Correlation of the biosynthesis of prostaglandin and cyclic AMP in monolayer cultures of rabbit articular chondrocytes

We have utilized ionophores to test whether stimulation of chondrocyte prostaglandin biosynthesis is accompanied by an increase in cyclic nucleotide levels in these cells. Radioimmunoassay of prostaglandin E2, 6-oxo-prostaglandin F1 alpha (the stable metabolite of prostaglandin I2) and prostaglandin F2 alpha showed that synthesis of each was stimulated by the divalent-cation ionophore, A23187 after short-term incubation (1-7 min) in serum-free medium. No stimulation of thromboxane B2 was detected. Two monovalent ionophores, lasalocid and monensin failed to stimulate prostaglandin biosynthesis after short-term incubation. Ionophore A23187-stimulated prostaglandin biosynthesis was variably and partially inhibited by sodium meclofenamate, indomethacin and aspirin, but not by sodium salicylate. Ionophore A23187-stimulated prostaglandin biosynthesis was accompanied by a 7.5-fold increase in cyclic AMP levels after 15 min. Sodium meclofenamate, indomethacin and aspirin which inhibited prostaglandin E2 biosynthesis also reduced cyclic AMP levels. Exogenous prostaglandin E2 (1 microgram/ml) stimulated cyclic AMP biosynthesis, which was not inhibited by aspirin. These results indicated that prostaglandins can be considered as one of the local effectors controlling cyclic AMP production in articular cartilage.     

Indomethacin induction of metamorphosis from the asexual stage to sexual stage in the moon jellyfish, Aurelia aurita

We found while screening a chemical library that indomethacin, an inhibitor of prostaglandin biosynthesis, induced strobilation (metamorphosis from the asexual to sexual stage) in the moon jellyfish, Aurelia aurita. Indomethacin initiated strobilation in a dose-dependent manner, but was not involved in the progression of strobilation. Pharmacological experiments suggested that indomethacin could induce strobilation independently of prostaglandin biosynthesis.     

Effects of inhibitors of steroid biosynthesis on prostaglandin formation in rabbit ovarian follicles

Rabbit ovarian follicles were incubated without stimulation, with LH and with LH + an inhibitor or steroid biosynthesis. Formation of prostaglandins PGE and PGF and of progesterone and estradiol was measured in these incubates. It was found that aminoglutethimide phosphate (AGP) inhibited the LH stimulated biosynthesis of both prostaglandins and steroids. However U 30870 and Metyrapone, while completely inhibiting the LH stimulated biosynthesis of progesterone and estradiol respectively, had no effect on the formation of prostaglandins. Further, the inhibition of prostaglandin formation by AGP could not be reversed by exogenou steroids. It, therefore, appears that the effect of AGP on prostaglandin biosynthesis may not be related to its effect on steroid biosynthesis. However, the response of rabbit follicles to AGP is contrary to that reported for rat follicles and indicates different control mechanisms for prostaglandin formation in the follicles of the two species.     

Effects of inhibitors of steroid biosynthesis on prostaglandin formation in rabbit ovarian follicles

Rabbit ovarian follicles were incubated without stimulation, with LH and with LH + an inhibitor of steroid biosynthesis. Formation of prostaglandins PGE and PGF and of progesterone and estradiol was measured in these incubates. It was found that aminoglutethimide phosphate (AGP) inhibited the LH stimulated biosynthesis of both prostaglandins and steroids. However U 30870 and Metyrapone, while completely inhibiting the LH stimulated biosynthesis of progesterone and estradiol respectively, had no effect on the formation of prostaglandins. Further, the inhibition of prostaglandin formation by AGP could not be reversed by exogenous steroids. It, therefore, appears that the effect of AGP on prostaglandin biosynthesis may not be related to its effect on steroid biosynthesis. However, the response of rabbit follicles to AGP is contrary to that reported for rat follicles and indicates different control mechanisms for prostaglandin formation in the follicles of the two species.     

Nonenzymatic reduction of prostaglandin H by lipoic acid.

Lipoic acid has recently been found to stimulate prostaglandin biosynthesis by sheep vesicular gland microsomes (Marnett, L. J., and Wilcox, C. L. (1977). Biochim. Biophys. Acta 487, 222). The increase in oxygenated products is predominantly in the formation of prostaglandin F and its structure has been verified by gas chromatography-mass spectrometry. Endoperoxide trapping experiments employing reduced glutathione show that the conversion of prostaglandin H to prostaglandin F is slow in lipoate containing incubation mixtures. Therefore, the net effect of the addition of lipoic acid to vesicular gland microsomes is the stimulation of prostaglandin endoperoxide biosynthesis. Further experiments reveal that the reduction of prostaglandin H to prostaglandin F by lipoate is nonenzymatic and occurs after the termination of biosynthesis in the work-up mixture. The reduction takes place preferentially in the organic phase of a Folch extract (chloroform-methanol-2% formic acid 8:4:3). Authentic prostaglandin H2 is reduced by lipoic acid to prostaglandin F 2alpha in high yield under these conditions.     

Altered glomerular eicosanoid biosynthesis in uranyl nitrate-induced acute renal failure

The present studies were designed (1) to examine the pattern of changes in eicosanoid biosynthesis in isolated rat glomeruli, and (2) to correlate these changes with the previously observed alterations in renal perfusion and glomerular filtration rate which occur after uranyl nitrate administration, a model of toxin-induced acute renal failure. In the first part of this study, the in vitro and the in vivo effects of two cyclooxygenase inhibitors were examined for their ability to inhibit rat glomerular eicosanoid biosynthesis. Inhibition of prostaglandin E2 and prostaglandin F2 alpha generation by 1 mM aspirin in vitro was 76 and 82%, respectively. Similar inhibitions of 85 and 72% of biosynthesis of the above-mentioned lipids by 0.1 mM indomethacin were also noted. Intraperitoneal administration of aspirin (150 mg/kg) resulted in a significant inhibition of 88% or greater of prostaglandin E2, prostaglandin F2 alpha, 6-keto-prostaglandin F2 alpha, and thromboxane B2 biosynthesis. These results indicated that the expected alterations produced under in vivo conditions were detectable by in vitro techniques used in this study. 24 h after the administration of uranyl nitrate (25 mg/kg), significant increases in the biosynthesis of prostaglandin E2 (124%) and prostaglandin F2 alpha (88%) were observed when compared to the control values. No significant changes in prostacyclin or thromboxane formation were noted at this time. A further increase in the biosynthesis of prostaglandin E2 (248%), prostaglandin F2 alpha (262%), and a significant increase in prostacyclin (120%), measured as 6-keto-prostaglandin F1 alpha, were noted at 48 h. No changes in thromboxane B2 biosynthesis were noted. It is concluded that these data are consistent with the hypothesis that the increased glomerular biosynthesis of vasodilator eicosanoids (i.e., prostaglandin E2 and prostacyclin) may play a significant role in the homeostatic regulation of renal perfusion and glomerular filtration after acute toxic injury to the kidney.     

Characterization of prostaglandin formation by human amnion cells in monolayer culture

In the present investigation, we found that among the prostanoids that human amnion cells, which are maintained in monolayer culture, secrete into the culture medium, prostaglandin E2 is by far the predominant one. In the presence of inhibitors of prostaglandin synthase, the production of prostaglandin E2 by these cells is abolished. Amnion cells maintained in the presence of fetal calf serum produce greater quantities of prostaglandin E2 than do cells maintained in serumless medium. In the amnion cells, there is little or no metabolism of prostaglandin E2; this also is true of amnion tissue. The unique characteristics of prostaglandin biosynthesis and metabolism by human amnion cells in monolayer culture are identical with those of human amnion tissue. Hence, we suggest that amnion cells in culture constitute an excellent model for investigations of the regulation of prostaglandin E2 biosynthesis in this tissue.     

Effect of low and high methional concentrations on prostaglandin biosynthesis in microsomes from bovine and sheep vesicular glands.

The effect of methional on prostaglandin biosynthesis from 5,8,11,14-eicosatetraenoic acid was studied with microsomes from both bovine vesicular glands (BVG) and sheep vesicular glands (SVG). Ethylene was identified when methional was added to the fatty acid-microsome incubation systems showing that oxygen centered radicals such as hydroxyl radical were generated during incubation. A low methional level, 1 mM, enhanced the rate of prostaglandin biosynthesis in both BVG and SVG. A high methional level, 10 mM, inhibited prostaglandin biosynthesis in both BVG alone and SVG solubilized with 1% Tween 20. The inhibitory effect of 10 mM methional was reversed by lyophilization. These data suggest that oxygen centered radicals are used in prostaglandin biosynthesis even though they inactivate the enzyme complex.     

Prostaglandin biosynthesis and its regulation in the bovine endometrium: A comparison between nonpregnant and pregnant status

Prostaglandin F(2alpha) (PGF(2alpha)), an arachidonic acid metabolism product of the prostaglandin synthetase pathway, is synthesized and released from the endometrium during luteolysis in nonpregnant animals. When proper conception occurs, the synthesis and release pattern is changed to maintain the corpus luteum (CL) function. The biosynthesis of prostaglandins in the bovine endometrium was highest in the microsomes but of low order. In nonpregnancy, the formation of prostaglandins from labelled precursor acid was higher than in pregnancy. Besides the prostaglandin synthetase, an inhibiting activity on the conversion of arachidonic acid to prostaglandins was found in both the nonpregnant and pregnant endometrium. During luteolysis (Day 17), a low inhibiting capacity was seen in comparison with other days of the estrous cycle (Days 1, 4 and 14). The inhibitory capacity was very high on Days 16 to 20, 25, and 31 of pregnancy. In the nonpregnant endometrium at Day 17, a very low inhibitor potency, calculated as IC(50) values, was found both in the cytoplasma and in the microsomes, whereas during early pregnancy (Days 17, 18, and 20) both cytoplasma and microsomes possessed very high inhibitor potency. This finding indicates that the bovine endometrium contains both prostaglandin synthetase and an unknown potent inhibitor of prostaglandin biosynthesis that regulates prostaglandin biosynthesis both during the estrous cycle and early pregnancy.     

Effect of low and high methional concentrations on prostaglandin biosynthesis in microsomes from bovine and sheep vesicular glands

The effect of methional on prostaglandin biosynthesis from 5,8,11, 14-eicosatetraenoic acid was studied with microsomes from both bovine vesicular glands (BVG) and sheep vesicular glands (SVG). Ethylene was identified when methional was added to the fatty acid-microsome incubation systems showing that oxygen centered radicals such as hydroxyl radical were generated during incubation. A low methional level, 1 mM, enhanced the rate of prostaglandin biosynthesis in both BVG and SVG. A high methional level, 10 mM, inhibited prostaglandin biosynthesis in both BVG alone and SVG solubilized with 1% Tween 20. The inhibitory effect of 10 mM methional was reversed by lyophilization. These data suggest that oxygen centered radicals are used in prostaglandin biosynthesis even though they inactivate the enzyme complex.     

Stereospecificity of hydrogen abstraction in the conversion of arachidonic acid to 15R-HETE by aspirin-treated cyclooxygenase-2. Implications for the alignment of substrate in the active site

The initial and rate-limiting step in prostaglandin biosynthesis is stereoselective removal of the pro-S hydrogen from the 13-carbon of arachidonic acid. This is followed by oxygenation at C-11, formation of the five-membered ring, and a second oxygenation at C-15 to yield the endoperoxide product, prostaglandin G(2). Aspirin treatment of cyclooxygenase-2 is known to acetylate an active site serine, block prostaglandin biosynthesis, and give 15R-hydroxyeicosatetraenoic acid (15R-HETE) as the only product. 15R-HETE and prostaglandins have opposite stereoconfigurations of the 15-hydroxyl. To understand the changes that lead to 15R-HETE synthesis in aspirin-treated COX-2, we employed pro-R- and pro-S-labeled [13-(3)H]arachidonic acids to investigate the selectivity of the initial hydrogen abstraction. Remarkably, aspirin-treated COX-2 formed 15R-HETE with removal of the pro-S hydrogen at C-13 (3-9% retention of pro-S tritium label), the same stereoselectivity as in the formation of prostaglandins by native cyclooxygenase. To account for this result and the change in oxygenase specificity, we suggest that the bulky serine acetyl group forces a realignment of the omega end of the arachidonic acid carbon chain. This can rationalize abstraction of the C-13 pro-S hydrogen, the blocking of prostaglandin synthesis, and the formation of 15R-HETE as the sole enzymatic product.     

Prostaglandin biosynthesis and catabolism in the developing fetal sheep lung.

The prostaglandin biosynthetic and catabolic capacity of homogenates of lungs from fetal sheep of various gestational ages was measured. Prostaglandin biosynthesis was assayed by the deuterium-isotope dilution technique making use of mass fragmentography whereas prostaglandin catabolism was measured by the radioisotope-dilution method described previous (Pace-Asciak, C.R. and Rangaraj, G. (1976) J. Biol. Chem. 251, 3381-3385). Homogenates of lungs from fetuses of all ages tested (40 days to term) formed both prostaglandins E2 and F2alpha; although prostaglandin F2alpha was formed to a greater extent than prostaglandin E2 by the 40 days lung, prostaglandin E2 increased with increasing age until at term the ratio of both prostaglandins approached unity. Total prostaglandin biosynthesis (E2 + F2alpha) rose gradually with age (approx. 3 fold increase between 40 days and term). Prostaglandin F2alpha catabolism occurred mainly by the prostaglandin 15-hydroxy dehydrogenase pathway; this activity was detectable even at 40 days and remained unchanged up to 80 days. Prostaglandin catabolic activity rose sharply at 90 days (approx. 3 fold) with a maximum around 110 days (approx. 4 fold) decreasing back to 40 day levels by term (143 days). The increasing prostaglandin catabolic activity around 90-100 days in this species is discussed in relation to the hemodynamic changes in the lungs starting around this age and the appearance of surfactant. Prostaglandin catabolism might play an important role in the developing organ controlling steady state concentrations of prostaglandins during certain periods of organogenesis.     

Properties of prostaglandin synthetase of rabbit kidney medulla.

The formation in vitro of prostaglandins E2, D2, and F2alpha from arachidonic acid by rabbit kidney medulla homogenate or microsomal fraction is markedly affected by the composition of the incubation medium employed. Optimal biosynthesis is obtained in 0.1 M potassium phosphate buffer, with the optimum pH being 8.0--8.8. Under these conditions prostaglandin formation is linear up to arachidonic acid concentration of 30 muM. The initial rate of formation of prostaglandin E2 + prostaglandin D2 is 3--4 times higher than that of prostaglandin F2alpha. Reduced glutathione (1 mM) did not affect the biosynthesis by medulla homogenate and produced only small stimulation of the biosynthesis by microsomal powder. Hydroquinone produced a small stimulation at a low concentration of 0.005 mM, and a strong inhibition at concentrations of 0.1 mM or higher. Addition of bovine serum albumin (0.1%) reduced the microsomal biosynthesis of prostaglandins by approximately 80%. Addition of boiled homogenate or boiled 140 000 X g supernatant produced small stimulation of microsomal biosynthesis while 140 000 X g supernatant (not boiled) caused small inhibition which was not dose-related. It appears that rabbit kidney prostaglandin-synthetase converts arachidonic acid to prostaglandins E2 and F2alpha in comparable amounts, without apparent need for a cytoplasmic soluble cofactor or specific reducing agents.     

Characterization of prostaglandin formation by human amnion cells in monolayer culture

In the present investigation, we found that among the prostanoids that human amnion cells, which are maintained in monolayer culture, secrete into the culture medium, prostaglandin E₂ is by far the predominant one. In the presence of inhibitors of prostaglandin synthase, the production of prostaglandin E₂ by these cells is abolished. Amnion cells maintained in the presence of fetal calf serum produce greater quantities of prostaglandin E₂ than do cells maintained in serumless medium. In the amnion cells, there is little or no metabolism of prostaglandin E₂; this also is true of amnion tissue. The unique characteristics of prostaglandin biosynthesis and metabolism by human amnion cells in monolayer culture are identical with those of human amnion tissue. Hence, we suggest that amnion cells in culture constitute an excellent model for investigations of the regulation of prostaglandin E₂ biosynthesis in this tissue.     

Inhibition of Prostaglandin Biosynthesis by Corticosteroids

Since prostaglandins have been consistently recovered from a wide range of inflammatory reactions, including cutaneous inflammation, we have studied the effect of the anti-inflammatory corticosteroids hydrocortisone and fluocinolone on in-vitro biosynthesis of prostaglandins by skin. Skin homogenates synthesized prostaglandins E₂ and F₂α in the presence of an excess of arachidonic acid substrate. Inhibition of biosynthesis of both these prostaglandins by corticosteroids was demonstrated. Since several members of the prostaglandin group of agents can reproduce all the cardinal features of inflammation and are found in a wide range of inflammatory reactions it is concluded that at least part of the anti-inflammatory properties of corticosteroids is due to inhibition of prostaglandin biosynthesis.     

Paradoxical stimulation of both lipocortin and prostaglandin production in human amnion cells by dexamethasone

Glucocorticoids inhibit prostaglandin biosynthesis by inducing the formation of lipocortins. In human amnion cells dexamethasone elicited a concentration-dependent increase in prostaglandin production and raised intracellular lipocortin 1 concentrations. Dexamethasone could also potentiate the epidermal growth factor (EGF)-induced stimulation of prostaglandin production. EGF alone or in combination with dexamethasone increased lipocortin 1 formation in amnion cells. Human amnion cells may provide a unique insight into interactions between glucocorticoids, lipocortin and eicosanoid biosynthesis.     

Mechanism of prostaglandin biosynthesis in rabbit kidney medulla. A rate-limiting step and the differential stimulatory actions of L-adrenaline and glutathione.

Microsomal prostaglandin synthase (EC 1.14.99.1) from rabbit kidney medulla was assayed with [5,6,8,9,11,12,14,15-3H]-and [1-14C]-arachidonic acid as the substrate. The ratios of prostaglandin F2 alpha to prostaglandin E2 and to prostaglandin D2 were determined by both 3H and 14C labelling. When 3H was used as a label the ratios were much higher than with 14C labelling indicating that the removal of hydrogen at C-9 or C-11 was the rate-limiting step in the biosynthesis of prostaglandin E2 or prostaglandin D2. This finding shows that the octatritiated arachidonic acid is not the appropriate substrate marker for studying the regulation of the synthesis of different prostaglandins by various agents. When the enzyme assay was carried out in the presence of SnCL2, which was capable of accumulating exclusively prostaglandin F2alpha at the expenses of prostaglandin E2 and prostaglandin D2, the addition of L-adrenaline to the microsomal fraction either alone or with reduced glutathione equally stimulated the formation of prostaglandin F2alpha, whereas the addition of reduced glutathione to the microsomal fraction either alone or with L-adrenaline produced no additional effect. These results suggest that endoperoxide is formed as the common intermediate for the biosynthesis of three different prostaglandins in rabbit kidney medulla, and that L-adrenaline stimulates the synthesis of endoperoxide, whereas reduced glutathione facilitates the formation of prostaglandins from endoperoxide.     

Metabolism of prostaglandin D2 in the monkey.

[3H7]Prostaglandin D2 was biosynthesized and infused into an unanesthetized monkey. The urinary metabolites were isolated and subsequently identified by gas chromatography-mass spectrometry. Two pathways of prostaglandin D2 metabolism were identified and resulted in metabolites with prostaglandin D (3-hydroxycyclopentanone) and prostaglandin F (cyclopentane-1,3-diol) ring structures. The major prostaglandin D ring metabolite was identified as 9,20-dihydroxy-11,15-dioxo-2,3-dinorprost-5-en-1-oic acid. Nine other prostaglandin D ring metabolites were identified reflecting various combinations of metabolism by beta and omega oxidation, 15 dehydrogenation, and 13-14 reduction. In greater abundance were those prostaglandin D2 metabolites which had the prostaglandin F ring structure. The major prostaglandin D2 metabolite which had the prostaglandin F ring structure was identified as 9,11,15-trihydroxy-2,3-dinorprosta-5,13-dien-1-oic acid (dinor prostaglandin F2 alpha). Nine other metabolites with the prostaglandin F ring structure were identified, including prostaglandin F2 alpha itself. These, for the most part, were the structural counterparts of the metabolites with the prostaglandin D ring. Since many prostaglandin D2 metabolites were found to be identical with the metabolites of prostaglandin F2 alpha, quantitative determinations of prostaglandin F ring metabolites may not be a specific indicator of prostaglandin F2 alpha biosynthesis. Likewise, data involving the measurement of a biological effect of prostaglandin D2 must be re-examined to account for the possible contribution of prostaglandin F2 alpha, a metabolite of prostaglandin D2, to the biological response.