Increased neural damage to global hemispheric hypoxic ischemia (GHHI) in febrile but not nonfebrile lipopolysaccharide Escherichia coli injected rats

Experiments were conducted to compare the impact of febrile versus nonfebrile lipopolysaccharide (LPS) induced bacterial infection at the time of global hemispheric hypoxic ischemia (GHHI) on the neural damage evoked by the GHHI insult. In the first study acute intraperitoneal (i.p.) sterile saline (SS) or LPS Escherichia coli (60 microg/kg) was given to groups of male, conscious Long Evans rats, and core (colonic, Tc) temperatures were monitored over 6 h postinjection. Peak febrile response occurred approximately 5 h after the LPS E. coli was injected. Upon sacrifice 7 days later, no hemispheric or regional brain damage occurred in the saline or LPS-injected groups of this first study. In the second study, GHHI was applied (ligation of right common carotid artery + 35 min of 12% O2) in groups of anesthetized, male Long Evans rats previously given an acute i.p. injection of sterile saline or 60 microg/kg LPS E. coli 5 h earlier. Temperatures (Tc) were monitored before, during, and 1.5 and 24 h following GHHI. The LPS-injected group was subdivided into a febrile (Tc > 38 degrees C before and (or) after GHHI) and nonfebrile (Tc < 38 degrees C before and after GHHI) subgroups. A significant correlation was found between the peak temperature rise from preinjection control values following drug administration of either saline or LPS E. coli and the resultant hemispheric damage caused by GHHI. Moreover, upon sacrifice 7 days later ipsilateral hemispheric and regional (i.e., hippocampal, thalamic) damage to GHHI of the febrile LPS E. coli group was significantly increased from respective hemispheric, hippocampal, and thalamic damage of the saline and nonfebrile, LPS groups given the same ischemic insult. Results suggest that the heightened Tc of a LPS infection at the time of global ischemia exacerbated the neural damage of GHHI, a finding similar to that reported with heightened core temperatures induced by external heating.     

Proliferative effect of PGD2 on osteoblast-like cells; independent activation of pertussis toxin-sensitive GTP-binding protein from PGE2 or PGF2 alpha.

PGD2 stimulated DNA synthesis and decreased alkaline phosphatase activity dose-dependently between 10 nM and 10 microM in osteoblast-like MC3T3-E1 cells. PGD2 had little effect on cAMP production, but caused very rapid enhancement of phosphoinositide (PI) hydrolysis dose-dependently between 10 nM and 10 microM. The formation of inositol trisphosphate (IP3) induced by PGD2 reached the peak within 1 min and decreased thereafter, which is more rapid than that induced by PGE2 or PGF2 alpha and both PGE2 and PGF2 alpha affected PGD2-induced IP3 formation additively. Pertussis toxin (PTX) inhibited both PGD2-induced formation of inositol phosphates and DNA synthesis. The degree of these PTX (1 micrograms/ml)-induced inhibitions was similar. In addition, neomycin, a phospholipase C inhibitor, inhibited PGD2-induced DNA synthesis as well as the formation of IP3, and the patterns of both inhibitions were similar. In the cell membranes, PTX-catalyzed ADP-ribosylation of a 40-kDa protein was significantly attenuated by pretreatment of PGD2. Time course of the attenuation of PTX-catalyzed ADP-ribosylation by PGD2 was apparently different from that by PGE2 or PGF2 alpha. These results indicate that PGD2 activates PTX-sensitive GTP-binding protein independently from PGE2 or PGF2 alpha and stimulates PI hydrolysis resulting in proliferation of osteoblast-like cells.     

The effects of certain vasodilating prostaglandins on the coronary and hindlimb vascular beds of the conscious sheep

Vasodilating prostaglandins were injected, in bolus doses, into the lower abdominal aorta or left circumflex coronary artery (LCCA) of conscious sheep. Local blood flow, mean arterial pressure (MAP), heart rate (HR) and ECG were monitored continuously. 6-Keto PGF1 alpha had no effect on either vascular bed in doses up to 100 micrograms. PGE2 was more potent than PGI2 in dilating hindlimb vasculature and PGE2 induced a more persistent hyperaemia whereas PGD2 elicited a biphasic response (constriction-dilation). PGE1, PGE2, PGD2 and PGI2 all produced dose-dependent vasodilation, the order of potency being PGD2 greater than PGI2 greater than PGE1 greater than or equal to PGE2. The effect of PGI2 was more transient and PGE1 and PGD2 caused small but consistent decreases in MAP and HR, respectively.     

Anhydrolevuglandin D2 inhibits the uterotonic activity of prostaglandins F2 alpha and D2

Anhydrolevuglandin D2 (AnLGD2), which is produced from PGH2 by a water-induced rearrangement and subsequent dehydration, is uterotonic. However, increasing concentrations caused decreased responses of the uterine horns. AnLGD2 inhibited responses of uteri to stimulation by specific prostaglandins. PGF2 alpha was inhibited at an AnLGD2:PGF2 alpha ratio of 0.05:1 with 5 to 25 pg/ml concentrations of PGF2 alpha. The response to PGD2 was inhibited at an AnLGD2:PGD2 ratio of 0.05:1 with PGD2 concentrations of 5 to 75 pg/ml. In contrast, the uterotonic effects of PGE2 were not inhibited by AnLGD2. When AnLGD2 was added to baths with contracting uteri it inhibited contractions less if the exposure period was 5 min than if it was 10 min. The longer exposure times produced prolonged inhibition of contractile activity with bath concentrations of AnLGD2 as little as 2.5 pg/ml.     

Role of COX-1 and COX-2 on skin PGs biosynthesis by mechanical scratching in mice

We examined the involvement of cyclooxygenase (COX)-1 and COX-2 on mechanical scratching-induced prostaglandins (PGs) production in the skin of mice. The dorsal regions of mice were scratched using a stainless brush. COXs expressions in the skin were analyzed using real-time PCR and Western blotting. The effect of acetylsalicylic acid (ASA) on the ability of PGs production were determined based on skin PGs level induced by arachidonic acid (AA) application. Mechanical scratching increased PGD2, PGE2, PGI2 and PGF(2 alpha). COX-1 was constitutively expressed and COX-2 expression was enhanced by scratching. Intravenous administration of ASA inhibited PGs biosynthesis in the normal skin. PGs levels of the skin 6h after ASA administration (ASA 6 h) were almost equal to those of the skin 10 min after ASA administration (ASA 10 min). In the scratched skin, AA-induced PGE2 and PGI2 of ASA 6 h were significantly higher than those of ASA 10 min. The skin PGD2 and PGF(2 alpha) of ASA 10 min were almost same to those of ASA 6 h. In the normal skin of COX-1-deficient mice, skin PGD2 level was lower than that of wild-type mice, although PGE2, PGI2 and PGF(2 alpha) levels were almost equal to those of wild type. In the scratched skin of COX-1-deficient mice, PGD2, PGE2, PGI2 and PGF(2 alpha) levels were lower than those of wild-type mice. These results suggested that cutaneous PGD2 could be mainly produced by COX-1, and PGE2 and PGI2 could be produced by COX-1 and COX-2, respectively, in mice.     

Prostaglandin synthesis by the cochlea

The exogenous and endogenous syntheses of prostaglandins (PG's) by the cochlea of adult mongolian gerbils were studied in vitro. After incubation of the whole membraneous cochlea with [3H]-arachidonic acid (AA), syntheses of PGF2 alpha, 6-keto PGF1 alpha, PGE2, thromboxane (TX) P2 and PGD2 were evidenced in this order. The synthesis of radioactive PG's was almost completely inhibited by incubation with 10(-5) M indomethacin. No significant amounts of those PG's were detected by radioimmunoassay (RIA) in the cochlea obtained from animals killed by microwave irradiation at 5.0 kw for 0.8 sec. However, when the homogenate of the whole membraneous cochlea obtained from animals without microwave irradiation was incubated at 37 degrees C for 0-15 min, PGD2, PGE2, PGF2 alpha and 6-keto PGF1 alpha were found to be formed from endogenous AA in the cochlea by RIA. PG's were formed already at 0 time to considerable level (PGD2, PGF2 alpha and 6-keto PGF1 alpha, 90-120 pg/cochlea; PGE2, 370 pg/cochlea), reached to the maximum level (PGD2, PGF2 alpha and 6-keto PGF1 alpha, 170-200 pg/cochlea; PGE2, 500 pg/cochlea) at a 5-min incubation, and then gradually decreased. On the other hand, the amount of TXB2 was lower than the detection limit by RIA (less than 50 pg/cochlea) even after the incubation. The cochlea was dissected into three parts: organ of Corti + modiolus (OC + M), lateral wall (LW), and cochlear nerve (CN), and then PG's formed by these tissues were determined after a 5-min incubation of the homogenates. In the CN and OC + M, PGE2 was the major PG (100 and 160 pg/tissue, respectively), and the amounts of PGD2, PGF2 alpha and 6-keto PGF1 alpha were about 1/3 of those of PGE2. In the LW, the amounts of PGD2, PGE2, PGF2 alpha and 6-keto PGF1 alpha were about the same level (70-100 pg/LW).     

The lack of involvement of central nervous system in the antiarrhythmic effects of prostaglandins E2, F2 alpha, and I2 in cat

The role of the central nervous system (CNS) in the antiarrhythmic effects of prostaglandins (PGs) E2, F2 alpha, and I2 was studied by administering each agent into the left lateral cerebral ventricle (i.c.v. administration) of chloralose-anaesthetized cats. The cardiac arrhythmias were produced by intravenous (i.v.) infusion of ouabain (1 microgram/kg/min). The PGs E2, F2 alpha and I2 on i.c.v. administration in the dose range of 1 ng to 10 micrograms failed to inhibit ouabain-induced cardiac arrhythmias. However, when infused i.v., PGE2 (1 microgram/kg/min), PGF2 alpha (5 micrograms/kg/min), and PGI2 (2 micrograms/kg/min) effectively suppressed these arrhythmias. The standard antiarrhythmic drug propranolol (0.5-8.0 mg) on i.c.v. administration also significantly reduced the ouabain-induced cardiac arrhythmias. It is suggested that the CNS is not the site of action of PGs E2, F2 alpha, and I2 in antagonising the ouabain-induced cardiotoxicity in cats.     

Contrasting effects of prostaglandins E2 and F2 alpha on sensitivity of the human cough reflex.

Prostaglandins have been shown to influence the sensitivity of the cough reflex. To investigate putative mechanisms of this, we examined the effects of inhaled prostaglandins E2 (PGE2) and F2 alpha (PGF2 alpha) on human cough responses elicited by two challenges, low chloride solution and capsaicin, which may activate different neural pathways. Baseline cough challenges were followed after 2 h by five breaths of PGE2, PGF2 alpha, or citric acid as a control. Cough challenges were repeated after 1 min. Potentiation of capsaicin responses occurred after PGE2 (median increase 2 coughs/min, range 0-7, P less than 0.01) and PGF2 alpha (median increase 8 coughs/min, range -3 to 27, P less than 0.01) compared with control. The effect of PGF2 alpha was greater (P less than 0.05) than that of PGE2. Potentiation of low chloride responses also occurred after PGF2 alpha (median increase 7 coughs/2 min, range -1 to 19, P less than 0.01), but effects of PGE2 were insignificant against this challenge (median change -1 coughs/2 min, range -4 to 13). These data suggest that PGE2 and PGF2 alpha have different effects on the sensitivity of the human cough reflex, which may be relevant during airway disease.     

Late-Phase Accumulation of Inositol Phosphates Stimulated by Prostaglandins D2 and F2α in Neuroblastoma × Glioma Hybrid NG108-15 Cells

The accumulation of inositol phosphates (IPs) in response to prostaglandins (PGs) was studied in NG108-15 cells preincubated with myo-[3H]inositol. As a positive control, bradykinin caused accumulation of IPs transiently at an early phase (within 1 min) and continuously during a late phase (15-60 min) of incubation in the cells. PGD2 and PGF2 alpha did not significantly cause the accumulation of IPs at an early phase but significantly stimulated inositol bisphosphate (IP2) and inositol monophosphate (IP) formation at late phase of incubation. The maximum stimulation was obtained at greater than 10(-7) M concentrations of these PGs, the levels being three-and twofold for IP2 and IP1, respectively. 9 alpha, 11 beta-PGF2 has a slight effect but PGE2 and the metabolites of PGD2 and PGF2 alpha have no effect up to 10(-6)M. The effects of PGD2 and PGF2 alpha were not additive, but the effect of each PG was additive to that of bradykinin at a late phase of incubation. Inositol 1-monophosphate was mainly identified in the stimulation by 10(-5) M PGD2 and 10(-5) M PGF2 alpha, whereas both inositol 1-monophosphate and inositol 4-monophosphate were produced in the stimulation by 10(5) M bradykinin. Depletion of extracellular Ca2+ diminished the stimulatory effect of PGD2 and PGF2 alpha and late-phase effect of bradykinin, but simple Ca2+ influx into the cells by high K+, ionomycin, or A23187 failed to cause such late-phase effects. These results suggest that PGD2 and PGF2 alpha specifically stimulate hydrolysis of inositol phospholipids.     

Evidence for separate PGD2 and PGF2 alpha receptors in the canine mesenteric vascular bed.

Potential interactions between PGD2 and PGF2 alpha in the mesenteric and renal vascular beds were investigated in the anesthetized dog. Regional blood flows were measured with electromagnetic flow probes. PGD2, PGF2 alpha and Norepinephrine (NE) were injected as a bolus directly into the appropriate artery, and responses to these agents were obtained before, during and after infusion of either PGD2 or PGF2 alpha into the left ventricle. In each case, the infused prostaglandin caused vascular effects of its own. Left ventricular infusion of PGD2 reduced responses to local injections of PGD2 in the intestine, and a similar effect was observed for PGF2 alpha, suggesting significant receptor or receptor-like interactions for each of the prostanoids. However, systemic infusion of prostaglandin F2 alpha (20--100 ng/kg/min) had no effect on renal or mesenteric vascular responses to local injection of prostaglandin D2. Similarly, PGD2 administration (100 ng/kg/min) did not affect responses to PGF2 alpha in the intestine. The present results therefore suggest that these prostaglandins, i.e., D2 and F2 alpha, act through separate receptors in the mesenteric and renal vascular beds. In addition, increased prostaglandin F2 alpha levels produced by infusion of F2 alpha reduced mesenteric but not renal blood flow, suggesting that redistribution of cardiac output might participate in side effects often observed with clinical use of this prostaglandin, such as nausea and abdominal pain.     

Isozyme specificity of rat liver glutathione S-transferases in the formation of PGF2 alpha and PGE2 from PGH2

When prostaglandin H2 (PGH2) was incubated with a mixture of glutathione S-transferases (GSTs) obtained from S-hexylglutathione affinity chromatography, as much as 40% of it was transformed into a prostanoid whose Rf value corresponded to that of the standard PGF2 alpha. The reaction product was identified as PGF2 alpha by cochromatography with a standard on TLC and HPLC. The stereochemistry of the hydroxyl groups on C-9 and C-11 of the cyclopentane ring was confirmed by mass-spectral analysis of the butylboronate derivative of the reaction product. Neither PGE2 nor PGD2 could substitute for PGH2 in the reaction mixture, indicating that the mechanism of formation of PGF2 alpha is a direct two-electron reduction of the endoperoxide moiety and not through a reduction of the keto group on PGE2 or PGD2. Individual GST isozymes exhibited distinct differences in their catalytic rates of formation of PGF2 alpha from PGH2. Among various GSTs, isozyme IV, a homodimer of Ya size subunit showed the highest activity with a Vmax value of approximately 6000 nmol.min-1.mg-1. In general, the isozymes containing Ya and Yc subunits exhibited relatively high activity toward PGH2, indicating that it is the non-selenium-dependent glutathione peroxidase activity associated with the GSTs that might be responsible for the reduction of PGH2 to PGF2 alpha. Interestingly, isozyme IV also exhibited the highest PGE2 forming activity with a Vmax value of approximately 3000 nmol.min-1.mg-1 followed by isozyme I, a homodimer of Yb subunit, which had a Vmax value of 420 nmol.min-1.mg-1. Based on these results, it appears that the GSTs play an important role in the biosynthesis of classical PGs. Therefore, it is conceivable that the tissue-specific formation of PGF2 alpha and PGE2 might, in part, be due to the relative distribution of these enzyme activities in a given tissue. Our results have not only confirmed the previously published reports (E. Christ-Hazelhof et al. (1976) Biochim. Biophys. Acta 450, 450-461), but also have characterized the specificity of GST isozymes in the formation of PGF2 alpha.     

Changes in endogenous prostaglandin levels during D-galactosamine-induced liver injury

The role of prostaglandins (PGs) in liver injury induced by D-galactosamine was investigated in the rat. The contents of PGD2 and PGF2 alpha in the liver were significantly increased from 3 h and 24 h after the D-galactosamine administration, respectively, but that of PGE2 was not significantly changed. Administration of 16,16-dimethyl PGE2, a long acting derivative of PGE2, or indomethacin, but not 16,16-dimethyl PGF2 alpha, a long acting derivative of PGF2 alpha, significantly depressed the increase in the serum transaminase activities induced by D-galactosamine. The protective effect of indomethacin was not disturbed by the 16, 16-dimethyl PGF2 alpha administration. These results indicate that PGE2 has a cytoprotective effect against the D-galactosamine induced liver injury and suggest that the protective effect of indomethacin is ascribable to its suppression of synthesis of PGs other than PGE2 or PGF2 alpha, e.g., PGD2.     

Central action of low-molecular weight polyphloretin phosphate fraction in rats

The central effects of a low-molecular weight fraction of polyphloretin phosphate (PPP) with molecular weight about 4600 were studied using several behavioural tests in animals (Lat's test, open-field test, hold-board test, irritability, spontaneous motor activity), chlorpromazine-induced catalepsy test, body temperature measurements, hexobarbital-induced sleep duration, reaction to thermal painful stimulus, measurements of arterial blood pressure, heart rate and respiratory rate. The activity of prostaglandin synthetase was determined also in the microsomes of bovine hypothalamic cells in vitro. Using some of the above tests the effect of PPP was studied on the central action of prostaglandins F2 alpha and E2 (PGF2 alpha and PGE2). PPP was administered intraventricularly (i.c.v.) in various doses (doses producing the lowest pharmacological effect in a given test) 10 minutes before i.c.v. administration of these prostaglandins in doses of 1 or 10 microgram. It was shown that PPP (low-molecular weight fraction) injected into the lateral cerebral ventricle of the rat exerted a biological effect on the central nervous system manifesting itself as behaviour changes in the tests used, and as changes of the arterial blood pressure. PPP i.c.v. antagonized certain central effects of PGF2 alpha and PGE2. The degree of inhibition of various prostaglandins differed in relation to the test used and was somewhat stronger in the case of PGF2 alpha.     

Prostaglandin moieties that determine receptor binding specificity in the bovine corpus luteum.

This study provided a pharmacological evaluation of prostaglandin binding to bovine luteal plasma membrane. It was found that [3H]PGF2 alpha' [3H]PGE2' [3H]PGE1 and [3H]PGD2 all bound with high affinity to luteal plasma membrane but had different specificities. Binding of [3H]PGF2 alpha and [3H]PGD2 was inhibited by non-radioactive PGF2 alpha (IC50 values of 21 and 9 nmol l-1, respectively), PGD2 (35 and 21 nmol l-1), and PGE2 (223 and 81 nmol l-1), but not by PGE1 (> 10,000 and 5616 nmol l-1). In contrast, [3H]PGE1 was inhibited by non-radioactive PGE1 (14 nmol l-1) and PGE2 (7 nmol l-1), but minimally by PGD2 (2316 nmol l-1) and PGF2 alpha (595 nmol l-1). Binding of [3H]PGE2 was inhibited by all four prostaglandins, but slopes of the dissociation curves indicated two binding sites. Binding of [3H]PGE1 was inhibited, resulting in low IC50 values, by pharmacological agonists that are specific for EP3 receptor and possibly EP2 receptor. High affinity binding of [3H]PGF2 alpha required a C15 hydroxyl group and a C1 carboxylic acid that are present on all physiological prostaglandins. Specificity of binding for the FP receptor depended on the C9 hydroxyl group and the C5/C6 double bond. Alteration of the C11 position had little effect on affinity for the FP receptor. In conclusion, there is a luteal EP receptor with high affinity for PGE1' PGE2' agonists of EP3 receptors, and some agonists of EP2 receptors. The luteal FP receptor binds PGF2 alpha' PGD2 (high affinity), and PGE2 (moderate affinity) but not PGE1 due to affinity determination by the C9 and C5/C6 moieties, but not the C11 moiety.     

Intraluteal infusions of prostaglandins of the E, D, I, and A series prevent PGF2 alpha-induced, but not spontaneous, luteal regression in rhesus monkeys

A luteotropic role for prostaglandins (PGs) during the luteal phase of the menstrual cycle of rhesus monkeys was suggested by the observation that intraluteal infusion of a PG synthesis inhibitor caused premature luteolysis. This study was designed to identify PGs that promote luteal function in primates. First, the effects of various PGs on progesterone (P) production by macaque luteal cells were examined in vitro. Collagenase-dispersed luteal cells from midluteal phase of the menstrual cycle (Day 6-7 after the estimated surge of LH, n = 3) were incubated with 0-5,000 ng/ml PGE2, PGD, 6 beta PGI1 (a stable analogue of PGI2), PGA2, or PGF2 alpha alone or with hCG (100 ng/ml). PGE2, PGD2, and 6 beta PGI1 alone stimulated (p less than 0.05) P production to a similar extent (2- to 3-fold over basal) as hCG alone, whereas PGA2 and PGF2 alpha alone had no effect on P production. Stimulation (p less than 0.05) of P synthesis by PGE2, PGD2, and 6 beta PGI1 in combination with hCG was similar to that of hCG alone. Whereas PGA2 inhibited gonadotropin-induced P production (p less than 0.05), that in the presence of PGF2 alpha plus hCG tended (p = 0.05) to remain elevated. Second, the effects of various PGs on P production during chronic infusion into the CL were studied in vivo. Saline with or without 0.1% BSA (n = 12), PGE2 (300 ng/h; n = 4), PGD2 (300 ng/h; n = 4), 6 beta PGI1 (500 ng/h; n = 3), PGA2 (300 ng/h; n = 4), or PGF2 alpha (10 ng/h; n = 8) was infused via osmotic minipump beginning at midluteal phase (Days 5-8 after the estimated LH surge) until menses. In addition, the same dose of PGE, PGD, PGI, or PGA was infused in combination with PGF2 alpha (n = 3-4/group) for 7 days. P levels over 5 days preceding treatment were not different among groups. In 5 of 8 monkeys receiving PGF2 alpha alone, P declined to less than 0.5 ng/ml within 72 h after initiation of infusion and was lower (p less than 0.05) than controls. The length of the luteal phase in PGF2 alpha-infused monkeys was shortened (12.3 +/- 0.9 days; mean +/- SEM, n = 8; p less than 0.05) compared to controls (15.8 +/- 0.5). Intraluteal infusion of PGE, PGD, PGI, or PGA alone did not affect patterns of circulating P or luteal phase length.(ABSTRACT TRUNCATED AT 400 WORDS)     

Liquid chromatographic-mass spectrometric determination of cyclooxygenase metabolites of arachidonic acid in cultured cells

A liquid chromatographic-electrospray ionization-mass spectrometric (LC-ESI-MS) technique was developed to simultaneously determine the cyclooxygenase metabolites of arachidonic acid (6-keto-PGF(1alpha), PGD(2), PGE(2), PGF(2alpha), and PGJ(2)) produced by cultured cells. Samples were separated on a C(18) column with water-acetonitrile mobile phase, ionized by electrospray, and detected in the positive mode. Selected ion monitoring (SIM) of m/z 353, 335, 335, 319, and 317 were used for quantifying 6-keto-PGF(1alpha), PGD(2), PGE(2), PGF(2alpha), and PGJ(2), respectively. Prostaglandins were detected at concentrations as low as 1 pg (S/N=3) on the column. The method was used to determine the production of PGs from bovine coronary artery endothelial cells (ECs) and human prostate cancer cells (PC-3) with different degree of invasiveness. Bradykinin (10(-6) M) stimulated a marked increase in the production of 6-keto-PGF(1alpha), PGE(2), and PGF(2alpha) and a small increase of PGD(2) by ECs. 6-Keto-PGF(1alpha) was the major metabolite in these cells. The production of PGE(2) was threefold higher and PGD(2) was twofold higher in PC-3-S (invasive) cells than in PC-3-U (non-invasive) cells.     

The combined use of isolated strips of guinea-pig lung parenchyma and ileum as a sensitive and selective bioassay for leukotriene B4

The biological effects of leukotriene (LT)B4 were compared, on a molar basis, with those of LTC4, LTD4, LTE4, 5-hydroxyeicosatetraenoic acid (5-HETE), PGD2, PGE1, PGE2, PGF2 alpha, PGI2, 6-oxo-PGF1 alpha, bradykinin (BK) and angiotensin II (Ang II) on isolated strips of guinea-pig lung parenchyma (GPP) and ileum smooth muscle (GPISM) superfused in series. LTB4 was similar to LTC4 and LTD4 on GPP, in relation to potency and contractions induced, but differed from LTE4 in being ten times more active and causing contractions of a much shorter duration of action on this tissue. However, unlike the other LTs, LTB4 produced contractions which were resistant to FPL 55712 (1.9 microM) and, when given repeatedly, caused tachyphylaxis in GPP. LTB4 was considerably more active on GPP than the other substances investigated. Further, PGD2, PGF2 alpha and PGI2 contracted GPP, the order of potency being PGD2 greater than PGF2 alpha approximately equal to PGI2, whereas PGE1 and PGE2 relaxed this tissue. In contrast to all other agonists tested which contracted GPISM, LTD4 displaying the highest activity, LTB4 was inactive on this tissue. 5-HETE and 6-oxo-PGF1 alpha were inactive on both GPP and GPISM. On the basis of differential effects of LTB4 on GPP and GPISM, this assay represents a simple and selective means to distinguish LTB4-like materials from other naturally-occurring substances likely to be generated in inflammatory fluids.     

Effects of prostaglandins on the bovine corpus luteum: granules, lipid inclusions and progesterone secretion

Corpora lutea collected at 15, 30 and 60 min after prostaglandin F2 alpha (PGF2 alpha) treatment were compared to control corpora lutea at 60 min after saline treatment. There were decreases (P less than 0.05) in the relative percentages of cytoplasm occupied by granules in large luteal cells (LLC) by 30 min and in small luteal cells (SLC) by 60 min. Differences were not observed among the groups for lipid inclusions. Luteal progesterone was decreased at all post-PGF2 alpha treatment times when compared to 60-min controls (P less than 0.05). PGF2 alpha was then compared with prostaglandin F1 alpha (PGF1 alpha), prostaglandin E1 (PGE1), and 17-phenyl-18,19,20-trinor-prostaglandin F2 alpha (17-phenyl-PGF2 alpha) in 60-min trials with plasma progesterone and luteinizing hormone (LH) determined every 5 min. LH was not affected by these treatments. Like PGF2 alpha, 17-phenyl-PGF2 alpha induced a greater loss of granules from LLC then SLC. 17-phenyl-PGF2 alpha also induced an increase in the lipid content of LLC. Treatments with PGF2 alpha and 17-phenyl-PGF2 alpha were associated with decreased concentrations of luteal progesterone but PGF1 alpha and PGE1 were without effect on this variable. In contrast to PGF1 alpha, PGE1 increased both luteal progesterone and the area occupied by cytoplasmic granules. The latter effect was greater in LLC than SLC.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacological activity of PGI2 and its metabolite 6-oxo-PGF1alpha on human uterus and fallopian tubes.

The actions of prostacyclin (PGI2) and its stable metabolite 6-OXO-PGF1alpha were investigated in strips of normal human uterus and in fallopian tubes. Both compounds were also compared with natural prostaglandins (PGE2, PGF2alpha and PGD2). PGI2 showed biphasic response both in uterus and fallopian tubes qualitatively and quantitatively similar to that induced by PGE2 and PGD2; prostacyclin was also able to inhibit the spasmus induced by PGF2alpha but not that induced by BaCl2 and vasopressin. 6-0XO-PGF1alpha on the other hand induced only small contractions on both tissues investigated. The authors discusse the possible implication of these findings in the physiology of the reproductive system.     

Prostaglandin F2 alpha as the luteolysin in swine: VI. Hormonal regulation of the movement of exogenous PGF2 alpha from the uterine lumen into the vasculature

To test the endocrine-exocrine theory of maternal recognition of pregnancy in the pig 16 gilts were assigned randomly to a 2 X 2 factorial involving pretreatment with sesame oil (SO) or estradiol valerate (5 mg; EV) injected on Days 11 through 14 of the estrous cycle and an intrauterine injection of saline (5 ml; SA) or prostaglandin F2 alpha (50 micrograms; PGF) on Day 14. Peripheral blood samples were collected for 120 min postinjection and analyzed for 15-keto-13,14-dihydro-PGF2 alpha (PGFM). PGFM concentrations were lower in EV than SO gilts (438 vs. 844 pg/ml; p less than 0.05). There was heterogeneity of regression between EV and SO gilts (p less than 0.01), with EV gilts having a slower release of PGF from the uterine lumen into the vasculature. Prostaglandin F2 alpha did not increase mean PGFM concentrations (p greater than 0.10), but resulted in an altered temporal pattern of PGFM (p less than 0.05) compared to SA gilts. There was an interaction between the two treatments over time, with EV-PGF gilts demonstrating a slower, more gradual release of PGFM than SO-PGF gilts. To test whether prostaglandins of the E series were involved in this mechanism, gilts were assigned to two 4 X 4 latin squares balanced for residual effects and treated with saline or flunixen meglumine (Banamine). Each gilt was treated with four PGE:PGF infusion sequences (SEQ) in each uterine horn: phosphate-buffered saline (PBS; PBS-SEQ), PGE1 (50 micrograms), PGE2 (50 micrograms), and PGE1 (25 micrograms) + PGE2 (25 micrograms) (PGE-SEQ), with each infusion followed 15 min later by PGF (25 micrograms).(ABSTRACT TRUNCATED AT 250 WORDS)