Study of the physico-chemical properties of prostaglandin F2 alpha and its complexes

To study the intracellular action mechanisms of prostaglandin F2 alpha its interaction with lipid components of biological membranes was investigated. It has been found that prostaglandin forms a complex with phosphatidylcholine and cholesterol. Immobilization ability of phospholipids is changed in the course of complex formation. Ability of prostaglandin F2 alpha for complex formation with insulin was also observed. Combination of monolayer technique and electron microscopy made possible to discover molecular reconstructions when prostaglandin is incorporated into monolayer of biologically active compounds.     

Prostaglandin production by type II alveolar epithelial cells.

Prostaglandin production was studied in fetal and adult type II alveolar epithelial cells. Two culture systems were employed, fetal rat lung organotypic cultures consisting of fetal type II cells and monolayer cultures of adult lung type II cells. Dexamethasone, thyroxine, prolactin and insulin, hormones which influence lung development, each reduced the production of prostaglandin E and F alpha by the organotypic cultures. The fetal cultures produced relatively large quantities of prostaglandin E and F alpha and smaller quantities of 6-keto-prostaglandin F1 alpha and thromboxane B2. However, prostaglandin E2 production was predominant. In contrast, the adult type II cells in monolayer culture produced predominantly prostacyclin (6-keto-prostaglandin F1 alpha) along with smaller quantities of prostaglandin E2 and F2 alpha. The type II cells were relatively unresponsive to prostaglandins. Exogenously added prostaglandin E, had no effect on cell growth, and only a minimal effect on cyclic AMP levels in the monolayer cultures.     

On the metabolism of prostaglandins by human gastric fundus mucosa.

1.Specific radioimmunoassays for the prostaglandins E2, F2alpha and A2 and the metabolites 13,14-dihydro-15-keto-prostaglandin E2, 15-keto-prostaglandin F2alpha and 13,14-dihydro-15-keto-prostaglandin F2alpha were used to study the metabolism of prostaglandins by gastroscopically obtained small biopsy specimens of human gastric fundus mucosa. 2.Three prostaglandin-metabolizing enzymes were found in the 100 000 X g supernatant of human gastric fundus mucosa, 15-hydroxy-prostaglandin-dehydrogenase, delta13-reductase and delta9-reductase. The specific activity was highest for 15-hydroxy-prostaglandin-dehydrogenase and lowest for delta9-reductase. 3.Formation of prostaglandin A2 (or B2) was not observed under the same conditions. 4.None of the three enzyme activities detected in the 100 000 X g supernatant was found in the 10 000 X g and 100 000 X g pellets of human gastric fundus mucosa. 5.The results indicate that high speed supernatant derived from human gastric mucosa can rapidly metabolize prostaglandin E2 and prostaglandin F2alpha to the 15-keto and 13,14-dihydro-15-keto-derivatives. Furthermore, prostaglandin E2 can be converted to prostaglandin F2alpha, the biological activity of which, on gastric functions, differs from that of prostaglandin E2.     

Metabolism of prostaglandins, prostaglandin analogs and thromboxane B2 by lung and liver microsomes from pregnant rabbits

Liver microsomes from pregnant rabbits converted prostaglandins F2 alpha, E1, and E2 to their 20-hydroxy metabolites along with smaller amounts of the corresponding 19-hydroxy compounds. Prostaglandins E1 and E2 were also reduced to prostaglandins F1 alpha and F2 alpha, respectively, and prostaglandin E1 was isomerized to 8-isoprostaglandin E1. The above products were also identified after incubation of prostaglandins with liver microsomes from non-pregnant rabbits. In this case, the yield of 20-hydroxy metabolites was much lower. Thromboxane B2 and a number of prostaglandin F2 alpha analogs were also hydroxylated by lung and liver microsomes from pregnant rabbits. The relative rates of hydroxylation by lung microsomes were: prostaglandin E2 approximately prostaglandin F2 alpha approximately 16,16-dimethylprostaglandin F2 alpha approximately 13,14-didehydroprostaglandin F2 alpha greater than thromboxane B2 greater than 15-methylprostaglandin F2 alpha approximately 17-phenyl-18,19,-20-trinorprostaglandin F2 alpha approximately ent-13,14-didehydro-15-epiprostaglandin F2 alpha. Similar results were obtained with liver microsomes except that thromboxane B2 was a relatively poorer substrate for hydroxylation.     

The effect of acute hypoxia on prostaglandin release in perfused human fetal placenta

The release of prostaglandin E2 and F2 alpha, thromboxane B2 and 6-keto-prostaglandin F1 alpha was measured in isolated human placental cotyledons perfused under high- and low-oxygen conditions. Also the effect of reoxygenation on prostaglandin production was studied. During the high-oxygen period, prostaglandin E2 accounted for 44% and 6-keto-prostaglandin F1 alpha for 28% of all prostaglandin release, and the rank order of prostaglandin release was E2 greater than 6-keto-prostaglandin F1 alpha greater than thromboxane B2 greater than prostaglandin F2 alpha. Hypoxia had no significant effect on quantitative prostaglandin release, but the ratio of prostaglandin E2 to prostaglandin F2 alpha was significantly increased. After the hypoxic period during reoxygenation the release of 6-keto-prostaglandin F1 alpha was significantly decreased, as was the ratio of 6-keto-prostaglandin F1 alpha to thromboxane B2. Also the ratio of the vasodilating prostaglandins (E2, 6-keto-prostaglandin F1 alpha) to the vasoconstricting prostaglandins (thromboxane B2, prostaglandin F2 alpha) was decreased during reoxygenation period. With the constant flow rate, the perfusion pressure increased during hypoxia in six and was unchanged in three preparations. The results indicate that changes in the tissue oxygenation in the placenta affect prostaglandin release in the fetal placental circulation. This may also have circulatory consequences.     

Prostacyclin and prostaglandin synthesis in isolated brain capillaries

The synthesis of prostacyclin and prostaglandins was examined in isolated blood-free brain capillaries of guinea-pigs and rats using 1-14C-arachidonic acid as a precursor. The main prostaglandins synthesized by guinea-pig microvessels were prostaglandin D2 and prostaglandin E2. Substantially less prostaglandin F2 alpha or the prostacyclin stable metabolite, 6-oxo-prostaglandin F1 alpha was synthesized. Rat capillary prostaglandin distribution differed substantially from that of the guinea-pigs although the principle prostaglandin was also PGD2. Total prostaglandin conversion was greater in guinea-pig capillaries than in the rat. Norepinephrine stimulated the prostaglandin forming capacity of blood free cerebral microvasculature of guinea-pigs. Prostacyclin and prostaglandins could be involved in the activity dependent regulation of regional cerebral blood flow and permeability.     

Metabolism of prostaglandins D2 and F2 alpha in primary cultures of rat hepatocytes

3H-Labeled prostaglandins D2 and F2 alpha rapidly degraded to more-polar metabolites in primary cultured rat hepatocytes. The metabolites of prostaglandins D2 and F2 alpha accumulated in the culture medium. The metabolites extracted by ethyl acetate at pH 3 were purified by silicic acid column and thin-layer chromatography of silica gel, and were analysed by gas chromatography-mass spectrometry. The major metabolites from prostaglandin D2 were identified as dinor-prostaglandin D1 (7 alpha,13-dihydroxy-9-ketodinorprost-11-enoic acid) and tetranor-prostaglandin D1 (5 alpha,11- dihydroxy-7-ketotetranorprost-9-enoic acid). Those from prostaglandin F2 alpha were identified as dinor-prostaglandin F1 alpha (7 alpha,9 alpha,13-trihydroxydinorprost-11-enoic acid), tetranor-prostaglandin F1 alpha (5 alpha,7 alpha,11-trihydroxytetranorprost-9-enoic acid) and 9 alpha,11 alpha,15-trihydroxyprost-13-ene-1,20-dioic acid. These data indicate that prostaglandins D2 and F2 alpha mainly degraded by beta-oxidation, which is the same process as reported earlier for prostaglandins E1 and E2, and that prostaglandin F2 alpha was also subjected to omega-oxidation.     

Prostaglandin responses in isolated perfused rat liver: Ca2+ and K+ fluxes, hemodynamic and metabolic effects

Addition of prostaglandin F2 alpha and prostaglandin E2 to isolated perfused rat liver led to a dose-dependent, transient net Ca2+ release, which was completed within 3 min. Withdrawal of the prostaglandins resulted in a Ca2+ re-uptake over a period of about 10 min. Simultaneously, these prostaglandins induced an increase of portal pressure, stimulated hepatic glucose output and 14CO2 production from [1-14C]glutamate and led to K+ movements across the hepatocyte plasma membrane similar to those observed with other Ca2+-mobilizing agents. With prostaglandin F2 alpha there was a close correlation between the net Ca2+ release and the maximal rate of initial net K+ uptake by the liver (linear regression coefficient r = 0.902; n = 20). Prostaglandin F2 alpha was more effective than prostaglandin E2 or D2. Because prostaglandins are known to be produced by hepatic non-parenchymal cells during stimulation by phagocytosis or by addition of extracellular ATP or UTP, these data suggest an interaction between non-parenchymal and parenchymal liver cells and point to a modulating role of prostaglandins in hepatic metabolism and microcirculation, which is mediated by Ca2+-mobilizing mechanisms.     

Distribution of prostaglandin biosynthetic pathways in organs and tissues of the fetal lamb

Five prostaglandins, i.e. prostaglandins E2, F2alpha and D2, 6-keto-prostaglandin F1alpha and thromboxane B2, were measured by mass spectrometry. Homogenates of fetal lamb brain, lung, liver, spleen and kidney and the ductus arteriosus, aorta and pulmonary artery formed different amounts of each product. Although the main prostaglandin in the fetal organs was prostaglandin E2, arterial tissue formed mostly 6-keto-prostaglandin F1alpha. These results demonstrate significant differences between organs and tissues in the relative direction of the 'prostaglandin synthetase' enzyme complex.     

Gonadotropin and prostaglandins binding sites in nuclei of bovine corpora lutea.

Highly purified nuclei isolated from bovine corpora lutea showed marked enrichment of NAD pyrophosphorylase, a marker for this organelle. Rough endoplasmic reticulum and lysosomal markers were undetectable, whereas plasma membrane and Golgi markers were detectable but not enriched in nuclei. These highly puridied nuclei exhibited specific binding with 125I-labeled human choriogonadotropin, [3H]prostaglandin E1 and [3H]prostaglandin F2 alpha. However, these bindings were only 15.4% (human choriogonadotropin), 7.9% (prostaglandin E1) and 8.9% (prostaglandin F2 alpha) of the plasma membrane binding observed under the same conditions. Washing of nuclei and plasma membranes twice with buffer containing 0.1% Triton X-100 resulted in gonadotropin and prostaglandin F2 alpha binding site and 5'-nucleotidase (EC 3.1.3.5) losses from nuclei that were different from those observed for plasma membranes. More importantly, the washed nuclei exhibited 44% (human choriogonadotropin), 21--26% (prostaglandins) of original specific binding despite virtual disappearance of 5'-nucleotidase activity. The nuclear membranes isolated from nuclei, specifically bound 125I-labeled human choriogonadotropin and [3H]prostaglandin F2 alpha to the same extent or significantly more ([3H]prostaglandin E1, P less than 0.05) than nuclei themselves, despite the marked losses of chromatin. In summary, our data suggest that gonadotropin and prostaglandins bind to nuclei and that this binding was intrinsic and was primarily associated with the nuclear membrane.     

Uterine vein prostaglandin levels in late pregnant dogs.

We studied the uterine venous plasma concentrations of prostaglandins E2, F2 alpha, 15 keto 13,14 dihydro E2 and 15 keto 13,14 dihydro F2 alpha in late pregnant dogs in order to evaluate the rates of production and metabolism of prostaglandin E2 and F2 alpha in pregnancy in vivo. We used a very specific and sensitive gas chromatography-mass spectrometry assay to measure these prostaglandins. The uterine venous concentrations of prostaglandin E2 and 15 keto 13,14 dihydro E2 were 1.35 +/- .27 ng/ml and 1.89 +/- .37 ng/ml, respectively; however, we could not find any prostaglandin F2 alpha and very little of its plasma metabolite in uterine venous plasma. Since uterine microsomes can generate prostaglandin F2 alpha and E2 from endoperoxides, prostaglandin F2 alpha production in vivo must be regulated through an enzymatic step after endoperoxide formation. Prostaglandin E2 is produced by pregnant canine uterus in quantities high enough to have a biological effect in late pregnancy; however, prostaglandin F2 alpha does not appear to play a role at this stage of pregnancy.     

Production of Hyperalgesic Prostaglandins by Sympathetic Postganglionic Neurons

Prostaglandin E2 and prostacyclin (prostaglandin I2) produce hyperalgesia in animals and humans. Because there is evidence that prostaglandins contribute to pain maintained by sympathetic nervous system activity, we evaluated whether sympathetic postganglionic neurons synthesize these hyperalgesic prostaglandins, and whether production of prostaglandins by these neurons can contribute to sensitization of primary afferent nociceptors. Intradermal injection of arachidonic acid but not linoleic acid, in the rat hindpaw, produces a decrease in mechanical nociceptive threshold. This hyperalgesic effect is prevented by indomethacin, an inhibitor of prostaglandin synthesis or by prior surgical removal of the lumbar sympathetic chain. To test the hypothesis that sympathetic postganglionic neurons are the source of prostaglandins, we measured production of prostaglandin E2 and 6-keto-prostaglandin F1 alpha (the stable metabolite of prostacyclin) by homogenates of adult rat sympathetic postganglionic neurons from superior cervical ganglia. These homogenates produced significant amounts of prostaglandin E2 and 6-keto-prostaglandin F1 alpha, and most of this production is eliminated by neonatal administration of 6-hydroxydopamine which selectively destroys sympathetic postganglionic neurons. These results demonstrate that sympathetic postganglionic neurons produce prostaglandins, and supports further the hypothesis that the release of prostaglandins from sympathetic postganglionic neurons contributes to the hyperalgesia associated with sympathetically maintained pain.     

Prostaglandin biosynthesis and catabolism in the lamb ductus arteriosus, aorta and pulmonary artery.

Homogenates of tissues from fetal and neonatal lamb ductus arteriosus, aorta and pulmonary artery have the capacity to convert arachidonic acid as well as the intermediate prostaglandin endoperoxide, prostaglandin H2, into three products: prostaglandins E2, F2alpha and a major product 6-ketoprostaglandin F1alpha. The three tissues also displayed prostaglandin 15-hydroxydehydrogenase and 13-reductase catabolic activities. The catabolishing system showed considerable substrate specificity: prostaglandin E1 was a good substrate whereas prostaglandins F1alpha and F2alpha were completely devoid of catabolism. The complete system was observed in immature as well as mature arterial vessels, in the fetus as well as the neonate (up to 7 days old). These experiments demonstrate the presence of several components of the prostaglandin system in these tissues and offer biochemical evidence for the implication of prostaglandins E2 and I2 in the maintenance of the ductus and neighboring vessels in a relaxed state in the fetus.     

Identification of metabolites from peroxisomal beta-oxidation of prostaglandins

We have recently shown that isolated rat liver peroxisomes can chain-shorten prostaglandin F2 alpha and prostaglandin E2 to tetranor-metabolites. In the present report dinor-metabolites of these two prostaglandins were also identified, suggesting that the peroxisomal chain-shortening reaction of prostaglandins is a beta-oxidation reaction. Furthermore, an intermediate containing an extra double bond was isolated from incubates of prostaglandin F2 alpha with peroxisomes. This intermediate was tentatively assigned the structure 2,3-dehydroprostaglandin F2 alpha. Prostaglandin E1 and a major circulating prostaglandin F2 alpha metabolite were also metabolized to chain-shortened products by peroxisomes. The accumulation of the 2,3-dehydro-metabolite and the dinor-metabolites suggest that the peroxisomal beta-oxidation sequence is not tightly coupled, in contrast to mitochondrial fatty acid oxidation.     

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.     

Prostaglandin synthesis and catabolism in the gastric mucosa: studies in normal rabbits and rabbits immunized with prostaglandin E2

Antral and fundic mucosal homogenates obtained from prostaglandin E2-immunized rabbits converted 14C-arachidonic acid to prostaglandin E2, 6-keto prostaglandin F1 alpha, prostaglandin F2 alpha, and prostaglandin D2. Percentage conversion of 14C-arachidonic acid to these prostaglandin products was not significantly different in prostaglandin E2-immunized rabbits compared with control rabbits (thyroglobulin-immunized and unimmunized rabbits combined). Synthesis of 6-keto prostaglandin F1 alpha, prostaglandin E2 and 13,14-dihydro 15-keto prostaglandin E2 from endogenous arachidonic acid after vortex mixing fundic mucosal homogenates was similar in prostaglandin E2 immunized rabbits and control rabbits. Both in prostaglandin E2-immunized rabbits and controls, 3H-prostaglandin E2 was catabolized extensively by the fundic mucosa, whereas 3H-6-keto prostaglandin F1 alpha, 3H-prostaglandin F2 alpha, and 3H-prostaglandin D2 were not catabolized to any appreciable extent. The rate of catabolism of PGs was not significantly different in prostaglandin E2-immunized rabbits and control rabbits, with the exception of prostaglandin F2 alpha which was catabolized slightly more rapidly in prostaglandin E2-immunized rabbits. These results indicate that development of gastric ulcers in prostaglandin E2-immunized rabbits is not associated with an alteration in the capacity of the gastric mucosa to synthesize or catabolize prostaglandins.     

Catabolism of an isolated, purified intermediate of prostaglandin biosynthesis by regions of the adult rat kidney.

1. A heat labile, cold-stable, stannous chloride-reducible intermediate of prostaglandin biosynthesis was formed in good yield (greater than 60%) from 3H-labeled arachidonic acid during brief incubations (30--90 s, 37 degrees C) with sheep seminal vesicle microsomes in the presence of p-hydroxymercuribenzoate (4 mM). This intermediate appears to have properties similar to one of the endoperoxides (15-hydroxyprostaglandin-9,11-endoperoxide) recently isolated by Hamberg and Samuelsson (Proc. Natl. Acad. Sci. U.S. (1973) 70, 889-903) AND Nugteren and Hazelhof (Biochem. Biophys. Acta. (1973) 326, 448-461). 2. Treatment of the purified intermediate with homogenates of rat kidney cortex, medulla and papilla resulted within 2 min (37 degrees C) in complete conversion into several compounds including prostaglandins E2 and F2alpha. The main product (40-50% yield formed by papilla homogenates was prostaglandin E2. The conversion into prostaglandin E2 was largely abolished by previous bo9ling of the homogenate whereas the conversion into prostaglandin F2alpha was not. The intermediate was stable in buffer for the same period of incubation. 3. The ratio of tritiated prostaglandins E2: F2alpha obtained were: papilla, 1.90; medulla, 0.76; cortex, 0.48. 4. These observations indicate that both types of prostaglandins can be formed by all three regions of the rat kidney and that regional differences exist in the proportion of E2 : F2alpha that is formed. Whereas prostaglandin E2 is mostly formed by an enzymatic process, prostaglandin F2alpha is not.     

The interaction of prostaglandins with high-density lipoproteins: a non-equilibrium model of ligand-receptor interaction

Using high-density lipoproteins (HDL) labeled with a fluorescent phospholipid probe (an anthrylvinyl-labeled analogue of sphingomyelin) it was found that low amounts (10(-12) M) of the prostaglandins E1 and F2 alpha induced different structural changes of the HDL surface, whereas prostaglandin E2 had no effect. The effects of prostaglandin E1 on HDL were largely paralleled by those of this prostaglandin on synthetic recombinants prepared from apolipoprotein A1, phospholipids and cholesterol. The prostaglandin E1-HDL interaction resembled that of a ligand with a receptor site because it was specific, reversible, concentration- and temperature-dependent and saturable. However, the maximal HDL retaining capacity for prostaglandin E1 as determined by equilibrium dialysis was very low, and a single prostaglandin E1 molecule was able to induce structural changes in a large number of discrete lipoprotein particles. To explain this remarkable fact, a non-equilibrium model of ligand-receptor interaction is proposed. According to this model in open systems characterized by a short life-time of the ligand-receptor complex, high diffusion rates of the ligand and long relaxation times which exceed the interval between two successive ligand-receptor occupations, the ligand-induced changes will accumulate, resulting in amplification of the primary biological signal. It is emphasized that the low mobility of lipids constituting the environment of the receptor protein plays a critical role in this type of signal amplification.     

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.     

Formation of 20-hydroxyprostaglandins by lungs of pregnant rabbits

Homogenates or particulate fractions (1,000 to 100,000 X g) from lungs of pregnant rabbits were incubated with prostaglandins or prostaglandin metabolites and the products were purified by chromatography and identified by gas chromatography-mass spectrometry. In the presence of NADPH, particulate fractions from pregnant rabbit lungs converted prostaglandins E1, E2, and F2alpha as well as 13,14-dihydro-15-oxoprostaglandin E2 and 13, 14-dihydro-15-oxoprostaglandin F2alpha to their 20-hydroxy derivatives. In the cases of the 3 primary prostaglandins, the corresponding omega-carboxylic acids were also isolated. The omega-hydroxylation reaction occurred in the presence of the microsomal fraction. The mitochondrial fraction was much less active whereas the cytosol fraction converted prostaglandins to their 13, 14-dihydro-15-oxo derivatives. When prostaglandin F2alpha was incubated with homogenates of lungs from pregnant rabbits, omega-oxidation was combined with oxidation of the 15-hydroxyl group and reduction of the 13, 14-double bond to give 13, 14-dihydro-20-hydroxy-15-oxoprostaglandin F2alpha as well as the corresponding derivative with an omega-carboxylic acid group. Lungs from nonpregnant rabbits were much less active than lungs from pregnant rabbits in the omega-oxidation of prostaglandins.