Philip Needleman

Identification of an enzyme in platelet microsomes which generates thromboxane A2 from prostaglandin endoperoxides

The microsomal fraction of horse and human platelets contains an enzyme which converts prostaglandin cyclic endoperoxides (PGG2 or PGH2) to a substance which is much more potent in contracting strips of rabbit aorta. This substance has the same characteristics as thromboxane A2, and can be distinguished from other products of arachidonic acid metabolism by differential bioassay.

Selective Regulation of Cellular Cyclooxygenase by Dexamethasone and Endotoxin in Mice

We have studied the effect of glucocorticoids administered in vivo on the activity and synthesis of the cyclooxygenase enzyme (COX) in mice treated with or without concurrent intravenous administration of LPS. Mouse peritoneal macrophages from LPS-treated animals showed a two to three fold increase in COX activity determined by the production of PGE2 and PGI2 after stimulation of the cells with exogenous arachidonate. Dexamethasone injected simultaneously with LPS, 12 h before killing of the animal and removal of the macrophages, completely blocked the LPS-induced increase COX activity in peritoneal macrophages. The regulation observed in COX activity by LPS and dexamethasone are due primarily to changes in COX mass as determined by immunoprecipitation of [35S]methionine endogenously labeled enzyme. In contrast, the COX present in the nonadherent cells and in renal medullary microsomes obtained from the same animals, showed no significant changes between treatments. These results indicate that LPS in vivo stimulates COX synthesis in the peritoneal macrophages but not in the kidney. The effect of dexamethasone to inhibit COX synthesis is selective to the LPS-induced enzyme.

Atriopeptins as Cardiac Hormones

P Needleman, SP Adams, BR Cole, MG Currie, DM Geller, ML Michener, CB Saper, D Atriopeptins as cardiac hormones ISSN: 1524-4563 Copyright

Endogenous nitric oxide enhances prostaglandin production in a model of renal inflammation.

The interaction between nitric oxide (NO) and cyclooxygenase (COX) was studied in a rabbit model of renal inflammation, the ureteral obstructed hydronephrotic kidney (HNK). Ex vivo perfusion of the HNK but not the control kidney (e.g., unobstructed contralateral kidney, CLK), led to a time-dependent release of nitrite (NO2-), a breakdown product of NO. Stimulation of the HNK with bradykinin (BK) evoked a time-dependent increase in prostaglandin E2 (PGE2) production. NG-monomethyl-L-arginine (L-NMMA), which blocks the activity of both constitutive and inducible nitric oxide synthase (cNOS and iNOS), aminoguanidine, a recently described selective iNOS inhibitor, dexamethasone, or cycloheximide abolished the release of NO2- and attenuated the exaggerated BK-induced PGE2 production. This supports the existence of iNOS and COX-2 in the HNK. In the CLK, BK elicited release of both NO2- and PGE2 but this did not augment with time. L-NMMA but not aminoguanidine, dexamethasone, or cycloheximide attenuated NO2- and PGE2 release indicative of the presence of constitutive but not inducible NOS or COX. The current study suggests that the endogenous release of NO from cNOS in the CLK activates a constitutive COX resulting in optimal PGE2 release by BK. In addition, in the HNK, NO release from iNOS activates the induced COX resulting in markedly increased release of proinflammatory prostaglandin. The broader implication of this study is that the cyclooxygenase isozymes are potential receptor targets for nitric oxide.

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.

Dual inhibition of nitric oxide and prostaglandin production contributes to the antiinflammatory properties of nitric oxide synthase inhibitors.

We have recently put forward the hypothesis that the dual inhibition of proinflammatory nitric oxide (NO) and prostaglandins (PG) may contribute to the antiinflammatory properties of nitric oxide synthase (NOS) inhibitors. This hypothesis was tested in the present study. A rapid inflammatory response characterized by edema, high levels of nitrites (NO2-, a breakdown product of NO), PG, and cellular infiltration into a fluid exudate was induced by the administration of carrageenan into the subcutaneous rat air pouch. The time course of the induction of inducible nitric oxide synthase (iNOS) protein in the pouch tissue was found to coincide with the production of NO2-. Dexamethasone inhibited both iNOS protein expression and NO2- synthesis in the fluid exudate (IC50 = 0.16 mg/kg). Oral administration of N-iminoethyl-L-lysine (L-NIL) or NG-nitro-L-arginine methyl ester (NO2Arg) not only blocked nitrite accumulation in the pouch fluid in a dose-dependent fashion but also attenuated the elevated release of PG. Finally, carrageenan administration produced a time-dependent increase in cellular infiltration into the pouch exudate that was inhibited by dexamethasone and NOS inhibitors. At early times, i.e., 6 h, the cellular infiltrate is composed primarily of neutrophils (98%). Pretreatment with colchicine reduced both neutrophil infiltration and leukotriene B4 accumulation in the air pouch by 98% but did not affect either NO2- or PG levels. In conclusion, the major findings of this paper are that (a) selective inhibitors of iNOS are clearly antiinflammatory agents by inhibiting not only NO but also PG and cellular infiltration and (b) that neutrophils are not responsible for high levels of NO and PG produced.

Stimulation of Prostaglandin Biosynthesis by Adenine Nucleotides: Profile of Prostaglandin Release by Perfused Organs

Prostaglandin release from various isolated perfused organs is characteristically dependent on the stimulus; thus, certain stimuli caused prostaglandin release in some organs and not in others. Adenosine triphosphate and adenosine diphosphate were potent stimulators of prostaglandin biosynthesis in the kidney, spleen, spleen fat pad, heart, liver and lung; adenosine monophosphate and adenosine were inactive. Epinephrine caused prostaglandin release from the kidney, spleen, and liver, whereas, angiotensin was agonistic in the kidney, spleen, spleen fat pad, and liver. Indomethacin abolished the release (biosynthesis) of prostaglandins from all organs by each agonist.

Modulation of keratinocyte proliferation in vitro by endogenous prostaglandin synthesis.

To understand the relationship between the proliferation of epidermis and its arachidonic acid metabolism, we studied human keratinocytes grown in vitro at confluent or nonconfluent densities. Keratinocyte cultures incubated with [14C]arachidonic acid synthesized prostaglandin (PG)E2 PGD2, PGF2 alpha, and small quantities of 6-keto-F1 alpha. Nonconfluent cultures, however, synthesized fourfold more PGE2 than did confluent cultures. When proliferation was studied using [3H]thymidine incorporation into DNA, it was found that this increased synthesis of PGE2 was accompanied by a fourfold increase in the rate of proliferation. When PGE2 synthesis was inhibited by indomethacin, the rate of proliferation of nonconfluent cultures was decreased 40%, while the rate of proliferation of confluent cultures was unchanged. Addition of 1 ng/ml of PGE2, but not PGF2 alpha, PGD2, or a stable analog of PGI2 to the indomethacin-treated nonconfluent cultures restored the initial rate of proliferation. These results suggest that PGE2 is a growth-promoting autocoid for epidermis. The synthesis of PGE2 by epidermis may be enhanced in wound healing and disease states where epidermal continuity is disrupted.

Platelet and blood vessel arachidonate metabolism and interactions.

Exogenous arachidonate addition to intact platelets, in the absence or the presence of blood vessel microsomes, results in the production of thromboxane B(2) (the stable degradation product of thromboxane A(2)) only. Prostaglandin (PG) endoperoxides are released from intact platelets only when thromboxane synthetase is inhibited. Thus, addition of exogenous arachidonate to imidazole-pretreated platelets in the presence of bovine aorta microsomes (source of prostacyclin synthetase) results predominantly in the synthesis of 6-keto-PGF(1alpha) (the stable degradation product of prostacyclin). Strips of intact aorta were removed from aspirin-treated rabbits, thus the isolated blood vessels were unable to convert endogenous or exogenous arachidonate to prostacyclin. Human platelets, with [(14)C]arachidonate-labeled phospholipids, adhered to the blood vessel segments and released some thromboxane B(2). The subsequent addition of thrombin facilitated the release of endogenous arachidonate and thromboxane, but no labeled 6-keto-PGF(1alpha) was detectable. There is therefore no direct chemical evidence of PG-endoperoxide release from human platelets during either aggregation or adhesion, which therefore precludes the possibility that blood vessels use platelet PG-endoperoxide for prostacyclin synthesis. Imidazole inhibited the thromboxane synthetase in the labeled platelets, and thereafter thrombin stimulation resulted in the release of platelet-derived, labeled PG-endoperoxides that were converted to labeled prostacyclin by the vascular prostacyclin synthetase. The latter result suggests a potential antithrombotic therapeutic benefit might be achieved using an effective thromboxane synthetase inhibitor.

Cardiac and Renal Prostaglandin I2: BIOSYNTHESIS AND BIOLOGICAL EFFECTS IN ISOLATED PERFUSED RABBIT TISSUES

Both the isolated perfused rabbit heart and kidney are capable of synthesizing prostaglandin (PG) I(2). The evidence that supports this finding includes: (a) radiochemical identification of the stable end-product of PGI(2), 6-keto-PGF(1alpha), in the venous effluent after arachidonic acid administration; (b) biological identification of the labile product in the venous effluents which causes relaxation of the bovine coronary artery assay tissue and inhibition of platelet aggregation; and (c) confirmation that arachidonic acid and its endoperoxide PGH(2), but not dihomo-gamma-linolenic acid and its endoperoxide PGH(1), serve as the precursor for the coronary vasodilator and the inhibitor of platelet aggregation. The rabbit heart and kidney are both capable of converting exogenous arachidonate into PGI(2) but the normal perfused rabbit kidney apparently primarily converts endogenous arachidonate (e.g., generated by stimulation with bradykinin, angiotensin, ATP, or ischemia) into PGE(2); while the heart converts endogenous arachidonate primarily into PGI(2). Indomethacin inhibition of the cyclo-oxygenase unmasks the continuous basal synthesis of PGI(2) by the heart, and of PGE(2) by the kidney. Cardiac PGI(2) administration causes a sharp transient reduction in coronary perfusion pressure, whereas the intracardiac injection of the PGH(2) causes an increase in coronary resistance without apparent cardiac conversion to PGI(2). The perfused heart rapidly degrades most of the exogenous endoperoxide probably into PGE(2), while exogenous PGI(2) traverses the heart without being metabolized. The coronary vasoconstriction produced by PGH(2) in the normal perfused rabbit heart suggests that the endoperoxide did not reach the PGI(2) synthetase, whereas the more lipid soluble precursor arachidonic acid (exogenous or endogenous) penetrated to the cyclooxygenase, which apparently is tightly coupled to the PGI(2) synthetase.