Isolation of 19,20-dehydroprostaglandins E1 and E2 in human seminal fluid and further studies on 18,19-dehydroprostaglandins E1 and E2

Human seminal fluid was recently found to contain 18,19-dehydroprostaglandins E1 and E2 (E. H. Oliw, H. Sprecher, and M. Hamberg, (1986) J. Biol. Chem. 261, 2675-2683). In the present study, the cis and trans isomers of 18,19-dehydroprostaglandins E1 and E2 were prepared by incubation of microsomes of ram vesicular glands and glutathione with the precursor fatty acids, 8(Z),11(Z),14(Z),18(E/Z)-eicosatetraenoic acids, and 5(Z),8(Z),11(Z),14(Z),18(E/Z)-eicosapentaenoic acids, and used as references to characterize the 18,19-dehydroprostaglandins of human seminal fluid. Based on separation by reversed-phase high-performance liquid chromatography, capillary gas chromatography-mass spectrometry, and ozonolysis of the (-)-menthoxycarbonyl derivatives and on comparison with the authentic compounds, human seminal fluid was found to contain both the cis and trans isomers of 18,19-dehydroprostaglandins E1 and E2. Furthermore, human seminal fluid contained two related compounds, viz. 19,20-dehydroprostaglandins E1 and E2. The structures of these compounds were established by conversion into the corresponding prostaglandin B compounds, by mass spectrometric analysis and by chemical degradation by oxidative ozonolysis, which afforded, inter alia, 2(S)-hydroxy-adipic acid.     

Prostaglandin E synthase, a terminal enzyme for prostaglandin E2 biosynthesis

Biosynthesis of prostanoids is regulated by three sequential enzymatic steps, namely phospholipase A2 enzymes, cyclooxygenase (COX) enzymes, and various lineagespecific terminal prostanoid synthases. Prostaglandin E synthase (PGES), which isomerizes COX-derived PGH2 specifically to PGE2, occurs in multiple forms with distinct enzymatic properties, expressions, localizations and functions. Two of them are membrane-bound enzymes and have been designated as mPGES-1 and mPGES-2. mPGES-1 is a perinuclear protein that is markedly induced by proinflammatory stimuli, is down-regulated by antiinflammatory glucocorticoids, and is functionally coupled with COX-2 in marked preference to COX-1. Recent gene targeting studies of mPGES-1 have revealed that this enzyme represents a novel target for anti-inflammatory and anti-cancer drugs. mPGES-2 is synthesized as a Golgi membrane-associated protein, and the proteolytic removal of the N-terminal hydrophobic domain leads to the formation of a mature cytosolic enzyme. This enzyme is rather constitutively expressed in various cells and tissues and is functionally coupled with both COX-1 and COX-2. Cytosolic PGES (cPGES) is constitutively expressed in a wide variety of cells and is functionally linked to COX-1 to promote immediate PGE2 production. This review highlights the latest understanding of the expression, regulation and functions of these three PGES enzymes.     

Microsomal prostaglandin E synthase-2 is not essential for in vivo prostaglandin E2 biosynthesis

Prostaglandin E₂ (PGE₂) plays an important role in the normal physiology of many organ systems. Increased levels of this lipid mediator are associated with many disease states, and it potently regulates inflammatory responses. Three enzymes capable of in vitro synthesis of PGE₂ from the cyclooxygenase metabolite PGH₂ have been described. Here, we examine the contribution of one of these enzymes to PGE₂ production, mPges-2, which encodes microsomal prostaglandin synthase-2 (mPGES-2), by generating mice homozygous for the null allele of this gene. Loss of mPges-2 expression did not result in a measurable decrease in PGE₂ levels in any tissue or cell type examined from healthy mice. Taken together, analysis of the mPGES-2 deficient mouse lines does not substantiate the contention that mPGES-2 is a PGE₂ synthase.     

Reaction mechanism of prostaglandin E2 biosynthesis and its modeling

The reaction mechanism of PGE₂ biosynthesis was investigated by a detailed examination of the cyclo-oxygenase and PGE₂-isomerase activities in acetone-pentane powder (microsomal fraction of ram seminal vesicular glands). Two main types of inactivating process were recognized in the reaction system. One type was due to irreversible inactivation caused by the oxidizing agent [O]^·_X released through the reduction of PGG₂ to PGH₂, while the other type was due to reversible inhibition which was supposed to be derived from the precursor arachidonic acid (AA). This inhibitor was found to block the activities of both cyclooxygenase and PGE₂-isomerase, and to compete with the substrates AA and PGH₂. Although no significant substrate inhibition was observed, arachidonic acid was slightly inhibitory toward PGE₂-isomerase.     

Catalytic asymmetric synthesis of 19,20-dihydroakuammicine

An enantiocontrolled total synthesis of 19,20-dihydroakuammicine using a catalytic asymmetric Michael addition of dimethyl malonate to cyclohexenone as the key step is described. The above catalytic asymmetric Michael addition proceeds quite efficiently in the presence of a heterobimetalic asymmetric catalyst (ALB-KO-t-Bu-MS 4A, 0.3 mol%), giving the corresponding Michael adduct in 94% yield and 99% ee.     

Impaired renal prostaglandin E2 biosynthesis in human hypertensive states

Urinary Prostaglandin E₂ (PGE2), a known indicator of renal production, was measured by specific radioimmunoassay in 111 normal volunteers, 85 patients with essential hypertension, 6 with renovascular hypertension, and 23 patients with primary aldosteronism. Women excreted less PGE₂ than men in both normotensive and hypertensive groups. When compared to normals, essential hypertensives demonstrated significantly lower PGE₂ levels, with one third excreting less than 100 ng/24 hr, values usually seen only in subjects receiving the prostaglandin synthetase inhibitor, indomethacin. Normal PGE2 was seen in patients with renovascular hypertension, and levels were uninfluenced by treatment with the converting enzyme inhibitor SQ14225, despite normalization of blood pressure and increased plasma renin activity. Normal PGE₂ was also encountered in primary aldosteronism. These data indicate that impaired renal PGE2 biosynthesis is specific for human essential hypertension, and is not secondary to the elevated blood pressure. Although PGE₂ excretion tends to be lower in low-renin hypertension, a constant relationship between PGE₂ and renin is not always apparent.     

On the mechanism of prostacyclin and thromboxane A2 biosynthesis

The present research describes studies which address the mechanism of prostacyclin (PGI2) and thromboxane A2 (TXA2) biosynthesis. In addition to prostaglandin H1 (PGH1), PGG2, PGH2, and PGH3, also 8-iso-PGH2, 13(S)-hydroxy-PGH2, and 15-keto-PGH2 were applied to determine the substrate specificities and kinetics of prostacyclin and thromboxane synthase in more detail. Human platelet thromboxane synthase converted PGH1, 8-iso-PGH2, 13(S)-hydroxy-PGH2 and 15-keto-PGH2 into the corresponding heptadecanoic acid (C17) plus malondialdehyde, whereas the thromboxane derivative was formed only from PGG2, PGH2, and PGH3 together with the corresponding C17 metabolite and malondialdehyde in a 1:1:1 ratio. In contrast, PGG2, PGH2, 13(S)-hydroxy-PGH2, 15-keto-PGH2 and PGH3 were almost completely isomerized to the corresponding prostacyclin derivative by bovine aortic prostacyclin synthase, whereas PGH1 and 8-iso-PGH2 only produced the corresponding C17 hydroxy acid plus malondialdehyde. Isotope-labeling experiments with [5,6,8,9,11,12,14,15-2H]PGH2 revealed complete retention of label and no isotope effect in the course of thromboxane biosynthesis, but the loss of one 2H atom at C-6 with an isotope effect of 1.20 during PGI2 formation. Prostacyclin and thromboxane synthase bind both 9,11-epoxymethano-PGF2 alpha and 11,9-epoxymethano-PGF2 alpha at the heme iron, but according to their difference spectra in opposite ways with respect to the 9- and 11-position. In agreement with published model studies, a cage radical mechanism is proposed for both enzymes according to which the initial radical process is terminated through oxidation of carbon-centered radicals by the iron-sulfur catalytic site, followed by ionic rearrangement to PGI2 or TXA2. Various Fe(III) model compounds as well as liver microsomes or cytochrome P-450CAM can also form small amounts of PGI2 and TXA2, but mainly yield 12(S)-hydroxy-5,8,10-heptadecatrienoic acid plus malondialdehyde probably by a radical fragmentation pathway.     

Stimulation of prostaglandin E2 biosynthesis by estradiol in rat kidneys

The effect of estradiol administration on renal prostaglandin (PG) E2 biosynthetic activity in rats was studied. A specific radioimmunoassay for PGE2 was developed and applied in the quantitation of PGE2 biosynthesis in kidney. Conversion of exogenous arachidonic acid into PGE2 by renal microsomal fraction was assayed. Formation of PGE2 was linear in fashion up to 5 min incubation at 37 degrees C, and linear in fashion up to 3.5 mg of microsome used as enzyme source. The renal biosynthesis of PGE2 was significantly increased by estradiol treatment.     

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.     

Isolation and biosynthesis of 20-hydroxyprostaglandins E1 and E2 in ram seminal fluid

Ram semen was found to contain 20-hydroxyprostaglandin E1 and 20-hydroxyprostaglandin E2. The relative amounts of the two compounds were almost equal, although ram semen contained at least 10 times more prostaglandin E1 than prostaglandin E2. The accessory genital glands of the ram were analyzed for their capacity to metabolize [14C]arachidonic acid to prostaglandins. Biosynthesis of prostaglandins was only found in microsomes of the mucosa of the ampulla of vas deferens and in microsomes of the vesicular glands. Ram vesicular glands and the ampulla of vas deferens were also found to contain the two 20-hydroxylated E prostaglandins. Microsomes of ram vesicular glands and NADPH metabolized exogenous prostaglandin E2 to 20-hydroxyprostaglandin E2 albeit in low yields. Prostaglandin E2 appeared to be a better substrate than prostaglandin E1. Microsomes of human seminal vesicles and NADPH metabolized exogenous prostaglandin E2 to 19-hydroxyprostaglandin E2. The results show that 19- and 20-hydroxylation of prostaglandins occurs in human and ram seminal vesicles, respectively, and possibly also in the ampulla of vas deferens of the ram. The ram and human enzymes specifically hydroxylated the terminal and the penultimate carbon of prostaglandin E2, respectively.     

Regulation of prostaglandin E2 biosynthesis by inducible membrane-associated prostaglandin E2 synthase that acts in concert with cyclooxygenase-2

Here we report the molecular identification of membrane-bound glutathione (GSH)-dependent prostaglandin (PG) E(2) synthase (mPGES), a terminal enzyme of the cyclooxygenase (COX)-2-mediated PGE(2) biosynthetic pathway. The activity of mPGES was increased markedly in macrophages and osteoblasts following proinflammatory stimuli. cDNA for mouse and rat mPGESs encoded functional proteins that showed high homology with the human ortholog (microsomal glutathione S-transferase-like 1). mPGES expression was markedly induced by proinflammatory stimuli in various tissues and cells and was down-regulated by dexamethasone, accompanied by changes in COX-2 expression and delayed PGE(2) generation. Arg(110), a residue well conserved in the microsomal GSH S-transferase family, was essential for catalytic function. mPGES was functionally coupled with COX-2 in marked preference to COX-1, particularly when the supply of arachidonic acid was limited. Increased supply of arachidonic acid by explosive activation of cytosolic phospholipase A(2) allowed mPGES to be coupled with COX-1. mPGES colocalized with both COX isozymes in the perinuclear envelope. Moreover, cells stably cotransfected with COX-2 and mPGES grew faster, were highly aggregated, and exhibited aberrant morphology. Thus, COX-2 and mPGES are essential components for delayed PGE(2) biosynthesis, which may be linked to inflammation, fever, osteogenesis, and even cancer.     

Molecular identification of cytosolic prostaglandin E2 synthase that is functionally coupled with cyclooxygenase-1 in immediate prostaglandin E2 biosynthesis

Here we report the molecular identification of cytosolic glutathione (GSH)-dependent prostaglandin (PG) E(2) synthase (cPGES), a terminal enzyme of the cyclooxygenase (COX)-1-mediated PGE(2) biosynthetic pathway. GSH-dependent PGES activity in the cytosol of rat brains, but not of other tissues, increased 3-fold after lipopolysaccharide (LPS) challenge. Peptide microsequencing of purified enzyme revealed that it was identical to p23, which is reportedly the weakly bound component of the steroid hormone receptor/hsp90 complex. Recombinant p23 expressed in Escherichia coli and 293 cells exhibited all the features of PGES activity detected in rat brain cytosol. A tyrosine residue near the N terminus (Tyr(9)), which is known to be critical for the activity of cytosolic GSH S-transferases, was essential for PGES activity. The expression of cPGES/p23 was constitutive and was unaltered by proinflammatory stimuli in various cells and tissues, except that it was increased significantly in rat brain after LPS treatment. cPGES/p23 was functionally linked with COX-1 in marked preference to COX-2 to produce PGE(2) from exogenous and endogenous arachidonic acid, the latter being supplied by cytosolic phospholipase A(2) in the immediate response. Thus, functional coupling between COX-1 and cPGES/p23 may contribute to production of the PGE(2) that plays a role in maintenance of tissue homeostasis.