Sequence of Physical Changes to the Cell Membrane During Glucocorticoid-Induced Apoptosis in S49 Lymphoma Cells

During apoptosis, physical changes in the plasma membrane prepare the cell for clearance by phagocytes and hydrolysis by secretory phospholipase A₂ (sPLA₂). The relationships among these changes have not been adequately established, especially for hormone-stimulated apoptosis. This study addresses these issues for glucocorticoid-induced apoptosis in S49 lymphoma cells. Flow cytometry, microscopy, and fluorescence spectroscopy were used to assess merocyanine 540 emission, laurdan generalized polarization, phosphatidylserine exposure, caspase activation, and membrane permeability to propidium iodide in the absence and presence of sPLA₂. The earliest event observed was activation of cellular caspases. Results with membrane probes suggest that interlipid spacing also increases early during apoptosis and precedes transbilayer migration of phosphatidylserine, DNA fragmentation, and a general increase in lipid order associated with blebbing and dissolution of the cells. The activity of sPLA₂ appeared to be linked more to lipid spacing than to loss of membrane asymmetry. The early nature of some of these events and their ability to promote activity of a proinflammatory enzyme suggests the possibility of an inflammatory response during T-lymphocyte apoptosis.     

Effects of cholesterol on physical properties of human erythrocyte membranes: impact on susceptibility to hydrolysis by secretory phospholipase A2

The ability of secretory phospholipase A₂ (sPLA₂) to hydrolyze cell membranes is highly dependent on the physical properties of the membrane. The effects of cholesterol on these properties have been characterized in artificial bilayers and found to alter sPLA₂ activity significantly. It is hypothesized that the natural difference in cholesterol content between erythrocytes and leukocytes is in part responsible for their differing susceptibility to hydrolysis by sPLA₂. To test this hypothesis, defined amounts of cholesterol were removed from erythrocyte membranes using methyl-β-cyclodextrin. Treatment of cells with methyl-β-cyclodextrin increased the hydrolysis rate and total substrate hydrolyzed by sPLA₂. In general, this effect of cholesterol removal was more pronounced at higher temperatures. Comparison of the level of membrane order (assessed with the fluorescent probe laurdan) with hydrolysis rate revealed that sPLA₂ activity was greatly enhanced upon significant reductions in lipid order. Additional treatment of the cells with calcium ionophore further enhanced the hydrolysis rate and altered the relationship with membrane order. These data demonstrated that interactions with sPLA₂ observed in artificial bilayers apply to biological membranes. It is also proposed that the high level of cholesterol in erythrocyte membranes is a protective mechanism to guard against hydrolytic enzymes.     

Secreted Phospholipases A2 - not just Enzymes: Revisited

Secreted phospholipases A₂ (sPLA₂s) participate in a very broad spectrum of biological processes through their enzymatic activity and as ligands for membrane and soluble receptors. The physiological roles of sPLA₂s as enzymes have been very well described, while their functions as ligands are still poorly known. Since the last overview of sPLA₂-binding proteins (sPLA₂-BPs) 10 years ago, several important discoveries have occurred in this area. New and more sensitive analytical tools have enabled the discovery of additional sPLA₂-BPs, which are presented and critically discussed here. The structural diversity of sPLA₂-BPs reveals sPLA₂s as very promiscuous proteins, and we offer some structural explanations for this nature that makes these proteins evolutionarily highly advantageous. Three areas of physiological engagement of sPLA₂-BPs have appeared most clearly: cellular transport and signalling, and regulation of the enzymatic activity of sPLA₂s. Due to the multifunctionality of sPLA₂s, they appear to be exceptional pharmacological targets. We reveal the potential to exploit interactions of sPLA₂s with other proteins in medical terms, for the development of original diagnostic and therapeutic procedures. We conclude this survey by suggesting the priority questions that need to be answered.     

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.     

Microparticles Mediate Hepatic Ischemia-Reperfusion Injury and Are the Targets of Diannexin (ASP8597)

Background & Aims

Ischemia–reperfusion injury (IRI) can cause hepatic failure after liver surgery or transplantation. IRI causes oxidative stress, which injures sinusoidal endothelial cells (SECs), leading to recruitment and activation of Kupffer cells, platelets and microcirculatory impairment. We investigated whether injured SECs and other cell types release microparticles during post-ischemic reperfusion, and whether such microparticles have pro-inflammatory, platelet-activating and pro-injurious effects that could contribute to IRI pathogenesis.

Methods

C57BL6 mice underwent 60 min of partial hepatic ischemia followed by 15 min–24 hrs of reperfusion. We collected blood and liver samples, isolated circulating microparticles, and determined protein and lipid content. To establish mechanism for microparticle production, we subjected murine primary hepatocytes to hypoxia-reoxygenation. Because microparticles express everted phosphatidylserine residues that are the target of annexin V, we analyzed the effects of an annexin V-homodimer (Diannexin or ASP8597) on post-ischemia microparticle production and function.

Results

Microparticles were detected in the circulation 15–30 min after post-ischemic reperfusion, and contained markers of SECs, platelets, natural killer T cells, and CD8⁺ cells; 4 hrs later, they contained markers of macrophages. Microparticles contained F2-isoprostanes, indicating oxidative damage to membrane lipids. Injection of mice with TNF-α increased microparticle formation, whereas Diannexin substantially reduced microparticle release and prevented IRI. Hypoxia-re-oxygenation generated microparticles from primary hepatocytes by processes that involved oxidative stress. Exposing cultured hepatocytes to preparations of microparticles isolated from the circulation during IRI caused injury involving mitochondrial membrane permeability transition. Microparticles also activated platelets and induced neutrophil migration in vitro. The inflammatory properties of microparticles involved activation of NF-κB and JNK, increased expression of E-selectin, P-selectin, ICAM-1 and VCAM-1. All these processes were blocked by coating microparticles with Diannexin.

Conclusions

Following hepatic IRI, microparticles circulate and can be taken up by hepatocytes, where they activate signaling pathways that mediate inflammation and hepatocyte injury. Diannexin prevents microparticle formation and subsequent inflammation.     

Induction of distinct sets of secretory phospholipase A2 in rodents during inflammation

Although the expression of the prototypic secretory phospholipase A₂ (sPLA₂), group IIA (sPLA₂-IIA), is known to be up-regulated during inflammation, it remains uncertain if other sPLA₂ enzymes display similar or distinct profiles of induction under pathological conditions. In this study, we investigated the expression of several sPLA₂s in rodent inflammation models. In lipopolysaccharide (LPS)-treated mice, the expression of sPLA₂-V, and to a lesser extent that of sPLA₂-IID, -IIE, and -IIF, were increased, whereas that of sPLA₂-X was rather constant, in distinct tissues. 12-O-Tetradecanoylphorbol-13-acetate (TPA)-induced mouse ear edema, in which the expression of sPLA₂-IID, -IIF and -V was increased, was significantly reduced by YM-26734, a competitive sPLA₂-IIA inhibitor that turned out to inhibit sPLA₂-IID, -IIE, -V and -X as well. In contrast, sPLA₂-IIA was dominant in carageenin-induced pleurisy in rats, where the accumulation of exudate fluids and leukocytes was significantly ameliorated by YM-26734. These results indicate that distinct sPLA₂s can participate in inflammatory diseases according to tissues, animal species, and types of inflammation.     

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.     

The role of mast cell-derived secreted phospholipases A2 in respiratory allergy

Secreted phospholipases A₂ (sPLA₂s) are molecules released in plasma and biological fluids of patients with systemic inflammatory, autoimmune and allergic diseases. These molecules exert proinflammatory effects by either enzymatic-mechanisms or through binding to surface molecules expressed on inflammatory cells. sPLA₂s are released at low levels in the normal airways and tend to increase during respiratory allergies (e.g., rhinitis and bronchial asthma) as the result of local secretion. Several sPLA₂ isoforms are expressed in the human lung and some of them (e.g., group IIA and group X) are released in the airways of patients with rhinitis or asthma. Mast cells play a major role in the pathogenesis of respiratory allergies and other chronic inflammatory lung diseases. Recent evidence indicates that mast cells purified from human lung express most of the sPLA₂ isoforms so far described. IgE-mediated activation of these cells induce the release of sPLA₂s suggesting that mast cells are a main source of extracellular sPLA₂s during allergic reactions. Once released, sPLA₂s may contribute to the generation of eicosanoids (e.g., PGD₂ and LTC₄) and to the release of preformed mediators (e.g., histamine) by an autocrine loop involving the interaction of sPLA₂s with surface molecules such as heparan sulphate proteoglycans or the M-type receptor. Thus, mast cell-derived sPLA₂s may play an important role in the initiation and amplification of the inflammatory reactions in patients with allergic rhinitis and bronchial asthma.     

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.     

Key Role of Group V Secreted Phospholipase A2 in Th2 Cytokine and Dendritic Cell-Driven Airway Hyperresponsiveness and Remodeling

Background

Previous work has shown that disruption of the gene for group X secreted phospholipase A₂ (sPLA₂-X) markedly diminishes airway hyperresponsiveness and remodeling in a mouse asthma model. With the large number of additional sPLA₂s in the mammalian genome, the involvement of other sPLA₂s in the asthma model is possible – in particular, the group V sPLA₂ (sPLA₂-V) that like sPLA₂-X is highly active at hydrolyzing membranes of mammalian cells.

Methodology and Principal Findings

The allergen-driven asthma phenotype was significantly reduced in sPLA₂-V-deficient mice but to a lesser extent than observed previously in sPLA₂-X-deficient mice. The most striking difference observed between the sPLA₂-V and sPLA₂-X knockouts was the significant impairment of the primary immune response to the allergen ovalbumin (OVA) in the sPLA₂-V^−/− mice. The impairment in eicosanoid generation and dendritic cell activation in sPLA2-V^−/− mice diminishes Th2 cytokine responses in the airways.

Conclusions

This paper illustrates the diverse roles of sPLA₂s in the immunopathogenesis of the asthma phenotype and directs attention to developing specific inhibitors of sPLA₂-V as a potential new therapy to treat asthma and other allergic disorders.     

Liquid-liquid immiscibility in model membranes activates secretory phospholipase A2

Secretory phospholipase A₂ (sPLA₂) hydrolyzes phosphatidylcholines (PC) within lipid bilayers to produce lyso-PC and a fatty acid, which can act as signaling molecule in biological membranes. The activity of sPLA₂ depends on the membrane structure. Bilayer defects, curvature, and gel-fluid micro-heterogeneity are known to activate sPLA₂. Here, we investigate if liquid-liquid immiscibility within model membranes is sufficient for sPLA₂ activation. The onset of the hydrolytic activity of cobra-venom sPLA₂ towards mixed monolayers of dimyristoyl-PC (DMPC)/cholesterol 2:1 (mol/mol) has been determined using infrared reflection-absorption spectroscopy (IRRAS) and polarization-modulated (PM-) IRRAS. The lag phase of sPLA₂ activity increases exponentially with rising surface pressures starting at 12 mN/m. This indicates that enzyme activation is hampered at higher surface pressures. Below 12 mN/m, no lag phase is observed, and sPLA₂ is efficiently activated. The surface pressure that is critical for sPLA₂ activation correlates with the critical miscibility pressure according to the phase diagram of DMPC and cholesterol. Thus, coexisting, liquid-phase domains provide sufficient boundaries to activate sPLA₂. Moreover, liquid-liquid immiscibility is an activating mechanism for sPLA₂ that also applies to biological membranes under physiological conditions because the corresponding bilayer structure is associated with that of membrane rafts.     

Leptin induces the generation of procoagulant,tissue factor bearing microparticles by human peripheral blood mononuclear cells

BackgroundObesity is linked to increased thrombotic risk. Circulating leptin concentration correlates with body mass index. Microparticles are small (.05–1 μm) vesicles shed by activated and apoptotic cells, involved in numerous pathophysiologically relevant phenomena including blood coagulation and thrombosis. We tested the hypothesis that leptin induces the shedding of procoagulant, tissue factor bearing microparticles by human peripheral blood mononuclear cells, and investigated the intracellular mechanisms leading to microparticle release upon incubation with leptin.MethodsPeripheral blood mononuclear cells were isolated from healthy donors. Cells were incubated with leptin in the presence or in the absence of a phospholipase C inhibitor, U73122, a calmodulin inhibitor, W-7, and three inhibitors of mitogen activated protein kinases. Microparticle generation was assessed as phosphatidylserine concentration with a prothrombinase assay and by cytofluorimetric analysis. Tissue factor expression on microparticles was measured with a one-stage clotting assay. Intracellular calcium concentration was assessed by a fluorescent probe.ResultsLeptin increased intracellular calcium mobilization and stimulated the generation of tissue factor-bearing MP by peripheral blood mononuclear cells, as assessed by phosphatidylserine quantification, clotting tests and flow-cytometry. U73122, PD98059 (an extracellular signal-regulated kinase1/2 inhibitor), and W-7, significantly inhibited leptin-induced MP release. SB203580 (a p38 inhibitor), and SP600125 (a c-Jun N-terminal kinase inhibitor) had no effect.ConclusionLeptin-induced generation of procoagulant microparticles might represent a link between obesity and atherothrombotic risk. Inhibition of leptin-induced microparticle generation might prove a viable strategy for the reduction of such risk in obese individuals.     

Type-IIA secreted phospholipase A2 is an endogenous antibiotic-like protein of the host

Type-IIA secreted phospholipase A₂ (sPLA₂-IIA) has been proposed to play a role in the development of inflammatory diseases. It has been shown to release arachidonic acid, the precursor of proinflammatory eicosanoids, to hydrolyze phospholipids of pulmonary surfactant, and to bind to specific receptors located on cell surface membranes. However, the most established biological role of sPLA₂-IIA is related to its potent bactericidal property in particular toward Gram-positive bacteria. This enzyme is present in animal and human biological fluids at concentrations sufficient to kill bacteria. Human recombinant sPLA₂-IIA is able to kill Gram-positive bacteria at concentrations as low as 1.1 ng/ml. This remarkable property is due to the unique preference of sPLA₂-IIA for anionic phospholipids such as phosphatidylglycerol, the main phospholipid component of bacterial membranes. Much higher concentrations of sPLA₂-IIA are required for its action on host cell membranes and surfactant both of which are mainly composed by phosphatidylcholine, a poor substrate for sPLA₂-IIA. Transgenic mice over-expressing human sPLA₂-IIA are resistant to infection by Staphylococcus aureus, Escherichia coli, and Bacillus anthracis, the etiological agent of anthrax. Conversely, certain bacteria, such as B. anthracis, E. coli and Bordetella pertussis are able to inhibit sPLA₂-IIA expression by host cells, thus highlighting a mechanism by which these bacteria can subvert the host immune system. Intranasal instillation of recombinant sPLA₂-IIA protects mice from mortality caused by pulmonary anthrax. Interestingly, this protective effect was obtained even with B. anthracis strains that down-regulate the expression of endogenous sPLA₂-IIA, indicating that instilled sPLA₂-IIA can overcome the subversive action of B. anthracis. We conclude that sPLA₂-IIA is an efficient endogenous antibiotic of the host and can play a role in host defense against pathogenic bacteria. It can be used as a therapeutic agent in adjunct with current therapy to treat bacteria resistant to multiple antibiotics.     

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)     

Apoptosis-inducing factor of a cytotoxic T cell line: involvement of a secretory phospholipase A2

Natural killer (NK) cells and cytotoxic T lymphocytes (CTLs) kill target cells by the granule-exocytosis pathway and by the engagement of molecules belonging to the tumor necrosis factor family. The involvement of secretory phospholipase A₂ (sPLA₂) in the cytotoxic process has been proposed in NK cells. However, its molecular identity and intracellular localization remain unknown, and its mechanism of action is poorly understood. Here, we have readdressed this issue by studying the cytotoxic activity of whole cell extracts of a CTL line. We observed that inactivation of the perforin-granzyme pathway at 37°C in the presence of 1 mM Ca²⁺ enhanced the ability of CTL extracts to induce apoptosis. This potentiation of cell death was Ca²⁺-dependent, thermo-resistant, and inhibited by 4-bromophenacyl bromide and scalaradial (two inhibitors of sPLA₂). The involvement of an sPLA₂ was confirmed by blocking the pro-apoptotic activity of the Ca²⁺-treated cell extract with an anti-sPLA₂ polyclonal antibody. By cell fractionation assays, we showed that the pro-apoptotic sPLA₂ was localized in the cytoplasmic fraction but not in perforin-rich granules or plasma membrane fractions. Western blotting analysis revealed the presence of four distinct bands of 56, 29.5, 21, and 15 kDa. The highest molecular weight band was consistent with the expression of a group III sPLA2. Taken together, these data indicate that an apoptosis-inducing sPLA₂ is expressed in the cytosol of a CTL cell line and suggest that it plays an effector role in CTL-mediated cytotoxicity. This work was supported by the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ), and Programa de Núcleos de Excelência (PRONEX–CNPq).     

Group IIA and group V secretory phospholipase A2: quantitative analysis of expression and secretion and determination of the localization and routing in rat mesangial cells

Mesangial cells can be induced to express group IIA and group V secretory phospholipase A₂ (sPLA₂) at the mRNA level and at the protein level. In this report we quantitatively analyze the expression of both proteins in stimulated cells by Western blot techniques. We found that 75–80% of the total amount of synthesized group IIA sPLA₂ was secreted. The synthesized group V sPLA₂, however, was present almost exclusively intracellularly. The amount of group V present in the cell was comparable to the intracellular amount of group IIA sPLA₂. We furthermore studied the localization and routing of both proteins. Using fusion proteins of the group IIA or group V pre-sPLA₂ with green fluorescent protein it was established that both presequences are able to direct the proteins to the Golgi system. In immunofluorescence studies group V sPLA₂ expressed by rat mesangial cells was located in a punctate pattern in the cytosol with an enrichment near the nucleus. Immunofluorescent confocal laser scanning microscopy revealed that the group V and IIA sPLA₂ show partial colocalization in a Golgi-like structure in the inner part in the cell, but no colocalization was seen in the vesicles in the cytoplasm. The images also showed that group IIA sPLA₂ was located throughout the cell while group V was mainly present in the inner part of the cell. After treatment of the cells with brefeldin A or monensin the group IIA enzyme could no longer be detected, while group V sPLA₂ was still present although its localization was somewhat dependent on the treatment. Collectively, these results indicate that the two enzymes differ in both localization and routing in the cell, which underscores the hypothesis that the enzymes might have different functions.     

Procoagulant,Tissue Factor-Bearing Microparticles in Bronchoalveolar Lavage of Interstitial Lung Disease Patients: An Observational Study

Coagulation factor Xa appears involved in the pathogenesis of pulmonary fibrosis. Through its interaction with protease activated receptor-1, this protease signals myofibroblast differentiation in lung fibroblasts. Although fibrogenic stimuli induce factor X synthesis by alveolar cells, the mechanisms of local posttranslational factor X activation are not fully understood. Cell-derived microparticles are submicron vesicles involved in different physiological processes, including blood coagulation; they potentially activate factor X due to the exposure on their outer membrane of both phosphatidylserine and tissue factor. We postulated a role for procoagulant microparticles in the pathogenesis of interstitial lung diseases. Nineteen patients with interstitial lung diseases and 11 controls were studied. All subjects underwent bronchoalveolar lavage; interstitial lung disease patients also underwent pulmonary function tests and high resolution CT scan. Microparticles were enumerated in the bronchoalveolar lavage fluid with a solid-phase assay based on thrombin generation. Microparticles were also tested for tissue factor activity. In vitro shedding of microparticles upon incubation with H₂O₂ was assessed in the human alveolar cell line, A549 and in normal bronchial epithelial cells. Tissue factor synthesis was quantitated by real-time PCR. Total microparticle number and microparticle-associated tissue factor activity were increased in interstitial lung disease patients compared to controls (84±8 vs. 39±3 nM phosphatidylserine; 293±37 vs. 105±21 arbitrary units of tissue factor activity; mean±SEM; p<.05 for both comparisons). Microparticle-bound tissue factor activity was inversely correlated with lung function as assessed by both diffusion capacity and forced vital capacity (r² = .27 and .31, respectively; p<.05 for both correlations). Exposure of lung epithelial cells to H₂O₂ caused an increase in microparticle-bound tissue factor without affecting tissue factor mRNA.Procoagulant microparticles are increased in interstitial lung diseases and correlate with functional impairment. These structures might contribute to the activation of factor X and to the factor Xa-mediated fibrotic response in lung injury.     

Lactadherin Inhibits Secretory Phospholipase A2 Activity on Pre-Apoptotic Leukemia Cells

Secretory phospholipase A₂ (sPLA₂) is a critical component of insect and snake venoms and is secreted by mammalian leukocytes during inflammation. Elevated secretory PLA₂ concentrations are associated with autoimmune diseases and septic shock. Many sPLA₂’s do not bind to plasma membranes of quiescent cells but bind and digest phospholipids on the membranes of stimulated or apoptotic cells. The capacity of these phospholipases to digest membranes of stimulated or apoptotic cells correlates to the exposure of phosphatidylserine. In the present study, the ability of the phosphatidyl-L-serine-binding protein, lactadherin to inhibit phospholipase enzyme activity has been assessed. Inhibition of human secretory phospholipase A₂-V on phospholipid vesicles exceeded 90%, whereas inhibition of Naja mossambica sPLA₂ plateaued at 50–60%. Lactadherin inhibited 45% of activity of Naja mossambica sPLA₂ and >70% of human secretory phospholipase A₂-V on the membranes of human NB4 leukemia cells treated with calcium ionophore A23187. The data indicate that lactadherin may decrease inflammation by inhibiting sPLA₂.     

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.     

The Role of Secretory Phospholipase A2 in the Central Nervous System and Neurological Diseases

Secretory phospholipase A₂ (sPLA₂s) are small secreted proteins (14–18 kDa) and require submillimolar levels of Ca²⁺ for liberating arachidonic acid from cell membrane lipids. In addition to the enzymatic function, sPLA₂ can exert various biological responses by binding to specific receptors. Physiologically, sPLA₂s play important roles on the neurotransmission in the central nervous system and the neuritogenesis in the peripheral nervous system. Pathologically, sPLA₂s are involved in the neurodegenerative diseases (e.g., Alzheimer’s disease) and cerebrovascular diseases (e.g., stoke). The common pathology (e.g., neuronal apoptosis) of Alzheimer’s disease and stroke coexists in the mixed dementia, suggesting common pathogenic mechanisms of the two neurological diseases. Among mammalian sPLA₂s, sPLA₂-IB and sPLA₂-IIA induce neuronal apoptosis in rat cortical neurons. The excess influx of calcium into neurons via l-type voltage-dependent Ca²⁺ channels mediates the two sPLA₂-induced apoptosis. The elevated concentration of intracellular calcium activates PKC, MAPK and cytosolic PLA₂. Moreover, it is linked with the production of reactive oxygen species and apoptosis through activation of the superoxide producing enzyme NADPH oxidase. NADPH oxidase is involved in the neurotoxicity of amyloid β peptide, which impairs synaptic plasticity long before its deposition in the form of amyloid plaques of Alzheimer’s disease. In turn, reactive oxygen species from NADPH oxidase can stimulate ERK1/2 phosphorylation and activation of cPLA₂ and result in a release of arachidonic acid. sPLA₂ is up-regulated in both Alzheimer’s disease and cerebrovascular disease, suggesting the involvement of sPLA₂ in the common pathogenic mechanisms of the two diseases. Thus, our review presents evidences for pathophysiological roles of sPLA₂ in the central nervous system and neurological diseases.