Isolation and biosynthesis of 18-hydroxyprostaglandins E1 and E2 in human seminal fluid

18-Hydroxy-PGE1 and 18-hydroxy-PGE2 were identified in human seminal fluid by capillary gas-liquid chromatography-mass spectrometry. The levels of these prostaglandins was 1-2% of the corresponding 19-hydroxy-PGE compounds in human semen. 18-Hydroxy-PGE1 and 18-hydroxy-PGE2 are likely formed by cytochrome P-450 in seminal vesicles in analogy with the 19-hydroxy-PGE compounds. This was supported by the finding that microsomes of seminal vesicles of the cynomolgus monkey, Macaca fascicularis, supplemented with 1 mM NADPH, metabolized PGE1 to both 19-hydroxy-PGE1 (92%) and 18-hydroxy-PGE1 (8%). The hydroxylation of prostaglandins in seminal vesicles of primates may thus show a high but not absolute specificity for the penultimate carbon of prostaglandins.     

Identification and biological activity of a novel natural prostagladin, 5,6-dihydro-prostaglandin E3

A novel natural E-prostaglandin was detected by HPLC among the endogenous prostaglandins extracted from ram seminal vesicles. The corresponding precursor — all-cis-eicosa-8,11,14,17-tetraenoic acid was isolated from bovine liver lipids and the preparative biosynthesis with the microsomal fraction of ram seminal vesicles was performed. The isolated product was purified by HPLC and identified by GC-MS as 5,6-dihydro-PGE₃. The results of in vitro testss demonstrate that 5,6-dihydro-PGE₃ is 14 times less active uterine stimulant than PGE₁, at the same time retaining 75% of the anti-aggregatory potency of PGE₁. Thus, 5,6-dihydro-PGE₃ meets the requirements of a selective antithrombotic agent more than PGE₁.     

Rapid and slow hydroxylators of seminal E prostaglandins

Human seminal fluid contains prostaglandin (PG) E1, PGE2, 19-hydroxy-PGE1 and 19-hydroxy-PGE2 in large and variable amounts. 19-Hydroxy-PGE1 and 19-hydroxy-PGE2 are formed from PGE1 and PGE2 by prostaglandin 19-hydroxylase, a cytochrome P-450 enzyme, in seminal vesicles. The hypothesis that genetic polymorphism of this enzyme might contribute to the variable concentrations of PGE1, PGE2, 19-hydroxy-PGE1 and 19-hydroxy-PGE2 was examined by analysis of seminal fluid of 40 normal men. E prostaglandins were measured with 17-phenyl-PGE2 as an internal standard by high-performance liquid chromatography on beta-cyclodextrin silica. Using the ratios of substrate/product, i.e., R1 = PGE1/19-hydroxy-PGE1 and R2 = PGE2/19-hydroxy-PGE2, as indicators of prostaglandin 19-hydroxylase capacity, a bimodal distribution of R values was found: nine men (23%) were slow hydroxylators (R1 greater than 0.45 and R2 greater than 0.45), while the remaining men were rapid hydroxylators (both R1 and R2 less than 0.45). Semen of slow hydroxylators and semen of the five most rapid hydroxylators (both R1 and R2 less than 0.10) differed in absolute amounts of PGE1 and PGE2 but not in 19-hydroxy-PGE1 and 19-hydroxy-PGE2. 20-Hydroxy-PGE1 and 20-hydroxy-PGE2 are formed from PGE1 and PGE2 by cytochrome P-450 in the vesicular glands and the ampullae of deferent ducts of the ram. Seminal fluid of five rams was analyzed for PGE1, PGE2, 20-hydroxy-PGE1 and 20-hydroxy-PGE2, and a large variation in substrate/product ratios was found. Polymorphism of cytochrome P-450 might contribute to variations in seminal prostaglandins in man and in sheep.     

Contraction of seminal vesicle and prostaglandin E1

It was studied how PGE₁ would affect the responses of isolated human seminal vesicles to adrenalin. PGE₁ in the final concentration of 1.3 μg/ml suppressed the contraction of human seminal vesicle that would have occurred in reaction to adrenalin added one minute later. When the concentration of PGE₁ was increased to 6.7 μg/ml, the inhibitory action was further enhanced. The meanings of this phenomenon were discussed.     

Identification of CYP4F8 in human seminal vesicles as a prominent 19-hydroxylase of prostaglandin endoperoxides

A novel cytochrome P450, CYP4F8, was recently cloned from human seminal vesicles. CYP4F8 was expressed in yeast. Recombinant CYP4F8 oxygenated arachidonic acid to (18R)-hydroxyarachidonate, whereas prostaglandin (PG) D(2), PGE(1), PGE(2), PGF(2alpha), and leukotriene B(4) appeared to be poor substrates. Three stable PGH(2) analogues, 9,11-epoxymethano-PGH(2) (U-44069), 11, 9-epoxymethano-PGH(2) (U-46619), and 9,11-diazo-15-deoxy-PGH(2) (U-51605) were rapidly metabolized by omega2- and omega3-hydroxylation. U-44069 was oxygenated with a V(max) of approximately 260 pmol min(-)(1) pmol P450(-1) and a K(m) of approximately 7 micrometer. PGH(2) decomposes mainly to PGE(2) in buffer and to PGF(2alpha) by reduction with SnCl(2). CYP4F8 metabolized PGH(2) to 19-hydroxy-PGH(2), which decomposed to 19-hydroxy-PGE(2) in buffer and could be reduced to 19-hydroxy-PGF(2alpha) with SnCl(2). 18-Hydroxy metabolites were also formed (approximately 17%). PGH(1) was metabolized to 19- and 18-hydroxy-PGH(1) in the same way. Microsomes of human seminal vesicles oxygenated arachidonate, U-44069, U-46619, U-51605, and PGH(2), similar to CYP4F8. (19R)-Hydroxy-PGE(1) and (19R)-hydroxy-PGE(2) are the main prostaglandins of human seminal fluid. We propose that they are formed by CYP4F8-catalyzed omega2-hydroxylation of PGH(1) and PGH(2) in the seminal vesicles and isomerization to (19R)-hydroxy-PGE by PGE synthase. CYP4F8 is the first described hydroxylase with specificity and catalytic competence for prostaglandin endoperoxides.     

Biochemical characterization of prostaglandin 19-hydroxylase of seminal vesicles

The microsomal fraction of homogenates of seminal vesicles of men and monkeys, Macaca fascicularis, were analyzed for prostaglandin (PG) 19-hydroxylase activity. The microsomes of the monkey seminal vesicles, supplemented with 1 mM NADPH, metabolized 0.2 mM PGE1 to 19-hydroxy-PGE1 at a mean rate of 0.26 nmol/min/mg of protein (with an apparent Km and an apparent Vmax of 40 microM and 0.30 nmol/min/mg of protein, respectively). The enzyme catalyzed the incorporation of atmospheric oxygen into the substrate. Substituting NADH for NADPH reduced the prostaglandin E1 19-hydroxylase activity to 40%. Carbon monoxide and proadifen (SKF 525A) inhibited the enzyme. Prostaglandin E2 (0.2 mM) was metabolized to 19-hydroxyprostaglandin E2 (0.2 nmol/min/mg of protein), but PGE1 was preferred as a substrate. Prostaglandin B1 was metabolized to 18-hydroxy-, 19-hydroxy-, and 20-hydroxyprostaglandin B1 at a combined rate of approximately 25% of prostaglandin E1. 19-Hydroxyprostaglandin B1 was the main product. The microsomes of human seminal vesicles metabolized 0.2 mM PGE2 to 19-hydroxy-PGE2 in the presence of 1 mM NADPH, while carbon monoxide inhibited this reaction. These results suggest that prostaglandin 19-hydroxylase of seminal vesicles might be a cytochrome P-450. The biosynthesis of 19-hydroxyprostaglandin E1 and 19-hydroxyprostaglandin E2 was also studied in vivo in man by analysis of the product/substrate ratios (i.e. 19-hydroxyprostaglandin E1/prostaglandin E1 and 19-hydroxyprostaglandin E2/prostaglandin E2) in a series of consecutive ejaculates, which were obtained during short intervals. There was a 10-fold interindividual difference in these ratios. Although the product/substrate ratios decreased, the 19-hydroxylation of E prostaglandins appeared to be efficient in vivo, which was in contrast to the rather slow biosynthesis in vitro.     

Phosphatidylethanolamide derivatives of prostaglandins E1 and E2

Prostaglandins E₁ (PGE₁) and E₂ (PGE₂) have been coupled with the amine group of phosphatidylethanolamine (PE) by means of dicyclohexylcarbodiimide. These complexes basically mimic the relaxant and contractile effects of the corresponding free prostaglandins (PGs) on various smooth muscle preparations, but exhibit a delayed onset of action and a lower affinity for the PG receptors. The complexes are comparable with the free, parent PGs, in their intrinsic activities. The same holds true for the effects on blood pressure and on the motility of the uterus . The PGE₂-PE complex is hydrolysed to release obviously free PGE₂ by cell-free homogenates prepared from various tissues, but not by blood plasma. The PGE₂-PE complex is immunologically indistinguishable from the free PGE₂.     

Failure of prostaglandins E1 and E2 to alter canine gastric mucosal cyclic nucleotides

The action of prostaglandins and indomethacin on gastric mucosal cyclic nucleotide concentrations was evaluated in 18 anesthetized mongrel dogs. Prostaglandins E₁ (PGE₁) and E₂ (PGE₂) (25 μg/kg bolus, then 2 μg/kg/min) were administered both intravenously (4 experiments; femoral vein) and directly into the gastric mucosal circulation (10 experiments; superior mesenteric artery). The possible synergistic effect of pre-treatment and continuous arterial infusion of indomethacin (5 mg/kg bolus for 5 min, then 5 mg/min), a prostaglandin synthetase inhibitor, with PGE₂ was studied in 4 experiments. Antral and fundic mucosa were biopsied and measured by radioimmunoassay for cyclic nucleotides. Doses of PGE₁ and PGE₂ which inhibited histamine-stimulated canine gastric acid secretion did not significantly alter antral or fundic mucosal cyclic nucleotide concentrations. Concomitant infusion of PGE₂ with indomethacin did not potentiate the mucosal nucleotide response compared to PGE₂ alone. These studies fail to implicate cyclic nucleotides as mediators of the inhibitory acid response induced by PGE₁ or PGE₂ in intact dog stomach.     

Quantitative determination of prostaglandins E1 and F1α by multiple ion analysis

Quantitative assays for prostaglandins (PG) E₁ and PGF_1α are described using [3,3,4,4,5,6-²H₆]labeled prostaglandins as carriers and methyl ester-O-methyloxime-acetate (PGE₁) and methyl ester-acetate (PGF_1α) derivatives for gas - liquid chromatography/mass spectrometric analysis. Thin-layer argentation chromatography was used to separate PGE₁ from PGE₂ and 13, 14-dihydro-PGE₂. These latter compounds, which do not separate from PGE₁ using conventional thin-layer chromatography or under the gas - liquid chromatographic conditions used, can significantly interfere with the quantitative analysis of PGE₁. The method described prevents this interference and is therefore suitable for the accurate analysis of PGE₁ in biological samples containing a high concentration of PGE₂ and/or 13, 14-dihydro-PGE₂.     

Effect of prostaglandins E1, E2 and F2α on neutrophil aggregation

Recently we have found that chemotactic factors stimulate neutrophils in suspension to aggregate. Because of an obvious analogy to platelet aggregation, we examined the influence of three prostaglandins on this process. Prostaglandins E₁, E₂ and F_2α alone did not cause aggregation of the neutrophils but were able to partially inhibit the aggregation response induced by the synthetic chemotactic tripeptide, formly-methionyl-leucyl-phenylalanine. The minimal inhibitory concentrations for prostaglandins E₁, E₂ and F_2α were 10⁻⁷, 10⁻⁶ and 10⁻⁵M, respectively. These results are similar to those found for the prostaglandin-induced inhibition of platelet aggregation. It may be, therefore, that neutrophil aggregation, like platelet aggregation, is modulated by intracellular prostaglandins and other products of arachidonic acid metabolism.     

Acute toxicity of prostaglandins E2,F2α and 15 (s) 15 methyl prostaglandin E2 methyl ester in the baboon

The cardiovascular, uterine stimulant and gastrointestinal effects of prostaglandins E₂, F_2α and 15 (S) 15 methyl PGE₂ methyl ester in the East African Baboon (P. Anubis) have been studied. In these three parameters the baboon responds both qualitatively and quantitatively in a similar manner to man. The lethal doses of the prostaglandins given by bolus intravenous injelctions have been determined and the human lethal doses estimated.     

Prostaglandins and inflammation: Enhancement of monocyte chemotactic responsiveness by prostaglandin E2

The effects of prostaglandins on human monocyte chemotaxis were studied $\text{in vitro}$. None of the prostaglandins tested, including members of the A, B, E or F series, were chemotactic for monocytes. Prostaglandin E₂ however, enhanced the chemotactic responsiveness of monocytes to complement - activated human serum by almost 200%. The enhancement of chemotaxis was not directly related to the ability of PGE₂ to raise intracellular cyclic AMP levels. These studies support a role for prostaglandins as modulators of the inflammatory response.     

Utility of d4-PGE2 as an internal standard to quantify endogenous levels of PGE1, PGE2, 190H PGE1 and 190H PGE2 in human seminal fluid by GC-MS-SIM

Four prostaglandins-PGE₁, PGE₂, 190H PGE₁ and 190H PGE₂-were quantified in human seminal fluid by GC-MS-SIM using only the internal standard, d₄-PGE₂. Methods and calculations were developed to minize errors inherent in using only one internal standard for quantifying four closely related prostaglandins. Preliminary data concerning the statistical significance of the differences found between PGE and 190H PGE levels in fertile, azospermic and oligospermic men are reported.     

Interactions of prostaglandins with subpopulations of ovine luteal cells. I. Stimulatory effects of prostaglandins E1, E2 and I2

Preparations of small and large steroidogenic cells from enzymatically dispersed ovine corpora lutea were utilized to study the effects of luteinizing hormone (LH) and prostaglandins (PG) E₁, E₂ and I₂. Cells were allowed to attach to culture dishes overnight and were incubated with either LH (100 ng/ml), PGE₂, PGE₂, or PGI₂ (250 ng/ml each). The secretion of progesterone by large cells was stimulated by all prostaglandins tested (P < 0.05) while the moderate stimulation observed after LH treatment was attributable to contamination of the large cell population with small cells. Prostaglandins E₁ and E₂ had no effect on progesterone secretion by small cells, while LH was stimulatory at all times (0.5 to 4 hr) and PGI₂ was stimulatory by 4 hr. Additional studies were conducted to determine if the effects of PGE₂ upon steroidogenesis in large cells were correlated with stimulated activity of adenylate cyclase. In both plated and suspended cells PGE₂ caused an increase (P < 0.05) in the rate of progesterone secretion but had no effect upon the activity of adenylate cyclase or cAMP concentrations within cells or in the incubation media. Exposure of luteal cells to forskolin, a nonhormonal stimulator of adenylate cyclase, resulted in marked increases in all parameters of cyclase activity but had no effect on progesterone secretion. These data suggest that the actions of prostaglandins E₁, E₂ and I₂ are directed primarily toward the large cells of the ovine corpus luteum and cast doubt upon the role of adenylate cyclase as the sole intermediary in regulation of progesterone secretion in this cell type.     

Effects of prostaglandins E2 and F2α on lecithin biosynthesis by cultured lung cells

Transformed cells from human lung carcinoma (Line A549), resembling type II pneumocytes, were cultured in monolayer at 37°C and incubated for five hours with ³H-choline and ¹⁴C-palmitate in the presence of various concentrations of prostaglandins (PGs) E₂ and F_2α. In the control (no PG) the level of % palmitate incorporation was 13.5 × as high as that of choline, after taking isotope dilution into account. Between the concentrations studied, 0.1 and 10 μM, both prostaglandins stimulated markedly the incorporation of both precursors, though choline up to 3 × better than palmitate. This was indicated by a change in the palmitate/choline incorporation ratio from 13.5 to as low as 4.2. At the lowest PG concentration, 0.1 μM, PGE₂ was much more effective than PGF_2α in stimulating the incorporation of both precursors.     

Metabolism of prostaglandins A1 and A2 by human whole blood

The effect of human blood on prostaglandin metabolism in vitro was studied at 37°C and 4°C. Labeled prostaglandins were incubated for up to one hour in whole blood or plasma. After extraction, the prostaglandins were purified by LH-20 Sephadex chromatography. Appropriate ¹⁴C labeled compounds, when available, were used to correct for losses. Metabolism was determined by comparison of incubated samples with zero time controls. There was no reduction in isotopic recovery of prostaglandins B₁, B₂ and E₁ after incubation with whole blood for up to one hour. In contrast, human whole blood, but not plasma, rapidly metabolized prostaglandins A₁ and A₂ at 37°C. The rate of metabolism was temperature dependent, but still continued at 4°C. The products of these reactions were not identified, but they appeared to remain in the aqueous solution after extraction with the neutral organic solvent.     

Prostaglandin E1 and E2 in bovine semen: Quantification by gas chromatography

Prostaglandins PGE₁ and PGE₂ extracted from bovine semen, purified via silicic column chromatography were quantified by gas chromatography as their methoxime methyl ester trimethylsilyl ether derivatives. The PGE₁ and PGE₂ concentrations of 19 bovine semen samples ranged from 395 ± 225 and 487 ± 407 ng/ml, respectively. A constant 1:1 ratio between PGE₁ and PGE₂ was observed. There was no relationship between PGE and sperm motility, but high sperm counts were generally associated with decreased PGE levels. The direct precursors of PGE₁ and PGE₂, i.e. 20:3n6 and 20:4n6, occurred in low concentrations compared to other related unsaturated fatty acids, i.e. 18:2n6 and 22:5n6 of the n-6 family.     

The preparation and characterization of prostaglandin E1 antiserum

Antiserum against PGE₁ was raised in rabbits following immunization with prostaglandin-thyroglobulin conjugates. The antiserum exhibits 22% cross reactivity with PGE₂ but little or no apparent cross reaction with PGE₁ metabolites or heterologous prostaglandins. The data indicate some limitations in the use of this antiserum for the measurement of PGE₁ in biologic samples.