Chimeric exchanges within the bradykinin B2 receptor intracellular face with the prostaglandin EP2 receptor as the donor: importance of the second intracellular loop for cAMP synthesis

The prostaglandin E2 (PGE(2)) EP2 receptor (EP2R) type is G protein coupled (GPCR) and links to Galphas. Through this receptor PGE(2) activates cAMP production. The bradykinin (BK) B2 receptor (BKB2R) is also a GPCR but links to Galphaq and Galphai and does not activate cAMP production in response to bradykinin. In an attempt to convert the BKB2R into a Galphas-linked adenylate cyclase-activating receptor we proceeded to make global and discrete motif replacements of the intracellular (IC) face of the BKB2R with the corresponding regions of the human EP2R. With this approach we produced hybrid receptors which, when stably transfected into wild type (WT) Rat-1 cells, bound BK but produced cAMP. Replacement of the second loop (IC2), third loop (IC3), the entire C terminus, and the distal C terminus resulted in receptors which bound BK. However, only the IC2 and IC3 exchanges resulted in cAMP-producing receptors. Of these two regions, the IC2 exchange was by far the better cAMP-generating receptor, producing cAMP at approximately 6.6-fold above WT BKB2R or approximately one fourth the amount produced by WT EP2R-transfected Rat-1 cells. Both human and rat EP2R and human beta2-adrenergic receptor exchanges of the IC2 produced equal quantities of cAMP. Focusing on the rBKB2R/hEP2R IC2 chimeras, the region consisting of residues 136-147 (BKB2R residue numbering) proved to contain a cAMP-generating motif. Within this region, the proximal six amino acids from the EP2R (HPYFYQ) at position 136-141 proved crucial for cAMP production (10-fold over WT BKB2R). The distal part of this region, the six residues at 142-147, played no role in cAMP production. On the other hand, the ALV motif of the BKB2R IC2, residues 133-135, proved important with respect to phosphatydilinositol (PI) turnover. Replacing the entire IC2 of BKB2R resulted in poor PI turnover, while including the AVL of BKB2R retained approximately half of the WT PI turnover. With respect to receptor uptake, all the IC2 mutants endocytosed as WT BKB2R (60% in 1h). However, the exchange of the distal and the whole C termini resulted in a marked drop in endocytosis (30% in 1h). These results demonstrate that the construction of a cAMP-producing BKB2/EP2 receptor hybrid is possible, with the IC2 region distal to DRYLALV proving important to Galphas linkage and the LALV motif within the IC2 of BKB2R and the region proximal to it proving important for Galphaq and Galphai linkage. Additionally, our results confirm the importance of the distal C terminus in determining receptor uptake.     

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.     

Indomethacin decreases EP2 prostanoid receptor expression in colon cancer cells

Nonsteroidal anti-inflammatory drugs (NSAIDs) can decrease the risk of colorectal cancer; however, it has not been established if this effect is solely through their ability to inhibit cyclooxygenase (COX). In this study the effects of indomethacin, a potent NSAID and nonselective COX inhibitor, was examined in LS174T human colon cancer cells. These cells were found to express EP2 prostanoid receptors, but not the EP1, EP3 or EP4 subtypes. Pretreatment of LS174T cells with indomethacin produced a complete inhibition of prostaglandin E(2) (PGE(2)) stimulated cyclic AMP (cAMP) formation in a dose dependent manner with an IC(50) of 21 microM. Interestingly, the inhibition of PGE(2)-stimulated cAMP formation by indomethacin was accompanied by a decrease in EP2 mRNA expression and by a decrease in the whole cell specific binding of [(3)H]PGE(2). Thus, treatment of LS174T cells with indomethacin causes a down regulation of EP2 prostanoid receptors expression that may be independent of COX inhibition.     

Role of prostaglandin E2 receptors in migration of murine and human breast cancer cells

Aberrant upregulation of COX-2 enzyme resulting in accumulation of PGE2 in a cancer cell environment is a marker for progression of many cancers, including breast cancer. Four subtypes of cell surface receptors (EP1, EP2, EP3, and EP4), which are coupled with different G-proteins, mediate PGE2 actions. Since migration is an essential step in invasion and metastasis, in the present study we defined the expression of EP receptors and their roles in migratory function of breast cancer cells of murine (C3L5) and human (MDA-MB-231 and MCF-7) origin. Highly metastatic C3L5 and MDA-MB-231 cells, found to be highly migratory in a Transwell migration assay, were shown to accumulate much higher levels of PGE2 in culture media in comparison with nonmetastatic and poorly migrating MCF-7 cells; the levels of PGF2alpha and 6-keto-PGF1alpha were low in all cases. The elevated PGE2 production by metastatic cancer cells was due to COX-2 activity since dual COX-1/2 inhibitor indomethacin and selective COX-2 inhibitor NS-398 equally suppressed both basal and inducible (by IFN-gamma/LPS or Ca2+-ionophores) PGE2 accumulation. RT-PCR analysis revealed that murine C3L5 cells expressed mRNA of EP1, EP3, and EP4 but not EP2 receptors. On the other hand, human MDA-MB-231 and MCF-7 cells expressed all the above receptors. High levels of expression of functional EP4 receptors coupled with Gs-protein was confirmed in C3L5 cells by biochemical assay showing a dose-dependent increase of intracellular cAMP synthesis in response to PGE2. EP receptor antagonists SC-19220, AH-6809, and AH-23848B, having highest affinity for EP1, EP1/EP2/DP, and EP4 receptors, respectively, variably inhibited migration of metastatic breast cancer cells. An autocrine PGE2-mediated migratory activity of these cells appeared to be associated predominantly with EP4 receptor-mediated signaling pathway, which uses cAMP as a second messenger. This conclusion is based on several observations: (1) selective EP4 antagonist AH-23848B effectively inhibited migration of both C3L5 and MDA-MB-231 cells in a dose-dependent manner; (2) exogenous PGE2 and EP4 agonist PGE1 alcohol increased migration of C3L5 cells; (3) forskolin, a potent activator of adenylate cyclase, as well as membrane-permeable analogues of cAMP (8-bromo-cAMP, dibutyryl-cAMP) stimulated migration of C3L5 cells; and (4) Rp-cAMPS, a selective protein kinase A inhibitor, reduced migration of C3L5 cells. Migration of poorly migratory MCF-7 cells remained unaffected with either PGE2 or EP4 antagonist. These findings are relevant for designing therapeutic strategies against breast cancer metastasis.     

Prostaglandin E2 induces cyclooxygenase-2 expression in human non-pigmented ciliary epithelial cells through activation of p38 and p42/44 mitogen-activated protein kinases

Prostaglandins (PGs) have been implicated in lowering intraocular pressure (IOP). A possible role of cyclooxygenase-2 (COX-2) in this process was emphasized by findings showing impaired COX-2 expression in the non-pigmented ciliary epithelium (NPE) of patients with primary open-angle glaucoma. The present study investigates the effect of the major COX-2 product, PGE(2), on the expression of its synthesizing enzyme in human NPE cells (ODM-2). PGE(2) led to an increase of COX-2 mRNA and protein expression, whereas the expression of COX-1 remained unchanged. Upregulation of COX-2 expression by PGE(2) was accompanied by time-dependent phosphorylations of p38 mitogen-activated protein kinase (MAPK) and p42/44 MAPK, and was abrogated by inhibitors of both pathways. Moreover, PGE(2)-induced COX-2 expression was suppressed by the intracellular calcium chelator, BAPTA/AM, and the protein kinase C inhibitor bisindolylmaleimide II, whereas the protein kinase A inhibitor H-89 was inactive in this respect. Induction of COX-2 expression was also elicited by butaprost (EP(2) receptor agonist) and 11-deoxy PGE(1) (EP(2)/EP(4) receptor agonist), but not by EP(1)/EP(3) receptor agonists (17-phenyl-omega-trinor PGE(2), sulprostone). Consistent with these findings, the EP(1)/EP(2) receptor antagonist, AH-6809, and the selective EP(4) receptor antagonist, ONO-AE3-208, significantly reduced PGE(2)-induced COX-2 expression. Collectively, our results demonstrate that PGE(2) at physiologically relevant concentrations induces COX-2 expression in human NPE cells via activation of EP(2)- and EP(4) receptors and phosphorylation of p38 and p42/44 MAPKs. Positive feedback regulation of COX-2 may contribute to the production of outflow-facilitating PGs and consequently to regulation of IOP.     

Potentiation of PGE2-mediated cAMP production during neuronal differentiation of human neuroblastoma SK-N-BE(2)C cells

The prostaglandin-evoked cAMP production was studied in human neuroblastoma SK-N-BE(2)C cells during neuronal differentiation induced by all-trans retinoic acid. The incubation with 5 microM all-trans retinoic acid for 4-6 days promoted neurite outgrowth of cells. After differentiation, prostaglandin E(2) (PGE(2))-induced cAMP production was dramatically increased, whereas forskolin- and AlF-induced cAMP productions were not changed. The increase reached maximum after 4-days of incubation with all-trans retinoic acid. The differentiation caused an increase in the maximal response and a decrease in the half-maximal effective concentration of the PGE(2)-induced cAMP production. In addition, the binding of [(3)H]PGE(2) to membrane receptors was enhanced in differentiated cells. However, the order of potency of the various prostaglandins (PGE(1) = PGE(2) > PGD(2) = PGF(2alpha) = PGI(2)) in cAMP production did not change during the differentiation, suggesting that mainly E-prostanoid (EP) receptors were involved. Butaprost, an EP(2) receptor specific agonist, increased the cAMP level in a concentration dependent manner and had a similar potentiating effect on cAMP production as PGE(2) upon differentiation. Northern blot analysis using the human cDNA probes shows that the EP(2) mRNA level was about seven times higher in differentiated cells, while the dopamine beta-hydroxylase (DBH) mRNA completely disappeared. Our results, thus, suggest that elevated gene expression of the prostanoid EP(2) receptor results in an increase in the PGE(2)-evoked cAMP production in SK-N-BE(2)C cells during neuronal differentiation.     

Prostaglandin E2 regulates macrophage colony stimulating factor secretion by human bone marrow stromal cells.

Bone marrow stromal cells regulate marrow haematopoiesis by secreting growth factors such as macrophage colony stimulating factor (M-CSF) that regulates the proliferation, differentiation and several functions of cells of the mononuclear-phagocytic lineage. By using a specific ELISA we found that their constitutive secretion of M-CSF is enhanced by tumour necrosis factor-alpha (TNF-alpha). The lipid mediator prostaglandin E2 (PGE2) markedly reduces in a time- and dose-dependent manner the constitutive and TNF-alpha-induced M-CSF synthesis by bone marrow stromal cells. In contrast, other lipid mediators such as 12-HETE, 15-HETE, leukotriene B4, leukotriene C4 and lipoxin A4 have no effect. EP2/EP4 selective agonists (11-deoxy PGE1 and 1-OH PGE1) and EP2 agonist (19-OH PGE2) inhibit M-CSF synthesis by bone marrow stromal cells while an EP1/EP3 agonist (sulprostone) has no effect. Stimulation with PGE2 induces an increase of intracellular cAMP levels in bone marrow stromal cells. cAMP elevating agents (forskolin and cholera toxin) mimic the PGE2-induced inhibition of M-CSF production. In conclusion, PGE2 is a potent regulator of M-CSF production by human bone marrow stromal cells, its effects being mediated via cAMP and PGE receptor EP2/EP4 subtypes.     

Effects of mechanical strain on the function of Gap junctions in osteocytes are mediated through the prostaglandin EP2 receptor

Osteocytes embedded in the matrix of bone are thought to be mechanosensory cells that translate mechanical strain into biochemical signals that regulate bone modeling and remodeling. We have shown previously that fluid flow shear stress dramatically induces prostaglandin release and COX-2 mRNA expression in osteocyte-like MLO-Y4 cells, and that prostaglandin E2 (PGE2) released by these cells functions in an autocrine manner to regulate gap junction function and connexin 43 (Cx43) expression. Here we show that fluid flow regulates gap junctions through the PGE2 receptor EP2 activation of cAMP-dependent protein kinase A (PKA) signaling. The expression of the EP2 receptor, but not the subtypes EP1,EP3, and EP4, increased in response to fluid flow. Application of PGE2 or conditioned medium from fluid flow-treated cells to non-stressed MLO-Y4 cells increased expression of the EP2 receptor. The EP2 receptor antagonist, AH6809, suppressed the stimulatory effects of PGE2 and fluid flow-conditioned medium on the expression of the EP2 receptor, on Cx43 protein expression, and on gap junction-mediated intercellular coupling. In contrast, the EP2 receptor agonist butaprost, not the E1/E3 receptor agonist sulprostone, stimulated the expression of Cx43 and gap junction function. Fluid flow conditioned medium and PGE2 stimulated cAMP production and PKA activity suggesting that PGE2 released by mechanically stimulated cells is responsible for the activation of cAMP and PKA. The adenylate cyclase activators, forskolin and 8-bromo-cAMP, enhanced intercellular connectivity, the number of functional gap junctions, and Cx43 protein expression, whereas the PKA inhibitor, H89, inhibited the stimulatory effect of PGE2 on gap junctions. These studies suggest that the EP2 receptor mediates the effects of autocrine PGE2 on the osteocyte gap junction in response to fluid flow-induced shear stress. These data support the hypothesis that the EP2 receptor, cAMP, and PKA are critical components of the signaling cascade between mechanical strain and gap junction-mediated communication between osteocytes.     

Prostaglandin E2 down-regulation of cytochrome P-450 2B1 expression induced by phenobarbital is through EP2 receptor in rat hepatocytes

Cytochrome P-450 is an important bioactivation-detoxification system in vivo. Its expression is regulated by foreign chemicals and dietary factors, and lipids have been found to regulate its gene expression. We showed previously that prostaglandin E(2) (PGE(2)), a fatty acid metabolite, down-regulates cytochrome P-450 2B1 (CYP 2B1) expression induced by phenobarbital. The objective of the present study was to determine whether PGE(2) type 2 receptor (EP(2))-which is coupled to Gs-protein when bound by PGE(2), leading to cAMP production-is involved in this down-regulation. We also determined the possible roles of EP(2) downstream pathways in this down-regulation. We used a primary rat hepatocyte culture model in which EP(2) was shown to be present to study this question. The intracellular cAMP concentration in primary rat hepatocytes was significantly higher after treatment with 1microM PGE(2) than after treatment with 0, 0.01, or 0.1microM PGE(2). Butaprost, an EP(2) agonist, down-regulated CYP 2B1 expression in a dose-dependent manner. SQ22536, an adenylate cyclase inhibitor, reversed the down-regulation by PGE(2) as did H-89, a protein kinase A inhibitor. These results suggest that EP(2) and the downstream pathways of cAMP and protein kinase A are involved in the down-regulation of CYP 2B1 expression by PGE(2) in the presence of phenobarbital.     

Role of the prostaglandin E2/E-prostanoid 2 receptor signalling pathway in TGFβ-induced mice mesangial cell damage

The prostaglandin E2 receptor, EP2 (E-prostanoid 2), plays an important role in mice glomerular MCs (mesangial cells) damage induced by TGFβ1 (transforming growth factor-β1); however, the molecular mechanisms for this remain unknown. The present study examined the role of the EP2 signalling pathway in TGFβ1-induced MCs proliferation, ECM (extracellular matrix) accumulation and expression of PGES (prostaglandin E₂ synthase). We generated primary mice MCs. Results showed MCs proliferation promoted by TGFβ1 were increased; however, the production of cAMP and PGE₂ (prostaglandin E₂) was decreased. EP2 deficiency in these MCs augmented FN (fibronectin), Col I (collagen type I), COX2 (cyclooxygenase-2), mPGES-1 (membrane-associated prostaglandin E1), CTGF (connective tissue growth factor) and CyclinD1 expression stimulated by TGFβ1. Silencing of EP2 also strengthened TGFβ1-induced p38MAPK (mitogen-activated protein kinase), ERK1/2 (extracellular-signal-regulated kinase 1/2) and CREB1 (cAMP responsive element-binding protein 1) phosphorylation. In contrast, Adenovirus-mediated EP2 overexpression reversed the effects of EP2-siRNA (small interfering RNA). Collectively, the investigation indicates that EP2 may block p38MAPK, ERK1/2 and CREB1 phosphorylation via activation of cAMP production and stimulation of PGE₂ through EP2 receptors which prevent TGFβ1-induced MCs damage. Our findings also suggest that pharmacological targeting of EP2 receptors may provide new inroads to antagonize the damage induced by TGFβ1.     

Formation of mineralized bone nodules by rat calvarial osteoblasts decreases with donor age due to a reduction in signaling through EP(1) subtype of prostaglandin E(2) receptor.

The effects of prostaglandin E(2) (PGE(2)) on the parameters for proliferation and differentiation were studied in calvarial osteoblast-like cells isolated from rats of various ages. In cells not treated with PGE(2), it was found that mineralized bone nodule (BN) formation, alkaline phosphatase (ALP) activity, and the incorporation rate of [(3)H]thymidine into the cells sharply decreased with the age of the cell donor at 6-50 weeks and then remained at a relatively constant level up to 120 weeks. Before studying the effects of PGE(2) on these parameters, we determined the change in the levels of PGE(2) produced by the untreated cells during the culture period and found that the endogenous PGE(2) reached a maximum on the 4th day of the culture, regardless of the cell donor age, followed by a sharp decrease. The endogenous production was blocked by pretreatment with a cyclooxygenase-2 (COX-2) inhibitor, NS-398, indicating the generation of PGE(2) through a COX-2 pathway. The area of BN was effectively suppressed by NS-398 in the cells from 10- to 35-week-old rats, whereas it was enhanced in the cells from 90- to 120-week-old rats. Treatment with PGE(2 )markedly increased the BN formation and the ALP activity in the cells from 4- to 35-week-old rats (defined as young rats). By contrast, PGE(2) decreased [(3)H]thymidine incorporation into the cells from young rats. The area of BN and the ALP activity decreased significantly, whereas [(3)H]thymidine incorporation into the cells increased by 60-80% in the cells of 80- to 120-week-old rats (defined as aged rats). The stimulatory effects on the cell differentiation and the inhibitory effect on the proliferation in the cells from young rats was mimicked by an EP(1) agonist, 17-phenyl-omega-trinor PGE(2), while an EP(2)/EP(4) agonist, 11-deoxy-PGE(1) and an adenylate cyclase activator, forskolin suppressed the differentiation and enhanced the proliferation regardless of the cell donor age. PGE(2), 11-deoxy-PGE(1) and forskolin, but not 17-phenyl-omega-trinor PGE(2) increased cyclic adenosine monophosphate (cAMP) production. Generation of inositol 1, 4,5-triphosphate (IP(3)) was stimulated by 17-phenyl-omega-trinor PGE(2) or PGE(2), but not by 11-deoxy-PGE(1) or forskolin increased cAMP production in the cells from young rats. By contrast, PGE(2 )had little effect on IP(3 )generation in aged rats. From the overall results, we concluded that PGE(2) exerts stimulatory and inhibitory effects on differentiation through the EP(1)-IP(3) pathway and EP(2)/EP(4)-cAMP pathway, respectively, in the cells from young rats. The EP(1)-IP(3) pathway seems to be inactive in the cells from aged rats.     

Prostaglandin E2 enhances interleukin-8 production via EP4 receptor in human pulmonary microvascular endothelial cells

Prostaglandin E(2) (PGE(2)) is a bioactive prostanoid implicated in the inflammatory processes of acute lung injury/acute respiratory distress syndrome. This study investigated whether PGE(2) can induce production of interleukin (IL)-8, the major chemokine for neutrophil activation, from human pulmonary microvascular endothelial cells (HPMVECs). PGE(2) significantly enhanced IL-8 protein production with increases in IL-8 mRNA expression and intracellular cAMP levels. HPMVECs expressed only EP4 receptor mRNA. The PGE(2) effects were mimicked by a selective EP4 receptor agonist, ONO-AE1-329, and inhibited by a selective EP4 receptor antagonist, ONO-AE3-208, or a protein kinase A inhibitor, Rp-adenosine 3',5'-cyclic monophosphorothioate triethylamine salt. The specific agonist for EP1, EP2, or EP3 receptor did not induce IL-8 production. PGE(2)-induced IL-8 production was accompanied by p38 phosphorylation and was significantly inhibited by a p38 inhibitor, SB-203580, but not by an ERK1/2 inhibitor, U-0126, or a JNK inhibitor, SP-600125. Additionally, PGE(2) increased cyclooxygenase-2 expression with no change in constitutive cyclooxygenase-1 expression, suggesting possible involvement of an autocrine or paracrine manner. In conclusion, PGE(2) enhances IL-8 production via EP4 receptor coupled to G(s) protein in HPMVECs. Activation of the cAMP/protein kinase A pathway, followed by p38 activation, is essential for these mechanisms. Because neutrophils play a critical role in the inflammation of acute lung injury/acute respiratory distress syndrome, IL-8 released from the pulmonary microvasculature in response to PGE(2) may contribute to pathophysiology of this disease.     

PGE2 enhances cytokine-elicited nitric oxide production in mouse cortical collecting duct cells.

It has been documented that arginine vasopressin (AVP) and prostaglandin E(2) (PGE(2)) regulate water reabsorption in renal tubular cells. The present study was attempted to delineate the downstream signaling of AVP and PGE(2) in a cortical collecting duct cell line (M-1 cell). Using RT-PCR, we detected mRNA for V2 and VACM-1 but not for V1a and AII/AVP receptors of AVP. Furthermore, neither AVP nor V2 receptor agonist and antagonist alter cellular cAMP. These together with unchanged cellular Ca(2+) by AVP suggested that AVP pathway was not operating in M-1 cells. All four classical PGE(2) receptors with EP3 and EP4 as the most prominent were detected in M-1 cells. PGE(2), 11-deoxy-PGE(1) (EP2 and EP4 agonist), and 17-phenyl-trinor-PGE(2) (EP1 agonist) increased cellular concentration of cAMP. There was no effect of PGE(2) or EP1 agonist on cellular Ca(2+). These findings provide evidence of the involvement of PGE(2) cascade in M-1 cells. M-1 cells were capable of synthesizing nitric oxide (NO). Although individual cytokines did not affect NO production, a mixture of tumor necrosis factor-alpha, interleukin-1beta, and interferon-gamma elevated NO concentration to 4.5-fold of the control. Addition of PGE(2) and db-cAMP to the cytokine mixture further increased NO production to 7.0- and 9.8-fold, respectively, of that seen in non-treated cells. PGE(2) or db-cAMP alone, however, had no effect on NO production. The results of the study led us to speculate that enhanced production of cAMP via PGE(2) signaling pathway in M-1 cells could either stimulate or attenuate water reabsorption in renal tubule. While an increase in cAMP alone may enhance water reabsorption, a concomitant increase in cAMP and cytokines may inhibit water reabsorption in renal tubule.     

Cross-talk regulation between cyclic AMP production and phosphoinositide hydrolysis induced by prostaglandin E2 in osteoblast-like cells.

In cloned osteoblast-like MC3T3-E1 cells, PGE2 stimulated both cAMP accumulation and the formation of inositol trisphosphate (IP3) dose dependently. The cAMP accumulation showed the peak value at 5 min and decreased thereafter, whereas the IP3 formation reached a plateau almost within 10 min and sustained it up to 30 min. The effect of PGE2 on cAMP accumulation (EC50 was 80 nM) was more potent than that on IP3 formation (EC50 was 0.8 microM). 12-O-Tetradecanoyl-phorbol-13-acetate (TPA), a protein kinase C (PKC)-activating phorbol ester, reduced the PGE2-induced cAMP accumulation, whereas 4 alpha-phorbol 12,13-didecanoate, a PKC-nonactivating phorbol ester, had little effect on the cAMP accumulation. 1-Oleoyl-2-acetyl-glycerol, a specific activator for PKC, inhibited PGE2-induced cAMP accumulation. TPA had little effect on cAMP accumulation induced by forskolin or NaF, a GTP-binding protein activator. So, the effect of TPA is presumed to be exerted at the point between the PGE2 receptor and Gs. On the other hand, forskolin and dibutyryl cAMP had little effect on the IP3 formation stimulated by PGE2. H-7, a PKC inhibitor, enhanced the PGE2-induced cAMP accumulation in comparison with HA1004, a control for H-7. Our data suggest that PGE2 regulates cAMP production through self-induced activation of PKC. These results strongly suggest that there is an autoregulatory mechanism in PGE2 signaling, and PGE2 modulates osteoblast functions through a cross-talk interaction between cAMP production and phosphoinositide hydrolysis in osteoblast-like cells.     

Agents that raise cAMP in human T lymphocytes release an intracellular pool of calcium in the absence of inositol phosphate production

Prostaglandins (PGs) of the E series are recognized by specific receptors on T lymphocytes which lead to an increase in cAMP. The role of cAMP in modulation of T lymphocyte function is unknown. Here, we demonstrate that agents which increase cAMP in human T cells raise the intracellular free calcium concentration ([Ca2+]i). This increase in [Ca2+]i occurred following receptor stimulation with PGEs or by bypassing the receptor with the cell-permeant analog 8-(4-chlorophenylthio)-cAMP or forskolin, a direct activator of adenylyl cyclase. The calcium response to a submaximally stimulatory concentration of PGE2 was potentiated by the cAMP phosphodiesterase inhibitor isobutylmethylxanthine. A time course of cAMP production in response to PGE2 stimulation closely resembled the calcium response and suggested that the two events were coincident. The PGE2 concentrations required to achieve 50% maximum effect of cAMP production and increases in [Ca2+]i were similar, 0.07 and 0.15 microM respectively. Chelation of extracellular Ca2+ did not abolish the PGE2-stimulated Ca2+ response, suggesting that an intracellular source of calcium was sensitive to cAMP. Significant inositol phosphate production was not detected in response to PGE2 over a wide concentration range. The PGE2-induced calcium response curves were of lesser magnitude with shorter times to peak than those of a known inositol 1,4,5 trisphosphate-producing agonist, anti-CD3, suggesting distinct Ca2+ release mechanisms. However, the cAMP-releasable store appeared to be contained within the inositol trisphosphate-releasable store since no response could be seen with cAMP-elevating agents following emptying of the inositol trisphosphate-sensitive pool of Ca2+.