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.     

Bronchopulmonary and cardiovascular effects of prostaglandin D2 in the dog

The effects of intravenously administered prostaglandin D₂ (PGD₂) on bronchopulmonary and cardiovascular functions were examined in the dog. PGD₂ (0.03–1.0 μg/kg) was shown to be more active than PGF_2α, a known bronchoconstrictor, in decreasing dynamic lung compliance, tidal volume, and expiratory airflow rate, as well as in elevating lung resistance. PGD₂ demonstrated a potency approximately 4–6 times that of PGF_2α on pulmonary mechanics. Atropine sulfate infusions reduced significantly the resistance and compliance responses to PGF_2α, but only the resistance responses to PGD₂, thereby suggesting that part of the bronchoconstrictor activities of these agents involved a cholinergic component.In another series of anesthetized dogs, PGD₂ (0.1–10.0 μg/kg) increased pulmonary arterial pressure (comparable to PGF_2α) and heart rate (greater than PGF_2α, but less than PGE₂), while concomitantly decreasing systemic arterial pressure in a dose-related manner ( that of PGE₂). Qualitatively similar alterations in cardiovascular parameters were obtained for PGD₂ in conscious dogs.Therefore, potent biologica activity of PGD₂ has been shown in the dog. No physiologic or pathologic role for PGD₂ has yet been demonstrated, but nonetheless, since it is a naturally occurring PG derived from arachidonic acid, further studies are warranted.     

Effects of prostaglandins E2, I2 and F2α, arachidonic acid and indomethacin on pressor responses to norepinephrine in conscious rats

The effects of prostaglandins E₂ (PGE₂), I₂ (PGI₂) and F₂α (PGF₂α), arachidonic acid and indomethacin on pressor responses to norepinephrine were examined in conscious rats. Intravenously infused PGE₂ (0.3, 1.25 μg/kg/min), PGI₂ (50, 100 ng/kg/min), PGF₂α (1.8, 5.4 μg/kg/min) and arachidonic acid (0.7, 1.4 mg/kg/min) did not change the basal blood pressure. Both PGE₂ and PGI₂ significantly attenuated pressor responses to norepinephrine, whereas PGF₂α significantly potentiated them. Arachidonic acid, a precursor of the prostaglandins (PGs), significantly attenuated pressor responses to norepinephrine. Since the attenuating effect of arachidonic acid was completely abolished by the pretreatment with indomethacin (5 mg/kg), arachidonic acid is thought to exert an effect through its conversion to PGs. On the contrary, intravenously injected indomethacin (0.2–5.0 mg/kg) facilitated pressor responses to norepinephrine in a dose-related manner without any direct effect on the basal blood pressure. These results suggest that endogenous PGs may participate in the regulation of blood pressure by modulating pressor responses to norepinephrine in conscious rats.     

Dose response relation of the renal effects of PGA1, PGE2, and PGF2α in dogs

The effects of the three prostaglandins A₁, E₂, and F_2α on renal blood flow, glomerular filtration rate (GFR), fluid excretion, and urinary output of Na, K, Ca, Cl, and solutes were evaluated at a dose range of 0.01 – 10 μg/min. The prostaglandins were infused into the renal artery of dogs. GFR was not significantly altered by the PGs. PGA₁ increased renal blood flow by approximately of the control at 0.01 μg/min without dose dependence at higher infusion rates. It had only little effects which were not dose dependent on fluid and electrolyte output. The effects of PGE₂ on renal blood flow, fluid, sodium, and chloride excretion were dose dependent with a steep slope of the dose response curve between 0.1 and 1.0 μg/min. Blood flow was increased maximally by 80 %, urine volume by more than 400 %. PGF_2α had no effect on renal blood flow, whereas urinary output was increased to approximately the same maximal level as by E₂ although ten times higher doses were needed. Potassium excretion was less influenced than the excretion of Na and Cl and osmolar clearance was less increased than urine volume by all three prostaglandins.It is concluded that if a PG is involved in the regulation of the renal fluid or electrolyte excretion it is likely to be of the PGE-type. A PGA could only be involved in regulation of renal hemodynamics, whereas PGF although effective in the kidney exerts its effects at doses too high to have physiological significance.     

Reversal of indomethacin-induced inhibition of tubuloglomerular feedback by prostaglandin infusion

Experiments were performed in rats to study the effect of infusion of PGI₂, PGE₂, and PGF_2α on tubuloglomerular feedback responses (i.e. the change of SNGFR in response to a change of loop of Henle flow rate) in the presence and absence of simultaneous inhibition of endogenous PG synthesis with indomethacin. Infusion of PGI₂ or PGE₂ at rates that did not alter arterial blood pressure did not significantly modify the magnitude of feedback responses (PGI₂) 8.5 μg/hr, PGE₂ 85 μg/hr). Some inhibition of feedback responses was seen when PGI₂ and PGE₂ were administered at higher rates were associated with a reduction of blood pressure (PGI₂ 20 μg/hr, PGE₂ 200 μg/hr). PGI₂ (8.5 μg/hr) and PGE₂ (85 μg/hr) largely prevented feedback inhibition induced by indomethacin. When given subsequent to indomethacin PGI₂ and PGE₂ restored feedback responsiveness almost to normal. In contrast, PGF_2α did not influence feedback inhibition caused by indomethacin. Infusion of PGI₂ induced partial restoration of feedback responses in DOCA-salt treated animals in which the feedback system is virtually completely inactive. Our results indicate that availability of PGI₂ or PGE₂ is necessary for the normal operation of the tubuloglomerular feedback mechanism for control of nephron filtration rate.     

Radioimmunological and biological measurement of prostaglandins in rabbit urine : Decrease of PGE2 excretion at high NaCl intake

The estimation of prostaglandin (PG) E₂ and of PGF_2α by radioimmunoassay is described in detail. PGE₂ was measured after conversion to either PGB₂ or PGF_2α and the results compared to bioassay. The methods were used to follow the excretion of PGE₂ and PGF_2α after salt loading in rabbits. A marked reduction of PGE₂ levels was observed at high NaCl intake, while PGF_2α excretion remained unchanged.     

Different responses to prostaglandin F2α and E2 in human extra- and intramyometrial arteries

Tubal segments of the ascending uterine arteries and of intramyometrial arteries were obtained from 18 women who underwent hysterectomy at various phases of the menstrual cycle. Ring preparations of the vessels were mounted in organ baths and isometric tension was recorded. In extramyometrial arteries (outer diameter 2–3 mm) prostaglandin (PG) F_2α most potently, but also PGE₂ caused concentration-related contractions. In contrast, the contractant effects of both PGs on intramyometrial arteries (outer diameter 0.5–0.6 mm) were negligible. Both extra- and intramyometrial vessels were relaxed to a moderate degree (10–25%) by low concentrations of PGF_2α and PGE₂. No significant differences between the responses to vasopressin and noradrenaline were found between the vessel preparations. Thus human uterine arteries seem to change their responses to PGF_2α and PGE₂ as they enter the myometrium and decrease in diameter, and the results raise doubt about the view that direct vasoconstrictor effects of these PGs contribute to the regulation of myometrial blood flow. Such effects of vasopressin and noradrenaline cannot be excluded.     

Biosynthesis of prostaglandins and thromboxane B2 by fetal lung homogenates

The conversion of arachidonic acid to prostaglandins (PG's) and thromboxane B₂ (TXB₂) was investigated in homogenates from fetal and adult bovine and rabbit lungs. Adult bovine lungs were very active in converting arachidonic acid (100 μg/g tissue) to both PGE₂ (10.7 μg/g tissue) and TXB₂ (6.2 μ/g tissue). Smaller amounts of PGF_2α (0.9 μ/g) and 6-oxoPGF_1α were formed. Homogenates from fetal calf lungs during the third trimester of pregnancy were quite active in converting arachidonic acid to PGE₂, but formed very little TXB₂, PGF_2α or 6-oxoPGF_1α. Homogenates from rabbit lungs converted arachidonic acid (100 μg/g) mainly to PGE₂, both before and after birth. The amount of PGE₂ formed increased during gestation to a maximum of about 6 μg/g tissue at 28 days of gestation. It then decreased to a minimum (1.5 μg/g) which was observed 8 days after birth, followed by an increase to about 4 μg/g in older rabbits.     

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.     

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.     

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.     

Chemotactic activity of thromboxane B2, prostaglandins and their metabolites for polymorphonuclear leucocytes

(1) The chemotactic activities of thromboxane B₂ (TxB₂, PGE₂, PGF_2α, the 15-oxo, 15-oxo-13,14-dihydro and 13,14-dihydro metabolites of PGE₂, PGF_2α, and a metabolite of TxB₂ for polymorphonuclear leucocytes (PMN) have been investigated.(2) Thromboxane B₂ increased the directional migrationm of rat peritoneal PMN at a concentration of 2.0 μg/ml and of human peripheral neutrophils at a concentration of 0.5 μg/ml.(3) Neither PGE₂, PGF_2α nor their metabolites showed chemotactic activity for rat peritoneal PMN.(4) PGF_2α and 15-oxo-13,14-dihydro-thromboxane B₂ showed no chemotactic activity for human peripheral PMN.(5) The possible role of thromboxane B₂ in inflammation is discussed.     

Effects of prostaglandins E1 and F2α on serum luteinizing hormone concentration and on some sexual functions in male rabbits

PGE₁(50μg/animal) and PGF_2α (250 μg/animal) caused a transient in serum LH at 5 min after injection. PGE₁ (250 μg/animal) had a biphasic effect on serum LH. A small peak was obtained at 5 min, and a second, larger peak at 60 min after injection. It is suggested that the first peak is a result of the stress associated with injection of the PGs, whereas the second peak represents a physiological effect of PGE. Subcutaneous injection of PGE₁ (1 mg in arachis oil b.i.d.) for 10 days did not affect the concentration of LH in serum, the function of the accessory sexual glands or the sexual activity. PGF_2α, given at the same dose and in the same manner, increased the sexual activity but left all other variables unaffected. The pituitary responsiveness to LH-RH was unaltered by the treatment with PGE₁ and PGF_2α.     

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.     

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.     

Effects of intracerebroventricular administration of PGE1, E2 and F2α on electrically induced convulsions in mice

Intracerebroventricular administration of prostaglandins E₁ or E₂ was shown to block, while PGF_2α increased the incidence of tonic convulsion due to electroshock in mice. The Prostaglandins were administered intracerebroventricularly (i.c.v.) to conscious mice by a modification of Haley and McCormick's method (1) prior to a transcorneal maximal electroshock (MES) or a transcorneal supra-maximal electroshock (SMES). PGE₁ and PGE₂ i.c.v. blocked the tonic hindlimb extension (THE) and protected the animals from death induced by MES with ED₅₀'s for PGE₁ and PGE₂ for inhibition of the THE of 6.6 (4.3–12.0) μg/mouse i.c.v. and 13.3 (8.9–22.4) μg/mouse i.c.v. respectively. When PGE₂ was administered intraperitoneally (i.p.) in doses as high as 4.0 mg/kg it did not block the THE. However, the duration of the THE as well as the mortality were reduced by doses of 0.5–4.0 mg/kg PGE₂ i.p.. Both PGE₁ and PGE₂ were shown to cause a dose related significant (p<.001) decrease in the duration of the THE with SMES in doses of 1–10 μg/mouse i.c.v. for PGE₁ and 2–40 μg/mouse i.c.v. for PGE₂. PGF_2α, administered i.c.v. prior to a transcorneal electroshock equivalent to a current at the ED₁ level, increased the incidence of the THE as well as the mortality in doses of 20–50 μg/mouse.     

Comparative studies of prostaglandins F2α and E2 in late cyclic and early pregnant sheep: synthesis by endometrium and conceptus effects of indomethacin treatment on establishment of pregnancy

Endometrial concentrations of prostaglandins F₂α (PGF₂α) and E₂ (PGE₂) were measured by specific radioimmunoassay in sheep, on day 14 of estrous cycle or pregnancy, during luteolysis (Day 16 of the cycle), and after implantation (Day 23 of pregnancy) : concentrations observed on day 14 of cycle and pregnancy were similar. During luteolysis, on day 16 of cycle, a consistent drop was noticed. If luteal regression did not occur, as a consequence of the presence of an embryo, endometrial concentrations of PGF₂α on day 23, were twice those of day 14, and PGE₂ remained unchanged. 2 hour incubations of endometrial caruncular tissue from 14 days cyclic or pregnant ewes resulted in de novo synthesis of PG which could be increased by Arachidonic Acid and inhibited by Indomethacin; during the first 30 min of incubation, the PGF₂α synthesis was comparable for both endometrial tissues, whereas PGE₂ synthesis was twice as great in pregnant endometrium. Fourteen and 23 day conceptuses had high PGF₂α and PGE₂ concentrations which were not due to maternal PG sequestration : PG synthesis which could be inhibited by Indomethacin was observed in incubated 14 day old embryos. Treatment of pregnant ewes from day 7 to day 22 after mating, either with Indomethacin (300 mg s.c. daily) or with Acetylsalicylic Acid (1 g I.V. daily) resulted in a sharp diminution of endometrial PG concentration and release, with no apparent effect on the establishment of pregnancy. These results tend to ascribe a less important role to PG during early pregnancy in sheep as compared with rodents, in terms of embryonic growth and implantation.     

Prostaglandin E2 opunteracts the effects of PGF2α in indomethacin treated cycling gilts

Twenty crossbred gilts with at least 2 consecutive estrous cycles of 18 to 21 days in length were used to study the effects of prostaglandins E₂ and F₂α (PGE₂ and PGF₂α) on luteal function in indomethacin (INDO) treated cycling gilts. Intrauterine and jugular vein catheters were surgically palced before day 7 of the treatment estrous cycle and gilts were randomly assigned to 1 of 5 treatment groups (4/groups). With exception of the controls (Group I) all gilts received 3.3 mg/kg INDO every 8 h, Groups III, IV and V received 2.5 mg PGF₂; 2.5 mg PGF₂α + 400 μg PGE₂ every 4 hr, or 400μg PGE₂ every 4 h, respectively. All treatments were initiated on day 7 and continued until estrus or day 23. Jugular blood for progesterone analysis was collected twice daily from day 7 to 30. Estradiol-17β (E₂-17β) concentrations were dtermined in samples collected twice daily, from 2 d before until 2 d following the day of estrus onset. When compared to pretreatment values, estrous cycle length was unaffected (P>0.05) in Group I, prolonged (P<0.05) in Groups II, IV and V; and shortened (P<0.05) in Group III. The decline in plasma progesterone concentration that normally occurs around day 15 was unaffected (P>.05) in Group I; delayed (P<0.05) in Groups II, IV and V; and occurred early (P<0.05) in Group III. Mean E₂-17β remained high (31.2 ± 4.9 to 49.3 ± 3.1 pg/ml) in Groups III and IV, while the mean concentrations in Groups III and V varied considerably (17.0 ± 2.0 to 52.2 ± 3.5 pg/ml). The results of this study have shown that PGE₂ will counteract the effects of PGF₂α in INDO treated cycling gilts. The inclusion of PGF₂α appeared to either stimulate E₂-17β secretion or maintain it at a higher level than other treatments.     

Midterm abortion in hamsters induced by Silastic-PVP-PGE2 tubes

Intrauterine insertion of a 0.5 cm long Silastic-PVP tube containing 750 μg PGE₂ (lyophilized sodium salt) caused midterm abortion in hamsters within 48 hours. An earlier study using a similar Silastic-PVP tube delivery system showed that 200 μg of PGF_2α (Tham) was sufficient to induce abortion in 100% of pregnant hamsters (18). Prostaglandin E₂ is, therefore, about 3.5–4 times less potent than PGF_2α as an abortifacient in the hamster. The release of ³H-PGE₂ from Silastic-PVP tube and is also described. It is suggested that an increase in LH release might be one of the factors leading to luteolysis; and that either PGE₂ exerts a direct luteolytic effect or this effect is manifested after its being converted to PGF_2α.     

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.