Alfred N. Fonteh

Secretory Phospholipase A2 Receptor-Mediated Activation of Cytosolic Phospholipase A2 in Murine Bone Marrow-Derived Mast Cells

The current study examined the signal transduction steps involved in the selective release of arachidonic acid (AA) induced by the addition of secretory phospholipase A2 (sPLA2) isotypes to bone marrow-derived mast cells (BMMC). Overexpression of sPLA2 receptors caused a marked increase in AA and PGD2 release after stimulation of BMMC, implicating sPLA2 receptors in this process. The hypothesis that the release of AA by sPLA2 involved activation of cytosolic PLA2 (cPLA2) was next tested. Addition of group IB PLA2 to BMMC caused a transient increase in cPLA2 activity and translocation of this activity to membrane fractions. Western analyses revealed that these changes in cPLA2 were accompanied by a time-dependent gel shift of cPLA2 induced by phosphorylation of cPLA2 at various sites. A noncatalytic ligand of the sPLA2 receptor, p-amino-phenyl-α-d-mannopyranoside BSA, also induced an increase in cPLA2 activity in BMMC. sPLA2 receptor ligands induced the phosphorylation of p44/p42 mitogen-activated protein kinase. Additionally, an inhibitor of p44/p42 mitogen-activated protein kinase (PD98059) significantly inhibited sPLA2-induced cPLA2 activation and AA release. sPLA2 receptor ligands also increased Ras activation while an inhibitor of tyrosine phosphorylation (herbimycin) inhibited the increase in cPLA2 activation and AA release. Addition of partially purified sPLA2 from BMMC enhanced cPLA2 activity and AA release. Similarly, overexpression of mouse groups IIA or V PLA2 in BMMC induced an increase in AA release. These data suggest that sPLA2 mediate the selective release of AA by binding to cell surface receptors and then inducing signal transduction events that lead to cPLA2 activation.

Magnitude of Peroxisome Proliferator-Activated Receptor-γ Activation is Associated With Important and Seemingly Opposite Biological Responses in Breast Cancer Cells

Background The nuclear receptor peroxisome proliferator-activated receptor-γ (PPARγ) has become a potential target for the prevention and treatment of breast cancer. However, recent in vitro and in vivo studies have raised the question of whether activation of PPARγ leads to the promotion or reduction of tumor formation. Studies using several cancer cell lines, animal models, and a variety of PPARγ agonists have shown discordant results, including changes in cellular proliferation, differentiation, and apoptosis of cancer cells and tumors. Methods We studied the effects of low-, moderate-, and high-dose treatment of the PPARγ ligands 15-deoxy-Δ12,14 prostaglandin J2 (15dPGJ2) and troglitazone (TGZ) on parameters of cell growth, differentiation, and apoptosis in the epithelial breast cancer cell line MDA-MB-231. Results The biologic effects of these compounds depend largely on ligand concentration and the degree of PPARγ activation. For example, low concentrations of 15dPGJ2 (<2.5 μM) and TGZ (<5 μM) increased cellular proliferation, but concentrations of 15dPGJ2 >10 μM and of TGZ at 100 μM blocked cell growth. TGZ (100 μM) slowed cell cycle progression, and 15dPGJ2 (10 μM) caused an S-phase arrest in the cell cycle and induced morphological characteristics consistent with apoptosis. Expression of CD36, a marker of differentiation in these cells, was induced by 2.5 μM 15dPGJ2 or 5 to 100 μM TGZ. However, higher concentrations of 15dPGJ2 did not alter CD36 expression. Transcriptional activation studies demonstrated that 15dPGJ2 is a more potent PPARγ ligand than TGZ. Regardless of the ligand used, though, low transcriptional activation correlated with an increased cellular proliferation, whereas higher levels of activation correlated with cell cycle arrest and apoptosis. Conclusions PPARγ activation induces several important and seemingly opposite changes in neoplastic cells, depending on the magnitude of PPARγ activation. These data may explain, at least in part, some of the discordant results previously reported.

Dietary n-3 fatty acid effects on neutrophil lipid composition and mediator production. Influence of duration and dosage.

Healthy volunteers supplemented their usual Western diets with Promega fish oil supplement (eicosapentaenoic acid [EPA], 0.28 g; docosahexaenoic acid [DCHA], 0.12 g; other n-3 fatty acids 0.10 g per capsule) using three protocols. Initial experiments (protocol 1 and 2) investigated the kinetics of incorporation of n-3 fatty acids into serum and neutrophil lipids after 10 capsules/d of Promega. EPA was rapidly detected in both serum and neutrophil lipids; the arachidonic acid (AA) to EPA ratio in neutrophil phospholipids showed a maximal reduction of 49:1 to 8:1 within 1 wk of beginning supplementation. EPA was preferentially incorporated into phosphatidyl-ethanolamine and phosphatidylcholine but not phosphatidylinositol. Long-term supplementation for up to 7 wk did not influence the AA/EPA ratio or the distribution of EPA among neutrophil phospholipids in a manner that was not observed after the first week. Neutrophils produced similar quantities of platelet-activating factor and slightly lower quantities of leukotriene B4 during long-term supplementation when compared with presupplementation values. Experiments examining the influence of Promega dosage indicated that the AA/EPA ratio in neutrophil lipids decreased in a dose-dependent manner. Only when the dose was increased to 15 capsules/d was there a reduction in the AA/DCHA ratio in neutrophil lipids. The quantity of AA in neutrophil lipids remained relatively constant at all supplement doses. Taken together, the current study demonstrates the capacity of n-3 fatty acids provided with a Western diet to be rapidly incorporated into neutrophil lipids. However, dietary n-3 fatty acids appear not to significantly reduce arachidonate content within neutrophil phospholipids. Constant arachidonate levels may account for the lack of large reductions in the biosynthesis of lipid mediators by neutrophils after fish-oil supplementation.

Mechanisms that account for the selective release of arachidonic acid from intact cells by secretory phospholipase A2

The current study examined mechanisms that account for the selective release of arachidonic acid (AA) from cells by secretory phospholipase A2 (sPLA2). Initial studies demonstrated that low concentrations of group I and group III PLA2 isotypes and an sPLA2-enriched extract from bone marrow-derived mast cells (BMMC) selectively released AA from mast cells. Much higher concentrations of group II PLA2 were required to release comparable quantities of AA. Group I PLA2 also selectively released AA from another mast cell line (CFTL-15) and a monocytic cell line (THP-1). In contrast, high concentrations of group I PLA2 were required to release fatty acids from a promyelocytic cell line (HL-60) and this release was not selective for AA. Binding studies revealed that cell types (BMMC, CFTL-15 and THP-1) which selectively released AA also had the capacity to specifically bind group I PLA2. However, group II PLA2, which did not selectively release AA from cells, also did not specifically bind to these same cell types. Additional studies revealed that sPLA2 binding to the mast cell receptor was attenuated after stimulation with antigen or ionophore A23187. Reverse transcriptase-polymerase chain reaction analyses indicated the presence of mRNA for the sPLA2 receptor in BMMC, CFTL-15 and THP-1 and the absence of this mRNA in HL-60. Final studies demonstrated that p-aminophenyl-alpha-D-mannopyranoside BSA, a known ligand of the sPLA2 receptor, also selectively released AA from mast cells but not from HL-60 cells. These experiments indicated that receptor occupancy alone (without PLA2 activity) is sufficient to induce the release of AA from mast cells. Together, these data reveal that specific isotypes of sPLA2 have the capacity to selectively release AA from certain cells by their capacity to bind to sPLA2 receptors on the cell surface.

Enhancement of Mast Cell Survival: A Novel Function of Some Secretory Phospholipase A2 Isotypes

This study tested the hypothesis that certain secretory phospholipase A2 (sPLA2) isotypes act in a cytokine-like fashion through cell surface receptors to influence mast cell survival. Initial experiments revealed that sPLA2 activity and sPLA2 receptor expression are increased, and mast cells lost their capacity to maintain membrane asymmetry upon cytokine depletion. Groups IB and III, but not group IIA PLA2, prevented the loss of membrane asymmetry. Similarly, group IB prevented nucleosomal DNA fragmentation in mast cells. Providing putative products of sPLA2 hydrolysis to cytokine-depleted mast cells did not influence survival. Furthermore, catalytic inactivation of sPLA2 did not alter its capacity to prevent apoptosis. Inhibition of protein synthesis using cycloheximide or actinomycin reversed the antiapoptotic effect of sPLA2. Additionally, both wild-type and catalytically inactive group IB PLA2 induced IL-3 synthesis in mast cells. However, adding IL-3-neutralizing Ab did not change Annexin VFITC binding and only partially inhibited thymidine incorporation in sPLA2-supplemented mast cells. In contrast, IL-3-neutralizing Ab inhibited both Annexin VFITC binding and thymidine incorporation in mast cells maintained with IL-3. sPLA2 enhanced phosphoinositide 3′-kinase activity, and a specific inhibitor of phosphoinositide 3′-kinase reversed the antiapoptotic effects of sPLA2. Likewise, sPLA2 increased the degradation of I-κBα, and specific inhibitors of nuclear factor κ activation (NF-κB) reversed the antiapoptotic effects of sPLA2. Together, these experiments reveal that certain isotypes of sPLA2 enhance the survival of mast cells in a cytokine-like fashion by activating antiapoptotic signaling pathways independent of IL-3 and probably via sPLA2 receptors rather than sPLA2 catalytic products.

Regulation of arachidonic acid, eicosanoid, and phospholipase A2 levels in murine mast cells by recombinant stem cell factor.

The current study evaluates the capacity of recombinant rat stem cell factor (rrSCF) to regulate enzymes that control AA release and eicosanoid generation in mouse bone marrow-derived mast cells (BMMCs). Initial studies indicated that rrSCF provided for 24 h inhibited the release of AA into supernatant fluids of antigen- and ionophore A23187-stimulated BMMCs. Agonist-induced increases in cellular levels of AA were also inhibited, albeit to a lesser degree by rrSCF. To determine the inhibitory mechanism, several steps (e.g., mobilization of cytosolic calcium, release of BMMC granules, and regulation of phospholipase A2 [PLA2] activity) that could influence AA release were measured in rrSCF-treated cells. rrSCF did not alter the capacity of BMMCs to mobilize cytosolic calcium or release histamine in response to antigen and ionophore. BMMCs released large amounts of PLA2 with characteristics of the group II family in response to antigen and ionophore A23187. rrSCF treatment of BMMCs reduced the secretion of this PLA2 activity by BMMCs. Partial purification of acid-extractable PLA2 from rrSCF-treated and untreated BMMCs suggested that rrSCF decreased the quantity of acid-stable PLA2 within the cells. In contrast to group II PLA2, the quantity of cPLA2 (as determined by Western blot analysis) increased in response to rrSCF. To assess the ramifications of rrSCF-induced reductions in AA and group II PLA2, eicosanoid formation was measured in antigen- and ionophore-stimulated BMMCs, rrSCF-inhibited (100 ng/ml, 24 h) prostaglandin D2 (PGD2), thromboxane B2, and leukotriene B4 by 48.4 +/- 7.7%, 61.1 +/- 10.0% AND 38.1 +/- 3.6%, respectively, in antigen-stimulated cells. Similar patterns of inhibition were observed in ionophore-stimulated BMMCs. The addition of a group I PLA2 or exogenous AA to BMMCs reversed the inhibition of eicosanoid generation induced by rrSCF. Together, these data indicate that rrSCF differentially regulates group II and cytosolic PLA2 activities in BMMCs. The resultant reductions in eicosanoid generation suggest that group II PLA2 provides a portion of AA that is used for eicosanoid biosynthesis by BMMCs.

Characterization of a secretory phospholipase A2 in human bronchoalveolar lavage fluid.

Phospholipase A2 (PLA2) is a pivotal enzyme involved in the synthesis of the potent lipid inflammatory mediators platelet activating factor (PAF) and the eicosanoids. This study characterizes a PLA2 recovered in the bronchoalveolar lavage fluid (BALF) of healthy adult human subjects. Human BALF PLA2 exhibited characteristics of secretory PLA2s that include an activity that is acid stable, sensitive to reducing agents, and optimally requires millimolar calcium. BALF PLA2 showed marked selectivity for phosphatidylcholine containing arachidonic acid (AA) over linoleic or palmitic acids. Size exclusion chromatography showed the BALF PLA2 protein to be approximately 14 kDa in mass, consistent with it being a secretory form of PLA2. The biological significance of BALF PLA2 was tested by applying BALF concentrates to cultures of the human bronchial epithelial cell line BEAS 2B. Cultures of BEAS 2B cells treated with BALF concentrates released increased amounts of AA and produced higher levels of PAF. These data show that the lining fluid of the human respiratory tract normally contains a secretory PLA2, which may be involved in the formation of lipid inflammatory mediators in normal and pathophysiologic states in the lung.

Arachidonic acid metabolism during antigen and ionophore activation of the mouse bone marrow derived mast cell

This study has examined the metabolism of arachidonic acid in the mouse bone marrow-derived mast cell (BMMC) during immunologic and nonimmunologic activation. The predominant pools of endogenous arachidonate in the mast cells were found in ethanolamine (46%), choline (39%) and inositol (14%) containing glycerolipids. Initial studies established conditions where equilibrium labelling of these major phospholipids in the BMMC could be reached. Upon challenge, arachidonate was lost from all major phospholipid classes (phosphatidylethanolamine greater than phosphatidylcholine greater than phosphatidylinositol). There was a small but significant increase in the amount of label associated with phosphatidic acid during cell activation. Arachidonate was distributed among 1-acyl, 1-alkyl and 1-alk-1-enyl-linked subclasses of PC and PE. The rank order of loss of labelled arachidonate from the major PE and PC subclasses during antigen and ionophore activation was 1-alk-enyl-2-arachidonoyl-GPE greater than 1-acyl-2-arachidonoyl-GPC greater than 1-acyl-2-arachidonoyl-GPE greater than 1-alkyl-2-arachidonoyl-GPC. Labelled products released into the supernatant fluids and free arachidonic acid within the cell accounted for the bulk of arachidonate lost from phospholipids. Labelled products in the supernatant fluids were composed of LTB4, LTC4, PGD2 and free arachidonic acid. BMMC phospholipids were also labelled for 24 hr with [3H]choline, [3H]myoinositol or [14H]ethanolamine and labelled 2-lyso phospholipids were measured after cell activation. Radioactivity in lysophospholipids from PC, PE and PI increased significantly between 30 s and 2 min after antigen activation and then declined. Taken together, these studies suggest that arachidonate is mobilized predominantly from PE and in particular 1-alk-1-enyl-2-arachidonoyl-GPE by the direct removal of arachidonate from the sn-2 position of the molecule. Most of this arachidonate is then released from cells as eicosanoids or free fatty acid.

Alterations in arachidonic acid metabolism in mouse mast cells induced to undergo maturation in vitro in response to stem cell factor

We studied arachidonic acid (AA) metabolism during the maturation of bone marrow-derived cultured mast cells (BMCMCs) into mast cells with phenotypic characteristics, which were more similar to those of connective tissue-type mast cells. BMCMCs were maintained in medium containing 100 ng/ml recombinant rat stem cell factor (SCF) for 1 to 6 weeks. After 3 to 4 weeks in SCF, BMCMCs acquired many phenotypic characteristics of maturation, including enlarged size, numerous electron-dense cytoplasmic granules, and a 50-fold elevation in histamine content. Maintenance in SCF for 6 weeks did not significantly alter the amounts or species of eicosanoids that were produced by BMCMCs stimulated with calcium ionophore A23187. However, SCF-treated mast cells released 2.6 +/- 0.13 times more free AA and accumulated 6.4 +/- 1.0 times higher levels of intracellular free AA than did immature BMCMCs not exposed to SCF. There was no increase in the mobilization of other fatty acids (e.g., linoleic or oleic acid), indicating specificity for AA. Moreover, there were no differences between the 5-lipoxygenase activities of SCF-treated or untreated cells, as assayed in cell homogenates prepared by nitrogen cavitation. Although the total AA content in SCF-treated cells was significantly elevated, the distribution of AA in phospholipid and neutral lipid classes was not altered by SCF treatment. Total phospholipase (PL)A2 activity increased 85% +/- 11.5% in SCF-treated cells. In homogenates of immature BMCMCs, 51.0% +/- 13.7% of the PLA2 activity was inhibited by 0.5 mmol/L dithiothreitol, whereas the same concentration of dithiothreitol caused only a 2.2% +/- 10.7% reduction in the PLA2 activity in homogenates of SCF-treated BMCMCs (p < or = 0.05, n = 4). These findings suggest that SCF treatment induces a dithiothreitol-resistant PLA2 and that this PLA2 may contribute to the mobilization of AA that is not further metabolized to eicosanoids.

Influence of arachidonic acid metabolism on cell proliferation and apoptosis

Research over the past three decades has revealed that arachidonic acid (AA) and oxygen-containing derivatives of AA, termed eicosanoids, play pivotal roles in controlling key cellular events that lead to acute and chronic inflammation (for review, see [1]). While it has been suggested for more than 50 years that diets high in certain fatty acids stimulate tumor development in animals, only within the last five years has there been strong mechanistic evidence that links AA metabolism to cell proliferation and apoptosis. Interest in this link began to intensify in the early 1990s as a result of several key observations; (1) Epidemiological studies in humans demonstrated that the use of nonsteroidal anti-inflammatory drugs (NSAIDs) is associated with a reduction in colon cancer deaths [2–5]. (2) Animal studies revealed that NSAIDs attenuate in vivo growth in colon, mammary, esophageal, lung and oral cancers [6–14]. (3) There is increased production of eicosanoids (in particular, prostaglandins) as well as a marked upregulation of certain isoforms of cyclooxygenase in transformed cells and tumors [6, 15–21]. Collectively, these observations emphasized the importance of understanding the mechanisms by which AA metabolism influences cellular events such as mitogenesis and apoptosis. This chapter will review in vitro and in vivo studies that have examined the relationship between AA metabolism and cell proliferation with a special emphasis on apoptosis. While the bulk of the data collected to date on this topic has focused on AA metabolism and cell proliferation in cellular models of cancer, similar relationships are now being observed in cell proliferation and survival during inflammation. It is important to point out that most of the major molecular events that link AA metabolism and cell proliferation currently are poorly understood and many events remain to be elucidated. Moreover, there are several circumstances where AA or its metabolites appear to have one effect on a particular cell type and another (often the opposite effect) in other cell types. Further progress in this area will depend, in large part, on our capacity to resolve these ambiguous links and controversial findings.