Reproductive Biology and Endocrinology Open Access Distinct Phospholipase A2 Enzymes Regulate Prostaglandin E2 and F2alpha Production by Bovine Endometrial Epithelial Cells

Background: The rate-limiting step in prostaglandin (PG) biosynthesis is catalyzed by phospholipase A2 (PLA2) enzymes which hydrolyze arachidonic acid from membrane phospholipids. Despite their importance in uterine PG production, little is known concerning the specific PLA2 enzymes that regulate arachidonic acid liberation in the uterine endometrium. The objectives of this study were to evaluate the expression and activities of calcium-independent Group VI and Group IVC PLA2 (PLA2G6 and PLA2G4C) and calcium-dependent Group IVA PLA2 (PLA2G4A) enzymes in the regulation of bovine uterine endometrial epithelial cell PG production.


Conclusion:
Results from these studies indicate that oxytocin stimulation of uterine PGF2alpha production is mediated, at least in part, by up-regulation of PLA2G6 expression and activity. In addition to its known inhibitory effect on oxytocin receptor expression, interferon-tau represses oxytocin-stimulated PLA2G6 expression and activity and this contributes to diminished PGF2alpha production. Furthermore, endometrial cell PGE2 biosynthesis was associated with PLA2G4C expression and activity and interferon-tau was stimulatory to this process.

Background
In domestic ruminants (sheep, cattle, goats) estrous cyclicity is regulated by uterine PGF 2α -induced demise of the corpus luteum [1,2]. PGF 2α is released from endometrial luminal and superficial glandular epithelium in an episodic fashion toward the end of the estrous cycle. Oxytocin (OT), of neurohypophyseal and luteal origin, is believed to bind endometrial OT receptors and initiate pulsatile PGF 2α secretion, which in turn, stimulates release of luteal OT and creates a positive feedback loop that results in several series of pulses of short duration which are effective in causing luteolysis [3,4]. During early pregnancy, the conceptus protein interferon tau (IFNT) binds to endometrial receptors and attenuates episodic PGF 2α secretion, thereby rescuing the CL from regression and maintaining progesterone production [5][6][7].
Release of arachidonic acid (AA) from membrane glycerophospholipids is catalyzed by phospholipase A 2 enzymes and is considered the rate-limiting step in PG biosynthesis [8]. Released AA is then metabolized to PGG 2 by a cyclooxygenase reaction and then to PGH 2 by a peroxidase reaction, both mediated by cyclooxygenase (COX) -1 and/or -2. Terminal PG synthases, which exhibit tissuespecific distribution, then convert PGH 2 to bioactive PGs including PGF 2α , PGE 2 , PGD 2 and PGI 2 .
Although PLA2 activation catalyzes the rate-limiting step in PG biosynthesis, most investigations of the mechanisms and regulation of uterine PG production have focused on the activation and expression of down-stream enzymes, such as the cyclooxygenases and PG synthases. The few studies [9][10][11][12] that have examined the role of PLA2 in uterine PG production in domestic ruminants have focused on a single enzyme, cPLA2α (Group IVA PLA2 or PLA2G4A). Surprisingly, none of these studies identified consistent changes in expression of protein or mRNA for PLA2G4A in association with alterations in PG production. In contrast, non-specific PLA2 inhibitors significantly diminished both basal and agonist-induced PG production [10][11][12].
Mammalian cells contain structurally diverse PLA2 enzymes that differ in their location and regulation [reviewed in [13] and [14]]. At least 14 groups, and numerous subgroups, of PLA2s have been classified. These groups include four main families of PLA2s, the low molecular weight secretory PLA2s, the cytosolic PLA2G4s, the calcium-independent PLA2G6s and the platelet activating factor (PAF) acid hydrolases (PLA2G7 and PLA2G8). The intracellular PLA2G4 and PLA2G6 enzymes are specifically important in the regulation of PG biosynthesis because their sites of action are the perinuclear membranes where down-stream AA metabolizing enzymes (cyclooxygenases and PG synthases) reside.
The first cytosolic PLA2 discovered was PLA2G4A and it has received, by far, the most attention. It is a 749 amino acid, 85 kDa protein that migrates at 100-112 kDa in polyacrylamide gels. It is present in the cytosol of resting cells and upon activation by a variety of agonists, undergoes Ca ++ -directed translocation to perinuclear membranes. The N-terminal Ca ++ -dependent lipid binding (CaLB) or C2 domain is essential for membrane association and responsible for translocation in response to stimuli that increase intracellular calcium [14+]. Gene disruption studies have indicated an important role for PLA2G4A in normal fertility, eicosanoid production from inflammatory cells, brain injury and allergic response in mice [15][16][17]. Mice with a null mutation for the gene have fewer implantation sites, smaller litters and fail to undergo labor at term.
Several additional Group IV PLA2 enzymes have been cloned recently, including IVB, IVC, IVD, IVE and IVF [18][19][20]. Of these enzymes, IVC (PLA2γ) is of interest because it is constitutively associated with membranes, the major site of prostaglandin biosynthesis, lacks the C2 domain and does not require Ca ++ for activation. Although first associated with membrane remodeling, recent studies demonstrate that PLA2G4C functions as a signaling PLA2 linked to PGE 2 production [21].
In the literature, the term calcium-independent PLA2, has generally referred to the Group 6 family of PLA2 enzymes [13], despite the fact that Group 4C is Ca ++ -independent as well. Two distinct subclasses of Group 6 have been identified and characterized, 6A (also referred to as iPLA2 and iPLA2B) and 6B (iPLA2γ). More recently several novel iPLA2s have been identified, including iPLA2δ, iPLA2ε, iPLA2ζ and iPLA2η [22]. These novel iPLA2 family members display primarily lysophospholipase, triacylglycerol lipase and/or transacylase activities rather than PLA2 activity. Group 6A has been cloned and characterized in several species and cell types [23][24][25]. It has a mass of 85-88 kDa, contains 7-8 terminal ankyrin repeats, and a consensus lipase motif. Several splice variants of the enzyme are expressed yielding multiple molecular weight isoforms [25]. Recently, expression of a 50 kDa Group 6 enzyme in rat myometrium was associated with agonistinduced uterine contractions [26].
All PLA2 enzymes catalyze the hydrolysis of the sn-2 ester bond of phospholipids to produce free fatty acids and lsophospholipid [13,14]. A distinguishing characteristic of PLA2G4A is that it exhibits greater selectivity for lipids containing arachidonic acid than other cytosolic PLA2s. For this reason, PLA2G4A has been the enzyme primarily associated with direct generation of arachidonic acid and initiation of the eicosanoid cascade. However, PLA2G4C [21] and PLA2G6 [32,33] have been associated with agonist-stimulated arachidonic acid release and eicosanoid biosynthesis. In addition, it has been shown that PLA2G6 may mediate release of arachidonic acid directly by hydrolysis of arachidonate-containing plasmalogens or through an indirect, multi-step process involving hydrolysis of diacyl lipids to arachidonyl lysophosphatidylcholine [34].
The objectives of the present study were to investigate the expression and activities of Group 4A, 4C and 6A PLA2 enzymes in association with PGF 2α and PGE 2 production in bovine endometrial epithelial cell cultures. Results indicate that in addition to PLA2G4A, PLA2G6 and PLA2G4C contribute to regulation of uterine cell PG production and these latter two enzymes are activated in response to oxytocin and INFT, respectively.

Cell culture
Bovine endometrial epithelial cells were cultured and propagated by procedures suggested by Cell Applications, Inc. According to the distributor, the cells, isolated from epithelium of bovine endometrium and cryopreserved at second passage, can be cultured and propagated for at least 10 doublings. Briefly, cells were seeded in tissue culture dishes of the appropriate size for each experiment (see below) at a concentration of 0.5 × 10 5 cells per ml in culture medium (40% Hams F-12, 40% MEM, 200 U insulin/L, 50 μg/ml gentamicin, 10% FBS and 10% horse serum) at 37°C in a humidified atmosphere of 95% air and 5% CO 2 and culture medium was changed every other day.

PG assays
Cells were grown to ~90% confluence in 6-well plates, washed three times with HBSS and cultured for 6 h in unsupplemented Hams F-12/MEM with the following treatments: control, oxytocin (OT, 0.1 μM), IFNT (50 ng/ ml), the PLA2G6 inhibitor BEL (7.5 μM), IFNT + OT and BEL + OT. Vehicles, Hams F-12/MEM for OT and IFNT, and DMSO for the inhibitor were added to each well. Treatments were performed in triplicate and the experiment was repeated (n = 6). At the end of the incubation period, medium was harvested and stored frozen at -20°C. Prostaglandin F 2α and E 2 assays were performed with enzyme immunoassay kits from Assay Designs, Inc., according to supplier's instructions. Inter-and intraassay coefficients of variation (n = 12) were 9% and 11%, respectively.

Western blot analysis
Western blot analysis was performed as described previously (27). Briefly, cells grown to confluence in 60 mm dishes were treated with vehicle (control), OT and IFNT (50 ng and 1000 ng), alone and in combination for 6 h as described above. Treatments were performed in triplicate. Cells were lysed in RIPA buffer (50 mM Tris-HCl, 150 mM NaCl, 1% SDS, 0.5% sodium deoxycholate, 1 mM DTT, 100 μM PMSF, 1% NP-40, and 1 × protease inhibitor cocktail (Roche Applied Science, Indianapolis, IN), soni-cated and centrifuged (10,000 g, 20 minutes). Supernatants from each treatment were combined and 30 μg protein from each treatment was subjected to 10% SDSpolyacrylamide gel electrophoresis and transferred onto nitrocellulose membranes. Non-specific binding sites were blocked with 5% non-fat dry milk and membranes were incubated with antibodies to PLA2G4A, PLA2G4C, and PLA2G6 in 1:800, 1:400 and 1:1000 dilutions, respectively, overnight at 4°C. Membranes were rinsed 3 times and protein bands were visualized using an enhanced fluorescent reagent (ECL Western blotting detection kit, Amersham Biosciences, Piscataway, NJ).

Over expression of PLA2G4C and PLA2G6A in BEE cells
Full-length cDNAs encoding human PLA2G4C (accession number XM_009119) and PLA2G6A (accession number XM_039248) were generated via PCR using templates from human coronary artery endothelial cells. Primers for PLA2G4C were: upstream 5'CCG CAG TGC ACC ATG GGA AGC TC 3', downstream 5'C TCC CAG CTA CCC GGC CAC GTT C 3'. Primers for PLA2G6A were: upstream 5' G GCG GGC ACC GCC ACT GGA GC 3', downstream 5'GAA TGC CCC ATG CGT CTC CCA G 3'. The cDNAs were ligated into the PCR2.1-TOPO plasmid vector of the TA cloning system (Invitrogen Corp, Carlsbad, CA), subcloned and sequenced. Homologies with the human PLA2G4C and PLA2G6A were >99%. The cDNAs were ligated into the PCR3.1 expression vector (Invitrogen Corp, Carlsbad, CA). Plasmids were incorporated into BEE cells using the Superfect™ (Qiagen Inc, Valencia, CA) transfection system according to manufacturers' instructions. Over expression of PLA2G4C and PLA2G6 was confirmed by Western blot analysis. Cells transfected with PLA2G6 were treated for 6 h with vehicle (control), IFNT (50 ng/ml), OT (0.1 μM), OT and IFNT, BEL (7.5 μM), and BEL and OT. Cells transfected with PLA2G4C were treated for 6 h with vehicle (control), IFNT (50 ng/ml), OT (0.1 μM), OT and IFNT. Treatments were performed in triplicate and repeated (n = 6). Prostaglandin E 2 and F 2α assays were performed as described above.

PLA 2 activity in cellular homogenates
PLA 2 assays were performed on cellular lysates, as described previously [27], following treatment of intact cells. Briefly, cells were grown to 80% confluence. Treatments, OT, IFNT, alone and in combination, were applied for 3 h. Some treatments included the inhibitors, BEL, MAFP and PYR-1, which were applied 30 min before other treatments. Concentrations of treatments were as listed above unless otherwise noted. Experiments were performed in triplicate and repeated twice. At the end of the incubation period, cells were washed with Ca ++ -free PBS containing 5 mM EGTA and 1 mM phenylmethyl-sulfonylchloride (PMSF), lysed in homogenizing buffer (50 mM Tris HCl, pH 7.4, 0.5 mM dithiothreitol, 20% glyc-erol, 1 μg/ml leupeptin, 10 μg/ml aprotinin, 1 mM PMSF and sonicated two times for 10 seconds on ice. The substrates 1-palmitoyl-2-[arachidonoyl] phophatidylcholine (cold AA-PC) and 1-palmitoyl-2-[arachidonoyl-1- 14 phosphatidylcholine (OA-PC) and 1-palmitoyl-2-[oleoyl-1-14 C] phosphatidylcholine ( 14 C-OA-PC) were used to assay for PLA 2 activity. The substrates were dried under nitrogen and resuspended by sonication in assay buffer (10 mM Hepes, pH 7.5) to a final optimum concentration of cold to radiolabeled substrate as determined previously. In preliminary studies, calciumdependent and -independent activities were identified. Calcium-dependent activity (primarily PLA2G4A) assays were performed with AA-PC and 14 C-AA-PC in the presence of 5 mM CaCl 2 and calcium-independent activity (primarily PLA2G6 and PLA2G4C) assays were performed using the same substrates but in the absence of CaCl 2 and the presence of EGTA (5 mM). Assays optimized for identification of PLA2G4C utilized OA-PC and 14 C-OA-PC in the absence of calcium (this enzyme is arachidonoyl-nonselective and Ca ++ -independent) and assays optimized for PLA2G6 utilized LA-PC and 14 C-LA-PC in the absence of Ca ++ and presence of 400 μM Triton-X and 0.8 mM ATP which enhance the activity of this enzyme [28]. Experiments were terminated by addition of chloroform-methanol, 2:1 (v/v), the chloroform layer was extracted and lipids separated by thin-layer chromatography (hexane: diethyl ether: glacial acetic acid, 7:3:0.2). Lipids were visualized with I 2 vapor, the zones corresponding to fatty acid and phospholipids were excised and radioactivity determined by scintillation counting.

Statistical analysis
Data for PG production and PLA2 activity are presented as means +/-SEM and subjected to least squares analysis of variance using the general linear models procedure of the Statistical Analysis System (SAS Institute, Cary, NC). Sources of variance included experiments, treatments and their interactions. Individual comparisons of means were made using Student-Neuman-Keuls test in which the independent variables were the treatments and the dependent variables were the levels of PG or PLA2 activity produced. Differences were considered statistically significant when P < 0.05.

Prostaglandin production
The effects of treatment on PGF 2α and PGE 2 production by bovine endometrial epithelial cells are illustrated in Figure 1. In the absence of stimulation (control), cells produced about twice the amount of PGF 2α as PGE 2 (p < 0.05). Oxytocin stimulated PGF 2α and PGE 2 production about five fold and two fold, respectively. Alone, IFNT had little effect on the production of either PG but it significantly inhibited the stimulatory effect of oxytocin on PGF 2α production and numerically diminished PGE 2 production. Alone, BEL, the PLA2G6 inhibitor [30], had little effect on PGF 2α production but enhanced PGE 2 synthesis. In combination with oxytocin, BEL completely abolished the stimulatory effect of oxytocin on PGF 2α but not PGE 2 production.
Prostaglandin production by BEE cells transfected with PLA2G6 plasmids, is illustrated in Figure 2. Overexpression (OE) of PLA2G6 in BEE cells significantly increased constitutive production of PGF 2α and PGE 2 compared to non-transfected cells (compare values in Fig. 2 to Fig. 1). Oxytocin significantly increased production of both PGs by about 50% compared to non-stimulated OE (control) cells. Alone, IFNT had little effect on PG production but it diminished, significantly, the stimulatory effect of oxytocin when the treatments were combined. The PLA2G6 inhibitor BEL, alone, did not affect PGF 2α production compared to controls, but it abolished oxytocin stimulation of PGF 2α production when the two treatments were combined. Conversely, BEL dramatically enhanced PGE 2 production, alone and in combination with oxytocin. Figure 3 illustrates results of prostaglandin production by BEE cells overexpressing the PLA2G4C enzyme. Production of both PGs was significantly enhanced compared to non-transfected cells and the increase in PGE 2 was significantly greater than that of PGF 2α . Alone, IFNT had little effect on PGF 2α production but significantly stimulated PGE 2 production. Oxytocin stimulated production of both PGs compared to control PLA2G4C transfected cells and the effect on PGE 2 production was greater. When combined, IFNT diminished oxytocin stimulation of PGF 2α but PGE 2 production values were similar to oxytocin and IFNT treatments, alone.

PLA 2 protein expression
Western blot analysis of cellular proteins from BEE cells demonstrated that the PLA2G4A antibody recognized a protein which migrated at ~110 kD, the PLA2G6 antibody recognized protein which migrated at 85 kD and the PLA2G4C antibody cross-reacted with a protein migrating at 61 kD ( Figure 4). Two isoforms of PLA2G6 were identified, a major band at 85 kd, and a minor band of slightly greater mass. Similar result have been observed previously and likely the result of alternative splicing of the PLA2G6 transcript resulting in multiple isoforms of the enzyme [25]. Cells were treated for 6 h with vehicle (control, lane 1), IFNT (50 ng, lane 2), IFNT(1000 ng, lane 3), oxy-Prostaglandin F 2α and E 2 production by BEE cells to determine the effects of these treatments on PLA 2 isotype expression. As shown in Figure 4A, expression of PLA2G6 (Fig 4A) was influenced by treatments. Oxytocin up-regulated PLA2G6 (Fig 4A, lane 4) and this effect was diminished by IFNT treatments (Fig 4A, lanes 5 and 6). Expression of PLA2G4C (Fig 4B) was barely detectable, except when cells were treated with IFNT, which enhanced expression of the enzyme (Fig 4B, lanes 2, 3, 5 and 6). In contrast, PLA2G4A was expressed at similar levels in all treatment groups ( Figure 4C).

PLA 2 activity assays
Cell lysate PLA 2 assays were performed in an attempt to identify enzyme-specific activities based on differences in substrate selectivity, Ca ++ requirements, cofactor-dependent activity amplification and specific inhibitor effects. Figure 5 illustrates that BEE cells exhibit both Ca ++dependent activity (primarily PLA2G4A) and Ca ++ -independent activity (primarily PLA2G6 and PLA2G4C). Calcium-dependent activity was inhibited by PYR-1, a PLA2G4A-specific inhibitor [31], MAFP, a G4 and G6 inhibitor [30] and BEL (a PLA2G6-specific inhibitor) due to the fact that both G4C and G6 PLA 2 enzymes do not require Ca ++ for activity but function in its presence. Calcium-independent activity was inhibited by BEL and MAFP, but not PYR-1, which inhibits only the Ca ++dependent PLA2G4A. stimulation of activity by BEL but not PYR-1 confirms that PLA2G6 activity was measured.
Results from PLA 2 assays designed to measure PLA2G4C activity are illustrated in Figure 7. BEE cells were treated for 3 h with vehicle (control), oxytocin, BEL, PYR-1, MAFP or IFNT. Considerable constitutive activity was present and this activity was inhibited by the G4 and G6 PLA2 inhibitor MAFP but not the G6-specific inhibitor BEL or the G4A-specific inhibitor PYR-1. Group IVC PLA2 activity was significantly stimulated by IFNT.

Discussion
Prostaglandins are essential regulators of numerous reproductive processes but, despite their primary involvement in fertility regulation, the cellular and molecular mechanisms that regulate prostaglandin production are poorly understood. The rate-limiting step in prostanoid biosynthesis is at the level of PLA2 enzymes but, surprisingly, little is known concerning the regulatory function of specific PLA2 isoforms that mediate arachidonic acid release and are likely coupled to downstream enzymes that synthesize the different PGs in reproductive tissues. Although in vivo studies may provide the most complete physiological conditions in which to evaluate uterine biology, they are not best suited for analysis of some cellular mechanisms involving biochemical pathways. For this reason, we turned to in vitro cell cultures to evaluate PLA2 regulation of PG biosynthesis. To our knowledge, this is the first study to demonstrate that expression and activity of the calcium-independent PLA2G6 and PLA2G4C in endometrial epithelial cells are differentially regulated by oxytocin and IFNT, resulting in altered prostaglandin biosynthesis.
Three lines of evidence support the concept that PLA2G6 is involved in oxytocin stimulation of endometrial PGF 2α production. One, the PLA2G6 inhibitor BEL abolished oxytocin stimulation of PGF 2α production. Two, oxytocin increased expression of PLA2G6 as determined by Western blot analysis; and three, PLA2G6-specific activity was increased by oxytocin and this response was blocked by BEL. Similarly, the results indicate that IFNT diminished oxytocin stimulated PLA2G6 expression ( Figure 4A, Western blot analysis) and activity ( Figure 6) resulting in diminished PGF 2α production ( Figure 1). These results do not exclude PLA2G4A from playing a role in oxytocin- stimulated uterine PG production. Indeed, PLA2G4A knock-out mice fail to initiate labor at term. On the other hand, the results presented may help to explain why previous studies [10][11][12] failed to identify consistent changes in PLA2G4A expression or activity in response to oxytocin.

Prostaglandin F 2α and E 2 production by BEE cells over-expressing PLA2G4C
The observation that BEL inhibition of PLA2G6 activity blocked oxytocin stimulation of PGF 2α production led to studies that examined the effects of PLA2G6 overexpression on PG production. Cells that over expressed this enzyme produced significantly more PGF 2α and PGE 2 than control non-transfected cells. Oxytocin increased production of both PGs and IFNT diminished these responses. As expected, BEL inhibited oxytocin-stimulated PGF 2α production. In contrast, BEL, alone or in combination with oxytocin, greatly enhanced PGE 2 production. Increased PGE 2 production in response to BEL was also observed in non-transfected BEE cells and, in previous studies [29], we have repeatedly observed stimulation of PGE 2 production by BEL in primary cultures of ovine endometrial epithelial cells. Although BEL is a relatively selective PLA2 inhibitor at the concentration used, it has also been shown to inhibit Mg ++ -dependent phosphatidic acid phosphohydrolase (PAP-1), an enzyme that catalyzes the dephosphorylation of phosphatidic acid to diacylglycerol [30]. Change in PAP-1 activity would not explain the observed increase in PGE 2 . Alteration of the PGE 2 : PGF 2α ratios could be affected at the level of the PG synthases. To our knowledge, there is no evidence that BEL affects PGE synthase expression or activity. In addition, studies in human monocytes [32] and rat mesangial cells [33] have demonstrated that stimulation of the arachadonic acid/ PGE cascade is mediated by PLA2G6 activation and BEL inhibited agonist-stimulated PGE 2 production in these cells. These data would argue against a stimulatory activity of BEL on PGE 2 synthase.
Functional coupling between different PLA2 isoforms, COX-2 and specific PG synthases has been suggested as a regulatory mechanism of prostanoid biosynthesis in a variety of cell types [36][37][38]. Individual isoforms, coupled to specific signaling stimuli, may act on different cellular pools of arachidonic acid at different locations in membranes. Inhibition of PLA2G6 with BEL blocked oxytocin stimulated PGF 2α production but stimulated PGE 2 production. One possible explanation for the differential effects of BEL on PG production may be that PLA2G6 is functionally coupled to PGF 2α production which is stimulated by oxytocin and inhibition of PLA2G6 blocks this response. Conversely, inhibition of PLA2G6 may be permissive to activation of other PLA2 isoforms, such as PLA2G4C, which may be functionally coupled to PGE 2 production. Clearly, confirmation of this hypothesis will require additional studies.
During early pregnancy in ruminants, IFNT not only suppresses episodic release of PGF 2α from the endometrium, but it also enhances production of PGE 2 [39][40][41]. PGE 2 has been proposed to have multiple roles in the maintenance of early pregnancy, including action as a luteotrophic or luteoprotective signal and as a mediator of endometrial receptivity [38,39]. The mechanism by which IFNT upregulates PGE 2 production is unknown but Arosh et al.
Oxytocin and interferon-tau differentially regulate expression of PLA2 enzymes BEE cells exhibit both Ca ++ -dependent and Ca ++ -independent PLA2 activities Figure 5 BEE cells exhibit both Ca ++ -dependent and Ca ++ -independent PLA2 activities. PLA2 activity assays were performed on cellular lysates following treatment of intact cells, as described in the Methods. Ca ++ -dependent PLA2 activity assays were performed with AA-PC and 14 C-AA-PC in the presence of 5 mM CaCl 2 and Ca ++ -independent assays were performed using the same substrates but in the absence of CaCL 2 and the presence of 5 mM EGTA. Treatments included the PLA2G6 inhibitor BEL, the PLA2G4 and PLA2G6 inhibitor MAFP and the PLA2G4A inhibitor PYR-1. Data from columns with different superscripts are significantly different (p < 0.05). Oxytocin stimulated PLA2G6 activity is blocked by IFNT Figure 6 Oxytocin stimulated PLA2G6 activity is blocked by IFNT. BEE cells were treated for 3 h with vehicle control, oxytocin, IFNT, BEL or PYR-1, alone or in combination. The symbols, + and -, indicate the presence or absence of treatments, respectively. PLA2G6 activity assays were performed on cellular lysates as described in the Methods. Inhibition of activity by BEL but not PYR-1 demonstrates that PLA2G6 activity was measured. Columns with different superscripts are significantly different (p < 0.05).  [39] have shown that it does not enhance PGE 2 synthase expression in bovine endometrium. We propose IFNT regulation of PGE 2 production involves, at least in part, modulation of expression and activity of a PLA2 isoform. Results from cell-free PLA 2 assays and Western blot analysis demonstrated that PLA2G4C activity and expression were up-regulated by IFNT. Over expression of PLA2G4C in BEE cells increased production of both PGs but the increased PGE 2 was significantly greater than the increased PGF 2α . Treatment of these cells with IFNT significantly stimulated PGE 2 production. Together, these results indicate that the PLA2G4C enzyme is coupled to PGE 2 production and this activity is positively regulated by IFNT.

Phospholipase
Luteolysis, resulting from episodic secretion of PGF 2α , is acknowledged, generally, to be orchestrated progesterone, estradiol and oxytocin acting through their respective endometrial receptors [1,2]

Conclusion
Together, the data indicate that uterine PG production is regulated, at least in part, by the expression and activity of PLA2 enzymes and that specific PLA2 isotypes may regulate the production of specific PGs.

Competing interests
The author(s) declare that they have no competing interests.
PLA2G4C activity is enhanced by IFNT but not oxytocin Figure 7 PLA2G4C activity is enhanced by IFNT but not oxytocin. BEE cells were treated for 3 h with vehicle control, oxytocin, BEL, PYR-1, MAFP or IFNT. The symbols, + and -, indicate the presence or absence of treatments, respectively. PLA2G4C activity assays were performed on cellular lysates as described in the Methods. Inhibition of activity by MAFP but not PYR-1 or BEL demonstrates that PLA2G4C activity was measured. Columns with different superscripts are significantly different (p < 0.05).