Arterial walls generate from prostaglandin endoperoxides a substance (prostaglandin X) which relaxes strips of mesenteric and coeliac arteries and inhibits platelet aggregation

Fresh arterial tissue generates an unstable substance (prostaglandin X) which relaxes vascular smooth muscle and potently inhibits platelet aggregation. The release of prostaglandin (PG) X can be stimulated by incubation with arachidonic acid or prostaglandin endoperoxides PGG₂ or PGH₂. The basal release of PGX or the release stimulated with arachidonic acid can be inhibited by previous treatment with indomethacin or by washing the tissue with a solution containing indomethacin. The formation of PGX from prostaglandin endoperoxides PGG₂ or PGH₂ is not inhibited by indomethacin. 15-hydro-peroxy arachidonic acid (15-HPAA) inhibits the basal release of PGX as well as the release stimulated by arachidonic acid or prostaglandin endoperoxides (PGG₂ or PGH₂). Fresh arterial tissue obtained from control or indomethacin treated rabbits, when incubated with platelet rich plasma (PRP) generates PGX. This generation is inhibited by treating the tissue with 15-HPAA. A biochemical interaction between platelets and vessel wall is postulated by which platelets feed the vessel wall with prostaglandin endoperoxides which are utilized to form PGX. Formation of PGX could be the underlying mechanism which actively prevents, under normal conditions, the accumulation of platelets on the vessel wall.     

Arterial walls are protected against deposition of platelet thrombi by a substance (prostaglandin X) which they make from prostaglandin endoperoxides

Prostaglandin (PG) endoperoxides (PGG₂ and PGH₂) contract arterial smooth muscle and cause platelet aggregation. Microsomes from pig aorta, pig mesenteric arteries, rabbit aorta and rat stomach fundus enzymically transform PG endoperoxides to an unstable product (PGX) which relaxes arterial strips and prevents platelet aggregation. Microsomes from rat stomach corpus, rat liver, rabbit lungs, rabbit spleen, rabbit brain, rabbit kidney medulla, ram seminal vesicles as well as particulate fractions of rat skin homogenates transform PG endoperoxides to PGE- and PGF- rather than to PGX-like activity.PGX differs from the products of enzymic transformation of prostaglandin endoperoxides so far identified, including PGE₂, F_2α, D₂, thromboxane A₂ and their metabolites.PGX is less active in contracting rat fundic strip, chick rectum, guinea pig ileum and guinea pig trachea than are PGG₂ and PGH₂. PGX does not contract the rat colon.PGX is unstable in aqueous solution and its anti-aggregating activity disappears within 0.25 min on boiling or within 10 min at 37° C.As an inhibitor of human platelet aggregation induced $\text{in vitro}$ by arachidonic acid PGX was 30 times more potent than PGE₁. The enzymic formation of PGX is inhibited by 15-hydroperoxy arachidonic acid (IC₅₀ = 0.48 μg/ml), by spontaneously oxidised arachidonic acid (IC₅₀ <100 μg/ml) and by tranylcypromine (IC₅₀ = 160 μg/ml).We conclude that a balance between formation by arterial walls of PGX which prevents platelet aggregation and release by blood platelets of prostaglandin endoperoxides which induce aggregation is of the utmost importance for the control of thrombus formation in vessels.     

Effects of all CIS-5, 8,11,14,17 eicosapentaenoic acid and PGH3 on platelet aggregation

In human platelet-rich plasma (PRP) eicosapentaenoic acid (EPA) inhibited platelet aggregation induced by a stable analogue of PGH₂ (U46619), arachidonic acid, collagen or ADP. EPA was more potent than oleic, linoleic, α-linolenic or γ-linolenic acids. In aspirin-treated platelets, aggregation induced by U46619 was inhibited to a similar extent by arachidonic acid or by EPA over a range of concentrations of 0.05–0.3 mM. EPA incubated with PRP did not induce the generation of a thromboxane (TXA)-like activity; indeed it prevented the formation of TXA₂ induced by arachidonic acid or by collagen. The anti-aggregatory activity of EPA was not influenced by inhibitors of cyclo-oxygenase and lipoxygenase. The anti-aggregatory action of EPA may be caused by a rapid occupancy by EPA of TXA₂/PGH₂ “receptors” on platelet membrane as well as by a slower displacement of arachidonic acid from platelet phospholipids by chemically unchanged molecules of EPA.Not all samples of PRP were irreversibly aggregated by PGH₂, but in those that were, PGH₃ also induced an immediate dose-dependent but reversible aggregation. After a 4 min incubation of non-aggregating doses of PGH₂ or PGH₃ (100–300 nM) with PRP a stable anti-aggregatory compound was detected. The inhibitory activity produced from PGH₃ was apparently more potent (ca 10 times) than that obtained from PGH₂. The anti-aggregating compounds were identified by TLC and GLC-MS as PGD₂ and PGD₃. The apparent difference of potency between PGD₂ and PGD₃ was attributed to the concurrent production of PGE₂ and PGE₃. PGE₂ prevented the inhibitory effect of PGD₂ whereas PGE₃ did not affect the activity of PGD₃.It is concluded that one of the reasons for the low incidence of myocardial infarction in Eskimos could be that the pro-aggregatory arachidonic acid is replaced in their phospholipids by the anti-aggregatory EPA.     

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.     

Some biological effects of prostaglandin endoperoxide analogs.

The effects of two methano-epoxy analogs of the prostaglandin endoperoxides PGG₂ and PGH₂ were tested on human platelets and rabbit aorta strips. One of these analogs, 9α, 11α-methano-epoxy-15- hydroxy-prosta-5, 13-dienoic acid, was 3.7 times more potent than the endoperoxide, PGG₂, as aggregating agent and was 6.2 times more active than PGH₂ in eliciting contractions of the isolated rabbit aorta. The analog initiated the platelet release reaction, but was less active than the endoperoxide in this respect. Furthermore, the release of ¹⁴C-serotonin induced by this analog was inhibited by indomethacin, which indicated that generation of endoperoxide was required.The corresponding 9α, 11α, epoxy-methano-analog was less active than the 9α, 11α, methano-epoxy analog in the test systems employed.     

Prostaglandin endoperoxides IV. Effects on smooth muscle

The effect on smooth muscle of the endoperoxides PGG₂ and PGH₂, which are intermediates in prostaglandin biosynthesis, was studied in different systems $\text{in vitro}$ and $\text{in vivo}$. On gastrointestinal smooth muscle (gerbil colon, rat stomach) PGG₂ and PGH₂ produced contractions comparable to those of PGE₂ and PGF_2a whereas contractions elicited on vascular (rabbit aorta) and airway (guinea-pig trachea) smooth muscle were considerably greater than those of PGE₂ and PGF_2a respectively. On intravenous injection into guinea-pigs PGG₂ and PGH₂ caused a triphasic change in blood pressure and were 8–10 times more effective than PGF_2a in producing an increase in tracheal insufflation pressure. When given as aerosols the unstable endoperoxides were less effective than PGF_2a. It is concluded that the endoperoxides are potent smooth muscle stimulants and that they are more effective than their degradation products (PGD₂, PGE₂, PGF_2a) in some systems.     

Cyclic AMP inhibits synthesis of prostaglandin endoperoxide (PGG2) in human platelets.

Dibutyryl-cAMP but not dibutyryl-cGMP inhibited platelet aggregation and release of ¹⁴C-serotonin and ADP when induced by collagen and arachidonate but not when induced by the endoperoxide PGG₂^* (TXB₂) induced by addition of collagen to platelet rich plasma (PRP) was decreased by dibutyryl-cAMP and agents known to increase the concentration of cAMP (PGE₁, PGD₂, theophylline and acetyl choline).PGE₂ in concentrations known to decrease cAMP levels increased the formation of TXB₂ whereas concentrations of PGE₂ known to increase cAMP levels decreased the amount of TXB₂ formed. That this was due to an effect on the cyclooxygenase was indicated by inhibition of the transformation of arachidonic acid by DB-cAMP and by high concentrations of PGE₂. Additional support for regulation of the cyclo-oxygenase by cAMP and its relevance to platelet aggregation was obtained by demonstrating stimulation of PGG₂ induced aggregation by low concentrations of PGE₂ and the absence of this effect in the presence of a cyclo-oxygenase inhibitor.     

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/rr 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-azoPGH₂, SQ 26,655, and U-46,619. It also blocked conversion of AA to TxB₂, PGE₂, and 6-ketoPGF₁α 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-azoPGH₂. 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 brochoconstriction induced by histamine or 9.11-azoPGH₂, indicating its specificity of action . 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.     

α-Adrenergic stimulants, prostaglandins and catecholamine release from the adrenal gland in vitro

Prostaglandin D₂ was found to be a potent inhibitor of platelet aggregation. Aggregation of human platelets by ADP, collagen and prostaglandin G₂ was inhibited more strongly by PGD₂ than by PGE₁. Although ADP-induced aggregation of rabbit platelets was inhibited more strongly by PGE₁ than by PGD₂ the latter prostaglandin gave a more long-lasting inhibitory effect on platelet aggregation following intravenous or oral administration. These results coupled with the finding that PGD₂ has less hypotensive effects on the cardiovascular system than PGE₁ suggest the possible use of PGD₂ as an antithrombotic agent.     

Prostaglandin D2 as a potential antithrombotic agent

Prostaglandin D₂ was found to be a potent inhibitor of platelet aggregation. Aggregation of human platelets by ADP, collagen and prostaglandin G₂ was inhibited more strongly by PGD₂ than by PGE₁. Although ADP-induced aggregation of rabbit platelets was inhibited more strongly by PGE₁ than by PGD₂ the latter prostaglandin gave a more long-lasting inhibitory effect on platelet aggregation following intravenous or oral administration. These results coupled with the finding that PGD₂ has less hypotensive effects on the cardiovascular system than PGE₁ suggest the possible use of PGD₂ as an antithrombotic agent.     

1-Arachidonyl-monoglyceride causes platelet aggregation: Indirect evidence for an acylglycerol acylhydrolase involvement in the release of arachidonic acid for prostaglandin synthesis

Phosphatidylcholine liposomes containing 1-arachidonylmonoglyceride were found to cause aggregation of human platelets. In contrast, addition of phosphatidylcholine liposomes, 1-arachidonyl-monoglyceride, or phosphatidylcholine liposomes containing 1-oleoyl-monoglyceride to a similar platelet preparation had no effect. Aggregation stimulated by 1-arachidonyl-monoglyceride was inhibited by 100 μM aspirin or 1 μM indomethacin, suggesting that the arachidonic acid is first released by a platelet acylglycerol acylhydrolase and then converted to PGG₂ and thromboxane AZ which initiate the platelet aggregation. Changes in platelet morphology in response to 1-arachidonyl-monoglyceride were similar to those reported previously to occur following stimulation of platelets by arachidonic acid or PGGZ providing further support for this concept. EDTA inhibited aggregation of platelets but not shape change or granule centralization in response to 1-arachidonyl-monoglyceride. PGE, and theophylline inhibited both aggregation and morphological changes. These results with inhibitors are similar to the effects of these inhibitors on PGGZ and provide further evidence for similarity between the action of 1-arachidonyl-monoglyceride and PGG₂. The results provide important evidence to support the concept that an acylglycerol acylhydrolase may be involved in arachidonic acid release and platelet aggregation.     

Reaction mechanism of prostaglandin E2 biosynthesis and its modeling

The reaction mechanism of PGE₂ biosynthesis was investigated by a detailed examination of the cyclo-oxygenase and PGE₂-isomerase activities in acetone-pentane powder (microsomal fraction of ram seminal vesicular glands). Two main types of inactivating process were recognized in the reaction system. One type was due to irreversible inactivation caused by the oxidizing agent [O]^·_X released through the reduction of PGG₂ to PGH₂, while the other type was due to reversible inhibition which was supposed to be derived from the precursor arachidonic acid (AA). This inhibitor was found to block the activities of both cyclooxygenase and PGE₂-isomerase, and to compete with the substrates AA and PGH₂. Although no significant substrate inhibition was observed, arachidonic acid was slightly inhibitory toward PGE₂-isomerase.     

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 supress 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 cycloogygenase (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-γ-linolenic acid (8,11,14,-eicosatrienoic acid) is primariley 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.     

Cyclic AMP and platelet prostaglandin synthesis

The present study has investigated the influence of agents which elevate intracellular levels of endogenous platelet adenosine 3′5′-cyclic monophosphate (cyclic AMP), and the effect of the exogenous cyclic AMP analog, dibutyryl cyclic AMP, on the conversion of ¹⁴C-arachidonic acid by washed platelets. Prostaglandin E₁ (PGE₁), PGE₁ with theophylline, or dibutyryl cyclic AMP incubated with washed platelets prevented arachidonic acid induced platelet aggregation, but had no effect on the conversion of arachidonic acid to 12L-hydroxy-5,8,10, 14-eicosatetraenoic acid (HETE), 12L-hydroxy-5,8,10 heptadecatrienoic acid (HHT), or thromboxane B₂. Ultrastructural studies of the platelet response revealed that agents acting directly or indirectly to increase the level of cyclic AMP inhibited the action of arachidonic acid on washed platelets and prevented internal platelet contraction as well as aggregation. The influence of PGE₁ with theophylline, and dibutyryl cyclic AMP on the thrombin induced release of ¹⁴C-arachidonic acid from platelet membrane phospholipids was also investigated. These agents were found to be potent inhibitors of the thrombin stimulated release of arachidonic acid from platelet phospholipids, due most likely to an inhibition of platelet phospholipase A activity. The results show that dibutyryl cyclic AMP and agents which elevate intracellular cyclic AMP levels act to inhibit platelet activation at two steps 1) internal contraction and 2) release of arachidonic acid from platelet phospholipids.     

Metabolism and action of the prostaglandin endoperoxide PGH2 in rat kidney

Kidney membrane fractions metabolized [1-¹⁴C]PGH₂ to TXB₂, PGE₂, PGF_2α, PGD₂, 6-keto PGF_1α, and HHT. TXA₂, as measured by TXB₂, was enzymatically formed in cortex microsomes and was identified by thin layer chromatography and gas chromatography - mass spectrometry. PGH₂ caused a labile inhibition of cortical PGE₂-stimulated adenylate cyclase. PGE₂, PGF_2α, and PGD₂ are stimulators of cortical adenylate cyclase. The inability of two thromboxane synthetase inhibitors, imidazole and 9,11-azoprosta-5,13 dienoic acid, to block PGH₂ inhibition suggested that TXA₂ was not an obligatory intermediate in this process. Therefore, a potential function of cortical PGH₂ is inhibition of adenylate cyclase.     

PGE2 secretion from organ cultured gastric mucosa: Correlation with cyclooxygenase activity and endogenous substrate release

In gastrointestinal research the in vitro release of prostaglandins from incubated or cultured biopsies is a widely used method to estimate prostaglandin synthesis. We therefore investigated the rate limiting mechanisms of PGE₂ release in organ cultured gastric mucosa of the rabbit, determining PGE₂ secretion from organ cultured mucosal biopsies by radioimmunoassay and prostaglandin synthesizing capacity by in vitro incubation of mucosal homogenate or microsomes with [¹⁴C]-arachidonic acid.Freshly taken biopsies secreted PGE₂ at an initial high rate, that decreased during the following 4 hrs of culture. This PGE₂ release was dose dependently reduced by inhibitors of the prostaglandin cyclooxygenase. 5mM acetylsalicylic acid (ASA) maximally suppressed PGE₂ secretion to 7% of controls, and the inhibition by ASA was quantitatively similar at every given culture period. PGE₂ release was markedly increased by carbenoxolone but was only slightly activated by extracellular calcium and the Ca⁺⁺-ionophore A23187. However, Ca⁺⁺/A23187 were unable to maintain PGE₂ secretion at the initial rate.PGE₂ secretion was undisturbed in calcium-free medium but was reduced to 50–60% of controls by excess EDTA. The intracellular calcium chelator 1,2-bis-(2-aminophenoxy)-ethane-N,N,N′,N′,-tetraacetic acid-acetoxymethyl ester (BAPTA-AM) similarly inhibited PGE₂ release to 72% of controls. In contrast, PGE₂ release was unaffected by the intracellular calcium antagonist 3,4,5-trimethylene-bis(4-formylpyridinium bromide) dioxime (TMB-8), the calmodulin antagonists N-(6-aminohexyl)-1-5-chloro-1-naphthalenesulfonamide (W-7) and calmidazolium (compound R24571) or various direct inhibitors of endogenous arachidonic acid release like tetracaine, bromophenacyl bromid, neomycine or low dose quinacrine, indicating that the reduction of PGE₂ release by EDTA or BAPTA may be mediated by mechanisms different from substrate release. In contrast, an inhibition of PGE₂ secretion by quinacrine at high concentrations (≥ 0.8mM) was attributed to a direct inhibition of the prostaglandin cyclooxygenase, similar to ASA. Finally, the reduction of the prostaglandin synthesizing capacity by ASA was strongly correlated with the inhibition of PGE₂ secretion, also at low concentrations and minor degrees of inhibition.From these data we conclude, that the activity of the prostaglandin cyclooxygenase is rate limiting for PGE₂ secretion from organ cultured mucosal biopsies rather than arachidonic acid release by a phospholipase A₂. This should be considered for interpretation of studies based on prostaglandin release from cultured mucosa.     

Influences of prostaglandins on electrophoretic mobility and aggregation of rabbit platelets

Influences of prostaglandin(PG)s on electrophoretic mobilities and aggregation of rabbit platelets were studied. The PGs studied (PGI₂, PGE₁, PGD₂, PGE₂, PGF_2α, PGA₂ and PGA₁) had no effect on platelet electrophoretic mobility. However, both PGE₁ and PGI₂ in 0.3 and 3.0 μM inhibited ADP-induced aggregation and ADP-induced decrease in the mobility. PGD₂ in 0.3 and 3.0, and PGE₂ in 30 μM inhibited the aggregation but did not depress the ADP-induced decrease in the mobility. PGF_2α, PGA₂ and PGA₁ had no effect on the decrease in electrophoretic mobility and on the aggregation caused by ADP.     

High concentrations of arachidonic acid induce platelet aggregation and serotonin release independent of prostagladin endoperoxides and thromboxane A2

We examined platelet aggregation and serotonin release, induced by less than 60 μM arachidonic acid, using washed platelet suspensions in the absense of albumin. The concentration of arachidonic acid use did not cause platelet lysis. Platelet responses induced by less than 20 μM arachidonic acid were inhibited by aspirin, whereas those induced by above 30 μM arachidonic acid were not inhibited, even by both aspirin and 5,8,11,14-eicosatetraynoic acid. Although phosphatidic acid and 1,2-diacylglcerol increased after the addition of arachidonic acid in aspirin-treated platelets, the amounts were not parallel to platelet aggregation. Oleic, linoleic and linolenic acids also induced platelet responses, while palmitic, stearic and arachidic acids did not. EDTA, dibutyryl cyclic AMP, apyrase and creatine phosphate / creatin phosphokinase brought about almost the same effects in platelet responses induced by the unsaturated fatty acids, other than arachodinic acid, as those induced by 40 μM arachodonic acid. These results suggest that the mechanism of the actions of more than 30 μM arachodinic acid on platelets is the same as that of the other unsaturated fatty acids and is independent of prostaglandin endoperoxides, thromboxane A₂ and, perhaps, phosphatidic acid and 1,2-diacylglycerol.     

Purification and Characterization of Fatty Acid Cyclooxygenase from Human Platelets

Abstract

The fatty acid cyclooxygenase (EC 1.14.99.1) that produces the prostaglandin, thromboxane, and prostacyclin precursor (PGHp), was solubilized from human platelet microsomes in 20 sucrose and 1.0% Triton X-100. The enzyme was purified 300-fold by electrofocusing, Sephadex G-200 gel filtration, and hydrophobic chromatography on ethyl agarose. The cyclooxygenase catalyzed the conversion of arachidonic acid to prostaglandin endoperioxide, PGH₂, that was trapped at ?25°C and separated on TLC at ?20°C. PGH₂ was hydrolyzed to HHT in acidic pH, or was chemically converted to PGE₂ in slightly alkaline pH in the absence of cofactors. The enzyme showed a broad pH optimum in the range of 7–9. Hemin containing substances such as methemoglobin were absolutely required as cofactors, while tryptophan, epinephrine, phenol, and hydro-quinone stimulated the PGH₂ formation. Metal ions, such as Zn²⁺ and Cd²⁺ inhibited the enzyme reaction at 0.1 to 1 mM.

The molecular weight of the purified enzyme was estimated at 79,432 by sodium dodecyl sulfate disc gel electrophoresis at pH 8.0. The properties of the human platelet enzyme was generally similar to the sheep vesicular enzyme in the method of solubilization, pH optimum, and molecular weight.     

Agonist regulation of the human platelet prostaglandin D2 receptor.

The effect of exposing platelets to prostaglandin D₂ (PGD₂) on hormone binding was studied. Incubation of platelets with PGD₂ for 2 hr resulted in a decrease in [³H]PGD₂ binding that was dose dependent. Inhibition of binding was 14% after incubation with 10^?8M PGD₂, 19% after incubation with 10^?7M PGD₂, and 40% after exposure to 10^?6M PGD₂. This decreased binding (desensitization) was specific for [³H]PGD₂ as binding to platelets by [³H]PGE₁ and the α-adrenergic antagonist [³H] dihydroergocryptine (DHEC) was comparable to control platelets. Saturation of [³]PGD₂ binding to desensitization platelets was at 27 fmole ligand/10⁸ platelets compared to 43 fmoles/10⁸ platelets in control platelets. Half-maximal saturation occured at 20 nM PGD₂ both for desensitized and control platelets, suggesting that decreased binding sites rather than altered affinity between ligand and receptor accounted for these results. These platelets had a partial increase in [³H]PGD₂ binding a few hours after plasma was washed free of PGD₂ with complete resensitization after 24 hr. Since prostaglandins such as PGI₂, PGD₂, and PGE₁ are potent inhibitors of platelet aggregation, decreased binding of platelets to these hormones after prostaglandin exposure may provide a mechanism for altered responsiveness of platelets to aggregating stimuli.