“Relationship between seminal PGE and 19-OH PGE and seminal fructose in man”

Seminal PGE, 19-OH PGE and fructose were assayed in normal volunteers and in infertile patients. From data obtained it appears that seminal PGE are probably not synthesized exclusively at seminal vesicles level since no relationship was observed between PGE and fructose. On the other hand the seminal vesicles appear to be the preferential site of seminal 19-OH PGE production since a close relationship was observed between 19-OH PGE and fructose in those case in which these prostaglandins were below minimum normal values. Various hypotheses are advanced in order to interpret the lack of correlation in the presence of high 19-OH PGE levels.     

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.     

Utility of d4-PGE2 as an internal standard to quantify endogenous levels of PGE1, PGE2, 19OH PGE1 and 19OH PGE2 in human seminal fluid by GC-MS-SIM

Four prostaglandins-PGE1, PGE2, 19OH PGE1 and 19OH PGE2-were quantified in human seminal fluid by GC-MS-SIM using only the internal standard, d4-PGE2. Methods and calculations were developed to minimize errors inherent in using only one internal standard for quantifying four closely related prostaglandins. Preliminary data concerning the statistical significance of the difference found between PGE and 19OH PGE levels in fertile, azospermic and oligospermic men are reported.     

Immunosuppression by seminal plasma from fertile and infertile men: Inhibition of natural killer cell function correlates with seminal PG concentration

Human seminal plasma has uniquely high concentrations of PGE and 19-hydroxy PGE but the function of these PGs has not been elucidated. PGs of the E series have been shown to be paracrine and autocrine regulators of the function of immune cells and high levels of PGE have been shown consistently to suppress function in such cells. Human seminal plasma has a potent immunosuppressive effect and evidence is accumulating that this is largely due to PG components. In this study the effects of human seminal plasma on the killing activity of natural killer (NK) cells as judged by 51Cr release from K562 cells have been studied in groups of fertile and infertile men. Although there was no significant difference in the PGE, 19-hydroxy PGE or the NK cell inhibitory activity in the two groups, the inhibition of NK cell activity was closely correlated with the PGE and the 19-OH PGE content of the seminal plasma in the fertile group. This finding is further evidence that the major contribution to the immunosuppressive properties of human semen is provide by the high concentration of PGs of the E series in this fluid.     

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.     

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.     

Observations on the substrate specificity of prostaglandin hydroxylases of monkey seminal vesicles and sheep vesicular glands

Prostaglandin (PG) 19-hydroxylase of monkey seminal vesicles metabolizes PGE1 and PGE2 to their 19-hydroxy metabolites, while PGE2 20-hydroxylase of ram vesicular glands metabolizes PGE2 to 20-hydroxy-PGE2. The purpose of the present study was determine whether PGF2 alpha is a substrate of these enzymes. Deuterated 20-hydroxy-PGF2 alpha was employed as an internal standard to study the hydroxylation of PGF2 alpha (0.2 mM) by microsomes of monkey (Macaca fascicularis) seminal vesicles in the presence of NADPH, and the biosynthesis was compared with the hydroxylation of PGE2 under identical conditions. 19-Hydroxy-PGF2 alpha was formed at a rate of 3.5% of the formation of 19-hydroxy-PGE2. Microsomes of ram vesicular glands also hydroxylated PGE2 more efficiently than PGF2 alpha, which was converted to both 20-hydroxy-PGF2 alpha and 19-hydroxy-PGF2 alpha at a combined rate of 5% of the biosynthesis of 20-hydroxy-PGE2 under the same conditions. 20-Hydroxy-PGF2 alpha was demonstrated in ram semen, but the concentration was low (0.1 microM) in comparison with 20-hydroxy-PGE2 (24 microM). The two genital PG hydroxylases thus metabolize PGF2 alpha much less efficiently than PGE2. This finding may suggest that 19-hydroxy- and 20-hydroxy-PGF2 alpha in seminal fluids also could be formed by other mechanisms, e.g., from 19-hydroxy- and 20-hydroxy-PGE2 by the PGE 9-keto reductase enzyme.     

The measurement of E and 19-hydroxy E prostaglandins in human seminal plasma.

A method is described which measures the four main prostaglandins of human semen (PGE1, E2, 19-hydroxy PGE1, and 19-hydroxy PGE2). For routine measurements E1 and E2 are measured together as are 19-OH E1 and 19-OH E2. These are measured by forming oximes in aqueous solution extraction, methylation and trimethyl silylation followed by gas chromatography. The method has sufficient sensitivity to measure the levels found in the majority of semen samples. The normal range in men with proven fertility was 90 to 260 mug/ml of 19-hydroxy Es and 30-200 mug/ml of Es.     

Testosterone concentration in testicular venous blood of adult rats and seminal citric acid and fructose concentration as well as weight of accessory sex organs.

In 31 adult rats of Wistar strain (body weight 231 +/- 14g) the relationships between testosterone concentration in testicular venous blood of an individual rat and weight of accessory sex organs (testes, seminal vesicles, ventral prostate, levator ani muscle) and citric acid and fructose concentrations in seminal vesicles were investigated. No direct relationship was found between testosterone concentration and the above parameters. The correlation coefficient varied from 0.042 to 0.394.     

Age-related changes in the seminal vesicles of a Brazilian (Nelore) zebu.

Age changes in the structure of the seminal vesicles and in the rate of production of fructose and citric acid have been studied in a Brazilian (Nelore) zebu, from the fetal period to 36 months of age. At 3 and 6 months, the microscopic anatomy of the gland resembled that of the fetus; the tubules of the seminal vesicles had a reduced diameter and a low epithelial layer; only a few presented traces of secretion, and tissue contents of fructose and citric acid were accordingly low. At 12 months, the tubules were more ramified and had a larger diameter. In the 18-month-old animals the seminal vesicles presented substantial modifications; the tubules were large, with irregular lumina and surrounded by narrow stroma, the epithelial layer was higher than that of previous stages and its columnar cells had nuclei located basally. Tissue levels of fructose increased rapidly between 12 and 18 months. At 24 months, the seminal vesicles had reached the adult condition characterized by intense proliferation of tubules with irregular lumina and abundant secretory material. Numerous dark columnar cells were found in the epithelium. Seminal vesicles of Nelore zebus contain less fructose and citric acid than those of taurine bulls of comparable age.     

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.     

Prostaglandins and the rat seminal vesicle: effects of mating and adrenergic stimulation

The concentrations of PGE, PGF, and 6-keto-PGF1 alpha were increased in rat seminal vesicle tissue following mating activity. Likewise, synthesis of PGE and PGF was stimulated by epinephrine (3 X 10(-7) to 3 X 10(-6) M) in tissues and media from in vitro incubations of intact rat seminal vesicles. The in vitro stimulation was inhibited by phentolamine, an alpha-adrenoreceptor blocking agent. Carbamylcholine (2 X 10(-6) M) and bradykinin (1 X 10(-6) M) had no effect on PGE or PGF synthesis, even though both compounds stimulated contractility of the rat seminal vesicle at these concentrations. These data suggest that mating and adrenergic stimulation increase prostaglandin synthesis in the rat seminal vesicle, probably through an alpha-adrenergically mediated mechanism.     

Prostaglandin levels in infertile patients affected by asthenozoospermia and prostatitis

19-hydroxy-prostaglandins and prostaglandins of the E series (19-OH PGEs) were estimated in the seminal plasma of asthenozoospermic patients (n = 15) and individuals affected by prostatitis (n = 10) and compared to controls (n = 13) and secretory azoospermic patients (n = 8). All of them were free from infections (except individuals affected by prostatitis), biochemical and ultrastructural problems. The results indicate that endogenous prostaglandin levels (19-OH PGEs and PGEs) bear no correlation either to motility or absence of spermatozoa. Significant increases of PGEs were observed in patients affected with prostatitis. Surprisingly PGE levels showed no correlation with the levels of 19-OH PGEs.     

Effect of hCG injection on prostaglandin E concentrations in ram seminal plasma

Ram and bull seminal plasma, respectively, contain 0.5-20 microg PGE/ml and 5-10 ng PGE/ml. To demonstrate that PGE concentrations in the seminal plasma are related to sperm quality and could be affected by hormonal stimulation in vivo, four rams were injected with 500 IU hCG, in and out of season. The rams responded 1 week after hCG with a 1.5- to 4-fold increase in seminal plasma PGE. The PGE peak was temporally separate from the hCG-induced rise in seminal plasma testosterone which was observed after 1 day. Using a simulated cryptochid ram, peaks in seminal fluid PGE were found to be associated with increased sperm velocity and sperm counts. In bulls, PGE concentrations in the seminal plasma of good bulls were significantly higher than that found in poor and cryptorchid bulls.     

High and testosterone-dependent glucose 6-phosphatase activity in epithelium of mouse seminal vesicle

For study of the mechanism of seminal fructogenesis, glucose 6-phosphatase activity was examined cytochemically (a method modified from that of Wachstein and Meisel) and biochemically (the method of Leskes et al.) in seminal vesicles from normal, castrated, and castrated and testosterone-treated mice. The reaction product for the activity was localized in the endoplasmic reticulum and nuclear envelope of all cell types composing the seminal vesicle. In normal seminal vesicle, the reaction product was apparently more abundant in columnar and basal cells than in other cell types. Ten, 20, and 30 days after castration, the abundant amount of reaction product in columnar and basal cells decreased to the level in other cell types. In animals treated with testosterone after castration, however, the reaction product in columnar and basal cells remained abundant. If fructose 6-phosphate was added to the reaction medium in place of glucose 6-phosphate, the amount and pattern of deposition of the reaction product did not change. Changes in biochemical activity in castrated or castrated and testosterone-treated animals paralleled the cytochemical results. The results show that the high activity in columnar and basal cells is under the control of testosterone, and the role of this enzyme is probably to release fructose into the seminal fluid.     

In vitro PGE2 synthesis by seminal vesicular microsomes: hysteretic behaviour in the presence of calcium ions

When 4 mM Ca2+ is added gratuitiously in the reaction mixture synthesizing prostaglandin E2 (PGE2) from arachidonic acid and cofactors by membrane associated microsomal multienzyme system (MES) prepared from goat seminal vesicles, one observes an immediate lag in the production of PGE2. This Ca2+ induced lag is clearly due to the hysteretic response of MES promoted by Ca2+ ligand and not mediated through any effect of the divalent cation on the membrane, such as membrane phase separation. Preincubation studies indicated that the hysteretic response of MES is not due to Ca2+ ligand alone, but the substrate(s) also co-operate to modulate the enzyme system to demonstrate the characteristic nonlinear kinetics.     

Prostaglandins in human seminal plasma. Prostaglandins and related factors 46

This study on human seminal plasma sought after the compounds which either possess the dienone chromophore or can be converted into it by treatment with sodium hydroxide. In addition, this investigation led to the isolation of 8 more (PGs) prostaglandins which were present in higher concentrations than the previously recognized PGs. Samples of human seminal plasma were subjected to silicic acid chromatography, reversed phase partition chromatography, thin layer chromatography, and gas liquid chromatography which isolated those 8 PGs not previously recognized. 4 of these compounds, PGE1-217, PGE2-217, PGE1-278, and PGE2-278 were known from earlier studies but had not been isolated from natural sources. The other 4 were 19 hydroxy derivatives of the 4 abovementioned compounds. The concentrations of the previously recognized PGs were recently determined and it was found that the 19 hydroxy derivatives were present in concentrations 4 times higher than the PGE compounds.     

Prostaglandins and the rat seminal vesicle: Effects of mating and adrenergic stimulation

The concentrations of PGE, PGF, and 6-keto-PGF_1α were increased in rat seminal vesicle tissue following mating activity. Likewise, synthesis of PGE and PGF was stimulated by epinephrine (3 × 10⁻⁷to 3 × 10⁻⁶ M) in tissues and media from incubations of intact rat seminal vesicles. The stimulation was inhibited by phentolamine, an α-adrenoreceptor blocking agent. Carbamylcholine (2 × 10⁻⁶ M) and bradykinin (1 × 10⁻⁶ M) had no effect on PGE or PGF synthesis, even though both compounds stimulated contractility of the rat seminal vesicle at these concentrations. These data suggest that mating and adrenergic stimulation increase prostaglandin synthesis in] the rat seminal vesicle, probably through an α-adrenergically mediated mechanism.