Prostaglandin 9-hydroxydehydrogenase activity in the adult rat kidney. Identification, assay, pathway, and some enzyme properties.

Prostaglandin F2alpha is converted to 15-keto-13,14-dihydroprostaglandin E2 by adult rat kidney homogenates. A variety of substrates labeled as either the 9beta position alone or at several other positions in the prostaglandin molecule were used to define the step at which the crossover from the F type to the E type prostaglandins takes place. Time course studies further confirmed that 15-keto-13,14-dihydroprostaglandin F2alpha is the immediate substrate for this enzyme which we have termed prostaglandin 9-hydroxydehydrogenase. An assay system based on specific loss of tritium from 9beta-tritiated prostaglandin F2alpha is described. Enzyme activity with prostaglandin F2alpha as substrate is linear with time up to 10 min, stimulated by NAD+, saturable at low concentrations of substrate, stable to storage at minus 25 degrees in phosphate buffer (up to 3 weeks), and has a broad pH optimum around 7.5. The product, 15-keto,13,14-dihydroprostaglandin E2 was identified by mass spectrometry through a sodium borohydride-sodium borodeuteride reduction method.     

Stimulation of the formation of 13,14-dihydroprostaglandin F2 alpha by gonadotropin in rat ovary

Effects of pregnant mare serum gonadotropin and human chorionic gonadotropin on the formation of 13,14-dihydroprostaglandin F2 alpha, a biologically active compound, were investigated in rat ovarian homogenate. The mass number of the compound, which was formed prostaglandin F2 alpha via 13,14-dihydro-15-ketoprostaglandin F2 alpha in rat ovarian homogenate but was not produced in rat homogenate, accorded with that of the authentic 13,14-dihydroprostaglandin F2 alpha by negative ion chemical ionization mass spectrometry. In the present experiment, the radioactivity of [3H]prostaglandin F2 alpha added to ovarian homogenate was decreased linearly and immediately until the incubation time of 10 min. The formation of 13,14-dihydroprostaglandin F2 alpha was increased up to 60 min. The formation of 13,14-dihydroprostaglandin F2 alpha from prostaglandin F2 alpha was markedly increased by pregnant mare serum gonadotropin and human chorionic gonadotropin. However, there was no additive or synergistic effect of these hormones. The formation of 13,14-dihydroprostaglandin F2 alpha from 13,14-dihydro-15-ketoprostaglandin F2 alpha weas also greatly stimulated by pregnant mare serum gonadotropin and human chorionic gonadotropin. The formation of 13,14-dihydro-15-ketoprostaglandin F2 alpha steeply declined until 24 h after treatment with human chorionic gonadotropin in pregnant mare serum gonadotropin-primed rats. In contrast, the formation of 13,14-dihydroprostaglandin F2 alpha was markedly increased until 24 h after human chorionic gonadotropin treatment, and the level was about 2.5-fold higher than that at 0 h, 48 h after injection of pregnant mare serum gonadotropin.     

Metabolism of prostaglandin D2 in isolated rat lung: the stereospecific formation of 9 alpha,11 beta-prostaglandin F2 from prostaglandin D2

The metabolic transformation of exogenous prostaglandin D2 was investigated in isolated perfused rat lung. Dose-dependent formation (2-150 ng) of 9 alpha,11 beta-prostaglandin F2, corresponding to about 0.1% of the perfused dose of prostaglandin D2, was observed by specific radioimmunoassay both in the perfusate and in lung tissue after a 5-min perfusion. To investigate the reason for this low conversion ratio, we analyzed the metabolites of tritium-labeled 9 alpha,11 beta-prostaglandin F2 and prostaglandin D2 by boric acid-impregnated TLC and HPLC. By 5 min after the start of perfusion, 9 alpha,11 beta-prostaglandin F2 disappeared completely from the perfusate and the major product formed remained unchanged during the remainder of the 30-min perfusion. The major product was separated by TLC and identified as 13,14-dihydro-15-keto-9 alpha,11 beta-prostaglandin F2 by GC/MS. In contrast, pulmonary breakdown of prostaglandin D2 was slow and two major metabolites in the perfusate increased with time, each representing 56% and 11% of the total radioactivity at the end of the perfusion. The major product (56%) was identified as 13,14-dihydro-15-ketoprostaglandin D2 and the minor one (11%) was tentatively identified as 13,14-dihydro-15-keto-9 alpha,11 beta-prostaglandin F2 based on the results from radioimmunoassays, TLC, HPLC, and the time course of pulmonary breakdown. These results demonstrate that the metabolism of prostaglandin D2 in rat lung involves at least two pathways, one by 15-hydroxyprostaglandin dehydrogenase and the other by 11-ketoreductase, and that the 9 alpha,11 beta-prostaglandin F2 formed is rapidly metabolized to 13,14-dihydro-15-keto-9 alpha,11 beta-prostaglandin F2.     

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.     

Prostaglandin 15-hydroxy dehydrogenase from human placenta.

The enzyme system prostaglandin 15-hydroxy dehydrogenase, which catalyzes the inactivation of all biologically active prostaglandins, has been purified 1270-fold from human placenta. Kinetic studies on the enzyme have provided information on a well-organized control mechanism to avoid prostaglandin accumulation and for a fast prostaglandin degradation. 15-Ketoprostaglandin E2 and 13,14-dihydro-15-ketoprostaglandin E2 inhibit prostaglandin 15-hydroxy dehydrogenase non-competitively with respect to prostaglandin E2. The rate equation of enzyme reaction for two substrates was used for determination of the equilibrium constant and Michaelis constants of the enzyme. The following kinetic constants for prostaglandin 15-hydroxy dehydrogenase have been found. The equilibrium constant with repect to prostaglandin E2 is 18 muM, the Michaelis constant Km for prostaglandin E2 is 1 muM for NAD+ 44muM. The inhibition constants for 15-ketoprostaglandin E2 ar Ki(slope) = 70 muM, Ki(intercept) = 150 muM, and for 13,14-dihydro-15-ketoprostaglandin E2 Ki(slope) = 80 muM, and Ki(intercept) = 150 muM. The maximal velocity for the forward reaction is V1 = 0.45 mumol/min. These kinetic data exclude a random or ping-pong mechanism, and also a Theorell-Chance type as suggested by Braithwaite and Jarabak. We propose, therefore, a sequential ordered mechanism. The isoelectric point for prostaglandin 15-hydroxy dehydrogenase is at pH 5.35, judged by isoelectric focusing.     

Formation of 6,15-diketoprostaglandin F1 alpha from prostaglandin G2 by bovine aortic endothelial cells

Besides 6-ketoprostaglandin F1 alpha, bovine aortic endothelial cells also produced considerable amounts of 6,15-diketoprostaglandin F1 alpha from arachidonic acid, either exogenously added or released from cellular phospholipids. Incubations of particulate fractions of endothelial cells with the cyclic endoperoxides prostaglandin G2 and prostaglandin H2 showed that 6,15-diketoprostaglandin F1 alpha is formed by the action of prostaglandin I2 synthetase on prostaglandin G2. The labile metabolite 15-hydroperoxyprostaglandin I2 is then converted nonenzymatically to the 15-keto derivative. In the presence of reduced glutathione, quantitative analysis of both metabolites by gas chromatography-mass spectrometry showed a significant decrease of 6,15-diketoprostaglandin F1 alpha formation, whereas prostaglandin I2 synthesis was markedly increased. This shift seems to be due to a stimulation of peroxidase by GSH, a well known cofactor of this enzyme. Thus, it seems that a decreased endothelial prostaglandin I2 formation may occur when cellular glutathione levels are reduced as a consequence of oxidant injury and lipid peroxidation. Additionally, ferrous ions seems to be involved in the regulation of endothelial prostaglandin I2 synthesis, since Desferal, a specific ferrous ion chelator that might have antimetastatic properties, produced a pronounced shift from 6,15-diketoprostaglandin F1 alpha to the 6-keto derivative, i.e., prostaglandin I2.     

The metabolism of prostaglandin D2 after inhalation or intravenous infusion in normal men

Tritium-labelled prostaglandin D2 (PGD2) was administered to normal volunteers by either intravenous infusion or inhalation in order to establish which metabolites of PGD2 are initially found in human plasma. Inhaled PGD2 was rapidly absorbed from the airways, as indicated by the rapid appearance of tritium in the plasma. Metabolites chromatographically similar to 9 alpha,11 beta-PGF2 and 13,14-dihydro-15-keto-9 alpha,11 beta-PGF2 were found after both routes of administration. At later time points, other unidentified compounds were present. Only after intravenous infusion was there evidence of metabolites with 9 alpha,11 alpha stereochemistry of the ring hydroxyl functions. In human lung, 9 alpha,11 beta-PGF2 was metabolized in the presence of NAD+ to compounds tentatively identified by gas chromatography/mass spectrometry (GC/MS) as 15-keto-9 alpha,11 beta-PGF2 and 13,14-dihydro-15-keto-9 alpha,11 beta-PGF2. Thus, after 11-ketoreductase-dependent metabolism of PGD2 to the biologically active compound 9 alpha,11 beta-PGF2, further metabolism probably proceeds by the combined action of 15-hydroxyprostaglandin dehydrogenase/15-ketoprostaglandin-delta 13-reductase (15-PGDH/delta 13R). Both 9 alpha,11 beta-PGF2 and its 13,14-dihydro-15-keto metabolite may be useful analytes for the measurement of PGD2 turnover, and may therefore prove to be important in understanding the pathophysiological significance of this putative mediator.     

Specific binding of the thromboxane A2 antagonist 13-azaprostanoic acid to human platelet membranes

In the present study we characterized the interaction between the thromboxane A2/prostaglandin H2 antagonist, trans-13-azaprostanoic acid (13-APA), and isolated human platelet membranes. In these studies, we developed a binding assay using trans [3H] 13-APA as the ligand. It was found that trans [3H] 13-APA specific binding was rapid, reversible, saturable and temperature dependent. Scatchard analysis of the binding data yielded a curvilinear plot which indicated the existence of two classes of binding sites: a high-affinity binding site with an estimated dissociation constant (Kd) of 100 nM; and a low-affinity binding site with an estimated Kd of 3.5 microM. At saturation, approximately 1 pmol/mg protein of [3H] 13-APA was bound to the high affinity site. In order to further characterize the nature of the [3H] 13-APA binding site, we evaluated competitive binding by cis 13-APA, cis 15-APA, prostaglandin F2 alpha, U46619, 6-ketoprostaglandin F1 alpha and thromboxane B2. It was found that the [3H] 13-APA binding site was stereospecific and structurally specific. Thus, the cis isomer of 13-APA exhibited substantially reduced affinity for binding. Furthermore, the prostaglandin derivatives, thromboxane B2 and 6-ketoprostaglandin F1 alpha, which do not possess biological activity, also did not compete for [3H] 13-APA binding. On the other hand, U46619 which acts as a thromboxane A2/prostaglandin H2 mimetic, and prostaglandin F2 alpha which acts as a thromboxane A2/prostaglandin H2 antagonist, both effectively competed for [3H] 13-APA binding. These findings indicate that trans 13-APA binds to a specific site on the platelet membrane which presumably represents the thromboxane A2/prostaglandin H2 receptor.     

Rat renal medulla possess high capacity to catabolize prostaglandins

Prostaglandin E2 is converted to 15-keto-13,14 dihydro prostaglandin E2,15-keto-prostaglandin F2 alpha and 15-keto-13,14 dihydro prostaglandin F2 alpha, by supernatants from rat kidney medulla. The main pathway for prostaglandin E2 inactivation is the combined action of 15 hydroxy dehydrogenase and delta 13 reductase enzymes. 9-Keto-reductase route constitutes a minor pathway. Prostaglandin F2 alpha is converted into 15-keto-prostaglandin F2 alpha, 15-keto-13, 14 dihydro prostaglandin F2 alpha and 15-keto-dihydro prostaglandin E2. Enzyme activities are time and substrate-concentration dependent. In the presence of an excess of substrate, rat renal medulla inactivates 40 and 56 times more prostaglandin E2 and prostaglandin F2 alpha, respectively, than the amount which is released under basal conditions. These results are in contrast to the generally accepted concept that the kidney cortex is the sole site of renal prostaglandin catabolism, and suggest, for the first time, that rat renal medulla may be a key site for the modulation of prostaglandin levels in the kidney.     

6-Ketoprostaglandin F1 alpha, prostaglandins E2, F2 alpha and thromboxane B2 production by endothelial cells, smooth muscle cells and fibroblasts cultured from piglet aorta

After [3H]arachidonic acid labeling, cyclooxygenase products were qualitatively analysed in the media of each cultured vascular cell type by reverse-phase high-performance liquid chromatography (rp-HPLC). The prostaglandin E2, prostaglandin F2 alpha, 6-ketoprostaglandin F1 alpha and thromboxane B2 detected in the rp-HPLC radioactive profile were then quantified by radioimmunoassay (RIA) in separate sets of experiments. In preconfluent endothelial cells prostaglandin F2 alpha and 6-ketoprostaglandin F1 alpha were detected in equal amounts (49%), whereas after confluence 6-ketoprostaglandin F1 alpha represented 57% of total secretion (P less than 0.05). Smooth muscle cells secreted mainly prostaglandin F2 alpha (48%) and fibroblasts prostaglandin E2 (44%). Using the bioassay method, antiaggregatory activity was detected only in endothelial cells, though a small percentage of immunoreactive 6-ketoprostaglandin F1 alpha was encountered in smooth muscle cells and fibroblasts (13 and 10%, respectively). Radioimmunological analysis after rp-HPLC separation of the medium of endothelial cells showed that the anti-6-ketoprostaglandin F1 alpha antibody recognized, among other substances, an unidentified compound. Its retention time was similar to that of prostaglandin F2 alpha. This unidentified compound was not detected in the media from smooth muscle cells and fibroblasts.     

PRESENCE OF 15-HYDROXY PROSTAGLANDIN DEHYDROGENASE, PROSTAGLANDIN-Δ13-REDUCTASE AND PROSTAGLANDIN E-9-KETO(α)-REDUCTASE IN THE FROG SPINAL CORD

Metabolism of prostaglandin E₁ (PGE₁) and F_1α (PGF_1α) was studied in the frog spinal cord, using a hemisected preparation in vitro and tissue homogenates (whole honiogenate and tissue fractions). In the intact tissue, PGE, was converted to three Metabolites, 1 to 111, whereas only Metabolites 11 and 111 werc detected in experiments with PGF_1α. Work with tissue homogenatcs confirmed that PG transformation is enzymatic, and endproducts were identified as PGF_1α (Metabolite 1), 15-kcto metabolite (Metabolite 11) and 15-keto-13,14-dihydro metabolite (Metabolite 111). The 15-keto-13,14-dihydro metabolite was formed via the 15-keto metabolite which is consistent with findings elsewhere. These results establish the presence in the frog spinal cord of two pathways for PG metabolism, consisting one of the 15-hydroxy prostaglandin dehydrogenase (15-PGDH) and the prostaglandin-A13- reductase (13-PGR), the other of the prostaglandin E 9-keto(α)-reductase (9K-PGR). 9K-PGR is regarded as an inactivating enzyme because amphibian spinal neurons are less responsive to PGF, than to PGE₁. In the intact or in the homogenized tissue, PGE, is metabolized more efficiently by the 15-PGDH/13-PGR than by the 9K-PGR route. The 15-PGDH metabolizes PGE, more readily than PGF_1α. The present findings, together with the previous demonstration of active PG synthesis in the tissue and the potent actions of exogenous PGs, strongly suggest that the PGs play an important role in the function of neurons in the frog spinal cord.     

Elimination of low steady-state concentrations of E15,6-3H2]prostaglandin E1 in the pulmonary and the systemic circulations of anaesthetized rats

The elimination of [3H]prostaglandin E1 in anaesthetized rats was studied by continuous intravenous or intraarterial infusions, producing steady-state concentrations at the level of endogenous prostaglandin E2 in mixed venous blood. Blood samples (0.5 ml) were collected from the carotid artery or the right atrium, respectively. The levels of [3H]prostaglandin E1 were measured at different infusion time intervals and the 3H-labeled hydrophobic metabolites characterized. Cardiac output was estimated by a modification of the dye injection method, using 125I-labelled albumin as the marker. From the cardiac output and the rate of infusion, the fractional clearance of the lung and the systemic beds in the steady-state situation were estimated to 88.3 +/- 3.2% and 54.1 +/- 15.2% (mean +/- S.D.), RESPECTIVELY. The hydrophobic metabolites were characterized chromatographically on Sephadez LH-20 columns, using synthetically prepared [14C]prostaglandin metabolites as internal standards and markers. The identities of some metabolites were further established by derivative formation to a constant [3H]/[14C] ratio. The major metabolite was 15-keto-13,14-dihydro-[3H]prostaglandin E1, while 15-keto-[3H]prostaglandin E1 and 13,14-dihydro-[3H]prostaglandin E1 could not be demonstrated.     

Purification and regulatory properties of chicken heart prostaglandin E 9-ketoreductase.

Prostaglandin E 9-ketoreductase was purified from chicken heart by ammonium sulfate fractionation, and DEAE-Sephadex, hydroxylapatite and phosphocellulose chromatography. Two peaks of activity were resolved during the phosphocellulose chromatographic step. Both peaks were stimulated by a substance that was not bound to the phosphocellulose column. This stimulatory substance was destroyed by treatment with phosphodiesterase and 0.1 M NaOH. It was heat-stable (100 degrees, 2 min), nondialyzable, and resistant to treatment with pronase, ribonuclease, and deoxyribonuclease; but it was dialyzable after heating or digestion with pronase. Sodium pyrophosphate also enhanced the activities of the prostaglandin E 9-ketoreductases as did angiotensin I; but not angiotensin II. In the presence of 3':5'-cyclic AMP, AMP, or several other ribonucleotides, the enhancing effects of the natural stimulatory substance, sodium pyrophosphate or angiotensin I were blocked, but these ribonucleotides themselves had little effect on the enzymes activity. The substrate specificities of the two prostaglandin E 9-ketoreductases were also studied. Both the 9-keto group and the 15-keto group of 15-ketoprostaglandin F2 alpha could be converted to the corresponding hydroxyl group; the 15-keto group was reduced faster than the 9-keto group. Prostaglandin D2, a prostaglandin with a 9-hydroxyl and an 11-keto group, could not be converted to prostaglandin F2 alpha nor could cyclohexanone be converted to cyclohexanol by the prostaglandin E 9-ketoreductase.     

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 prostacyclin. III. Urinary metabolite profile of 6-keto PGF1 alpha in rat.

The in vivo metabolism of 6-keto PGF1 alpha was investigated in rats. Following continuous intravenous infusion for 14 days the urinary metabolites were isolated and identified. A substantial amount of unchanged 6-keto PGF1 alpha was recovered in the urine. The metabolic pattern very closely resembles that of PGI2 in rats. Metabolites were found which represented 15-dehydrogenation, beta-oxidation, omega and omega-1-hydroxylation and oxidation. Previous work showed that 6-keto PGF1 alpha is very poorly oxidized by 15-PGDH. We administered 15-[H3]-PGI2 and 15-[H3]-6-keto PGF1 alpha to rats and measured urinary tritiated water as an index for in vivo 15-PGDH activity. The results showed that PGI2 and 6-keto PGF1 alpha were both oxidized to the 15-keto product, although the rate of oxidation of PGI2 was greater than that of 6-keto PGF1 alpha. We concluded that the administered PGI2 was oxidized by 15-PGDH before hydrolysis to 6-keto PGF1 alpha. A portion of the dose is probably hydrolzyed before 15-dehydrogenation.     

Development of enzyme immunoassay for serum 13,14-dihydro-15-ketoprostaglandin F2 alpha

An enzyme immunoassay was developed for a convenient and sensitive assay of 13,14-dihydro-15-ketoprostaglandin F2 alpha, a metabolite of prostaglandin F2 alpha appearing in human blood. The compound was chemically conjugated to beta-galactosidase from Escherichia coli. The enzyme-labeled antigen was mixed with a sample containing 13,14-dihydro-15-ketoprostaglandin F2 alpha, and the mixture was allowed to react competitively with the antibody immobilized in a polystyrene tube. The activity of beta-galactosidase bound to the antibody was assayed by fluorometry. The enzyme activity was plotted against the amount of authentic 13,14-dihydro-15-ketoprostaglandin F2 alpha to obtain a calibration curve, and the compound was detectable over a range of 10 fmol to 10 pmol. Prostaglandins were extracted from human serum by the use of an octadecylsilyl silica column, and the extract gave an abnormally high level of 13,14-dihydro-15-ketoprostaglandin F2 alpha by enzyme immunoassay due to the presence of unidentified interfering substance(s), which was removed by high-performance liquid chromatography (HPLC). The purified material gave a value in the order of 0.1 pmol per ml of human serum. Validity of the enzyme immunoassay was confirmed by radioimmunoassay and gas chromatography/mass spectrometry (GC-MS) of a methyl ester n-butoximedimethylisopropylsilyl ether derivative.     

On the metabolism of prostaglandin F 2 in female subjects. Structures of two C 14 metabolites

[9 beta-3H] prostaglandin F2alpha was injected intravenously into female subjects and the metabolites appearing in the urine were isolated. The structures of 2 metabolites were determined. These were C14 compounds and were assigned the structures alpha dihydroxy-11-keto(tetranor, omega-dinor)-prosta-1,14-dioic acid and 5 alpha, Palphoc 11-trihydroxy-(tetranor omega-dinor)-prosta-1,14-dioic acid (identified as its gamma lactone). Both these metabolites also occurred in their corresponding delta-lactone forms.     

The purification and properties of NADPH-dependent carbonyl reductases from rat ovary

Two carbonyl reductases have been highly purified from rat ovary to apparent homogeneity. Though they have similarities in terms of molecular weight (33,000), substrate specificities, inhibitor sensitivities, amino acid composition, and immunological properties, they differed in pI values (6.0 and 5.9). Both enzymes reduced aromatic aldehydes, ketones, and quinones at higher rates, compared to prostaglandins and 3-ketosteroids, whereas they showed higher affinity for prostaglandins and 3-ketosteroids. The enzymes also catalyzed oxidation of the 9-hydroxy group of prostaglandin F2 alpha. Moreover, they showed the remarkable characteristic of catalyzing the reduction of not only the 9-keto group of prostaglandin E2 but also the 15-keto group of 13,14-dihydro-15-keto-prostaglandin F2 alpha. Both enzymes were inhibited by SH-reagents, quercitrin, indomethacin, furosemide, and disulfiram. The results of immunoinhibition, using antibody against the purified enzymes, indicated that the enzymes were solely responsible for the overall catalytic activities of prostaglandin E series reduction, as well as 13,14-dihydro-15-keto-prostaglandin F2 alpha reduction and prostaglandin F2 alpha oxidation in rat ovarian cytosol. Western-blot analysis revealed that immunoreactive proteins were present in adrenal gland and various reproductive tissues except uterus of rats.     

Prostaglandin catabolism in fetal and maternal tissues--a study of 15-hydroxyprostaglandin dehydrogenase and delta 13 reductase with specific assay methods

Recent studies have demonstrated that extraductal tissues such as lung are important sources of prostaglandin E2 which maintains the patency of ductus arteriosus in fetuses and prematurely-born infants. Also, organs such as lung are known to be active in the catabolism of PGE2. Earlier studies of enzymes involved in the catabolism of PGE2 such as 15-hydroxyprostaglandin dehydrogenase (15-PGDH) and delta 13 reductase all used non-specific methods. In the present report, we studied 15-PGDH in fetal and maternal rat lung, kidney, and fetal lamb lung, kidney and ductus arteriosus with the use of a specific substrate (15-S)-[15(3)H-PGE2]. In addition, we measured the activity of delta 13 reductase in these tissues by measuring the conversion of [1-14C]-15-keto PGE2 to [1-14C]-15-keto-13,14-dihydro PGE2. The results from these studies demonstrated that in fetal rat lung and kidney, 15-PGDH activities increased rapidly while delta 13 reductase remained unchanged during late gestation. Ductus arteriosus possessed little 15-PGDH activities. These results strongly suggest that extraductal regulation of PGE2 metabolism is important in determining ductal caliber in fetuses and prematurely delivered neonates.     

The effect of vitreous humour on prostaglandin production by cultured rabbit chorioretinal fibroblasts

Factors in vitreous humour which regulate prostaglandin production were investigated using cultured rabbit chorioretinal fibroblasts. These cells produced predominantly prostaglandin E2, 6-ketoprostaglandin F1 alpha, a compound likely to be a metabolite of prostaglandin E2 and 5-hydroxyeicosatetraenoic acid. The synthesis of 6-ketoprostaglandin F1 alpha was nearly completely inhibited by the cyclooxygenase inhibitor aspirin and partially inhibited by 10(-6) M dexamethasone (49%) and 10(-5) M forskolin (68%). Addition of 10% rabbit vitreous humour to subconfluent cells maintained in Dulbecco's modified Eagle's medium plus 1% fetal bovine serum resulted in stimulation of 6-ketoprostaglandin F1 alpha production by as much as 246% as measured by radioimmunoassay. Chorioretinal fibroblasts labelled by [3H]arachidonic acid incorporation into cellular phospholipids synthesised greater amounts of all labelled arachidonic acid metabolites in response to vitreous humour. It was concluded, therefore, that there are factors present in vitreous humour of molecular weight above 10 kDa which are capable of stimulating cellular cyclooxygenase activity. Confluent cells also responded to a factor(s) present in vitreous humour. The fraction of less than 10 kDa inhibited 6-ketoprostaglandin F1 alpha production by 50% when used at a concentration of 10%. Furthermore, 6-ketoprostaglandin F1 alpha production in confluent cells (but not subconfluent cells) was inhibited to 40% of control levels by vitamin C at a concentration of 1 mg/100 ml. The latter result points to an inhibitory role for vitamin C in vitreous humour. We conclude, therefore, that vitreous humour contains factors important for the regulation of prostaglandin metabolism in the eye.