Modulation of human platelet adenylate cyclase by prostacyclin (PGX).

Prostacyclin (PGX) (57)-9-deoxy-6,9alpha-epoxy-delta5-PGF1alpha has been found to be a potent stimulator of cAMP accumulation in platelets than PGE1. The prostacyclin stimulation of platelet cAMP accumulation can be antagonized by the prostaglandin endoperoxide PGH2, and a PGH2-induced platelet aggregation is antagonized by prostacyclin. A model of platelet homeostasis is proposed that suggests platelet aggregation is controlled by a balance between the adenylate cyclase stimulating activity of prostacyclin, and the cAMP lowering activity of PGH2.     

Inhibition of PGE1-stimulated cAMP accumulation in human platelets by thromboxane A2

The prostaglandin endoperoxide PGH₂, HHT, HETE, thromboxane A₂, and thromboxane B₂, which are all products of arachidonic acid metabolites of human platelets, were tested for their ability to modulate platelet cyclic nucleotide levels. None of the compounds tested altered the basal level of cAMP or cGMP, and only PGH₂ and thromboxane A₂ inhibited PGE₁-stimulated cAMP accumulation. Thromboxane A₂ was found to be a more potent inhibitor of PGE₁-stimulated cAMP accumulation and inducer of platelet aggregation thatn PHG₂.     

Modulation of platelet cyclic nucleotide content by PGE1 and the prostaglandin endoperoxide PGG2.

The effects of prostaglandin E1 and prostaglandin G2, the prostaglandin endoperoxide, on platelet cyclic nucleotide concentrations were measured in platelet rich plasma (PRP), and in washed intact platelets. PGE1 was found to be a potent stimulator of platelet cAMP levels in both PRP and washed cells, and to inhibit aggregation in both systems. PGE1 did not change platelet cGMP levels in either PRP or washed cells. PGG2 which is a potent inducer of platelet aggregation, did not affect either the basal cAMP or the basal cGMP concentration. However, PGG2 was found to antagonize the increases in cAMP content in response to PGE1 in both PRP and washed platelets. The addition to our system of a cyclic nucleotide phosphodiesterase inhbitor, theophylline, did not change our findings. It is suggested that PGG2 may induce platelet aggregation by inhibiting PGE1-stimulated cAMP accumulation.     

Metabolism and effect of prostaglandin H2 in adipose tissue.

Prostaglandin H2 (PGH2) inhibited noradrenaline induced cyclic AMP accumulation in isolated rat fat cells in a dose-dependent manner. IC50 was 10-25 ng/ml both in the absence and in the presence of theophylline. The degree of inhibition produced by PGH2 increased with time of incubation. A stable PGH2 analog did not inhibit cyclic AMP accumulation. PGH2 was rapidly converted by isolated fat cells to PGD2, PGE2 and PGF2alpha' but no formation of thromboxane B2 was found either in vitro or in vivo. PGE2 was a more potent inhibitor than PGH2 of noradrenaline induced cyclic AMP accumulation. PGD2 enhanced cyclic AMP accumulation in a limited concentration interval, while PGF2alpha was essentially uneffective. Our results suggest that PGH2 is an inhibitor of cyclic AMP formation in isolated rat fat cells only after conversion to PGE2. A physiological role for PGH2 as a modulator of lipolysis is considered unlikely.     

The effect of prostaglandins on the cyclic AMP content of limb mesenchymal cells

We have been investigating the hypothesis that prostaglandins including prostaglandin E2 (PGE2) produced during the critical condensation phase of limb chondrogenesis are involved in the regulation of cartilage differentiation by acting as local modulators of cyclic AMP (cAMP) accumulation. The purpose of the present study was to determine directly whether PGE2 and other prostanoids which had previously been shown to stimulate in vitro chondrogenic differentiation do indeed elevate the cAMP content of limb mesenchymal cells, and to determine whether the ability of various prostanoids to increase cAMP production by these cells directly reflects the potencies of these same molecules in stimulating chondrogenesis. We have found that PGE2 does indeed elicit a striking elevation in the cAMP content of subridge mesenchymal cells, indicating that the cells possess adenylate cyclase-coupled receptors for this molecule. The effect of PGE2 on cAMP accumulation is potentiated by a phosphodiesterase inhibitor, thus paralleling the potentiating effect phosphodiesterase inhibitors have on PGE2-stimulated in vitro chondrogenesis. The effect of PGE2 on cAMP content is dose-dependent with a 3-fold increase seen at 10(-8)M, which is the lowest concentration at which PGE2 effectively stimulates chondrogenesis. PGE1, which is just as effective as PGE2 in stimulating chondrogenesis, is just as effective as PGE2 in stimulating cAMP accumulation. PGA1, which is a much less effective stimulator of chondrogenesis than PGE2 or PGE1, is less than half as potent as these molecules in elevating cAMP levels. PGF1 alpha, 6-keto PGF1 alpha, and thromboxane B2, which have little or no effect on chondrogenesis, have little or no effect on cAMP content.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activation of protein kinase C inhibits prostaglandin- and potentiates adenosine receptor-stimulated accumulation of cyclic AMP in a human T-cell leukemia line

Accumulation of cAMP in the human T-cell leukemia cell line Jurkat was stimulated by the adenosine analogue 5'-N-ethylcarboxamidoadenosine (NECA) and by prostaglandin E2 (PGE2). Addition of two phorbol esters, PDiBu and TPA, markedly enhanced the NECA-stimulated accumulation of cAMP whereas the PGE2-stimulated cAMP accumulation was substantially reduced. The non-tumor-promoting phorbol ester, 4 alpha-PDD, had no effect on either NECA- or PGE2-stimulated cAMP accumulation. The ability of PDiBu to inhibit the effect of PGE2 and to stimulate the effect of NECA remained in the presence a low concentration of forskolin (0.3 microM), which per se increased both NECA- and PGE2-stimulated cAMP accumulation. Our results suggest that the effect of PK-C-activating drugs on receptor-mediated cAMP accumulation is entirely dependent on which receptor is being stimulated.     

Manipulation of platelet aggregation by prostaglandins and their fatty acid precursors: pharmacological basis for a therapeutic approach

Addition of the one-, two- or three- series endoperoxide to human platelet-rich plasma tend to suppress aggregation, through the action of their respective non-enzymatic breakdown products PGE1, PGD2, or PGD3 all of which elevate cyclic AMP levels. On the other hand, these stable primary products do not arise in appreciable amounts from intrinsic endoperoxides generated from either endogenous or exogenous free fatty acids. 5,8,11,14,17-Eicosapentaenoic acid (EPA) suppresses arachidonic acid (5,8,11,14-eicosatetraenoic acid) conversion by cyclooxygenase (as well as lipoxygenase) to aggregatory metabolites in platelets. Exogenously added EPA was capable of inhibiting PRP aggregation induced either by exogenous or endogenous (released by ADP or collagen) arachidonate. The hypothetical combination of an EPA-rich diet and a thromboxane synthetase inhibitor might abolish production of the pro-aggregatory species, thromboxane A2, and enhance formation of the anti-aggregatory metabolite, prostacyclin. Whereas EPA is not detectably metabolized by platelets, dihomo-gamma-linolenic acid (8,11,14-eicosatrienoic acid) is primarily converted by cyclooxygenase and thromboxane synthetase into the inactive metabolite, 12-hydroxyheptadecadienoic (HHD) acid. Pretreatment of human platelet suspensions with the thromboxane synthetase inhibitor imidazole unmasks the aggregatory property of PGH1 and DLL which was partially compromised by the PGE1 formed. The combination of the thromboxane synthetase inhibitor and an adenylate cyclase inhibitor unmasks a complete irreversible aggregation by DLL or PGH1. The basis of a dietary strategy that replaces AA with DLL must rely on the production by the platelet of an inactive metabolite (HHD) rather than thromboxane A2.     

Prostacyclin stimulation of dog arterial cyclic AMP levels.

Prostacyclin (PGI2) dose-dependently increases the adenosine 3',5'-cyclic monophosphate (cyclic AMP) levels in canine femoral, carotid, and canine and bovine coronary arteries. The prostacyclin-stimulation is enhanced by phosphodiesterase inhibitors, and is readily measurable after 60 sec incubation. The prostaglandin endoperoxide PGH2, but not PGH1, also elevates cAMP levels in femoral arteries. Inhibition of arterial prostacyclin synthetase with 28 microM 9,11-azoprosta-5,13-dienoic acid (azo analog I) blocks the PGH2-stimulation of cAMP accumulation. Azo analog I does not attenuate a direct PGI2 stimulation, indicating that the PGH2 dependent elevation of cAMP is due to conversion of PGH2 to PGI2 by the artery. PGI2 and PGE1 increase cyclic AMP levels and relax dog femoral and bovine coronary arteries, while PGE2, which actually contracts bovine coronary arteries, has no effect on arterial cyclic AMP levels. The significance of the PGI2-stimulation of arterial cyclic AMP is not known, but it is probably related to relaxation of arterial strips.     

Interleukin 1 stimulates prostaglandin synthesis and cyclic AMP accumulation in Swiss 3T3 fibroblasts: interactions between two second messenger systems

Biochemical events elicited by interleukin 1 (IL-1) were studied in Swiss 3T3 fibroblasts. One hour after its addition, IL-1 stimulated synthesis of prostaglandin E2 (PGE2), which continued to accumulate for 4 days. IL-1 also stimulated cAMP accumulation. Indomethacin blocked cAMP accumulation in response to IL-1, suggesting that PGE2 was responsible for the increase. Addition of exogenous PGE2 to indomethacin-treated cells restored cAMP accumulation. IL-1 enhanced thymidine incorporation, and indomethacin attenuated responses to lower concentrations. Thus, PGE2 appeared to play a role in the ability of low concentrations of IL-1 to stimulate thymidine incorporation. PGE2 augmented thymidine incorporation by increasing cAMP accumulation because in the presence of indomethacin addition of exogenous cAMP enhanced thymidine incorporation in response to low concentrations of IL-1. Elevated cAMP further stimulated PGE2 synthesis. Thus, PGE2 and cAMP interacted to potentiate their mutual accumulation. In summary, IL-1 stimulates PGE2 synthesis. PGE2, in turn, stimulates cAMP accumulation which potentiates IL-1-stimulated PGE2 synthesis and thymidine incorporation.     

Inhibition of ADP-induced platelet aggregation by reduced factor Xa

Treatment of blood coagulation factor Xa with insolubilized hexyl-agarose derivative of prostaglandin E1 (PGE1) results in the generation of two sulfhydryl groups in the protein molecule. The reduced factor Xa was found to be a potent inhibitor of platelet aggregation and thromboxane A2 synthesis induced by ADP. In contrast to the inhibition of thromboxane formation, the reduced factor Xa had no effect on the formation of PGE2 indicating that thromboxane synthetase might be selectively inhibited by the reduced factor Xa. Incubation with oxidized glutathione reversed the inhibitory activity of factor Xa previously exposed to the insolubilized hormone. Soluble PGE1 also reduces factor Xa, but more slowly than the insolubilized PGE1. PGE1 also exhibits reducing ability as tested with redox dyes. Reduction of factor Xa by dithiothreitol also transformed the coagulation factor into an inhibitor of platelet aggregation and thromboxane A2 formation. These experiments indicate that reduction of factor Xa leads to a reversible alteration of the molecule which inhibits platelet aggregation induced by ADP. This effect of reduced factor Xa is probably mediated through the inhibition of thromboxane A2 synthesis.     

The effects of prostaglandins on secretion of glucagon and insulin by the perfused rat pancreas.

The secretion of both glucagon and insulin by the isolated perfused rat pancreas was significantly stimulated by 10(-7) M PGH2. Experiments to show that the stimulated secretion was mediated by conversion of PGH2 to TXA2 or TXB2 revealed no correlation between the amount of secretion and the amount of thromboxane formed. Conversion of PGH2 with a crude platelet thromboxane synthase preparation caused a progressive loss of ability to secret insulin, whereas the capacity to stimulate release of glucagon remained at about one-half the maximal level. This relatively stable and selective secretagogue action on the alpha-cells appeared to be due to the formation of PGD2 by the platelet preparation. Direct administration of PGD2 confirmed this interpretation and showed clearly that this prostaglandin is a potent secretagogue for glucagon with little activity in stimulating the release of insulin. Our results have shown high and relatively equal stimulation of secretion by alpha- and beta-cells with exogenous PGE2, PGF2 alpha, and PGH2, little or no secretion by either cell type with TXA2, TXB2, or PGI2, and a unique selective stimulatory action of PGD2 upon the alpha-cell.     

Mechanism of the inhibition of platelet aggregation produced by prostaglandin F2 alpha

The inhibition of human platelet aggregation produced by PGF2 alpha is not specific for thromboxane A2 mimetics. Aggregation waves induced by PAF and thrombin are also inhibited by PGF2 alpha (8 microM); ADP is unaffected. These effects are still seen in platelets from aspirin-treated donors and platelets desensitized to thromboxane-like agonists (e.g. 11,9-epoxymethano PGH2). In contrast the thromboxane receptor antagonist EP 045 (up to 20 microM) had no effect on primary aggregation induced by PAF, thrombin and ADP. We have previously shown that EP 045 (IC50 = 0.5 microM), but not PGF2 alpha (28 microM), displaces the specific binding of [3H] 9,11-epoxymethano PGH2 to washed human platelets. PGF2 alpha produces small increases in cAMP levels, and both this effect and the anti-aggregation are diminished by the adenyl cyclase inhibitor SQ 22536. The rise in cAMP induced by PGF2 alpha is inhibited to a greater extent by the presence of ADP than by thrombin, PAF or a thromboxane mimetic. The ability of aggregating agents to inhibit this increase correlates inversely with their sensitivity to inhibition by PGF2 alpha. We suggest that the very weak effect of PGF2 alpha on cyclic AMP production is sufficient to account for its inhibitory activity, and it is unlikely to be a competitive antagonist at the platelet thromboxane receptor as suggested by others.     

Metabolism of the endocannabinoids, 2-arachidonylglycerol and anandamide,into prostaglandin,thromboxane, and prostacyclin glycerol esters and ethanolamides

Cyclooxygenase-2 (COX-2) action on the endocannabinoids, 2-arachidonylglycerol (2-AG) and anandamide (AEA), generates prostaglandin glycerol esters (PG-G) and ethanolamides (PG-EA), respectively. The diversity of PG-Gs and PG-EAs that can be formed enzymatically following COX-2 oxygenation of endocannabinoids was examined in cellular and subcellular systems. In cellular systems, glycerol esters and ethanolamides of PGE(2), PGD(2), and PGF(2alpha) were major products of the endocannabinoid-derived COX-2 products, PGH(2)-G and PGH(2)-EA. The sequential action of purified COX-2 and thromboxane synthase on AEA and 2-AG provided thromboxane A(2) ethanolamide and glycerol ester, respectively. Similarly, bovine prostacyclin synthase catalyzed the isomerization of the intermediate endoperoxides, PGH(2)-G and PGH(2)-EA, to the corresponding prostacyclin derivatives. Quantification of the efficiency of prostaglandin and thromboxane synthase-directed endoperoxide isomerization demonstrated that PGE, PGD, and PGI synthases catalyze the isomerization of PGH(2)-G at rates approaching those observed with PGH(2). In contrast, thromboxane synthase was far more efficient at catalyzing PGH(2) isomerization than at catalyzing the isomerization of PGH(2)-G. These results define the in vitro diversity of endocannabinoid-derived prostanoids and will permit focused investigations into their production and potential biological actions in vivo.     

Acetyl glycerylphosphorylcholine inhibition of prostaglandin I2-stimulated adenosine 3',5'-cyclic monophosphate levels in human platelets. Evidence for thromboxane A2 dependence

Previous studies with AGEPC (1-O-hexadecyl/octadecyl-2-acetyl-sn-glyceryl-3-phosphorylcholine) stress the independence of the proaggregatory activity of AGEPC from the platelet cyclooxygenase. However, our dose response analyses in human platelet-rich plasma show distinct primary and secondary waves of aggregation in response to AGEPC. Second wave aggregation is inhibited completely by either 10 micro M indomethacin, a cyclooxygenase inhibitor, or 5.6 micro M 9,11-azoprosta-5,13-dienoic acid, a thromboxane A2 synthetase inhibitor. Simultaneous addition of AGEPC and prostaglandin I2 to platelet-rich plasma results in a marked increase in platelet cyclic AMP, which is not different from the prostaglandin I2 response alone. However, if prostaglandin I2 is added to AGEPC-stimulated platelets at a point where secondary aggregation is just beginning, AGEPC can attenuate prostaglandin I2-stimulated cyclic AMP accumulation. The inhibition by AGEPC is blocked by either cyclooxygenase or thromboxane A2 synthetase inhibitors, and radioimmunoassay of thromboxane B2 confirmed that the inhibition of prostaglandin I2-stimulated cyclic AMP accumulation is due to thromboxane A2 synthesis, and that AGEPC-stimulated secondary aggregation does not start until thromboxane A2 is synthesized. These data suggest that much of the bioactivity of AGEPC is attributable to thromboxane A2.     

Phosphatidic acid inhibition of PGE1-stimulated cAMP accumulation in WI-38 fibroblasts: similarities with carbachol inhibition

To test the hypothesis that phosphatidic acid (PhA) is involved in the carbachol inhibition of hormone stimulated accumulation of cAMP we observed the effects of PhA on PGE1-stimulation of cAMP in WI-38 fibroblasts. PhA inhibited PGE1-stimulated cAMP accumulation of WI-38 fibroblasts; maximum inhibition (approximately 50-80%) occurred at a PhA concentration of 1.0 microM and significant inhibition was observed with a concentration of 0.1 microM. The full effects of PhA were evident within 15 sec after the co-addition of PGE1 and PhA. Addition of PhA to cells which had been pre-stimulated with PGE1 resulted in the rapid decay of cAMP levels to a new steady state level with a t 1/2 of approximately 65 sec. The inhibition produced by PhA did not appear to be simply attributable to a depolarization or increased intracellular Ca2+, since addition of either KCl or the Ca2+ ionophore A23187 did not lower PGE1-stimulated cAMP accumulation. When intact cells were pretreated with PhA then lysed and adenylate cyclase immediately assayed, no detectable changes in broken cell adenylate cyclase activities were observed. Also, PhA added directly to adenylate cyclase assays at concentrations as high as 100 microM produced no detectable inhibition of the membrane fraction adenylate cyclase activities. Nonetheless, our results suggest that adenylate cyclase activity in intact cells may be directly affected by physiological levels of PhA . Further, the similarities of carbachol [Butcher, R. W., Journal of Cyclic Nucleotide Research, 4:411 (1978)] and PhA inhibition support the hypothesis that carbachol (acetylcholine) exerts its effect on adenylate cyclase through alterations of the plasma membrane phospholipid composition.     

In SHR aorta, calcium ionophore A-23187 releases prostacyclin and thromboxane A2 as endothelium-derived contracting factors

In mature spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY), acetylcholine and the calcium ionophore A-23187 release endothelium-derived contracting factors (EDCFs), cyclooxygenase derivatives that activate thromboxane-endoperoxide (TP) receptors on vascular smooth muscle. The EDCFs released by acetylcholine are most likely prostacyclin and prostaglandin (PG)H(2), whereas those released by A-23187 remain to be identified. Isometric tension and the release of PGs were measured in rings of isolated aortas of WKY and SHR. A-23187 evoked the endothelium-dependent release of prostacyclin, thromboxane A(2), PGF(2alpha), PGE(2), and possibly PGH(2) (PGI(2) > thromboxane A(2) = PGF(2alpha) = PGE(2)). In SHR aortas, the release of prostacyclin and thromboxane A(2) was significantly larger in response to A-23187 than to acetylcholine. In response to the calcium ionophore, the release of thromboxane A(2) was significantly larger in aortas of SHR than in those of WKY. In both strains of rat, the inhibition of cyclooxygenase-1 prevented the release of PGs and the occurrence of endothelium-dependent contractions. Dazoxiben, the thromboxane synthase inhibitor, abolished the A-23187-dependent production of thromboxane A(2) and inhibited by approximately one-half the endothelium-dependent contractions. U-51605, an inhibitor of PGI synthase, reduced the release of prostacyclin elicited by A-23187 but induced a parallel increase in the production of PGE(2) and PGF(2alpha), suggestive of a PGH(2) spillover, which was associated with the enhancement of the endothelium-dependent contractions. These results indicate that in the aorta of SHR and WKY, the endothelium-dependent contractions elicited by A-23187 involve the release of thromboxane A(2) and prostacyclin with a most likely concomitant contribution of PGH(2).     

Inhibition of prostaglandin biosynthesis by SQ 28,852, a 7-oxabicyclo[2.2.1]heptane analog

7-Oxabicyclo[2.2.1]heptane analogs of prostaglandin (PG) H2 can act as thromboxane (Tx) A2 receptor antagonists or agonists, PGI2 and/or PGD2 receptor agonists, or exhibit a mixture of the above activities. SQ 28,852, a new analog with a hexyloxymethyl omega side chain, is a potent inhibitor of PG synthesis. SQ 28,852 inhibited collagen and arachidonic acid (AA)-induced platelet aggregation and TxB2 and PGE2 formation, but did not block platelet aggregation induced by ADP or the TxA2 mimics, 9,11-azo PGH2, SQ 26,655, and U-46,619. It also blocked conversion of AA to TxB2, PGE2, and 6-keto PGF1 alpha by microsomal preparations of human platelets, bovine seminal vesicles, and bovine aortas, respectively, but did not inhibit the conversion of PGH2 to TxA2 by the platelet microsomal preparation. SQ 28,852 (p.o.) protected mice against the lethal effects of AA (75 mg/kg, i.v.). The I50 values for SQ 28,852, indomethacin and aspirin were 0.025, 0.05 and 15 mg/kg, respectively. Neither SQ 28,852 nor indomethacin protected mice from death caused by 9,11-azo PGH2. SQ 28,852 (0.01 to 1 mg/kg, i.v.) inhibited AA-induced bronchoconstriction in anesthetized guinea pigs for at least 60 min. As an inhibitor of AA-induced bronchoconstriction, SQ 28,852 was 16- and 45-times more potent than indomethacin at 3 and 60 min after i.v. administration, respectively. SQ 28,852 did not inhibit bronchoconstriction induced by histamine or 9,11-azo PGH2, indicating its specificity of action in vivo. SQ 28,852 is the first example of a new class of cyclooxygenase inhibitors whose structure is similar to that of the naturally occurring endoperoxide, PGH2.     

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.     

A common binding site for primary prostanoids in vascular smooth muscles: a definitive discrimination of the binding for thromboxane A2/prostaglandin H2 receptor agonist from its antagonist

Differences in binding characteristics between agonists and antagonists for the thromboxane A2/prostaglandin H2 (TXA2/PGH2) receptor were examined in rat cultured vascular smooth muscle cells (VSMC). Scatchard analysis indicated the existence of two binding sites for the TXA2/PGH2 agonist, whereas a single class of recognition sites for the receptor antagonists were observed with approximately the same maximum binding capacity (Bmax) as a high-affinity binding site of the agonist. Weak binding inhibition by approx. 100 nM of primary prostanoids (PGE1, PGF2 alpha and PGD2) was detected only with the TXA2/PGH2 agonist, and not with the antagonist. Primary prostanoids as well as TXA2/PGH2 agonists (U46619 and STA2) suppressed the [3H]PGF2 alpha and [3H]PGE1 binding with almost the same potency, whereas TXA2/PGH2 antagonists (S-145, SQ29,548 and ONO3708) did not. The Bmax value of the binding sites was roughly identical in PGF2 alpha, PGE1 and a low-affinity binding site of U46619. These results suggest the existence of two binding sites for TXA2/PGH2 in VSMC, i.e., a high-affinity binding site corresponding to that of the TXA2/PGH2 antagonists and a low-affinity binding site in common with primary prostanoids.     

Imidazole: a selective inhibitor of thromboxane synthetase

Imidazole inhibits the enzymic conversion of the endoperoxides (PGG2 and PGH2) to thromboxane A2 by platelet microsomes (IC50: 22 MICRONG/ML; DETERMINED BY BIOASSAY). The inhibitor is selective, for prostaglandin cyclo-oxygenase is only affected at high doses. Radiochemical data confirms that imidazole blocks the formation of 14C-thromboxane B2 from 14C-PGH2. Several imidazole analogues and other substances were tested but only 1-methyl-imidazole was more potent than imidazole itself. The use of imidazole to inhibit thromboxane formation could help to elucidate the role of thromboxanes in physiology or pathophysiology.