Cellular Assays for Evaluating Calcium-Dependent Translocation of cPLA2α to Membrane.

The group IVA phospholipase A2, commonly called cytosolic phospholipase A2α (cPLA2α), is a widely expressed enzyme that hydrolyzes membrane phospholipid to produce arachidonic acid and lysophospholipids, which are precursors for a number of bioactive lipid mediators. Arachidonic acid is metabolized through the cyclooxygenase and lipoxygenase pathways for production of prostaglandins and leukotrienes that regulate normal physiological processes and contribute to disease pathogenesis. cPLA2α is composed of an N-terminal C2 domain and a C-terminal catalytic domain that contains the Ser-Asp catalytic dyad. The catalytic domain contains phosphorylation sites and basic residues that regulate the catalytic activity of cPLA2α. In response to cell stimulation, cPLA2α is rapidly activated by posttranslational mechanisms including increases in intracellular calcium and phosphorylation by mitogen-activated protein kinases. In resting cells, cPLA2α is localized in the cytosol but translocates to membrane including the Golgi, endoplasmic reticulum, and the peri-nuclear membrane in response to increases in intracellular calcium. Calcium binds to the C2 domain, which promotes the interaction of cPLA2α with membrane through hydrophobic interactions. In this chapter, we describe assays used to study the calcium-dependent translocation of cPLA2α to membrane, a regulatory step necessary for access to phospholipid and release of arachidonic acid.

Arachidonate metabolism and the signaling pathway of induction of apoptosis by oxidized LDL/oxysterol.

Owing at least in part to oxysterol components that can induce apoptosis, oxidized LDL (oxLDL) is cytotoxic to mammalian cells with receptors that can internalize it. Vascular cells possess such receptors, and it appears that the apoptotic response of vascular cells to the oxysterols borne by oxLDL is an important part of the atherogenic effects of oxLDL. Thus, an analysis of the signaling pathway of apoptotic induction by oxysterols is of value in understanding the development of atherosclerotic plaque. In a prior study, we demonstrated an induction of calcium ion flux into cells treated with 25-hydroxycholesterol (25-OHC) and showed that this response is essential for 25-OHC-induced apoptosis. One possible signal transduction pathway initiated by calcium ion fluxes is the activation of cytosolic phospholipase A2 (cPLA2). In the current study, we demonstrate that activation of cPLA2 does occur in both macrophages and fibroblasts treated with 25-OHC or oxLDL. Activation is evidenced by 25-OHC-induced relocalization of cPLA2 to the nuclear envelope and arachidonic acid release. Loss of cPLA2 activity, either through genetic knockout in mice, or by treatment with a cPLA2 inhibitor, results in an attenuation of arachidonic acid release as well as of the apoptotic response to oxLDL in peritoneal macrophages or to 25-OHC in cultured fibroblast and macrophage cell lines.

A pyrrolidine-based specific inhibitor of cytosolic phospholipase A(2)alpha blocks arachidonic acid release in a variety of mammalian cells.

We analyzed a recently reported (K. Seno, T. Okuno, K. Nishi, Y. Murakami, F. Watanabe, T. Matsuur, M. Wada, Y. Fujii, M. Yamada, T. Ogawa, T. Okada, H. Hashizume, M. Kii, S.-H. Hara, S. Hagishita, S. Nakamoto, J. Med. Chem. 43 (2000)) pyrrolidine-based inhibitor, pyrrolidine-1, against the human group IV cytosolic phospholipase A(2) alpha-isoform (cPLA(2)alpha). Pyrrolidine-1 inhibits cPLA(2)alpha by 50% when present at approx. 0.002 mole fraction in the interface in a number of in vitro assays. It is much less potent on the cPLA(2)gamma isoform, calcium-independent group VI PLA(2) and groups IIA, X, and V secreted PLA(2)s. Pyrrolidine-1 blocked all of the arachidonic acid released in Ca(2+) ionophore-stimulated CHO cells stably transfected with cPLA(2)alpha, in zymosan- and okadaic acid-stimulated mouse peritoneal macrophages, and in ATP- and Ca(2+) ionophore-stimulated MDCK cells.

Intracellular calcium signals regulating cytosolic phospholipase A2 translocation to internal membranes.

Increased intracellular Ca(2+) concentrations ([Ca(2+)](i)) promote cytosolic phospholipase A(2) (cPLA(2)) translocation to intracellular membranes. The specific membranes to which cPLA(2) translocates and the [Ca(2+)](i) signals required were investigated. Plasmids of EGFP fused to full-length cPLA(2) (EGFP-FL) or to the cPLA(2) C2 domain (EGFP-C2) were used in Ca(2+)/EGFP imaging experiments of cells treated with [Ca(2+)](i)-mobilizing agonists. EGFP-FL and -C2 translocated to Golgi in response to sustained [Ca(2+)](i) greater than approximately 100-125 nm and to Golgi, ER, and perinuclear membranes (PNM) at [Ca(2+)](i) greater than approximately 210-280 nm. In response to short duration [Ca(2+)](i) transients, EGFP-C2 translocated to Golgi, ER, and PNM, but EGFP-FL translocation was restricted to Golgi. However, EGFP-FL translocated to Golgi, ER, and PNM in response to long duration transients. In response to declining [Ca(2+)](i), EGFP-C2 readily dissociated from Golgi, but EGFP-FL dissociation was delayed. Agonist-induced arachidonic acid release was proportional to the [Ca(2+)](i) and to the extent of cPLA(2) translocation. In summary, we find that the differential translocation of cPLA(2) to Golgi or to ER and PNM is a function of [Ca(2+)](i) amplitude and duration. These results suggest that the cPLA(2) C2 domain regulates differential, Ca(2+)-dependent membrane targeting and that the catalytic domain regulates both the rate of translocation and enzyme residence.

Cytosolic phospholipase A2 is required for macrophage arachidonic acid release by agonists that Do and Do not mobilize calcium. Novel role of mitogen-activated protein kinase pathways in cytosolic phospholipase A2 regulation.

The 85-kDa cytosolic phospholipase A(2) (cPLA(2)) mediates agonist-induced arachidonic acid release and eicosanoid production. Calcium and phosphorylation on Ser-505 by mitogen-activated protein kinases (MAPKs) regulate cPLA(2). Arachidonic acid release and eicosanoid production induced by stimuli that do (A23187, zymosan) or do not (phorbol myristate acetate (PMA), okadaic acid) mobilize calcium were quantitatively suppressed in cPLA(2)-deficient mouse peritoneal macrophages. The contribution of MAPKs to cPLA(2)-mediated arachidonic acid release was investigated. Both extracellular signal-regulated kinases (ERKs) and p38 contributed to cPLA(2) phosphorylation on Ser-505. However, although ERK inhibition did not affect A23187-induced arachidonic acid release, it suppressed zymosan-, PMA-, and okadaic acid-induced arachidonic acid release under conditions where phosphorylation of cPLA(2) on Ser-505 was unaffected. This indicates an additional regulatory mechanism for the ERK pathway. A role for transcriptional regulation is suggested by data showing that cycloheximide and actinomycin D inhibited arachidonic acid release induced by zymosan, PMA and, okadaic acid but not by A23187. Our results show that MAPK pathways contribute to arachidonic acid release in macrophages through alternative mechanisms in addition to their ability to phosphorylate cPLA(2) on Ser-505 and suggest a role for new protein synthesis.

Regulation of human PLD1 and PLD2 by calcium and protein kinase C.

Numerous studies show that PLD is activated in cells by calcium and by protein kinase C (PKC). We found that human PLD1 and PLD2 expressed in Sf9 cells can be activated by calcium-mobilizing agonists and by co-expression with PKCalpha. The calcium-mobilizing agonists A23187 and CryIC toxin triggered large increases in phosphatidylethanol (PtdEth) production in Sf9 cells over-expressing PLD1 and PLD2, but not in vector controls. PLD activation by these agonists was largely dependent on extracellular calcium. Membrane assays demonstrated significant PLD1 and PLD2 activity in the absence of divalent cations, which could be enhanced by low levels of calcium either in the presence or absence of magnesium. PLD1 but not PLD2 activity was slightly enhanced by magnesium. Treatment of Sf9 cells expressing PLD1 and PLD2 with PMA resulted in little PtdEth production. However, a significant and comparable formation of PtdEth occurred when PLD1 or PLD2 were co-expressed with PKCalpha, but not PKCdelta, and was further augmented by PMA. In contrast to PLD1, co-expressing PLD2 with PKCalpha or PKCdelta further enhanced A23187-induced PtdEth production. Immunoprecipitation experiments demonstrated that PLD1 and PLD2 associated with the PKC isoforms in Sf9 cells. Furthermore, in membrane reconstitution assays, both PLD1 and PLD2 could be stimulated by calmodulin and PKCalpha-enriched cytosol. The results indicate that PLD2 as well as PLD1 is subject to agonist-induced activation in intact cells and can be regulated by calcium and PKC.

Role of phosphorylation sites and the C2 domain in regulation of cytosolic phospholipase A2.

Cytosolic phospholipase A2 (cPLA2) mediates agonist-induced arachidonic acid release, the first step in eicosanoid production. cPLA2 is regulated by phosphorylation and by calcium, which binds to a C2 domain and induces its translocation to membrane. The functional roles of phosphorylation sites and the C2 domain of cPLA2 were investigated. In Sf9 insect cells expressing cPLA2, okadaic acid, and the calcium-mobilizing agonists A23187 and CryIC toxin induce arachidonic acid release and translocation of green fluorescent protein (GFP)-cPLA2 to the nuclear envelope. cPLA2 is phosphorylated on multiple sites in Sf9 cells; however, only S505 phosphorylation partially contributes to cPLA2 activation. Although okadaic acid does not increase calcium, mutating the calcium-binding residues D43 and D93 prevents arachidonic acid release and translocation of cPLA2, demonstrating the requirement for a functional C2 domain. However, the D93N mutant is fully functional with A23187, whereas the D43N mutant is nearly inactive. The C2 domain of cPLA2 linked to GFP translocates to the nuclear envelope with calcium-mobilizing agonists but not with okadaic acid. Consequently, the C2 domain is necessary and sufficient for translocation of cPLA2 to the nuclear envelope when calcium is increased; however, it is required but not sufficient with okadaic acid.

Regulation of arachidonic acid release and cytosolic phospholipase A2 activation.

The 85-kDa cytosolic PLA2 (cPLA2) mediates agonist-induced arachidonic acid release in many cell models, including mouse peritoneal macrophages. cPLA2 is regulated by an increase in intracellular calcium, which binds to an amino-terminal C2 domain and induces its translocation to the nuclear envelope and endoplasmic reticulum. Phosphorylation of cPLA2 on S505 by mitogen-activated protein kinases (MAPK) also contributes to activation. In macrophages, zymosan induces a transient increase in intracellular calcium and activation of MAPK, which together fully activate cPLA2 and synergistically promote arachidonic acid release. There are alternative pathways for regulating cPLA2 in macrophages because PMA and okadaic acid induce arachidonic acid release without increasing calcium. The baculovirus expression system is a useful model to study cPLA2 activation. Sf9 cells expressing cPLA2 release arachidonic acid to either A23187 or okadaic acid. cPLA2 is phosphorylated on multiple sites in Sf9 cells, and phosphorylation of S727 is preferentially induced by okadaic acid. However, the phosphorylation sites are non-essential and only S505 phosphorylation partially contributes to cPLA2 activation in this model. Although okadaic acid does not increase intracellular calcium in Sf9 cells, calcium binding by the C2 domain is necessary for arachidonic acid release. A23187 and okadaic acid activate cPLA2 by different mechanisms, yet both induce translocation to the nuclear envelope in Sf9 cells. The results demonstrate that alternative regulatory pathways can lead to cPLA2 activation and arachidonic acid release.

The role of calcium and phosphorylation of cytosolic phospholipase A2 in regulating arachidonic acid release in macrophages.

Arachidonic acid release is induced in macrophages with diverse agonists including calcium ionophores, phorbol myristate acetate (PMA), okadaic acid, and the phagocytic particle, zymosan, and correlates with activation of cytosolic phospholipase A2 (cPLA2). The role of calcium and phosphorylation of cPLA2 in regulating arachidonic acid release was investigated. Zymosan induced a rapid and transient increase in [Ca2+]i. This in itself is not sufficient to induce arachidonic acid release since ATP and platelet activating factor (PAF), agonists that induce transient calcium mobilization in macrophages, induced little arachidonic acid release. Unlike zymosan, which is a strong activator of mitogen-activated protein kinase (MAPK), ATP and PAF were weak MAPK activators and induced only a partial and transient increase in cPLA2 phosphorylation (gel shift). However, ATP or PAF together with colony stimulating factor-1 (CSF-1) synergistically stimulated arachidonic acid release. CSF-1 is a strong MAPK activator that induces a rapid and complete cPLA2 gel shift but not calcium mobilization or arachidonic acid release. Arachidonic acid release was more rapid in response to CSF-1 plus ATP or PAF than zymosan and correlated with the time course of the cPLA2 gel shift. Although low concentrations of ionomycin induced a lower magnitude of calcium mobilization than ATP, the response was more sustained resulting in arachidonic acid release. A23187 and ionomycin induced weak MAPK activation, and a partial and transient cPLA2 gel shift. The MAPK kinase inhibitor, PD 98059 suppressed A23187-induced MAPK activation and cPLA2 gel shift but had little effect on arachidonic acid release. These results indicate that in macrophages a transient increase in [Ca2+]i and sustained phosphorylation of cPLA2 can act together to promote arachidonic acid release but neither alone is sufficient. A sustained increase in calcium is sufficient for inducing arachidonic acid release. However, PMA and okadaic acid induce arachidonic acid release without increasing [Ca2+]i, although resting levels of calcium are required, suggesting alternative mechanisms of regulation.

The mitogen-activated protein kinase pathway can mediate growth inhibition and proliferation in smooth muscle cells. Dependence on the availability of downstream targets.

Activation of the classical mitogen-activated protein kinase (MAPK) pathway leads to proliferation of many cell types. Accordingly, an inhibitor of MAPK kinase, PD 098059, inhibits PDGF-induced proliferation of human arterial smooth muscle cells (SMCs) that do not secrete growth-inhibitory PGs such as PGE2. In striking contrast, in SMCs that express the inducible form of cyclooxygenase (COX-2), activation of MAPK serves as a negative regulator of proliferation. In these cells, PDGF-induced MAPK activation leads to cytosolic phospholipase A2 activation, PGE2 release, and subsequent activation of the cAMP-dependent protein kinase (PKA), which acts as a strong inhibitor of SMC proliferation. Inhibition of either MAPK kinase signaling or of COX-2 in these cells releases them from the influence of the growth-inhibitory PGs and results in the subsequent cell cycle traverse and proliferation. Thus, the MAPK pathway mediates either proliferation or growth inhibition in human arterial SMCs depending on the availability of specific downstream enzyme targets.

Heparin-binding EGF-like growth factor is a mitogen for rat alveolar type II cells.

Alveolar type II cells proliferate and differentiate into type I epithelial cells to restore the alveolar epithelium after lung injury. Since mitogens that bind the epidermal growth factor (EGF), EGF, receptor and transforming growth factor alpha (TGF alpha) have been shown to stimulate type II cell proliferation, studies were undertaken to determine whether the recently described protein, heparin-binding EGF-like growth factor (HB-EGF), was a mitogen for rat alveolar type II cells in primary culture. In addition, since HB-EGF is produced by macrophages, it was of interest to determine whether mitogenic activity for type II cells present in macrophage conditioned medium was due to HB-EGF. Rat and human recombinant HB-EGF stimulated thymidine incorporation into rat type II cells in a concentration-dependent manner up to 10-50 ng/ml then became inhibitory. The nuclear labeling index of type II cells increased from 2% to 16% with 10 ng/ml HB-EGF. However, HB-EGF induced only a small increase in cell number after 48 h and did not support low-density proliferation of alveolar type II cells. Conditioned medium from the human monocytic cell line, U937, stimulated type II cell DNA synthesis, and stimulatory activity could be partially purified by S-sepharose and heparin-sepharose chromatography. The growth-promoting activity from U937 cells that bound to heparin-sepharose was inhibited by a neutralizing antibody to human HB-EGF. Immunoblot analysis of active fractions also verified the presence of HB-EGF. However, the neutralizing antibody to rat HB-EGF did not inhibit mitogenic activity for type II cells found in rat bronchoalveolar lavage fluid. HB-EGF mRNA was found to be expressed in human alveolar macrophages to similar levels as differentiated U937 cells but was not detected in rat alveolar macrophages by Northern analysis of total mRNA. There was no difference in the level of HB-EGF mRNA expression in human alveolar macrophages from patients with interstitial lung disease compared with macrophages from normal subjects. The results demonstrate that HB-EGF is a mitogen for rat alveolar type II cells but appears to show species-specific differences with regard to its production by macrophages. Leslie, C. C., K. McCormick-Shannon, J. M. Shannon, B. Garrick, D. Damm, J. A. Abraham, and R. J. Mason. 1997. Heparin-binding EGF-like growth factor is a mitogen for rat alveolar type II cells. Am. J. Respir. Cell Mol. Biol. 16:379-387.

Lipid mediator networks in cell signaling: update and impact of cytokines.

Biomembranes serve barrier functions and serve as a store for precursors of rapidly generated, structurally diverse intracellular and extracellular lipid-derived mediators (LM). Cell activation is accompanied by remodeling of membrane components that appear to be essential in signal transduction. Phospholipases (PLA2, PLC, PLD, sphingomyelinase) are pivotal in the generation of these LM including eicosanoids, platelet activating factor (PAF), diacylglycerides, ceramide, and other newly discovered bioactive autacoids. Cytokines exert a dramatic multilevel impact both in regulating enzymes in individual LM pathways and in generating LM central to their action. Here, we provide an overview and update of recent progress in this area with emphasis on the effect of cytokines on LM networks. The generation of eicosanoids (prostaglandins, leukotrienes, and lipoxins), oxygenated lipids, and PAF remain the focus of rational drug design targets given their established roles in cell-cell communication and as mediators in inflammation and pathophysiologic events. Key enzymes in these pathways are cloned, sequenced, and their subcellular organization is investigated with surprising findings implicating involvement of the nuclear membrane at the functional level. Several LM receptors are identified and cloned, and results from transgenic animals have emerged for several key enzymes. Novel bioactive eicosanoids were discovered, including 15-epi-lipoxins, isoprostanes, and isoleukotrienes, that offered new concepts to consider in formation of LM and the actions of nonsteroidal anti-inflammatory drugs. Together, these findings indicate that LM play critical and essential roles in both signal transduction and cell-cell communication and will continue to be important pathways to be considered in novel therapeutic approaches.-Serhan, C. N., Haeggström, J. Z., Leslie, C. C. Lipid mediator networks in cell signaling: update and impact of cytokines.

Hepatocyte growth factor is a mitogen for alveolar type II cells in rat lavage fluid.

Proliferation of type II cells is required for maintenance of the alveolar epithelium and for restoration after lung injury. Although various known growth factors have been reported to stimulate type II cell proliferation in vitro, there is very little knowledge on which growth factors are present in the lung in vivo. We have previously reported that rat lavage fluid contains a mitogen(s) for type II cells, and this study was de signed to identify the growth factor(s) in this biological fluid for type II cells. The mitogenic activity was purified by sequential chromatography on blue Sepharose and heparin Sepharose. Hepatocyte growth factor (HGF) and acidic fibroblast growth factor by Western analysis. The amount of HGF recovered by lavage was approximately 6 ng/rat. By a use of neutralizing antibodies for different growth factors, HGF was found to be responsible for most of the stimulatory activity for rat type II cells in the partially purified lavage fluid. In addition to HGF, rat lavage fluid also contained potent mitogenic activity for fibroblasts. Finally, we have demonstrated that much of the mitogenic activity in salt extracts of human lung is HGF. We conclude that HGF is found in rat lavage fluid and is possibly an important mitogen for adult type II cells in vivo.

Identification of phosphorylation sites of human 85-kDa cytosolic phospholipase A2 expressed in insect cells and present in human monocytes.

The phosphorylation sites on the human, 85-kDa cytosolic phospholipase A2 (cPLA2) were identified using recombinant cPLA2 expressed in Spodoptera frugiperda (Sf9) cells. Analysis by high performance liquid chromatography of tryptic digests of 32P-labeled recombinant cPLA2 showed four major peaks of radiolabeled phosphopeptides. The phosphorylated residues were identified as Ser-437, Ser-454, Ser-505, and Ser-727 using mass spectrometry and automated Edman sequencing. Sf9 cells infected with recombinant virus expressing cPLA2 exhibited a time-dependent release of arachidonic acid in response to the calcium ionophore A23187 or the protein phosphatase inhibitor okadaic acid, which was not observed in Sf9 cells infected with wild-type virus. Stimulation of Sf9 cells with A23187 and okadaic acid also increased the level of phosphorylation of cPLA2. Okadaic acid, but not A23187, induced a gel shift of cPLA2 and increased the level of phosphorylation of Ser-727 by 4.5-fold, whereas the level of phosphorylation of the other sites increased by 60% or less in response to both agonists. To determine whether the same sites on cPLA2 were phosphorylated in mammalian cells, human monocytes were studied. Okadaic acid stimulation of monocytes induced a gel shift of cPLA2, increased the release of arachidonic acid, and increased the level of phosphorylation of cPLA2 on serine residues. Comparison of two-dimensional peptide maps of tryptic digests of 32P-labeled recombinant cPLA2 and human monocyte cPLA2 demonstrated that the same peptides on cPLA2 were phosphorylated in mammalian cells as in insect cells. These results show that the Sf9-baculovirus expression system is useful for investigation of the phosphorylation sites on cPLA2. The results also suggest that phosphorylation of the cPLA2 by protein kinases other than mitogen-activated protein kinase may be important for the regulation of arachidonic acid release.

Platelet-derived growth factor stimulates protein kinase A through a mitogen-activated protein kinase-dependent pathway in human arterial smooth muscle cells.

The abilities of platelet-derived growth factor (PDGF) and insulin-like growth factor (IGF-I) to regulate cAMP metabolism and mitogen-activated protein kinase (MAP kinase) activity were compared in human arterial smooth muscle cells (hSMC). PDGF-BB stimulated cAMP accumulation up to 150-fold in a concentration-dependent manner (EC50 approximately 0.7 nM). The peak of cAMP formation and cAMP-dependent protein kinase (PKA) activity occurred approximately 5 min after the addition of PDGF and rapidly declined thereafter. Incubating cells with PDGF and 3-isobutyl-1-methylxanthine (IBMX, a phosphodiesterase inhibitor) enhanced the accumulation of cAMP and PKA activity by an additional 2.5-3-fold, whereas IBMX alone was essentially without effect. The PDGF-stimulated increase in cAMP was prevented by addition of the cyclooxygenase inhibitor indomethacin, consistent with release of prostaglandins stimulating cAMP. PDGF, but not IGF-I, stimulated MAPK activity, cytosolic phospholipase A2 (cPLA2) phosphorylation, and cAMP synthesis which indicated a key role for MAP kinase in the activation of cPLA2. Further, PDGF stimulated the rapid release of arachidonic acid and synthesis of prostaglandin E2 (PGE2) which could be inhibited by a cPLA2 inhibitor (AACOCF3). Calcium mobilization was required for PDGF-induced arachidonic acid release and PGE2 synthesis but not for MAPK activation, whereas PKC was required for PGE2-mediated activation of PKA. In summary, these results demonstrated that PDGF increases cAMP formation and PKA activity through a MAP kinase-mediated activation of cPLA2, arachidonic acid release, and PGE2 synthesis in human arterial smooth muscle cells.

Regulation of lysophospholipase activity of the 85-kDa phospholipase A2 and activation in mouse peritoneal macrophages.

The regulation of the lysophospholipase activity of the 85-kDa cytosolic phospholipase A2 (PLA2) was studied in vitro and in stimulated macrophages. Bovine serum albumin was found to inhibit lysophospholipase activity of the recombinant 85-kDa PLA2 when assayed at a relatively low substrate concentration. Inhibition could be reversed if the substrate concentration was increased or if Ca2+ was present in the assay. Incubation of recombinant enzyme with macrophage membranes and lipid extracts from macrophage membranes resulted in the release of arachidonic acid, as well as, stearic acid, which is enriched at the sn-1 position of macrophage phospholipids. This suggests that with a bilayer substrate the PLA2 can sequentially deacylate the sn-2 then sn-1 acyl groups. This was verified by demonstrating that the phospholipids, phosphatidylcholine and phosphatidylinositol, were hydrolyzed to glycerophosphocholine and glycerophosphoinositol by incubation with recombinant 85-kDa PLA2. The 85-kDa enzyme was identified as the main lysophospholipase activity in mouse peritoneal macrophage cytosols. Addition of Ca2+ to the assay enhanced activity, but this effect decreased as the substrate concentration was increased. Incubation of macrophages with zymosan increased the lysophospholipase activity of the 85-kDa PLA2 in cytosols. Phosphorylation of recombinant PLA2 with mitogen-activated protein kinase resulted in an increase in lysophospholipase, as well as, PLA2 activity. In macrophages stimulated with zymosan release of stearic acid (18:0) and palmitic acid (16:0) was observed in addition to arachidonic acid (20:4). These results are consistent with a role of the 85-kDa PLA2 in regulating lysophospholipid levels in macrophages during zymosan stimulation.

Translocation of the 85-kDa phospholipase A2 from cytosol to the nuclear envelope in rat basophilic leukemia cells stimulated with calcium ionophore or IgE/antigen.

The rat mast cell line RBL-2H3.1 contains an 85-kDa cytosolic phospholipase A2 (cPLA2) that is very likely involved in liberating arachidonate from membrane phospholipid for the synthesis of eicosanoids following stimulation with either calcium ionophore or IgE/antigen. In this study, the intracellular location of cPLA2 was determined using immunofluorescence microscopy and immuno-gold electron microscopy. In nonstimulated cells, cPLA2 is distributed throughout the cytosol and is excluded from the nucleoplasm. Following cell activation with calcium ionophore, most of the cPLA2 translocates to the nuclear envelope, and the enzyme remains there during the entire period that ionophore is present. With IgE/antigen stimulation for 5 min, approximately 20-30% of the cPLA2 translocates to the nuclear envelope, and after 30 min of stimulation, most of the enzyme returns to the cytosol. Measurement of intracellular calcium using the dye Fura-2/AM shows that the level of calcium rises immediately after antigen is added, remains high for about 30 s, and then declines back to resting levels. Activation with calcium ionophore produces a 10-fold larger release of arachidonate than does stimulation with IgE/antigen. Thus, the results suggest that the extent of membrane binding of cPLA2 correlates with the release of arachidonate and that the site of arachidonate liberation is the nuclear envelope where many of the enzymes that oxygenate this fatty acid are located.

Regulation of cytosolic phospholipase A2 phosphorylation and eicosanoid production by colony-stimulating factor 1.

A colony-stimulating factor 1 (CSF-1)-dependent murine macrophage cell line (BAC1.2F5) and peritoneal macrophages were used to investigate the relationship between growth factor-dependent phosphorylation/activation of the 85-kDa cytosolic phospholipase A2 (cPLA2) and arachidonic acid metabolism. The addition of CSF-1 to quiescent BAC1.2F5 cells was followed by the rapid phosphorylation, electrophoretic gel retardation, and stable increase in the specific activity of cPLA2 that correlated with the activation of ERK kinases. cPLA2 phosphorylation depended on the presence of growth factor and persisted throughout the cell cycle. CSF-1 inhibited prostaglandin E2 production and did not enhance arachidonic acid release or increase the levels of lysophosphatidylcholine or glycerophosphocholine. Treatment of BAC1.2F5 cells with the calcium ionophore A23187 plus CSF-1 did not stimulate eicosanoid release. Instead, CSF-1 enhanced the rate of exogenous arachidonic acid incorporation into phosphatidylcholine and its subsequent transfer to phosphatidylethanolamine suggesting that higher rates of arachidonic acid acylation may contribute to the suppression of prostaglandin production. In peritoneal macrophages, ERK kinase activity was stimulated and cPLA2 was phosphorylated and activated in response to CSF-1. However, CSF-1 did not trigger eicosanoid release but did augment arachidonic acid mobilization and prostaglandin E2 production elicited by zymosan and A23187. Thus, cPLA2 phosphorylation/activation and calcium mobilization are not the only determinants for eicosanoid release, and additional components in differentiated tissue macrophages are also required.