Three secretory phospholipase A(2) genes that map to human chromosome 1P35-36 are not mutated in individuals with attenuated adenomatous polyposis coli.

Mutation of Pla2g2a, a secretory phospholipase A(2) gene, dramatically increases the number of intestinal polyps that develop in the multiple intestinal neoplasia (Min) mouse, a murine model for adenomatous polyposis coli in humans. We tested the hypothesis that mutation of the human homologue(s) of this gene might be responsible for the more severe phenotype (hundreds of polyps) seen in a subset of individuals with attenuated adenomatous polyposis coli (AAPC). DNA sequence analysis demonstrated that alterations of PLA2G2A, as well as related genes PLA2G2C and PLA2G5, were evenly distributed between three classes of AAPC subjects: those with small, intermediate, and large numbers of adenomatous colonic polyps. Among 67 additional unrelated AAPC subjects, a stop mutation in PLA2G2C did not correlate with an increased burden of adenomatous polyps. Therefore, mutation of the human homologue(s) of murine Pla2g2a does not appear to be responsible for phenotypic variation among subjects with AAPC.

Calcium-independent phospholipase A(2): structure and function.

The classical Ca(2+)-independent phospholipase A(2) enzyme, now known as Group VIA PLA(2), was initially purified and characterized from the P388D(1) macrophage-like cell line. The corresponding cDNA was subsequently cloned from a variety of sources, and it is now known that multiple splice variants of the enzyme are expressed, some of which may act as negative regulators of the active enzyme. Group VIA PLA(2) has a consensus lipase motif (GTSTG) containing the catalytic serine, is 85-88 kDa, and exists in an aggregated form. The enzyme contains multiple ankyrin repeats, which may play a role in oligomerization. The Group VIA enzyme exhibits lysophospholipase activity as well as phospholipase A(2) activity, and it is capable of hydrolyzing a wide variety of phospholipid substrates. A major function of Group VIA PLA(2) is to mediate phospholipid remodeling, but the enzyme may play other roles as well. Other Ca(2+)-independent PLA(2) enzymes have more recently been identified, and it may be possible to discriminate between the various Ca(2+)-independent PLA(2) enzymes based on sequence or inhibitor-sensitivity. However, the physiological functions of the newly identified enzymes have yet to be elucidated.

VEGF stimulation of endothelial cell PAF synthesis is mediated by group V 14 kDa secretory phospholipase A2.

1. Vascular endothelial growth factor (VEGF) is a potent inducer of inflammation, and we have shown that this latter effect is mediated through endothelial cell (EC) PAF synthesis. Since the phospholipid remodelling pathway enzymes (CoA-independent transacylase, CoA-IT; phospholipase A2, PLA2; and lyso-PAF acetyltransferase, lyso-PAF-AT) may participate in PAF synthesis, we assessed their contribution to VEGF-induced PAF synthesis in bovine aortic EC (BAEC) and human umbilical vein EC (HUVEC). 2. VEGF enhanced BAEC and HUVEC PAF synthesis by up to 28 and 4 fold above basal levels respectively. 3. A pretreatment with a CoA-IT and lyso-PAF-AT inhibitor (Sanguinarin; 500 nM) blocked VEGF-induced PAF synthesis by 95%, a specific CoA-IT inhibitor (SKF45905; 10 - 50 microM) was without effect, confirming the crucial role of the PLA2 and lyso-PAF-AT. 4. Treatment with secreted PLA2 (sPLA2) inhibitors which have been shown to inhibit both groups IIA and V sPLA2 (SB203347; 10 microM and LY311727; 100 microM) blocked EC PAF synthesis by up to 90%, whereas selective inhibition of group IIA sPLA2 (LY311727; 1 microM) had no significant effect. 5. RT - PCR and Western blot analyses demonstrated the presence of group V sPLA2 whereas group IIA sPLA2 was undetected in EC. 6. Treatment with cytosolic and calcium-independent PLA2 inhibitors (Arachidonyl trifluoromethyl ketone, Bromoenol lactone, Methyl arachydonyl fluorophosphate, up to 50 microM) did not prevent but rather potentiated the VEGF effect on EC PAF synthesis. 7. These results provide evidence that with VEGF activation of EC cells, the group V sPLA2 provides substrate for EC PAF formation.

Novel group V phospholipase A2 involved in arachidonic acid mobilization in murine P388D1 macrophages.

Four related genes encode four different secretory phospholipase A2 (sPLA2) enzymes in mammals, namely the well described Group I and IIA enzymes and the more recently described Groups IIC and V. A large body of research has putatively demonstrated that the Group IIA sPLA2 is involved in diverse pathologic processes, such as rheumatoid arthritis, septic shock, intestinal neoplasia, and epidermal hyperplasia, as well as in cellular signaling by regulating the formation of arachidonate-derived lipid messengers. However, we demonstrate herein the involvement of another sPLA2, i.e. the Group V sPLA2, in arachidonic acid release and prostaglandin production in the mouse macrophage-like cell line P388D1. Abundant message for Group V sPLA2 was detected in both resting and activated cells. In contrast, Group IIA sPLA2 message was undetectable as analyzed by Northern blot and reverse transcriptase-polymerase chain reaction. Moreover, blockage of Group V sPLA2 gene expression by antisense RNA oligonucleotides resulted in inhibition of prostaglandin E2 production as well as reduction of the amount of sPLA2 protein at the cellular surface. Collectively, these results uncover Group V sPLA2 as a novel effector involved in arachidonic acid-mediated signal transduction.

Analysis of the secretory phospholipase A2 that mediates prostaglandin production in mast cells.

Prostaglandin D2 (PGD2) synthesis in activated mast cells occurs in two phases, an early phase that is dependent on prostaglandin synthase 1 and a delayed phase that is dependent on activation-induced prostaglandin synthase 2 gene expression. Early phase PGD2 synthesis in activated mast cells also requires the activity of a secretory phospholipase A2 (PLA2). It has been thought that the secretory PLA2 expressed in mast cells is group IIa PLA2, encoded by the Pla2 g2a gene. However, activated bone marrow-derived mast cells prepared from Pla2 g2a+/+ mice and mast cells prepared from mice with a mutation in the Pla2 g2a gene both demonstrate early phase PGD2 synthesis. Moreover, mast cells from both murine strains secrete PLA2 activity following activation. Northern and reverse transcriptase/polymerase chain reaction analyses demonstrate that mast cells from Pla2 g2a+/+ and Pla2 g2a-/- mice do not express group IIa PLA2 message. Instead, Northern and reverse transcriptase/polymerase chain reaction analyses demonstrate that both Pla2 g2a+/+ and Pla2 g2a-/- mast cells express mRNA for group V PLA2, encoded by the Pla2gV gene. An antisense oligonucleotide directed against group V PLA2 is also able to inhibit both the early phase of PGD2 production and the secretion of PLA2 activity by activated mast cells. Our data suggest that (i) group IIa PLA2 does not play a significant role in murine mast cell prostaglandin synthesis, (ii) group V PLA2 mediates early mast cell PGD2 production and transcellular PGE2 production in murine mast cells, and (iii) much of the data, based on studies with chemical inhibitors and antibodies, suggesting that group IIa PLA2 is responsible for arachidonic acid mobilization needs to be reevaluated.

The functions of five distinct mammalian phospholipase A2S in regulating arachidonic acid release. Type IIa and type V secretory phospholipase A2S are functionally redundant and act in concert with cytosolic phospholipase A2.

We examined the relative contributions of five distinct mammalian phospholipase A2 (PLA2) enzymes (cytosolic PLA2 (cPLA2; type IV), secretory PLA2s (sPLA2s; types IIA, V, and IIC), and Ca2+-independent PLA2 (iPLA2; type VI)) to arachidonic acid (AA) metabolism by overexpressing them in human embryonic kidney 293 fibroblasts and Chinese hamster ovary cells. Analyses using these transfectants revealed that cPLA2 was a prerequisite for both the calcium ionophore-stimulated immediate and the interleukin (IL)-1- and serum-induced delayed phases of AA release. Type IIA sPLA2 (sPLA2-IIA) mediated delayed AA release and, when expressed in larger amounts, also participated in immediate AA release. sPLA2-V, but not sPLA2-IIC, behaved in a manner similar to sPLA2-IIA. Both sPLA2s-IIA and -V, but not sPLA2-IIC, were heparin-binding PLA2s that exhibited significant affinity for cell-surface proteoglycans, and site-directed mutations in residues responsible for their membrane association or catalytic activity markedly reduced their ability to release AA from activated cells. Pharmacological studies using selective inhibitors as well as co-expression experiments supported the proposal that cPLA2 is crucial for these sPLA2s to act properly. The AA-releasing effects of these sPLA2s were independent of the expression of the M-type sPLA2 receptor. Both cPLA2, sPLA2s-IIA, and -V were able to supply AA to downstream cyclooxygenase-2 for IL-1-induced prostaglandin E2 biosynthesis. iPLA2 increased the spontaneous release of fatty acids, and this was further augmented by serum but not by IL-1. Finally, iPLA2-derived AA was not metabolized to prostaglandin E2. These observations provide evidence for the functional cross-talk or segregation of distinct PLA2s in mammalian cells in regulating AA metabolism and phospholipid turnover.

Low-molecular-weight, calcium-dependent phospholipase A2 genes are linked and map to homologous chromosome regions in mouse and human.

The Group IIA phospholipase gene (PLA2G2A) protein coding regions exhibit significant homology with recently described Group IIC (PLA2G2C) and Group V (PLA2GV) genes. All three genes are present in many mammalian species and are expressed in a tissue-specific pattern. Here, we demonstrate in human that they are tightly linked and map to chromosome 1p34-p36.1. We also show that the homologous mouse loci are tightly linked (no observed recombination) on the distal part of chromosome 4, a region exhibiting synteny with human 1p34-p36. Unlike its rodent counterpart, human PLA2G2C appears to be a nonfunctional pseudogene.