The effect of prostaglandin F2alpha on the activator calcium of the uterus.

The mechanism through which PGF2_α exerts its oxytocic action was studied in 150 uterine strips, 48 excised from 25 days pregnant and 102 from post partum rabbits. PGF2_α delayed the loss of excitability upon exposure of the uterus to Ca-free Krebs Ringer Bicarbonate (KRB) solution and accelerated recovery when half (1.25 mM) of the normal CaCl₂ was replaced in the KRB. This effect of PGF2_α was more pronounced in the post partum than the pregnant uterus, which resisted Ca-deficiency by high affinity binding in its plasma membrane of the activator-Ca (A-Ca).The Ca-ionophore A23187 simulated the action of PGF2_α but only during stimulation with 12 V/5 cm and not with 60 V/5 cm. This finding suggests that while the effect of PGF2_α is limited to a control of the movement of the extracellular and membrane-bound Ca, A23187 affects the distribution of Ca liberated by the strong (60 V/5 cm) electric field from internal stores of the myometrial cells. In the presence of Ruthenium-red (a Ca-influx inhibitor) and only 1.25 mM CaCl₂, PGF2_α restored excitability slowly, indicating that PGF2_α is an oxytocic agent because it promotes Ca-influx. However, knowing that Ca-efflux is in part dependent upon Ca-influx the most informative present finding was the observation that PGF2_α did not promote ⁴⁵Ca-efflux when ⁴⁰Ca-influx was inhibited by Verapamil. This demonstration provided more direct evidence that PGF2_α promotes the influx of the A-Ca and thus explained the mechanism of action of this key regulator at the molecular level.     

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.     

The effect of prostaglandin F2β on expiratory flow rates

Prostaglandin F_2β (PGF_2β), a stereoisomer of F₂ was administered by ultrasonic nebulization to eight patients with bronchial asthma and four normal subjects in increasing doses up to a 200 μg maximum dose. Maximum expiratory flow (MEF) and forced vital capacity (FVC) were analyzed at 5, 15, 30, 60 and 120 minutes after administration of aerosol.

All expiratory flow rates were reduced after 5 minutes. Some increase in terminal flow rates was observed after 60 minutes. We conclude that PGF_2β is not an effective bronchodilator at this dose level.     

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.     

Determination of prostaglandin F2α, E2, D2 and 6-keto-F1α in human cerebrospinal fluid

Prostaglandin (PG)F_2α, E₂, D₂ and 6-keto-F_1α were determined in human cerebrospinal fluid by a mass spectrometric technique. The samples were obtained from 12 patients with suspected intracranial disease. A 64 fold variation in PG levels was observed. The major PG was 6-keto-F_1α (0.12–15 ng/ml). PGF_2α and PGE₂ were present in lower concentrations PGD₂ was below the level of detection (0.05 ng/ml) except in one patient with extremely high total levels of PGs.     

Urinary excretion of prostaglandin E2 and prostaglandin F2α in potassium-deficient rats

Potassium-deficiency was induced in rats by dietary deprivation of potassium. The animals became polyuric and urine osmolality decreased more then three-fold compared to controls. Urinary excretion of prostaglandin E₂ (PGE₂) and prostaglandin F_2α (PGF_2α) did not increase during 2 weeks of potassium depletion. Partial inhibition of renal prostaglandin synthesis by meclofenamate did not increase the urine osmolality after water deprivation. These results make unlikely the hypothesis that the polyuria of potassium-deficiency, is the result of enhanced renal synthesis of prostaglandins with subsequent antagonism of the hydro-osmotic effect of vasopressin. Male animals consistently excreted less PGE₂ than female animals.     

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.     

The effect of intra-uterine prostaglandin F2α on corpus luteum function in the human

Prostaglandin F_2α (PGF_2α) was administered via a Foley catheter over a 12 hour period to 8 healthy volunteers awaiting laparoscopic sterilisation. The amount of PGF_2α infused varied between 500 μg and 2000 μg every 2 hours for 6 doses. Plasma progestins and oestradiol 17β, and urinary estrogens and pregnanediol were assayed throughout the study period.There was no evidence of luteolysis in any patient although vaginal bleeding of varying duration occurred in all women within 36 hours of administration of PGF_2α.     

Effect of prostaglandin F3α on gastric mucosal injury by ethanol in rats: Comparison with prostaglandin F2α

In humans eicosapentaenoic acid can be converted to 3-series prostaglandins (PGF_3α, PGI₃, and PGE₃). Whether 3-series prostaglandins can protect the gastric mucosa from injury as effectively as their 2-series analogs is unknown. Therefore, we compared the protective effects of PGF_3α and PGF_2α against gross and microscopic gastric mucosal injury in rats. Animals received a subcutaneous injection of either PGF_3α or PGF_2α in doses raning from 0 (vehicle) to 16.8 μmol/kg and 30 min later they received intragastric administration of 1 ml of absolute ethanol. Whether mucosal injury was assessed 60 min or 5 min after ethanol, PGF_3α was significantly less protective against ethanol-induced damage than PGF_2α. These findings indicate that the presence of a third double bond in the prostaglandin F molecule between carbons 17 and 18 markedly reduces the protective effects of this prostaglandin on the gastric mucosa.     

Intracellular recording of cerebral cortical actions of prostaglandin F2α (PGF2α)

Our reported data on the cortical inhibitory actions of prostaglandin F_2α (PGF_2α) and the diversity of data in the literature on cerebral PG actions are examined here in the light of intracellular recording which provides the requisite membrane data for the first time. Thus, 1) intracellular recording from the cat cerebral cortex is obtained for the actions of PGF_2α and for norepinephrine (NE) and serotonin (5HT). 2) The parallel changes in firing and polarization and the simultaneous transmembrane conductance changes are qualitatively identical for PGF_2α, NE and 5HT. 3) The reduction in firing accompanied by hyperpolarization indicates that PGF_2α, NE and 5HT all inhibit these cells. 4) The ionic species responsible for this inhibition is such that it increased the transmembrane resistance, and this was true for all three. 5) The changes in membrane parameters, identical in direction for PGF_2α and NE, but stronger for the latter, constitute conditions that can lead to competitive inhibition and therefore conote, presumably, actions at the same or related receptors. Such competition with evoked cortical field potentials is shown in the preceding paper.     

Stereospecificity of enzymatic reduction of prostaglandin E2 to F2α

Antibodies directed toward PGF_2β were prepared in rabbits. The serologic specificity of the immune reaction was determined by inhibition of sodium borohydride-reduced (³H) PGE₂ anti-PGF_2β binding by several prostaglandins. The antibodies to PGF_2β recognize the β-hydroxyl configuration in the cyclopentane ring of PGF_2β. With the use of both anti-PGF_2α and anti-PGF_2β, the product of PGE₂ reduction by 9-ketoreductase purified from chicken heart was identified as PGF_2α. Guinea pig liver and kidney homogenates were examined for PGE 9-ketoreductase activity. Although enzyme activity was present, no evidence of PGF_2β production was found.     

Radioimmunoassays of prostaglandin F2α and prostaglandin F2α-main urinary metabolite with prostaglandin-I-tyrosine methylester amide

Radioimmunoassays for measuring prostaglandin F_2α (PGF_2α) and 5α, 7α-dihydroxy-11-keto tetranorprosta-1,16-dioic acid, PGF_2α-main urinary metabolite (PGF_2α-MUM), with ¹²⁵I-tyrosine methylester amide (TMA) of PGF_2α and PGF_2α-MUM were developed.Antibody to PGF_2α was produced in rabbits immunized with conjugates of PGF_2α coupled to bovine serum albumine. Antibody to PGF_2α-MUM was also produced in rabbits immunized with conjugates of PGF_2α-MUM coupled to bovine serum albumin.PGF_2α-¹²⁵I-TMA had an affinity to antiserum to PGF_2α. PGF_2α-MUM-¹²⁵I-TMA also responded to antiserum to PGF_2α-MUM.     

The effect of indomethacin on the biosynthesis and metabolism of prostaglandin F2α in man

Healthy volunteers received 60 μg of [8,10,10-²H₃] PGF_2α by intravenous infusion both before and during a course of treatment with indomethacin (200 mg/day). Excretion of deuterated 5α, 7α-dihydroxy-11-ketotetranor-prostane-1, 16-dioic acid in urine was quantified by GC-MS using a reverse stable isotope dilution procedure. Indomethacin was found to have no detectable effect on the metabolism of the labelled PGF_2α whereas output of the endogenous metabolite was markedly reduced by the effect of the drug on prostaglandin biosynthesis.     

The action of prostaglandin E2 and F1α on myocardial ischaemia-infarction arrhythmias in the dog

Prostaglandin E₂ and F_1α infusions have been tested for their ability to reduce the arrhythmias associated with occlusion of the left descending coronary artery in the anaesthetised dog. At 1 μg/kg/min both PGs reduced the incidence of premature ventricular contractions occurring during 25-min occlusions, while not reducing the incidence of ventricular fibrillation occurring on occlusion release. When infused for 5-min periods at 1 to 16 μg/kg/min, neither PGE₂ nor PGF_1α effectively reduced the frequency of ventricular arrhythmias occurring 24 hr after a permanent coronary occlusion.     

Production rates of prostaglandin F, 6-keto-PGF1α and thromboxane B2 by perifused human endometrium

Human endometrium obtained from fresh hysterectomy specimens was perifused for 7 hr in 95% O₂/5% CO₂ at 37°C. The phase of the menstrual cycle was determined by histological examination. The concentrations of PGF, 6-keto-PGF_1α and TxB₂ in 20 min fractions of the perifusion medium were measured by radioimmunoassay and production rates were calculated in terms of dry weight of tissue. Biphasic patterns of production were observed; high initial values fell to about 20% at 2 hr and then increased to relatively stable values at about 4 hr which were maintained for the next 2 hr. During this latter period, production rates in endometria taken at different phases of the cycle differed markedly from each other; the production rates of PGF in secretory and early proliferative endometria were low (15.8 ± 2.6, mean ± SEM and 67.2 ± 8.3 ng/min/g respectively) whereas they were high in late proliferative and premenstrual endometria (188.0 ± 16.7 and 196.4 ± 16.9 ng/min/g respectively). The patterns of production of 6-keto-PGF_1α and TxB₂ were similar to those of PGF but the absolute values were much lower (<10%). We conclude that the observed rates of production of prostaglandins by perifused human endometrium are consistent with synthesis being stimulated either by estrogen or withdrawal of hormonal support and being inhibited by progesterone.     

Cardiovascular actions of prostaglandins F2α; 15-me-F2α; F1α; F2β and F1β in the cat

Prostaglandin F_2α (5μg/kg, i.v.) causes an increase in pulmonary arterial pressure, decrease in systemic arterial pressure, and reflex bradycardia in the anesthetized cat. The same dose of the 15-methyl analogue of PGF_2α produces the same triad of effects but of greater magnitude and duration. Although prostaglandins F_1α, F_2β and F_1β also cause the same cardiovascular effects as F_2α, there is a decrease in potency for all parameters measured, with PGF_2α>PGF_1α>PGF_2β>PGF_1β. When compared to the actions of PGF_2α in producing an increase in pulmonary arterial pressure, PGs F_1α, F_2β and F_1β were less potent by approximately 10, 100, and 1000 fold respectively.     

The effects of prostaglandin F2α on sperm output in boars

The effect of prostaglandin F_2α (PGF_2α) on the sperm output of six boars was investigated in two studies. Although PGF_2α did not significantly affect sperm numbers in the ejaculate, a significantly longer (P < 0.05) ejaculation of the sperm rich fraction occurred following injection of PGF_2α. In the second study it was found that PGF_2α produced a 49% increase (P < 0.05) in the number of sperm in the sperm rich fraction of the ejaculate. The implications of these results on artificial breeding are discussed.     

Viroimmunoassay of prostaglandin F2α at the picogram level

A viroimmunoassay of PG F_2α is presented here. By a modification of the technique used by Dray et al. (3), it allowed us to measure as low as one picogram of PG F_2α. It seems that such a sensitive assay might be usefull for many purposes in the prostaglandin field.     

The excretion of prostaglandin F2α in milk of cows

Prostaglandin F_2α (PGF_2α) was measured by immunoassay in plasma and milk of four cows (six experiments). After 30 mg PGF_2α im, plasma PGF_2α peaked at 15 minutes (2.4 ± 0.7 ng/ml) and declined toward basal values by 3 hours; maximum milk PGF_2α (0.91 ± 0.12 ng/ml) occurred at 1 hour. The average excretion rate in milk was 2.9 μg/day 0.9 μg (0.003%) of which was due to the 30 mg PGF_2α injected. In six non-pregnant control cows, daily changes of milk PGF_2α and progesterone were not consistently related.     

The effects of progesterone, prostaglandin F2α and oxytocin on the calcium-activation of the uterus

The relationship between “activator-calcium” (A-Ca), progesterone (P), prostaglandin F2α (PGF2α) and oxytocin (Oxy) has been examined in 100 uterine strips of 34 pregnant and 100 strips of 34 post partum rabbits. At the 25th day of gestation, uterine P was 13.9±1.3 ng/g, while within 3–12 hours post partum 3.3±0.3 ng/g tissue (P<0.001). Uterine strips, mounted isometrically in Krebs' solution, sustained maximum excitability in a steady state when exposed every 30 seconds for 4 seconds to an electric field of 12 V/5 cm (a.c.). The maximally contracting muscles were then rinsed at intervals of 6 minutes with Ca-free Krebs.In Ca-free Krebs, the post partum uterus lost 31% of its Ca and 96% of its excitability in a short 25 minutes, while the pregnant uterus lost 30% of its Ca and 93% of its excitability in 50 minutes (P<0.001). Since the extracellular space is 30% in the uterus, this 30% Ca, lost by both muscles, most probably was extracellular Ca and the small A-Ca fraction which is presumably “bound” more strongly at the membrane systems of the P-dominated pregnant, than the non-dominated post partum uterus. The significantly faster and more complete recovery from Ca-deficiency and inexcitability of the pregnant than the post partum uterus (P<0.001), at different levels of external Ca, further substantiates this premise. So does the demonstration that exposure to Ca-free Krebs increases ⁴⁵Ca-efflux 400% in the post partum and only 110% in the pregnant uterus (P<0.001). Exposure to 100 ng/ml PGF2α in normal Krebs has a similar effect on the ⁴⁵Ca-efflux of the post partum uterus, while the response of the pregnant uterus is indistinct (P<0.001).These highly significant differences between the post partum and the pregnant uteri in their Ca-efflux explain the higher threshold (P<0.001) and lower “sensitivity” to PGF2α and Oxy (P<0.001) of the pregnant than the post partum uterus. The already very highly significant differences between the two muscles, in threshold and sensitivity to these two most potent oxytocics, were increased still further by rendering the uterine strips Ca-deficient. All together, these findings substantiate the early contention (1–7,18,19) that uterine function at the cellular level is regulated by opposing actions of the suppressor P and the intrinsic stimulant PG or other oxytocic agents on threshold, excitability and the Ca-activation of the contractile process.