteins with that of wild type protein helped in identification of some of the residues important for both the activities.     

Effects of the propeptide of group X secreted phospholipase A2 on substrate specificity and interfacial activity on phospholipid monolayers

Group X secreted phospholipase A₂ (GX sPLA₂) plays important physiological roles in the gastrointestinal tract, in immune and sperm cells and is involved in several types of inflammatory diseases. It is secreted either as a mature enzyme or as a mixture of proenzyme (with a basic 11 amino acid propeptide) and mature enzyme. The role of the propeptide in the repression of sPLA₂ activity has been studied extensively using liposomes and micelles as model interfaces. These substrates are however not always suitable for detecting some fine tuning of lipolytic enzymes. In the present study, the monolayer technique is used to compare PLA₂ activity of recombinant mouse GX sPLA₂ (mGX) and its pro-form (PromGX) on monomolecular films of dilauroyl-phosphatidyl-ethanolamine (DLPE), -choline (DLPC) and -glycerol (DLPG). The PLA₂ activity and substrate specificity of mGX (PE ≈ PG > PC) were found to be surface pressure-dependent. mGX displayed a high activity on DLPE and DLPG but not on DLPC monolayers up to surface pressures corresponding to the lateral pressure of biological membranes (30–35 mN/m). Overall, the propeptide impaired the enzyme activity, particularly on DLPE whatever the surface pressure. However some conditions could be found where the propeptide had little effects on the repression of PLA₂ activity. In particular, both PromGX and mGX had similar activities on DLPG at a surface pressure of 30 mN/m. These findings show that PromGX can be potentially active depending on the presentation of the substrate (i.e., lipid packing) and one cannot exclude such an activity in a physiological context. A structural model of PromGX was built to investigate how the propeptide controls the activity of GX sPLA₂. This model shows that the propeptide is located within the interfacial binding site (i-face) and could disrupt both the interfacial binding of the enzyme and the access to the active site by steric hindrance.     

Ectopically Expressed Pro-group X Secretory Phospholipase A2 Is Proteolytically Activated in Mouse Adrenal Cells by Furin-like Proprotein Convertases: IMPLICATIONS FOR THE REGULATION OF ADRENAL STEROIDOGENESIS*

Group X secretory phospholipase A₂ (GX sPLA₂) hydrolyzes mammalian cell membranes, liberating free fatty acids and lysophospholipids. GX sPLA₂ is produced as a pro-enzyme (pro-GX sPLA₂) that contains an N-terminal 11-amino acid propeptide ending in a dibasic motif, suggesting cleavage by a furin-like proprotein convertase (PC). Although propeptide cleavage is clearly required for enzymatic activity, the protease(s) responsible for pro-GX sPLA₂ activation have not been identified. We previously reported that GX sPLA₂ negatively regulates adrenal glucocorticoid production, likely by suppressing liver X receptor-mediated activation of steroidogenic acute regulatory protein expression. In this study, using a FLAG epitope-tagged pro-GX sPLA₂ expression construct (FLAG-pro-GX sPLA₂), we determined that adrenocorticotropic hormone (ACTH) enhanced FLAG-pro-GX sPLA₂ processing and phospholipase activity secreted by Y1 adrenal cells. ACTH increased the expression of furin and PCSK6, but not other members of the PC family, in Y1 cells. Overexpression of furin and PCSK6 in HEK 293 cells significantly enhanced FLAG-pro-GX sPLA₂ processing, whereas siRNA-mediated knockdown of both PCs almost completely abolished FLAG-pro-GX sPLA₂ processing in Y1 cells. Expression of either furin or PCSK6 enhanced the ability of GX sPLA₂ to suppress liver X receptor reporter activity. The PC inhibitor decanoyl-Arg-Val-Lys-Arg-chloromethyl ketone significantly suppressed FLAG-pro-GX sPLA₂ processing and sPLA₂ activity in Y1 cells, and it significantly attenuated GX sPLA₂-dependent inhibition of steroidogenic acute regulatory protein expression and progesterone production. These findings provide strong evidence that pro-GX sPLA₂ is a substrate for furin and PCSK6 proteolytic processing and define a novel mechanism for regulating corticosteroid production in adrenal cells.     

Thematic Review Series: Phospholipases: Central Role in Lipid Signaling and Disease: A new era of secreted phospholipase A2

Among more than 30 members of the phospholipase A₂ (PLA₂) superfamily, secreted PLA₂ (sPLA₂) enzymes represent the largest family, being Ca²⁺-dependent low-molecular-weight enzymes with a His-Asp catalytic dyad. Individual sPLA₂s exhibit unique tissue and cellular distributions and enzymatic properties, suggesting their distinct biological roles. Recent studies using transgenic and knockout mice for nearly a full set of sPLA₂ subtypes, in combination with sophisticated lipidomics as well as biochemical and cell biological studies, have revealed distinct contributions of individual sPLA₂s to various pathophysiological events, including production of pro- and anti-inflammatory lipid mediators, regulation of membrane remodeling, degradation of foreign phospholipids in microbes or food, or modification of extracellular noncellular lipid components. In this review, we highlight the current understanding of the in vivo functions of sPLA₂s and the underlying lipid pathways as revealed by a series of studies over the last decade.     

Acidity and lipolysis by group V secreted phospholipase A2 strongly increase the binding of apoB-100-containing lipoproteins to human aortic proteoglycans

Local acidic areas characterize diffuse intimal thickening (DIT) and advanced atherosclerotic lesions. The role of acidity in the modification and extra- and intracellular accumulation of triglyceride-rich VLDL and IDL particles has not been studied before. Here, we examined the effects of acidic pH on the activity of recombinant human group V secreted phospholipase A₂ (sPLA₂-V) toward small VLDL (sVLDL), IDL, and LDL, on the binding of these apoB-100-containing lipoproteins to human aortic proteoglycans, and on their uptake by human monocyte-derived macrophages. At acidic pH, the ability of sPLA₂-V to lipolyze the apoB-100-containing lipoproteins was moderately, but significantly, increased while binding of the lipoproteins to proteoglycans increased > 60-fold and sPLA₂-V-modification further doubled the binding. Moreover, acidic pH more than doubled macrophage uptake of soluble complexes of sPLA₂-V-LDL with aortic proteoglycans. Proteoglycan-affinity chromatography at pH 7.5 and 5.5 revealed that sVLDL, IDL, and LDL consisted of populations with different proteoglycan-binding affinities, and, surprisingly, the sVLDL fractions with the highest proteoglycan-affinity contained only low amounts of apolipoproteins E and C-III. Our results suggest that in atherosclerotic lesions with acidic extracellular pH, sPLA₂-V is able to lipolyze sVLDL, IDL, and LDL, and increase their binding to proteoglycans. This is likely to provoke extracellular accumulation of lipids derived from these atherogenic lipoprotein particles and to increase the progression of the atherosclerotic lesions.     

The catalytically active secretory phospholipase A2 type IIA is involved in restenosis development after PTCA in human coronary arteries and generation of atherogenic LDL

Secretory phospholipase A₂ type IIA (sPLA₂) may actively contribute to atherogenesis, acting either within the arterial wall or in plasma. Proinflammatory eicosanoids and lysophospholipids, generated through hydrolysis of cell membrane phospholipids by sPLA₂, initiate and prolong the inflammatory process. In the present study we examined the possible involvement of sPLA₂ in development of restenosis in patients undergoing percutaneous transluminal coronary angioplasty (PTCA). We also investigated whether serum sPLA₂ could catalyze accumulation of lysophosphatidylcholine (LPC) in LDL. Concentrations and catalytic activities of sPLA₂ were measured in blood serum of 49 consenting patients immediately before, 1–7 and 180 days after PTCA. All patients had repeat angiograms at 180-day follow-up. Restenosis was registered in 19 patients. Accumulation of LPC in LDL was evaluated by thin-layer chromatography after incubation of blood serum with LDL. Serum sPLA₂ concentrations increased in all study patients by day 1 post-PTCA, but the increase was significantly greater and more protracted in patients who developed restenosis. Catalytic activities increased significantly 6 days post-PTCA in patients who developed restenosis, whereas for patients without restenosis there was no change in serum sPLA₂ activity throughout the study period in spite of the sPLA2 presence in blood. Incubation of blood serum (6 days post-PTCA) with LDL resulted in accumulation of LPC only for those patients who subsequently developed restenosis. Manoalide, a specific inhibitor of sPLA₂, completely blocked the LPC accumulation. The data indicate that elevated serum sPLA₂ activity after PTCA is associated with restenosis development and may be involved in atherogenic modification of LDL in blood serum. (Mol Cell Biochem 270: 107–113, 2005)     

Genes encoding phospholipases A2 mediate insect nodulation reactions to bacterial challenge

We propose that expression of four genes encoding secretory phospholipases A₂ (sPLA₂) mediates insect nodulation responses to bacterial infection. Nodulation is the quantitatively predominant cellular defense reaction to bacterial infection. This reaction is mediated by eicosanoids, the biosynthesis of which depends on PLA₂-catalyzed hydrolysis of arachidonic acid (AA) from cellular phospholipids. Injecting late instar larvae of the red flour beetle, Tribolium castaneum, with the bacterium, Escherichia coli, stimulated nodulation reactions and sPLA₂ activity in time- and dose-related manners. Nodulation was inhibited by pharmaceutical inhibitors of enzymes involved in eicosanoid biosynthesis, and the inhibition was rescued by AA. We cloned five genes encoding sPLA₂ and expressed them in E. coli cells to demonstrate these genes encode catalytically active sPLA₂s. The recombinant sPLA₂s were inhibited by sPLA₂ inhibitors. Injecting larvae with double-stranded RNAs specific to each of the five genes led to reduced expression of the corresponding sPLA₂ genes and to reduced nodulation reactions to bacterial infections for four of the five genes. The reduced nodulation was rescued by AA, indicating that expression of four genes encoding sPLA₂s mediates nodulation reactions. A polyclonal antibody that reacted with all five sPLA₂s showed the presence of the sPLA₂ enzymes in hemocytes and revealed that the enzymes were more closely associated with hemocyte plasma membranes following infection. Identifying specific sPLA₂ genes that mediate nodulation reactions strongly supports our hypothesis that sPLA₂s are central enzymes in insect cellular immune reactions.     

Leukotriene receptor antagonists,LY293111 and ONO-1078, protect neurons from the sPLA2-IB-induced neuronal cell death independently of blocking their receptors

In the ischemic brain, leukotrienes (LTs) are increased and their receptor antagonists protect neurons. However, it has not yet been sufficiently clarified how antagonists for LT receptors exhibit neuroprotective effects. In the present study, we evaluated protective effects of receptor antagonists for LTB₄ (LY293111) and cysteinyl LTs (ONO-1078) in the primary culture of rat cortical neurons. The group IB secretory phospholipase A₂ (sPLA₂-IB)-induced neuronal cell death had been established as the in vitro model for cerebral ischemia. sPLA₂-IB triggered the influx of Ca²⁺ into neurons via L-type voltage-dependent calcium channel (L-VDCC). Subsequently, the enzyme produced eicosanoids including LTB₄ before neuronal cell death. Neither administration of LTB₄ nor cysteinyl LTs such as LTC₄, LTD₄ and LTE₄ killed neurons. However, both LY293111 and ONO-1078 significantly prevented neurons from the neurotoxicity of sPLA₂-IB, suggesting that the two LT receptor blockers protected neurons through alternative pathways beside LT receptors. An L-VDCC blocker does not only inhibit the influx of Ca²⁺ into neurons but also rescues neurons from the sPLA₂-IB-induced neuronal cell death. The two LT receptor antagonists also blocked the sPLA₂-IB-induced Ca²⁺ influx significantly. Thus, LTs exhibited no neurotoxicity, but their receptor antagonists protected neurons directly in the in vitro ischemic model. Furthermore, the suppression of L-VDCC appeared to be involved in the neuroprotective effects of LY293111 and ONO-1078 independent of blocking their receptors.