The effects of prostaglandins PGE1, PGE2, PGF1a, and PGF2a on canine synovial perfusion

In these experiments we have examined the effects of PGE₁, PGE₂, PGF_1α and PGF_2α on synovial perfusion in the normal canine synovial microcirculation. The effects of the drugs on synovial perfusion were determined indirectly from the changes produced in the rate of clearance of ¹³³Xenon from the joint by their intra-articular injection. Prostaglandins PGE₁ and PGE₂ were found to be strongly vasodilator with PGE₁ being the more active. PGF_1α appeared to have little or no vasoactive properties in doses up to 1 ugm. (2.8 × 10^−5M) in our I preparation while PGF_2α was vasodilator at this high dosage only. Neither SC19920 nor diphloretin phosphate antagonised the effects of PGE₁ in these experiments.     

Prostaglandin-E2-9-ketoreductase in rabbit kidney

The 100,000 xg supernatant of rabbit kidney contains a prostaglandin-E₂-9-ketoreductase which has an obligatory requirement for NADPH. This enzyme is localised in the renal cortex and is able to quantitatively convert PGE₂ to PGF_2α. A broad pH profile was evident with an optimum at pH 7·5. Kinetic studies indicated a K_m of 3·2 × 10⁻⁴M PGE₂. The isoelectric point was at pH 5·65 and the molecular weight, as estimated by gel filtration, was 21,800. These values differ from those obtained with enzyme from monkey brain tissue and suggest a tissue specificity of PGE₂-9-ketoreductase. By combining isoelectric focussing techniques with sephadex filtration considerable purification of the renal enzyme was achieved.     

Prostaglandin E1 and F2α specific binding in bovine corpora lutea: Comparison with luteolytic effects

Preliminary characterization indicated the presence of separate prostaglandin (PG)E₁ and (PG)F_2α binding sites in membrane fractions prepared from bovine corpora lutea. These differ in the rate and temperature dependence of the specific binding. Equilibrium binding data indicate the apparent dissociation constants as 1.32 × 10⁻⁹M and 2.1 × 10⁻⁸M for PGE₁ and PGF_2α, respectively. Competition of several natural prostaglandins for the PGE₁ and PGF_2α bovine luteal specific binding sites indicates specificity for the 9-keto or 9α-hydroxyl moiety, respectively. Differences in relative ability to inhibit ³H-PG binding were found due to sensitivity to the absence or presence of the 5,6-cis-double bond as well.Bovine luteal function was affected following treatment of heifers with 25 mg PGF_2α as measured by reduced estrous cycle length, decreased corpus luteum size and significantly decreased plasma progesterone levels. In contrast, treatment with 25 mg PGE₁ resulted in cycle lengths comparable to those of non-treated herdmates with no apparent modification in corpus luteum size. However, plasma progesterone levels were increased significantly following PGE₁ treatment compared to pretreatment values. In so far as data obtained on PGF_2α relative binding affinity to the bovine CL can be compared to data obtained independently on PGF_2α induced luteolysis in the bovine, PGF_2α relative binding to the CL and luteolysis appeared to be associated. By similar reasoning, there was no apparent relationship between PGE₁ relative binding affinity in the luteal fractions and luteolysis in estrous cyclic cattle.     

Prostaglandin E1 and F2α specific binding in bovine corpora lutea: Comparison with luteolytic effects

Preliminary characterization indicated the presence of separate prostaglandin (PG)E₁ and (PG)F_2α binding sites in membrane fractions prepared from bovine corpora lutea. These differ in the rate and temperature dependence of the specific binding. Equilibrium binding data indicate the apparent dissociation constants as 1.32 × 10⁻⁹M and 2.1 × 10⁻⁸M for PGE₁ and PGF_2α, respectively. Competition of several natural prostaglandins for the PGE₁ and PGF_2α bovine luteal specific binding sites indicates specificity for the 9-keto or 9α-hydroxyl moiety, respectively. Differences in relative ability to inhibit ³H-PG binding were found due to sensitivity to the absence or presence of the 5,6-cis-double bond as well.Bovine luteal function was affected following treatment of heifers with 25 mg PGF_2α as measured by reduced estrous cycle length, decreased corpus luteum size and significantly decreased plasma progesterone levels. In contrast, treatment with 25 mg PGE₁ resulted in cycle lengths comparable to those of non-treated herdmates with no apparent modification in corpus luteum size. However, plasma progesterone levels were increased significantly following PGE₁ treatment compared to pretreatment values. In so far as data obtained in vitro on PGF_2α relative binding affinity to the bovine CL can be compared to data obtained independently in vitro on PGF_2α induced luteolysis in the bovine, PGF_2α relative binding to the CL and luteolysis appeared to be associated. By similar reasoning, there was no apparent relationship between PGE₁ relative binding affinity in the luteal fractions and luteolysis in estrous cyclic cattle.     

Effect of PGI2, PGE2 and 6-keto PGF1α on canine gastric blood flow and acid secretion

Prostaglandins (PG)I₂, PGE₂ and 6-keto PGF₁α were infused directly into the gastric arterial supply at 10⁻⁹, 10⁻⁸ and 10⁻⁷ g/kg/min during an intra-gastric artery pentagastrin infusion in anesthetized dogs. 6-keto PGF₁α was also infused at 10⁻⁶ g/kg/min. Gastric arterial blood flow was measured continuously with a non-cannulating electromagnetic flow probe and gastric acid collected directly from the stomach. PGI₂ and PGE₂ produced similar dose-dependent increases in blood flow with an increase of more than four-fold at the highest dose. Both PGs inhibited acid output over this dose range with PGE₂ having 10 times the potency of PGI₂. 6-keto PGF₁α was at least 1000 times less active than PGI₂ or PGE₂ at increasing blood flow and failed to inhibit acid output even at 10⁻⁶ g/kg/min.     

PGE2 is a more potent vasodilator of the lamb ductus arteriosus than is either PGI2 or 6 keto PGFα

It has been shown in vitro that the lamb ductus arteriosus forms prostaglandins PGE₂, PGF_2α, 6 keto PGF_1α (and its unstable precursor PGI₂). In this study the relative potencies of these endogenous prostaglandins were investigated on isolated lamb ductus arteriosus preparations contracted by exposure to elevated PO₂ and indomethacin. All the prostaglandins (except PGF_2α) relaxed the vessel. This is consistent with the hypothesis that endogenous prostaglandins inhibit the tendency of the vessel to contract in response to oxygen. Only PGE₂, however, relaxed the vessel at concentrations below 10⁻⁸M. PGI₂ and 6 keto PGF_1α had approximately 0.001 and 0.0001 times the activity of PGE₂. Although PGE₂ has been observed to be a minor product of prostaglandin production in the lamb ductus arteriosus, the tissue's marked sensitivity to PGE₂ might make it the most significant prostaglandin in regulating the patency of the vessel.     

Prostaglandin-E2-9-ketoreductase in rabbit kidney

The 100,000 x g supernatant of rabbit kidney contains a prostaglandin-E₂-9-ketoreductase which has an obligatory requirement for NADPH. This enzyme is localised in the renal cortex and is able to quantitatively convert PGE₂ to PGF_2α. A broad pH profile was evident with an optimum at pH 7·5. Kinetic studies indicated a K_m of PGE₂. The isoelectric point was at pH 5·65 and the molecular weight, as estimated by gel filtration, was 21,800. These values differ from those obtained with enzyme from monkey brain tissue and suggest a tissue specificity of PGE₂-9-ketoreductase. By combining isoelectric focussing techniques with sephadex filtration considerable purification of the renal enzyme was achieved.     

Characterization and ontogeny of PGE2 and PGF2α receptors on the retinal vasculature of the pig

The vasoconstrictor effects of PGE₂ and PGF_2α are less pronounced on retinal vessels of the newborn than of the adult pig. We tested the hypothesis that the decreased vasomotor response to these prostaglandins might be due to relatively fewer receptors and/or different receptor subtypes (in the case of PGE₂) on retinal vessels of the newborn animal. Binding studies using [³H]PGE₂ and [³H]PGF_2α revealed that PGE₂ (EP) and PGF_2α (FP) receptor densities in retinal microvessel membrane preparations from newborn animals were approximately 25% of those found in vessels from the adult. The K_d for PGF_2α did not differ; however, the K_d for PGE₂ was less in newborn than in adult vessels. Competition binding studies using AH 6809 (EP₁ antagonist), butaprost (EP₂ agonist), M&B 28,767 (EP₃ agonist), and AH 23848B (EP₄ antagonist) suggested that the retinal vessels of the newborn contained approximately equal number of EP₁ and EP₂ receptor subtypes whereas the main receptor subtype in the adult vessels was EP₁. In addition, PGE₂ and butaprost produced comparable increases in adenosine 3′,5′-cyclic monophosphate synthesis in newborn and adult vessels. PGE₂, 17-phenyl trinor PGE₂ (EP₁agonist) and PGF_2α caused a 2.5 to 3-fold greater increase in inositol1,4,5-triphosphate (IP₃) formation in adult than in newborn preparations. It is concluded that fewer PGF_2α receptors and an associated decrease in receptor-coupled IP₃ formation in the retinal vessels of the newborn could lead to weaker vasoconstrictor effects of PGF_2α on retinal vessels of the newborn than of adult pigs; fewer EP₁ receptors (associated with vasoconstriction) and a relatively greater proportion of EP₂ receptors (associated with vasodilation) might be responsible for the reduced retinal vasoconstrictor effects of PGE₂ in the newborn.     

Sperm output and serum testosterone in rabbits given prostaglandin F2α or E2

Two experiments were conducted, the first to compare sperm output and the second to determine serum testosterone in rabbits given PGF₂α or PGE₂. In the first, six rabbits were ejaculated twice each Monday, Wednesday and Friday for 5 weeks. Each rabbit was given subcutaneously (sc) each of the following treatments five times: 1) saline, 2) 5 mg PGF₂α and 3) 5 mg PGE₂. Treatments were given, half at 4 hr and half at 2 hr before first ejaculations. Both PGF₂α and PGE₂ caused increased (50% and 84%) sperm content of first ejacula, without significantly altering characteristics of second ejacula. The extra sperm in first ejacula was a function of increased sperm density, because seminal volume was unaltered.In the second experiment, 15 rabbits were bled at 0.5-hr intervals for 9 hr and given (sc): 1) saline at 1 and 3 hr (n=4), 2) 2.5 mg PGF₂α at 1 and 3 hr (n=4), 3) 2.5 mg PGE₂ at 1 and 3 hr (n=4) or 4) 5 mg PGF₂α at 1 hr after the onset of blood sampling. In saline-treated controls, episodic surges of testosterone occurred on the average every 5 hours. After the injection of 2.5 or 5.0 mg PGF₂α, serum testosterone began to rise at 0.5 hr, peaked (8 to 13 ng/ml) at 1 hr and approached a nadir (0.5 ng/ml) within 4 hours. The second injection of 2.5 mg PGF₂α failed to significantly affect serum testosterone. PGE₂ treatment was followed by significantly depressed serum testosterone; only 1 of these 4 rabbits had any surge of testosterone for the 8 hr after treatment. In conclusion, PGF₂α and PGE₂ both increased sperm output, but PGF₂α increased serum testosterone while PGE₂ depressed serum testosterone. Thus, the sperm output effect of these prostaglandins probably is independent of the acute changes in testosterone secretion.     

The effects of prostaglandins E2 and F2α on synaptosomal accumulation and release of H-norepinephrine

Prostaglandins (PG) of both the E and F series may serve as modulators of norepinephrine (NE) release from peripheral sympathetic neurons. We have studied the effects of PGE₂ and PGF_2α on the accumulation and release of ³H-NE in the CNS using synaptosomes isolated from rat hypothalami.The release of ³H-NE from synaptosomes superfused with Krebs-Ringer bicarbonate buffer was multiphasic with an initial fast release phase followed by a slower release. Raising KC1 concentration of the superfusion medium to 56mM during the slow release phase is known to stimulate ³H-NE release. PGE₂ (1 × 10⁻⁶M) attenuated ³H-NE release during the fast phase and reduced the amount of ³H-NE released due to KC1 stimulation. At lower concentrations of PGE₂ there was no change in the release profile. PGF_2α was without effect on ³H-NE release at all concentrations tested.The accumulation of ³H-NE was significantly diminished by PGE₂ at a concentration of 1 × 10⁻⁶M, while a lower concentration (1 × 10⁻⁷M) was ineffective. PGF_2α had no effect on ³H-NE accumulation at all concentrations investigated.     

PGE2 attenuates PGF2α-induced increases in free intracellular calcium in ovine large luteal cells

When ovine large luteal cells are placed in culture and exposed to PGF_2α, there is a rapid and sustained increase in the concentration of free intracellular calcium which is believed to play a major role in the luteolytic and cytotoxic effects of PGF_2α. Since administration of exogenous PGE₂ can prevent spontaneous and PGF_2α-induced luteolysis in vivo, and the cytotoxic effects of PGF_2α on large luteal cells in vitro, the objective of this study was to determine if one mechanism by which PGE₂ acts is to attenuate increases in free intracellular calcium induced by PGF_2α. At concentrations of 10 nM or greater, PGF_2α caused a significant and sustained increase in free intracellular calcium in large luteal cells. Similarly, PGE₂ also induced increases in free intracellular calcium but required doses 20-fold greater than PGF_2α. When PGE₂ (1, 10 or 100 nM) was incubated with PGF_2α (100 nM) increases in free intracellular calcium induced by PGF_2α were attenuated (P<0.05) when measured 5 min, but not at 30 min, after initiation of treatment. The observed decrease in the concentration of free intracellular calcium at 5 min in response to PGF_2α was the result of fewer cells responding to PGF_2α. In addition, the concentrations of free intracellular calcium attained in the cells that did respond was reduced 25% compared to cells treated with PGF_2α alone. Thus, part of the luteal protective actions of PGE₂ appears to involve an inhibition of the early (5 min) increase in free intracellular calcium induced by PGF_2α.     

The enzymatic conversion of prostaglandin D2 to prostaglandin F2α

Prostaglandins E₂ and D₂ were both converted to prostaglandin F_2α (9α, 11α) by an enzyme present in sheep blood. Neither the 9β, 11α epimer nor the 9α, 11β epimer was produced from PGE₂ or PGD₂ respectively. The rate of reduction was measured using isotope dilution (D₄ PGF_2α) and multiple-ion detection gas chromatography-mass spectrometry.     

Prostaglandin E2: Midterm abortion in rats using Silastic-PVP tubes

The results of the present study establish that 1.5 mg PGE₂ (lyophilized sodium salt) incorporated in one cm long open-ended Silastic-polyvinylpyrrolidone (PVP) tube when inserted into 10 day pregnant rats induced abortion within 70–72 hours in all the treated rats. A combined treatment of PGE₂ and 17β-estradiol failed to increase the abortion inducing effect of a Silastic-PVP-PGE₂ tube. It is observed that PGE₂ is about 4 times less potent than PGF_2α in inducing midterm abortion in rats. It is suggested that either PGE₂ exerts luteolytic effect after being converted to PGF_2α, although how it occurs is not clear; or PGE₂ causes expulsion of the fetuses by its uterine stimulating property. 17β- estradiol increases the uterine synthesis of PGF_2α as described earlier but seems not affecting the production of PGE₂ by the uterus. The release rate of ³H-PGE₂ from Silastic-PVP tube and is also described.     

Differential effects of detergents and dimethylsulfoxide on membrane prostaglandin E1 and F2α receptors

Pretreatment of membranes for 1 hr at 4° with up to 0.1% Triton X-100 (TX-100) and sodium desoxycholate (SDC), resulted in a greater loss of [³H] prostaglandin (PG)F₂α binding compared to E₁ binding. Lubrol WX (LWX) tended to cause a greater loss of [³H]PGF₂α than E₁ binding. However, the differential loss was not as marked as with TX-100 or SDC. Triton X-305 was relatively ineffective, but loss of [³H]PGE₁ binding was greater than for PGF₂α. Increasing concentrations of dimethylsulfoxide (DMSO) progressively inhibited PGF₂α binding without affecting PGE₁ binding. The detergent, but not DMSO, induced losses of membrane PG binding were due to solubilization of the receptors. Greater amounts of membrane protein and phospholipids were solubilized at detergent (TX-100 and SDC) concentrations that solubilized 100% of PGE₁ receptors compared to 100% solubilization of F₂α receptors. Neither the duration of preincubation nor the amount of membrane protein chosen were responsible for differential PGE₁ and F₂α receptor losses. These differential membrane PG receptor losses raise the possibility of differences in PGE₁ and F₂α receptors association with the membrane structure.     

The effects of PGF1α, PGE2 and 16,16 dimethyl PGE2 on gastric emptying and small intestinal transit in rat

Prostaglandins are well known for their ability to stimulate contraction in gastrointestinal smooth muscle, yet very little information is available on how their activity affects propulsion . Thus, studies were undertaken to determine the effect of various prostaglandins on qastric emptying (GE) and small intestinal transit (SIT) in unanesthetized fasted rats. Rats were treated with intravenous, subcutaneous, or oral PGF_2α, PGE₂, or 16,16 dimethyl PGE₂ at various doses, followed 1 (intravenous), 20 (subcutaneous) or 10 (oral) mins later by intragastric ⁵¹Cr oxide in black ink. Forty-five mins later, rats were sacrificed by CO₂ asphyxiation, the pylorus clamped, and the gut excised. SIT was expressed as the percent of intestinal length traveled by the most distal portion of ink. GE was expressed as the percent of the ⁵¹Cr emptied into the intestines. If GE was affected by prostaglandin treatment, the experiments were repeated with rats pre-implanted with duodenal cannula. This preparation allowed the visual transit marker to be deposited directly into the dueodenum, thus avoiding acceleration or delay of SIT caused by fluctuations in GE. The results of these studies show that: (1) intravenous 16,16 dimethyl PGE₂ (5–50 μg/kg), but not PGF_2α or PGE₂, accelerates GE and delays SIT; (2) oral prostaglandin administration increases SIT; (3) oral 16,16 dimethyl PGE₂ delays GE; (4) subcutaneous 16,16 dimethyl PGE₂ accelerates, has no effect upon, or delays GE depending upon dose, but accelerates SIT at all doses tested; and (5) subcutaneous PGE₂ accelerates SIT while PGF_2α does not. Thus, the effect of prostaglandins on GE and SIT depends upon the dosage and route of administration as well as type of prostaglandin used.     

Effects of indomethacin, prostaglandin E2, prostaglandin F2α and 6-keto-prostaglandin F1α on hatching of mouse blastocysts

The present study has been performed to investigate how PGs would participate the hatching process. Effects of indomethacin, an antagonist to PGs biosynthesis, on the hatching of mouse blastocysts were examined in vitro. Furthermore, it was studied that prostaglandin E₂ (PGE₂), prostaglandin F_2α (PGF_2α) or 6-keto-prostaglandin F_1α (6-keto-PGF_1α) were added to the culture media with indomethacin. (1) The hatching was inhibited by indomethacin yet the inhibition was reversible. (2) In the groups with indomethacin and PGE₂, no improvement was seen in the inhibition of hatching and the inhibition was irreversible. (3) In the groups with indomethacin and PGF_2α, inhibition of hatching was improved in comparison with the group with indomethacin. (4) In the groups with indomethacin and 6-keto-PGF_1α, no improvement was seen. The above results indicated that PGF_2α possibly had an accelerating effect on hatching and a high concentration of PGE₂ would exert cytotoxic effect on blastocysts.     

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.     

Receptor binding in various tissues of PGE2, PGF2α and sulprostone, a novel PGE2-derivative

Sulprostone is a tissue-specific PGE₂-derivative with high abortifacient activity in various species including man. The dissociation constant K_D of the receptor binding of this compound was compared with PGE₂ and PGF_2α in various tissue preparations of different species. A structure-binding relationship was developed from competition curves after a logit/log transformation. It is demonstrated that the relative affinities of Sulprostone, PGE₂ and PGF_2α remain essentially constant in all the tissues investigated. It is concluded that the tissue-specificity of Sulprostone cannot be ascribed to structural differences of the receptor molecule.     

The effect of adrenergic stimulation on urinary prostaglandin E2 and 6 keto PGF1α in man

To evaluate the details of the adrenergic stimulation of urinary prostaglandins in man, ten normal volunteers were given various agonists and antagonists. The effect of 4 hour IV infusions of norepinephrine (NE), NE + phentolamine (PHT), NE + phenoxybenzamine (PHB), NE + prazosin (PZ), isoproterenol (ISO), and PHT alone on urinary PGE₂ and PGI₂ (6 keto PGF_1α) were determined. PGE₂ and 6 keto PGF_1α were measured by radioimmunoassay from 4 hour urine samples. NE stimulated both PGE₂ (196±40 to 370±84 ng/4 hrs/g creatinine and 6 keto PGF_1α(184±30 to 326±36), both p<0.01. In contrast, ISO had no effect on either PGE₂ or 6 keto PGF_1α excretion. Alpha blockade with PHT. PHB, or PZ inhibited the NE induced systemic pressor effect. However, the effect of the alpha blockers on the NE induced stimulation of PGE₂ and 6 keto PGF_1α varied. PHT did not alter the NE stimulated PGE₂ or 6 keto PGF_1α release (370±84 vs. 381±80) PGE₂ and (326±50 vs. 315±40) 6 keto PGF_1α, both p>0.2). PHT alone stimulated only 6 keto PGF_1α. PHB and the specific α₁ antagonist PZ similarly eliminated the NE induced prostaglandin release. These results suggest that adrenergically mediated urinary prostaglandin release in man is via an alpha receptor with α₁ characteristics.     

Synthesis and metabolism of prostaglandins E2, F2α and D2 by the rat gastrointestinal tract. Stimulation by a hypertonic environment in vitro

Whole cell preparations of rat stomach corpus, jejunum, and colon were incubated and the released prostaglandin E₂ (PGE₂), PGF_2α, PGD₂, 15 keto-13,14 dihydro PGE₂, and 15 keto-13,14 dihydro PGF_2α were measured by combined gas chromatography-mass spectrometry. All regions made PGD₂ and possessed a high capacity for producing 15 keto-13,14 dihydro derivatives of both PGE₂ and PGF_2α. Hypertonic sucrose solutions resulted in concentration-dependent increases in prostaglandin release, particularly of PGE₂ and its metabolite. It is suggested that PG's may play a role in the local effects of luminal hyperosomolarity on digestive tract functions.