Protease-activated receptor-1 in human lung fibroblasts mediates a negative feedback downregulation via prostaglandin E2

Among the four protease-activated receptors (PARs), PAR-1 plays an important role in normal lung functioning and in the development of lung diseases, including fibrosis. We compared the expression and functional activity of PARs in normal and fibrotic human lung fibroblasts. Both normal and fibrotic cells express PAR-1, -2, and -3, with PAR-2 showing the lowest level. There was no significant difference between normal and fibrotic fibroblasts in expression levels of PAR-1 and PAR-3, whereas a fourfold higher expression level of PAR-2 was observed in fibrotic cells compared with normal cells. Ca(2+) imaging studies revealed apparently only PAR-1-induced Ca(2+) signaling in lung fibroblasts. PAR-1 agonists, thrombin and synthetic activating peptide, induced concentration-dependent Ca(2+) mobilization with EC(50) values of 5 nM and 1 microM, respectively. The neutrophil protease cathepsin G produced a transient Ca(2+) response followed by disabling PAR-1, whereas elastase did not affect Ca(2+) level. PAR-1 activation by thrombin or receptor-activating peptide downregulated expression of all three PARs in lung fibroblasts, with maximal effect at 3-6 h, whereas expression returned toward basal level after 24 h. Furthermore, PAR-1 agonists dose dependently increased PGE(2) secretion from lung fibroblasts and induction of cyclooxygenase-2 expression. We then found that PGE(2) downregulated expression of all three PARs. The effect of PGE(2) was continuously growing with time. Furthermore, PGE(2) exerts its effect through the EP2 receptor that was confirmed using the selective EP2 agonist butaprost. This novel autocrine feedback mechanism of PGE(2) in lung fibroblasts seems to be an important regulator in lung physiology and pathology.     

Role of prostaglandin E(2) EP receptors and cAMP in the expression of connective tissue growth factor

Wild-type (WT) Rat-1 fibroblasts express undetectable quantities of the prostaglandin E(2) (PGE(2)) EP1, EP2, and EP3 receptor types and detectable amounts of the EP4 receptor. In the WT Rat-1, PGE(2) enhances connective tissue growth factor (CTGF) mRNA. PGE(2) does not stimulate cAMP production in these cells. However, forskolin induces cAMP production and ablates TGF beta-stimulated increases in CTGF mRNA. A similar pattern of CTGF expression in response to PGE(2) and forskolin is observed in neonatal rat primary smooth muscle cell cultures. When WT Rat-1 cells are stably transfected with the EP2 receptor, PGE(2) causes a sizable elevation in intracellular cAMP and ablates the TGF beta-stimulated increase in CTGF mRNA. PGE(2) does not have this effect on cells expressing the EP1, EP3, or EP4 receptor subtypes. These results demonstrate the importance of the EP2 receptor and cAMP in the inhibition of TGF beta-stimulated CTGF production and suggest a role for PGE(2) in increasing CTGF mRNA levels in the absence of the EP2 receptor. Involvement of inositol phosphate in this upregulation of CTGF expression by PGE(2) is doubtful. None of the cell lines containing the four EP transfectants nor the WT Rat-1 cells responded to PGE(2) with inositol phosphate production.     

Prostaglandin E(2) inhibits collagen expression and proliferation in patient-derived normal lung fibroblasts via E prostanoid 2 receptor and cAMP signaling

Uncontrolled fibroblast activation is one of the hallmarks of fibrotic lung disease. Prostaglandin E(2) (PGE(2)) has been shown to inhibit fibroblast migration, proliferation, collagen deposition, and myofibroblast differentiation in the lung. Understanding the mechanisms for these effects may provide insight into the pathogenesis of fibrotic lung disease. Previous work has focused on commercially available fibroblast cell lines derived from tissue whose precise origin and histopathology are often unknown. Here, we sought to define the mechanism of PGE(2) inhibition in patient-derived fibroblasts from peripheral lung verified to be histologically normal. Fibroblasts were grown from explants of resected lung, and proliferation and collagen I expression was determined following treatment with PGE(2) or modulators of its receptors and downstream signaling components. PGE(2) inhibited fibroblast proliferation by 33% and collagen I expression by 62%. PGE(2) resulted in a 15-fold increase in intracellular cAMP; other cAMP-elevating agents inhibited collagen I in a manner similar to PGE(2). These effects were reproduced by butaprost, a PGE(2) analog selective for the cAMP-coupled E prostanoid (EP) 2 receptor, but not by selective EP3 or EP4 agonists. Fibroblasts expressed both major cAMP effectors, protein kinase A (PKA) and exchange protein activated by cAMP-1 (Epac-1), but only a selective PKA agonist was able to appreciably inhibit collagen I expression. Treatment with okadaic acid, a phosphatase inhibitor, potentiated the effects of PGE(2). Our data indicate that PGE(2) inhibits fibroblast activation in primary lung fibroblasts via binding of EP2 receptor and production of cAMP; inhibition of collagen I proceeds via activation of PKA.     

Tissue-specific mechanisms for CCN2/CTGF persistence in fibrotic gingiva: interactions between cAMP and MAPK signaling pathways, and prostaglandin E2-EP3 receptor mediated activation of the c-JUN N-terminal kinase

Prostaglandin E(2) blocks transforming growth factor TGF beta1-induced CCN2/CTGF expression in lung and kidney fibroblasts. PGE(2) levels are high in gingival tissues yet CCN2/CTGF expression is elevated in fibrotic gingival overgrowth. Gingival fibroblast expression of CCN2/CTGF in the presence of PGE(2) led us to compare the regulation of CCN2/CTGF expression in fibroblasts cultured from different tissues. Data demonstrate that the TGFbeta1-induced expression of CCN2/CTGF in human lung and renal mesangial cells is inhibited by 10 nm PGE(2), whereas human gingival fibroblasts are resistant. Ten nm PGE(2) increases cAMP accumulation in lung but not gingival fibroblasts, which require 1 mum PGE(2) to elevate cAMP. Micromolar PGE(2) only slightly reduces the TGFbeta1-stimulated CCN2/CTGF levels in gingival cells. EP2 prostaglandin receptor activation with butaprost blocks the TGFbeta1-stimulated expression of CCN2/CTGF expression in lung, but not gingival, fibroblasts. In lung fibroblasts, inhibition of the TGFbeta1-stimulated CCN2/CTGF by PGE(2), butaprost, or forskolin is due to p38, ERK, and JNK MAP kinase inhibition that is cAMP-dependent. Inhibition of any two MAPKs completely blocks CCN2/CTGF expression stimulated by TGFbeta1. These data mimic the inhibitory effects of 10 nm PGE(2) and forskolin that were dependent on PKA activity. In gingival fibroblasts, the sole MAPK mediating the TGFbeta1-stimulated CCN2/CTGF expression is JNK. Whereas forskolin reduces TGFbeta1-stimulated expression of CCN2/CTGF by 35% and JNK activation in gingival fibroblasts, micromolar PGE(2)-stimulated JNK in gingival fibroblasts and opposes the inhibitory effects of cAMP on CCN2/CTGF expression. Stimulation of the EP3 receptor with sulprostone results in a robust increase in JNK activation in these cells. Taken together, data identify two mechanisms by which TGFbeta1-stimulated CCN2/CTGF levels in human gingival fibroblasts resist down-regulation by PGE(2): (i) cAMP cross-talk with MAPK pathways is limited in gingival fibroblasts; (ii) PGE(2) activation of the EP3 prostanoid receptor stimulates the activation of JNK.     

Bleomycin-induced E prostanoid receptor changes alter fibroblast responses to prostaglandin E2

Although PGE(2) is a potent inhibitor of fibroblast function, PGE(2) levels are paradoxically elevated in murine lungs undergoing fibrotic responses. Pulmonary fibroblasts from untreated mice expressed all four E prostanoid (EP) receptors for PGE(2). However, following challenge with the fibrogenic agent, bleomycin, fibroblasts showed loss of EP2 expression. Lack of EP2 expression correlated with an inability of fibroblasts from bleomycin-treated mice to be inhibited by PGE(2) in assays of proliferation or collagen synthesis and blunted cAMP elevations in response to PGE(2). PGE(2) was similarly unable to suppress proliferation or collagen synthesis in fibroblasts from EP2(-/-) mice despite expression of the other EP receptors. EP2(-/-), but not EP1(-/-) or EP3(-/-) mice, showed exaggerated fibrotic responses to bleomycin administration in vivo as compared with wild-type controls. EP2 loss on fibroblasts was verified in a second model of pulmonary fibrosis using FITC. Our results for the first time link EP2 receptor loss on fibroblasts following fibrotic lung injury to altered suppression by PGE(2) and thus identify a novel fibrogenic mechanism.     

Mechanisms of prostaglandin E2-induced interleukin-6 release in astrocytes: possible involvement of EP4-like receptors, p38 mitogen-activated protein kinase and protein kinase C.

The expression of cyclooxygenase-2 (COX-2) and the synthesis of prostaglandin E2 (PGE2) as well as of cytokines such as interleukin-6 (IL-6) have all been suggested to propagate neuropathology in different brain disorders such as HIV-dementia, prion diseases, stroke and Alzheimer's disease. In this report, we show that PGE2-stimulated IL-6 release in U373 MG human astroglioma cells and primary rat astrocytes. PGE2-induced intracellular cAMP formation was mediated via prostaglandin E receptor 2 (EP2), but inhibition of cAMP formation and protein kinase A or blockade of EP1/EP2 receptors did not affect PGE2-induced IL-6 synthesis. This indicates that the cAMP pathway is not part of PGE2-induced signal transduction cascade leading to IL-6 release. The EP3/EP1-receptor agonist sulprostone failed to induce IL-6 release, suggesting an involvement of EP4-like receptors. PGE2-activated p38 mitogen-activated kinase (p38 MAPK) and protein kinase C (PKC). PGE2-induced IL-6 synthesis was inhibited by specific inhibitors of p38 MAPK (SB202190) and PKC (GF203190X). Although, up to now, EP receptors have only rarely been linked to p38 MAPK or PKC activation, these results suggest that PGE2 induces IL-6 via an EP4-like receptor by the activation of PKC and p38 MAPK via an EP4-like receptor independently of cAMP.     

Suppression of prostaglandin E(2)-mediated c-fos mRNA induction by interleukin-4 in murine macrophages

When murine peritoneal macrophages were stimulated for 30 min with arachidonic acid, the growth-associated immediate early gene c-fos was induced in a concentration-dependent manner as assessed by Northern blot analysis. The arachidonic acid-induced c-fos mRNA expression was inhibited by a cyclooxygenase inhibitor, indomethacin, but not by a lipoxygenase inhibitor, nordihydroguaiaretic acid. Macrophages produced prostaglandin (PG) E(2) from arachidonic acid as determined by an enzyme immunoassay. Northern blot analysis revealed the expression of PGE receptor EP2 and EP4 subtypes, but not EP1 and EP3 in murine macrophages. PGE(2) brought about a marked elevation of cAMP, and c-fos mRNA expression was increased by PGE(2) and dibutyryl cAMP in these cells. These results suggest that arachidonic acid is transformed to PGE(2), which then binds to EP2 and EP4 receptors to increase intracellular cAMP and c-fos mRNA expression. Furthermore, the induction of c-fos by arachidonic acid, PGE(2), and cAMP was suppressed by pretreatment with interleukin (IL)-4. We also showed that the tyrosine phosphorylation of a Janus kinase, JAK3, is enhanced by IL-4 treatment, suggesting that the PGE(2)-mediated c-fos mRNA induction is inhibited by IL-4 through the tyrosine phosphorylation of JAK3.     

Plasmin overcomes resistance to prostaglandin E2 in fibrotic lung fibroblasts by reorganizing protein kinase A signaling

Collagen deposition by fibroblasts contributes to scarring in fibrotic diseases. Activation of protein kinase A (PKA) by cAMP represents a pivotal brake on fibroblast activation, and the lipid mediator prostaglandin E(2) (PGE(2)) exerts its well known anti-fibrotic actions through cAMP signaling. However, fibrotic fibroblasts from the lungs of patients with idiopathic pulmonary fibrosis, or of mice with bleomycin-induced fibrosis, are resistant to the normal collagen-inhibiting action of PGE(2). In this study, we demonstrate that plasminogen activation to plasmin restores PGE(2) sensitivity in fibrotic lung fibroblasts from human and mouse. This involves amplified PKA signaling resulting from the promotion of new interactions between AKAP9 and PKA regulatory subunit II in the perinuclear region as well as from the inhibition of protein phosphatase 2A. This is the first report to show that an extracellular mediator can dramatically reorganize and amplify the intracellular PKA-A-kinase anchoring protein signaling network and suggests a new strategy to control collagen deposition by fibrotic fibroblasts.     

Prostaglandin E2 mediates IL-1beta-related fibroblast mitogenic effects in acute lung injury through differential utilization of prostanoid receptors

The fibroproliferative response to acute lung injury (ALI) results in severe, persistent respiratory dysfunction. We have reported that IL-1beta is elevated in pulmonary edema fluid in those with ALI and mediates an autocrine-acting, fibroblast mitogenic pathway. In this study, we examine the role of IL-1beta-mediated induction of cyclooxygenase-2 and PGE2, and evaluate the significance of individual E prostanoid (EP) receptors in mediating the fibroproliferative effects of IL-1beta in ALI. Blocking studies on human lung fibroblasts indicate that IL-1beta is the major cyclooxygenase-2 mRNA and PGE2-inducing factor in pulmonary edema fluid and accounts for the differential PGE2 induction noted in samples from ALI patients. Surprisingly, we found that PGE2 produced by IL-1beta-stimulated fibroblasts enhances fibroblast proliferation. Further studies revealed that the effect of fibroblast proliferation is biphasic, with the promitogenic effect of PGE2 noted at concentrations close to that detected in pulmonary edema fluid from ALI patients. The suppressive effects of PGE2 were mimicked by the EP2-selective receptor agonist, butaprost, by cAMP activation, and were lost in murine lung fibroblasts that lack EP2. Conversely, the promitogenic effects of mid-range concentrations of PGE2 were mimicked by the EP3-selective agent, sulprostone, by cAMP reduction, and lost upon inhibition of Gi-mediated signaling with pertussis toxin. Taken together, these data demonstrate that PGE2 can stimulate or inhibit fibroblast proliferation at clinically relevant concentrations, via preferential signaling through EP3 or EP2 receptors, respectively. Such mechanisms may drive the fibroproliferative response to ALI.     

Differential mRNA expression of prostaglandin receptor subtypes in macrophage activation

Assessing the regulation of macrophage receptors for prostaglandin (PGE2) is essential to understanding the control which that potent lipid mediator has in modulating macrophage activities. The purpose of this study was to assess the differential mRNA expression of PGE2 receptor subtypes (EP) during macrophage exposure to activating and transducing agents. RAW 264.7 macrophages constitutively expressed mRNA for EP2,EP3 and EP4 receptor subtypes. Messenger RNA for EP4 was expressed at a much higher level when compared to EP2 in unstimulated macrophages as assessed by kinetic quantitative RT-PCR. When macrophages were stimulated with LPS, EP2 m RNA levels were 12-fold higher when compared to unstimulated macrophages, while EP4 m RNA remained unchanged. Conversely, mRNA levels of both EP2 and EP4 receptors were lower after macrophages were treated with IFN-gamma. Messenger RNA levels of both receptors were lower in macrophages after treatment with PGE2 or dibutyryl (db) cAMP Addition of the PKA inhibitor H89 reversed the effects of PGE2 and dbcAMP to varying degrees. Proteosome and p38 MAP kinase inhibitors blocked the LPS-stimulated increase in EP2 mRNA levels. Those inhibitors had no effect on EP4 mRNA.Thus, activating agents such as LPS and IFN-gamma may differentially regulate mRNAfor PGE2 receptor types in macrophages but the ligand and its associated signal transducing factors probably have similar regulatory effects.     

PGE(2) inhibition of TGF-beta1-induced myofibroblast differentiation is Smad-independent but involves cell shape and adhesion-dependent signaling

Myofibroblasts are pathogenic in pulmonary fibrotic disease due to their exuberant production of matrix rich in collagen that interferes with gas exchange and the ability of these cells to contract and distort the alveolar space. Transforming growth factor-beta1 (TGF-beta1) is a well-known inducer of myofibroblast differentiation. TGF-beta1-induced transformation of fibroblasts to apoptosis-resistant myofibroblasts is adhesion-dependent and focal adhesion kinase (FAK)-mediated. Prostaglandin E(2) (PGE(2)) inhibits this differentiation via E prostanoid receptor 2 (EP2) signaling and cAMP elevation, but whether PGE(2) does so by interfering with TGF-beta1 signaling is unknown. Thus we examined the effects of PGE(2) in the presence and absence of TGF-beta1 stimulation on candidate signaling pathways in human lung fibroblasts. We now demonstrate that PGE(2) does not interfere with TGF-beta1-induced Smad phosphorylation or its translocation to the nucleus. Rather, PGE(2) has dramatic effects on cell shape and cytoskeletal architecture and disrupts the formation of appropriate focal adhesions. PGE(2) treatment diminishes TGF-beta1-induced phosphorylation of paxillin, STAT-3, and FAK and, in turn, limits activation of the protein kinase B (PKB/Akt) pathway. These alterations do not, however, result in increased apoptosis within the first 24 h of treatment. Interestingly, the effects of PGE(2) stimulation alone do not always mirror the effects of PGE(2) in the presence of TGF-beta1, indicating that the context for EP2 signaling is different in the presence of TGF-beta1. Taken together, our results demonstrate that PGE(2) has the potential to limit TGF-beta1-induced myofibroblast differentiation via adhesion-dependent, but Smad-independent, pathways.     

Protein kinase C activation reduces microglial cyclic AMP response to prostaglandin E2 by interfering with EP2 receptors

We studied the modulation by protein kinase C (PKC) of the cyclic AMP (cAMP) accumulation induced by prostaglandin (PG) E2 in rat neonatal microglial cultures. Short pretreatment of microglia with phorbol 12-myristate 13-acetate (PMA) or 4beta-phorbol 12,13-didecanoate, which activate PKC, but not with the inactive 4alpha-phorbol 12,13-didecanoate, substantially reduced cAMP accumulation induced by 1 microM PGE2. The action of PMA was dose and time dependent, and the maximal inhibition (approximately 85%) was obtained after 10-min preincubation with 100 nM PMA. The inhibitory effect of PMA was mimicked by diacylglycerol and was prevented by the PKC inhibitor calphostin C. As PMA did not affect isoproterenol- or forskolin-stimulated cAMP accumulation, we investigated whether activation of PKC decreased cAMP production by acting directly at PGE2 EP receptors. Neither sulprostone (10(-9)-10(-5) M), a potent agonist at EP3 receptors (coupled to adenylyl cyclase inhibition), nor 17-phenyl-PGE2 (10(-6)-10(-5) M), an agonist of EP1 receptors, modified cAMP accumulation induced by forskolin. On the contrary, 11-deoxy-16,16-dimethyl PGE2, which does not discriminate between EP2 and EP4 receptors, both coupled to the activation of adenylyl cyclase, and butaprost, a selective EP2 agonist, induced a dose-dependent elevation of cAMP that was largely reduced by PMA pretreatment, as in the case of PGE2. These results indicated EP2 receptors as a possible target of PKC and suggest that PKC-activating agents present in the pathological brain may prevent the cAMP-mediated microglia-deactivating function of PGE2.     

Molecular cloning and functional characterization of the canine prostaglandin E2 receptor EP4 subtype.

Prostaglandin E2 (PGE2) is an important mediator of diverse biologic functions in many tissues and binds with high affinity to four cell surface, seven-transmembrane domain, G protein-coupled receptors (EP1-EP4). The EP4 receptor subtype has a long intracellular carboxy-terminal region and is functionally coupled to adenylate cyclase, resulting in elevated intracellular cyclic adenosine 5' monophosphate (cAMP) levels upon activation. To further study EP4 receptor subtype function, a canine kidney cDNA library was screened and three clones were isolated and sequenced. The longest clone was 3,103 bp and contained a single open reading frame of 1,476 bp, potentially encoding a protein of 492 amino acids with a predicted molecular weight of 53.4 kDa. Sequence analysis of this open reading frame reveals 89% identity to the human EP4 protein coding region at the nucleotide level and 90% identity when the putative canine and human protein sequences are compared. Northern blot analysis showed relatively high levels of canine EP4 expression in heart, lung and kidney, while Southern blot analysis of canine genomic DNA suggests the presence of a single copy gene. Following transfection of canine EP4 into CHO-KI cells, Scatchard analysis revealed a dissociation constant of 24 nM for PGE, while competition binding studies using 3H-PGE2 as ligand demonstrated specific displacement by PGE2 prostaglandin E, (PGE1), and prostaglandin A3 (PGA3). Treatment with PGE2 also resulted in increased levels of cAMP in transfected, but not in parental, CHO-KI cells. In contrast, butaprost, an EP2 selective ligand, and sulprostone, an EP1/EP3 selective ligand, did not bind to this receptor at the maximal concentration used (320 nM). To further investigate secondary signaling, the canine EP4 cDNA was truncated to produce an 1,117 bp fragment encoding a 356 amino acid protein lacking the intracellular carboxy-terminus. When transfected, this truncated cDNA produced a protein with a dissociation constant of 11 nM for PGE2 and a binding and cAMP accumulation profile similar to that of the full-length protein. Both full-length and truncated canine EP4 underwent short term PGE2-induced desensitization as shown by a lack of continuing cAMP accumulation after the initial PGE2 stimulation, suggesting no involvement of the C-terminal intracellular tail. This result is in contrast to that reported for the human EP4 receptor, where residues within the C-terminal intracellular tail were shown to mediate short term, ligand induced desensitization.     

PGE1 and PGE2 modify platelet function through different prostanoid receptors

There is evidence that the overall effects of prostaglandin E(2) (PGE(2)) on human platelet function are the consequence of a balance between promotory effects of PGE(2) acting at the EP3 receptor and inhibitory effects acting at the EP4 receptor, with no role for the IP receptor. Another prostaglandin that has been reported to affect platelet function is prostaglandin E(1) (PGE(1)), however the receptors that mediate its actions on platelet function have not been fully defined. Here we have used measurements of platelet aggregation and P-selectin expression induced by the thromboxane A(2) mimetic U46619 to compare the effects of PGE(1) and PGE(2) on platelet function. Their effects on vasodilator-stimulated phosphoprotein (VASP) phosphorylation, as a marker of cAMP, were also determined. We also investigated the ability of the selective prostanoid receptor antagonists CAY10441 (IP antagonist), DG-041 (EP3 antagonist) and ONO-AE3-208 (EP4 antagonist) to modify the effects of the prostaglandins on platelet function. The results obtained confirm that PGE(2) interacts with EP3 and EP4 receptors, but not IP receptors. In contrast PGE(1) interacts with EP3 and IP receptors, but not EP4 receptors. In both cases the overall effects on platelet function reflect the balance between promotory and inhibitory effects at receptors that have opposite effects on adenylate cyclase.     

Cyclooxygenase-2 expression in lipopolysaccharide-stimulated human monocytes is modulated by cyclic AMP, prostaglandin E(2), and nonsteroidal anti-inflammatory drugs

Using human blood monocytes (for determination of cyclooxygenase-2 (COX-2) mRNA by RT-PCR) and human whole blood (for prostanoid determination), the present study investigates the influence of the second messenger cAMP on lipopolysaccharide (LPS)-induced COX-2 expression with particular emphasis on the role of prostaglandin E(2) (PGE(2)) in this process. Elevation of intracellular cAMP with a cell-permeable cAMP analogue (dibutyryl cAMP), an adenylyl cyclase activator (cholera toxin), or a phosphodiesterase inhibitor (3-isobutyl-1-methylxanthine) substantially enhanced LPS-induced PGE(2) formation and COX-2 mRNA expression, but did not modify COX-2 enzyme activity. Moreover, up-regulation of LPS-induced COX-2 expression was caused by PGE(2), butaprost (selective agonist of the adenylyl cyclase-coupled EP(2) receptor) and 11-deoxy PGE(1) (EP(2)/EP(4) agonist), whereas sulprostone (EP(3)/EP(1) agonist) left COX-2 expression unaltered. Abrogation of LPS-induced PGE(2) synthesis with the selective COX-2 inhibitor NS-398 caused a decrease in COX-2 mRNA levels that was restored by exogenous PGE(2) and mimicked by S(+)-flurbiprofen and ketoprofen. Overall, these results indicate a modulatory role of cAMP in the regulation of COX-2 expression. PGE(2), a cAMP-elevating final product of the COX-2 pathway, may autoregulate COX-2 expression in human monocytes via a positive feedback mechanism.