Analysis of A,B, E,and F prostaglandins as pentafluorobenzyl esters by electron-capture gas-liquid chromatography

A new and sensitive method is described for the simultaneous analysis of a mixture containing PGE₁, PGE₂, PGF_1α, and PGF_2α by electron-capture gas-liquid chromatography. During derivatization of the mixture, PGE₁ and PGE₂ were converted to PGB₁ and PGB₂, respectively, yielding a mixture of PGB₁, PGB₂, PGF_1α, and PGF_2α trimethylsilyl ether pentafluorobenzyl esters. Gas chromatographic resolution of all four derivatives is sufficient for quantitation of each prostaglandin. The A prostaglandins were analyzed by similar conversion to the respective B prostaglandin derivatives. Minimum detection limits for the B and F prostaglandin derivatives were 10 pg and 1 pg, respectively. Samples of rabbit kidney medulla were incubated and analyzed for A, B, E, and F prostaglandins. The results indicate that the method is capable of high recovery and reproducibility.     

Studies on the oxidation of ω-hydroxyprostaglandins by an NAD-dependent dehydrogenase from mammalian liver cytosol

The oxidation of 12-hydroxylauric acid methyl ester (12-OH-L-Me) and of ω-hydroxy-prostaglandins (ω-OH-PGs) such as 20-OH-PGB₁ and 20-OH-PGE₁, was demonstrated with liver cytosol from rat, rabbit, and guinea pig in the presence of NAD; however, NADP did not support this oxidation. (ω-1)-Hydroxy-compounds (11-OH-laurate and 19-OH-PGB₁) and PGE₁, PGF_1α, and PGB₁, all lacking the terminal (ω)-hydroxyl, did not reduce NAD. However, at pH 10, PGE₁ slightly enhanced NAD reduction, suggesting that at this pH PGE₁, could be a substrate for 15-hydroxy-PG dehydrogenase (PGDH). The oxidation products from incubations of 12-OH-L-Me, 20-OH-PGB₁-Me, and 20-OH-PGE₁ with guinea pig liver cytosol were isolated and identified by gas chromatography/mass fragmentation spectrometry as being the corresponding dicarboxylic acids. In contrast to the liver cytosol, guinea pig kidney cytosol had only a minimal effect on NAD reduction by 12-OH-L-Me but nevertheless did support the stimulation of NAD reduction by PGE₁, and PGF_1α, but not by PGB₁, indicating the participation of kidney cytosolic PGDH in PGE₁ and PGF_1α oxidation and demonstrating that the oxidation of ω-OH to the carboxylic acid is not mediated by PGDH. Though the in vivo rate of oxidation of ω-OH-PGs has not been established, these results suggest that the urinary dicarboxylic-PG metabolites involve a multiple sequentialstep oxidation of PGs involving ω-hydroxylation by an NADPH-cytochrome P-450 system in the endoplasmic reticulum and the subsequent oxidation of the ω-OH by an NAD-dependent dehydrogenase in the cytosol.     

Prostaglandins lack a direct inhibitory action on electrolyte and water transport in the kidney and the erythrocyte

The possibility of a direct effect of prostaglandins of the E, A, and F series upon renal electrolyte and water transport was assessed using in vitro preparations of rabbit cortical and medullary tubular suspensions as well as cortical renal slices from rat and guinea pig and medullary renal slices from rabbit. Net fluxes of Na, K, Cl and H₂O between the intracellular compartment and the extracellular fluid were measured in the presence of PGE₁, PGE₂, PGA₁, PGA₂ and PGF_2α in concentrations ranging from 1 × 10^?5 to 1 × 10^?10M. No inhibitory action was observed with any of these prostaglandins and in fact a slight stimulation of Na transport was seen under some circumstances. We conclude that the natriuresis which follows in vivo administration of some prostaglandins is not the result of a direct inhibition of Na reabsorption at the contraluminal pump site and is most likely secondary to renal vasodilation.We also studied net and isotopic Na fluxes in human erythrocytes. Na transport was not affected by prostaglandins of the E, A or F series using both normal and high sodium erythrocytes. Our results emphasize the need for caution in extrapolating the effects of prostaglandins upon Na transport from one tissue to another since their actions appear to be tissue-specific.     

Uptake and metabolism of prostaglandins by isolated perfused lung: Species comparison and the role of plasma protein binding

We have investigated the uptake and subsequent metabolism of the prostaglandins (PGs) PGE₁, PGA₁, and PGB₁ by rat, guinea pig and rabbit isolated perfused lungs (IPL). Significant species differences were not observed in the uptake or metabolism of any PG on passage through the IPL. However, differences in the uptake of PGA₁ and PGB₁ and in the metabolism of PGA₁ were observed with a given species when the composition of the perfusion medium was varied. The IPL removed minimal amounts (<20% of the supply rate) of PGA₁ and PGB₁ from the circulation when the perfusate contained 4.5% bovine serum albumin (BSA). In the absence of BSA, however, both PGA₁ and PGB₁ were substantially removed from circulation (～53% of the supply rate) and PGA₁ was also metabolized. The composition of the perfusate had no effect on the uptake and metabolism of PGE₁ which was always taken up and metabolized to a greater extent than was PGA₁ and PGB₁. Thus, the apparent species differences previously reported for the pulmonary biotransformation of PGA can result from differences in the perfusion medium used. Our data suggest that both plasma protein binding and a transport system play important roles in determining the selectivity of the uptake of PGs by the lung.     

Hydroxylation of prostaglandin E1 by kidney cortex microsomal monooxygenase in the guinea pig

The incubation of [5,6-³H]prostaglandin E₁ ([³H]PGE₁) with guinea pig kidney cortex microsomes in the presence of NADPH in an atmosphere of air, resulted in chromatographically polar metabolites. The incubation products were treated with base which converted PGE₁ derivatives into PGB₁ derivatives, with a λ_max = 278 nm and the products were analyzed by TLC and high pressure-liquid chromatography (HPLC). Based on UV absorption, mobility on TLC and retention time in HPLC, as compared with authentic compounds, it was concluded that the two polar UV-absorbing peaks in HPLC represented 19-hydroxy-PGB₁ (19-OH-PGB₁) and 20-hydroxy-PGB₁ (20-OH-PGB₁). Further identification of the metabolites was obtained by derivatizing the incubation products as methyl esters and t-butyldimethylsilyl ethers, followed by co-injection with similarly derivatized authentic compounds in HPLC and gas chromatography. Finally, the derivatized metabolites were identified by comparing their mass fragmentation with that of similarly derivatized authentic compounds. There was an absolute requirement for NADPH, and NADH did not significantly support the hydroxylation of PGE₁. Inhibitors of microsomal monooxygenase (SKF 525A, metyrapone, and cytochrome c) inhibited the hydroxylation of PGE₁ by kidney cortex microsomes. By contrast, carbon monoxide at a CO:O₂ ratio of 5:1 did not inhibit the hydroxylation of PGE₁, pointing to a low or lack of CO sensitivity of the hydroxylation of PGE₁. The addition of PGE₁ or laurate to guinea pig kidney cortex microsomes elicited Type I spectral changes. The spectral dissociation constant (K_s) for PGE₁ was 2.4 × 10^?4m. The kinetic constants for 19- and 20-hydroxylations of PGE₁ were determined. The K_M values for the 19- and 20-hydroxylation pathways were found to be identical, being 3.3 × 10^?4m, suggesting that the same enzyme is involved in both hydroxylations; however, the V_max values for 19-hydroxylation and 20-hydroxylation of PGE₁ were 50 nmol/hr and 20.8 nmol/hr respectively. These results demonstrate that PGE₁ is a substrate for the kidney cortex microsomal monooxygenase. The similarities and differences of the kidney monooxygenase in the guinea pig with that in the rat are discussed.     

High performance liquid chromatography and UV detection for the separation and quantitation of prostaglandins

A fast and reliable method for the separation and quantitation of arachidonic acid metabolites PGF_1α, PGF_2α, PGD₂, PGE₁, PGE₂, PGB₂, PGA₂, 6-keto PGE₁, 6-keto PGF_1α, T×B₂ and 15-keto PGE₂ by high-performance liquid chromatography has been developed. Utilizing a single reverse-phase column and a UV spectrophotometer, sensitivity as little as 30 nanograms of each of these prostaglandins can be separated and subsequently detected. Although this study was performed using standards, it is highly promising for future application to biological fluids.     

The effect of prostaglandins on cultured lapine articular chondrocytes

The effect of 8 prostaglandins (PG) on growth and sulfate incorporation by monolayer and spinner-cultured rabbit articular chondrocytes has been measured. PGA₁, PGB₁, PGE₁ and PGE₂ reduced synthesis of sulfated glycosaminoglycans (GAG) but the PGF series did not. PGA₁ was the most potent, being effective at a concentration of 2.5 μg/ml [6.8 μM] while the others required 25 μg/ml. These compounds had no effect on degradation of GAG. All 8 PGs augmented growth slightly but significantly at 2.5 μg/ml. At the higher concentration, PGA₁ was highly cytotoxic, and PGB₁ as well as PGE₂ reduced cell growth. The cytotoxicity of PGA₁ was also observed in two additional types of cultured connective tissue cells, but the inhibition of sulfated-GAG synthesis by PGA₁ and PGB₁ was confined to the chondrocytes. The response of cultured chondrocytes to exogenous PGs, albeit at apparently unphysiologically high concentrations, together with other evidence, suggests that these compounds may conceivably play a direct role in cartilage metabolism in vivo.     

Further studies on prostaglandin E2 (PGE2)-induced gonadotropin release: Comparison with the effect of 15-methyl PGE2, PGAs, PGBs and prostaglandin endoperoxide analogs

It is known that PGE₂ is a potent stimulus of LH release. To determine if the effect of PGE₂ could be enhanced and/or prolonged by retarding its metabolic degradation, a derivative, 15-methyl PGE₂ (15-E₂) which is more slowly degraded than the natural compound was injected intravenously (i.v.) at various dose levels or into the third ventricle (3rd V) of ether-anesthetized, ovariectomized, estrogen (OVX, Eb)-treated rats and its effect on gonadotropin release was compared with that of PGE₂. Both PGs injected i.v. were equally effective in increasing plasma LH and maintaining the elevated levels, although 15-E₂ induced a larger and more sustained increase in plasma FSH than PGE₂. By contrast, 3rd V PGE₂ was clearly more effective than 3rd V 15-E₂ in releasing LH and to a lesser extent, FSH. The effect of 15-E₂ on LH was similar to that produced by 3rd V PGE₁ injected at a similar dose. However, its effect on FSH was greater than that of PGE₁.To evaluate the effect(s) of prostaglandins of the A and B series on gonadotropin release, PGA₁, PGA₂, PGB₁ or PGB₂ were injected intraventricularly in OVX, Eb-treated rats. PGBs were injected into conscious, free-moving rats. PGA₂ or PGB₂ increased plasma LH concnetrations although much less effectively than PGE₂. Third V PGA₁ or PGB₁ were ineffective. The 3rd V injection of two cyclic esters (U-44069 and U-46619), stable analogs of the PG endoperoxide PGG₂ and PGH₂, induced a small, transient increase in LH levels and did not alter plasma FSH in conscious, free-moving animals. PGE₂ injected intraventricularly at a similar dose was demonstrated to be much more potent than the analogs in stimulating LH and FSH release. The results indicate that: 1) 15-E₂, in spite of its described long-lasting activity, does not appear to be more potent than the natural compound in releasing LH, although when injected i.v., it appeared to induce a more sustained increase in plasma FSH; 2) although PGA₂ and PGB₂ can also act centrally to stimulate LH release, their low potency suggests that this is a pharmacological effect; and 3) the two analogs of PG endoperoxides tested proved to be poor stimuli for gonadotropin release. The significance of these findings is discussed.     

Prostaglandin Biosynthesis from Endogenous Precursors in Rabbit Kidney

THIS report describes the biosynthesis of the naturally occurring renal prostaglandins E₂ (PGE₂) and F_2α (PGF_2α)^1,2 by homogenates and slices of rabbit renal medulla, from endogenous precursors. I have confirmed that rabbit renal cortex contains little prostaglandin and cannot synthesize them from endogenous lipids³. Hamberg has reported that arachidonic acid, which is converted to PGE₂ and PGF_2α by enzymes present in ram seminal vesicles⁴, can be efficiently converted to PGE₂ and PGF_2α by homogenates of rabbit renal medulla³. I have now confirmed that arachidonic acid, added to such medullary homogenates, can increase the quantities of prostaglandins synthesized. There was no evidence that the major prostaglandin biosynthesized, PGE2, was further metabolized to inactive products.     

Prostaglandin-mediated inhibition of noradrenaline release: III. Separation of prostaglandins released from stimulated hearts and analysis of their neurosecretion inhibitory capacity

Isolated rabbit hearts were infused with ¹⁴C-arachidonic acid and subjected to sympathetic nerve stimulation. Prostaglandins in the cardiac effluent were extracted and separated using thin layer chromatography. Other hearts were infused with un-labelled arachidonic acid and the effluent was assayed for neurosecretion inhibitory capacity on the field-stimulated guinea pig vas deferens, and for anti-aggregatory activity on ADP-induced platelet aggregation. PGs in the effluent from hearts infused with un-labelled arachidonic acid were extracted and separated on TLC, and the different fractions were assayed for neurosecretion inhibitory activity.Sympathetic nerve stimulation after preincubation with ¹⁴C-AA elicited outflow of four different peaks of ¹⁴C-labelled PGs: one chromatographing close to PGF_2α (probably mainly 6-keto-PGF_1α), and three peaks corresponding to PGA₂/PGB₂, PGD₂, and PGE₂ respectively. The cardiac interstitial effluent contained anti-aggregatory material which was inactivated by heat treatment, and thus probably identical to PGI₂. The cardiac effluent also contained material with neuro-secretion inhibitory activity, which was resistant to heat treatment. Fractional assay of the TLC separated cardiac effluent demonstrated that the neurosecretion inhibitory activity chromatographed with PGE₂ only.It has earlier been observed that endogenous PGs inhibit trans-mitter release in sympathetically stimulated organs. On the basis of the current data we suggest that PGE₂ is the only physiological inhibitor of sympathetic transmitter release.     

Prostaglandin inhibition of cartilage chondromucoprotein synthesis: Concept of “intrinsic activity”

We have recently reported that cartilage has two sites for prostaglandin (PG) action. One site (S₁) is stimulated by PGA₁, PGE₁ and PGF_1α and elevates tissue cyclic 3′5′adenosine monophosphate (cAMP). A second site (S₂) is activated by PGA₁ (but not PGE₁ or PGF_1α) and inhibits the synthesis of cartilage macromolecules. The present study is an investigation of the effects of PGB₁ on embryonic chicken cartilage chondromucoprotein synthesis in vitro. PGB₁ was found to inhibit chondromucoprotein synthesis with an apparent affinity for S₂ which was similar to that of PGA₁. The maximal inhibition produced by PGB₁ was, however, approximately one-half the maximal inhibition caused by PGA₁. Studies of the combined effects of PGB₁ and PGA₁ were consistent with the hypothesis that both classes of prostaglandins act at a common site (S₂) with about equal affinity but that PGB₁ has a lower intrinsic activity than PGA₁. Similar studies of the combined effects of PGE₁ or PGF_1α with PGA₁ indicate that neither PGE₁ nor PGF_1α binds significantly to S₂. An independent effect of PGB₁ to activate S₁ and elevate tissue cAMP was also found.     

Isolation and identification of prostaglandin PGB1 in growth cartilage

Prostaglandin PGB₁, and lesser amounts of other prostaglandin-like compounds, have been isolated from calf growth-cartilage by a series of chromatographic procedures. The major compound, present at about 3 ppm fresh weight, was identified as PGB₁ by comigration with authentic PGB₁ in a wide variety of thin-layer chromatographic solvent systems; as well as by infrared and UV spectroscopy, and by radioimmunoassay. The presence in cartilage of larger amounts of PGB₁ than the other kinds of prostaglandins may be due to a conversion of PGE₁ to PGB₁ in vivo,or perhaps during the extraction and isolation procedures.     

Prostaglandins and in vitro ovarian progestin biosynthesis

Prostaglandin F_2α (PGF_2α) did not alter the $\text{in vitro}$ biosynthesis of progesterone by slices of luteinized rat ovaries when used in concentrations from 1 to 10,000 ng/ml of incubation medium; likewise, PGF_2α did not affect the incorporation of acetate-1-¹⁴C into progestins. PGF_1α, 15-keto PGF_2α, and PGE₁ did not alter the biosynthesis of progesterone by luteinized rat ovaries; PGE₂ inhibited the production of progesterone when used at a concentration of 10 μg/ml, but not at lower doses. PGF_2α in combination with luteinizing hormone (LH) enhanced the metabolism of progesterone to 20α-hydroxypregn-4-en-3-one in luteinized rat ovaries. Interestingly, PGF_2α, at a high concentration of 10 μg/ml, did stimulate progesterone biosynthesis by slices of ovarian tissue from immature rats hormonally primed to simulate “pseudopregnancy,” suggesting a steroidogenic action of prostaglandins on the ovarian follicular or interstitial cell. PGF_2α (10 μg/ml) did not stimulate the $\text{in vitro}$ biosynthesis of progesterone or 20α-hydroxypregn-4-en-3-one by slices of rabbit corpora lutea or rabbit ovarian interstitial tissue. It is concluded that prostaglandins do not stimulate progestin biosynthesis in rat luteal tissue.     

Prostaglandins and renin release: III. Effects of PGE1, E2 F2α and D2 on renin release from rabbit renal cortical slices

We have investigated the direct effects of prostaglandins E₁, E₂, F_2α and D₂ on renin release from rabbit renal cortical slices. Prostaglandin E₁ (PGE₁) was the most potent stimulant of renin release, while PGE₂ was 20–30 fold less active. PGF_2α was found not to be an inhibitor of renin release as reported by others, but rather a weak agonist. PGD₂ up to a concentration of 10 μg/ml had no activity in this system. That the stimulation of renin release by PGE₁ is a direct effect is supported by the finding that PGE₁-induced release is not blocked by L-propranolol or by Δ^5,8,11,14-eicosatetraynoic acid (ETYA), a prostaglandin synthesis is inhibitor. The fatty acid precursor of PGE₁, Δ^8,11,14-eicosatrienoic acid, also stimulated renin release, an effect which was blocked by ETYA. In addition to the above findings, ethanol, a compound frequently used to dissolve prostaglandins, was shown to inhibit renin release.     

Role of prostaglandins on the regulation of macrophage proliferation and cytotoxic functions

The data presented show different effects of prostaglandins on proliferation and cytotoxic effector functions of murine bone-marrow derived mononuclear cells. Colony stimulating factor (CSF)-dependent proliferation of colony forming unit-cells (CFU c) was inhibited by PGE₁, PGE₂ and PGB₂. Lymphokine induced cytotoxicity and antibody mediated cytotoxicity (ADCC) of monocytes and macrophages were also affected by PG. We conclude that PGE₂ may regulate macrophage mediated tumorcell-lysis mainly at the induction phase.If there processes function in vivo, one would therefore expect high affinity binding sites for PGE₂ on macrophages. The existence of a receptor for PGE₂ one murine bone marrow derived macrophages is described.     

Localization of exaggerated prostaglandin synthesis associated with renal damage

Regional localization of the exaggerated prostaglandin E₂ (PGE₂) synthesis caused by hydronephrosis was studied in unilateral ureteral ligated rabbits. The renal distribution of PGE₂ production was compared in the hydronephrotic and contralateral kidneys. Basal and bradykinin-stimulated PGE₂ synthesis were increased in cortical and medullary slices of the hydronephrotic kidneys. Contralateral (control) cortical slices produced very low levels of PGE₂ and were insensitive to stimulation by bradykinin (BK). The hydronephrotic cortex produced 10 times more PGE₂ than the contralateral cortex and responded to BK stimulation with increased PGE₂ synthesis. Cortical slices from the hydronephrotic kidney exhibited a time-dependent increase in PGE₂ release, presumably as a result of new protein synthesis. The division of the hydronephrotic cortex into outer and inner regions revealed that the inner cortex produced more PGE₂ than the outer cortex. A similar division of the hydronephrotic medulla showed that the inner medulla produced slightly greater amounts of PGE₂ than the outer medulla. The present study demonstrates that hydronephrosis causes increases in prostaglandin synthesis throughout the kidney. We suggest from these results and other studies that a possible explanation for this finding is the involvement of the collecting duct system in this response. The gradient of PGE₂ production detected in the cortex may have a very significant role in the control of renal hemodynamics and could provide an explanation for the large decrease in blood flow to the inner cortex caused by indomethacin treatment.     

Inhibition of renal PGE2-9-ketoreductase by diuretics

The metabolism of PGE₂ by extracts of renal cortex is species dependent. In the rat PGE₂-15-hydroxydehydrogenase initiates metabolism whereas in the rabbit PGE₂-9-ketoreductase predominates. In man both mechanisms may operate. Each of the metabolic enzymes, which limits the vasodilator-diuretic actions of PGE₂, was inhibited by ethacrynic acid, furosemide and indomethacin. Some inhibition of PGE₂-9-ketoreductase was also observed with chlorthalidone, hydralazine and phentolamine but the thiazide diuretics and a number of other cardiovascular-active agents were without significant effect. We conclude that the inhibition of PGE₂-9-ketoreductase and PGE₂-15-hydroxydehydrogenase could contribute to the mechanism of action of the non-thiazide diuretics in man.     

Accumulation of adenosine 3',5'-monophosphate in rat brain slices: effects of prostaglandins.

Prostaglandin E₁ and E₂ and 15(S)-15-methyl PGE₂ methyl ester stimulate the accumulation of radioactive cyclic AMP in brain slices from Sprague-Dawley rats, labelled during a prior incubation with [¹⁴C] adenine. Prostaglandins A₁ and B₁ have marginal effects and prostaglandin F_1α has no effect. Relatively high concentrations of about 80 μM PGE₁, PGE₂ and 15(S)-15-methyl PGE₂ are required to elicit a maximal 2–5 fold increase in accumulation of cyclic AMP in slices from cerebrum, but significant increases are elicited by 3.5 μM prostaglandin. Similar increases are elicited in slices from neocortex, striatum or midbrain-thalamus-hypothalamus, while lesser increases pertain in slices from cerebellum, medulla-pons or hippocampus. The accumulation of cyclic AMP elicited by PGE₁ in slices from cerebrum was not blocked by naloxone, propranololphentolamine, tetracaine, theophylline, or by nearly equimolar concentrations of either of two prostaglandin antagonists, 7-oxa-13-prostynoic acid and the dibenzoxazepine hydrazide, SC 19220. Morphine potentiated the effects of PGE₁. The combination of 85 μM PGE₁ with either isoproterenol, norepinephrine, adenosine or veratridin did not increase the accumulation of cycli AMP significantly above those elicited by the isoproterenol, norepinephrine, adenosine or veratridine alone. The combined effect of PGE₁ and norepinephrine in the presence of a β-adrenergic antagonist, sotalol, was, however, additive. The results indicate that PGE₁ stimulates cyclic AMP formation in rat brain slices, but that it either has antagonist activity with respect to accumulations of cyclic AMP-elicited by other agents or has no detectable agonist activity when cyclases are maximally stimulated by other agents.     

A mass fragmentographic method for the quantitative evaluation of brain prostaglandin biosynthesis

A method for the evaluation of PGF_2α and PGE₂ biosynthesis in rat cerebral cortex is described. Tissue slices were incubated without any added precursor for different lengths of time. The analytical procedure involves prostaglandin extraction, purification and quantitative determination by mass fragmentography. Significant amounts of both prostaglandins were synthesized. The biosynthesis reached a plateau after 30 minutes and the ratio of PGF_2α to PGE₂ was approximately 3.