Molecular basis for prostaglandin potency. III. Tests of the significance of the “hairpin conformation” in biorecognition phenomena

Prostaglandin analogs of the PGF_2α, 15-epi-PGF_2α, and PGE₂ type bearing the following methyl substitution patterns — 15-Me, 16, 16-(Me)₂, 17, 17-(Me)₂, and 18, 18, 20-(Me)₃ — and analogs constrained to “hairpin” alignment [via 1, (ω-1)-olide formation] and to “non-hairpin” arrangements [via 1,9- and 1,15-olide formation] are compared in the following biological assays: contraction of uterine and gastro-intestinal smooth muscle strips, luteolytic antifertility potency in the hamster, binding affinity to two different PGF₂α-receptor preparations from bovine corpora lutea, binding to the PGE-specific receptors from rat kidney and liver, inhibition of ADP-induced aggregation of human platelet-rich-plasma, and the effect on rat blood blood pressure. The methylated prostaglandins were also converted to the corresponding prostacyclins and examined as to action on the platelet and on rat blood pressure. All evidence points to topographically distinct receptors for F₂α-, E- and I₂-type prostaglandins. Cross-reactivity is reduced in most of the analogs examined. Independent of the target organ or tissue, the receptors show common features based on the functional class of PG recognized. “Hairpin” alignment improves binding (and potency) only for the PGF₂α specific assays. PGE-specific binding and potency is disrupted to an increasing extent as the chain branching point is moved $\text{further}$ from the 15-hydroxyl center. In contrast 16, 16-dimethylation is particularly disruptive for the PGI₂/E₁platelet receptor interaction.     

Fluorometric documentation of increased cutaneous blood flow after topical application of a PGE2 analog in man

The present study employed fiberoptic fluorometry, a noninvasive means of documenting delivery and removal of fluorescein dye, to evaluate the local circulatory changes elicited by topical application of DHV-PGE₂ ME, an investigational PGE₂ analog. On Day 1, inactive vehicle was applied to a 5 × 4 cm study site on each thigh of healthy volunteer subjects (n=12). Symmetrical perfusion was confirmed by similar determinations of dye delivery and removal at each site. On Day 2, DHV-PGE₂ ME, 30 or 120 micrograms, was applied to one site while inactive vehicle again was applied to the other. After administration of 120 micrograms in a petrolatum vehicle, fluorometry detected a pronounced increase in nutritive perfusion. There was significant acceleration of dye delivery and removal (p < 0.05 by ANOVA). Less pronounced changes were noted after the lower dose of DHV-PGE₂ ME and when the drug was applied in a triethyl citrate vehicle. The local circulatory changes were not accompanied by systemic effects; there were no changes in vital signs or in fluorometric indices at remote sites.     

Omega chain methylated analogs of PGF2α and PGE2

Our previously published prostaglandin (PG) synthesis route, in which the ω-chain is added in the penultimate step, provides facile access to a wide variety of ω-chain variant PG analogs. Each series requires only the synthesis of the appropriate methylated acylphosphonate for the Emmons' condensation. The syntheses of analogs bearing the following methylation pattern are detailed: 15-Me; 17, 17-(Me)₂; 17, 17, 20-(Me)₃; 18, 18, 20-(Me)₃; 15, 18, 18, 20-(Me)₄; and 15-Ome-18, 18, 20-(Me)₃. The well-known 16, 16-dimethyl prostaglandins have also been prepared by this sequence. The synthesis of 16, 16-tetramethylene-PG analogs is also described.     

Differences in types of prostaglandins produced by two MDCK canine kidney cell sublines

The pattern of prostaglandins produced from arachidonic acid by two sublines of MDCK canine kidney epithelia cells was different. In one subline designated MDCK₁, the most prevalent prostaglandin product was PGE₂, whereas the most prevalent product in the subline designated MDCK₂ was PGF_2α. This difference was observed when cells previously labeled with [1^?14C]arachidonic acid were stimulated with either bradykinin or the calcium ionophore A23187, or when prostaglandins were produced from labeled arachidonic acid added directly to the assay medium. In the latter case, the difference was maintained over a 38-fold range of extracellular arachidoante concentrations. These findings indicate the there is a persistent difference in the distribution of prostaglandins produced by the two commonly used sublines of MDCK cells.     

Effect of intravenous eicosapentaenoic acid on cerebral blood flow, edema and brain prostaglandins in ischemic gerbils

Eicosapentaenoic acid is converted by cyclo-oxygenase to the prostacyclin, PGI₃. Consequently eicosapentaenoic acid might protect the brain from the impairment in cerebral blood flow that follows temporary cerebral artirial occlusion. We studied the effect of 90% pure eicosapentaenoic acid, given intravenously, on cerebral blood flow, brain water and prostaglandins after ischemia in gerbils. Ischemia was produced by bilateral carotid occlusion for 15 min followed by reperfusion for 2 h. In experimental gerbils, 0.833 mg or 0.167 mg of eicosapentaenoic acid (Na salt) was given intravenously followed by a continuous infusion of 1 mg h⁻¹. Control gerbils were given 0.167 mg of linoleic acid (Na salt) intravenously followed by a continuous infusion of 1 mg h⁻¹ or a saline infusion. Regional cerebral blood flow was measured by the hydrogen clearance method and brain water by the specific gravity technique. Brain diene prostaglandins were measured by radioimmunoassay. In control gerbils cerebral blood flow decreased significantly during reperfusion and remained depressed after 2 h of reperfusion. In eicosapentaenoic acid treated gerbils blood flow decreased initially but after 2 h of reperfusion blood flow was significantly higher than in control gerbils. Brain edema and brain diene prostaglandins were not significantly different between control and experimental groups.Our study indicates that eicosapentaenoic acid, given intravenously, improves cerebral blood flow after ischemia and reperfusion. We speculate that this effect may be due to the formation of the prostacyclin, PGI₃.     

Prostaglandin release from the human umbilical artery in vitro

Release of prostaglandins from human umbilical artery preparations into the surrounding bathing fluid was studied by radioimmunoassay using PGF_2α antibodies. A significant release of prostaglandins was found under conditions where a spontaneous tone of the artery could be maintained. Indometacin reduced the prostaglandin release and the spontaneous tone of the artery. Intramural synthesis of prostaglandins in the human umbilical arteries is postulated.     

Prostacyclin and prostagladin synthesis in isolated brain capillaries

The synthesis of prostacyclin and prostaglandins was examined in isolated blood-free brain capillaries of guinea-pigs and rats using 1-¹⁴C-arachidonic acid as a precursor. The main prostaglandins synthesized by guinea-pig microvessels were prostaglandin D₂ and prostaglandin E₂. Substantially less prostaglandin F_2α or the prostacyclin stable metabolite, 6-oxo-prostaglandin F_1α was synthesized. Rat capillary prostaglandin distribution differed substantially from that of the guinea-pigs although the principle prostaglandin was also PGD₂. Total prostaglandin conversion was greater in guinea-pig capillaries than in the rat.Norepinephrine stimulated the prostaglandin forming capacity of blood free cerebral microvasculature of guinea-pigs. Prostacyclin and prostaglandins could be involved in the activity dependent regulation of regional cerebral blood flow and permeability.     

Prostaglandin D2, another renal prostaglandin?

Prostaglandin (PG) D₂ was biosynthesized by rabbit renal papillae incubates in vitro. Quantification of the renal prostaglandins by gas chromatography-mass spectroscopy demonstrated that the concentration of PGD₂ generated by renal papillae was to the amount of PGE₂ or about 1 μg/g tissue/30 min. Infusion of the sodium salt of PGD₂ into the renal artery of the dog produced a dose related increase in renal blood flow and urine flow, free water clearance, sodium excretion and potassium excretion without changes in systemic hemodynamics. At low doses PGD₂ increased renal blood flow to all cortical zones. Higher concentrations of PGD₂ produced a shift in the intrarenal distribution of blood flow toward the juxtamedullary nephrons.     

Prostaglandin synthesis in isolated glomeruli

Prostaglandins are thought to play an important role in the local regulation of glomerular blood flow and in the release of renin from the juxtaglomerular apparatus. We therefore examined prostaglandin synthesis by isolated rat glomeruli. Isolated glomeruli were either prelabeled with [14_C] arachidonic acid or were incubated with [14_C] arachidonic acid for the entire experimental incubation in Krebs buffer. Prostaglandin synthesis was determined by thin layer radiochromatography of acid extracts of the supernatant solutions. Indomethacin inhibitable synthesis of small amounts of 6-keto-PGF_1α, the metabolite of prostacyclin(PGI₂,) and larger amounts of PGF_2α, and PGE₂, and possibly thromboxane B₂ (TXB₂) by isolated glomeruli could be demonstrated with either prelabeling or direct incubation. These findings support the hypothesis that prostaglandins are produced within the glomerulus where they may affect local glomerular blood flow and function.     

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.     

Metabolism of prostaglandins A1 and A2 by human whole blood

The effect of human blood on prostaglandin metabolism in vitro was studied at 37°C and 4°C. Labeled prostaglandins were incubated for up to one hour in whole blood or plasma. After extraction, the prostaglandins were purified by LH-20 Sephadex chromatography. Appropriate ¹⁴C labeled compounds, when available, were used to correct for losses. Metabolism was determined by comparison of incubated samples with zero time controls. There was no reduction in isotopic recovery of prostaglandins B₁, B₂ and E₁ after incubation with whole blood for up to one hour. In contrast, human whole blood, but not plasma, rapidly metabolized prostaglandins A₁ and A₂ at 37°C. The rate of metabolism was temperature dependent, but still continued at 4°C. The products of these reactions were not identified, but they appeared to remain in the aqueous solution after extraction with the neutral organic solvent.     

Stimulation of microsomal prostaglandin synthesis by a vasoactive material isolated from blood plasma

Stimulation of prostaglandin synthesis by a material with coronary vasoconstrictor activity extracted from blood plasma was examined. The vasoactive material decreased the Km for arachidonate in the overall synthesis of prostaglandins by rabbit renal microsomal preparations but did not change Vmax. Increases in prostaglandin synthesis caused by the vasoactive material and L-tryptophan or L-epinephrine were additive or synergistic, whereas increases produced by the vasoactive material and hemin or hemoglobin were not. However, hemin and hemoglobin stimulated synthesis of all prostaglandins equally whereas the active material increased the synthesis of prostaglandin F_2α at the expense of other prostaglandins, both in the presence and absence of heme compounds. The increase in prostaglandin F_2α with respect to the other prostaglandins occurred in the presence of reduced glutathione. The vasoactive material attenuated inhibition of prostaglandin synthesis induced by indomethacin or aspirin but not that produced by 5,8,11,14-eicosatetraynoic acid. The interaction of the vasoactive material and indomethacin was competitive whereas hemin attenuated the effects of only low concentrations of indomethacin. Epinephrine enhanced indomethacin inhibition. These data indicate that mode of action of the vasoactive material in prostaglandin synthesis is unlike that of glutathione, aromatic amines, or heme containing compounds.     

Noninvasive estimation of human tissue respiration with wavelet-analysis of oxygen saturation and blood flow oscillations in skin microvessels

Laser Doppler flowmetry, laser spectrophotometry of oxygen saturation, and the fluorescence determination of the NADH/FAD ratio were carried out in 30 subjects in the upper limb skin zones with and without arteriolovenular anastomoses (AVAs). It was demonstrated that the wavelet-analysis of oxygen saturation and blood flow oscillations in microvessels was an efficient approach to noninvasive estimation of the skin oxygen extraction (OE) and oxygen consumption (OC) rates. OE = (SaO₂ ? SvO₂)/SaO₂, where SaO₂ (%) and SvO₂ (%) are the oxygen saturations of arterial and venular blood, respectively. If the cardiac (A_c, perfusion units, p.u.) to respiratory rhythm amplitude (A_r, p.u.) ratio A_c/A_r ?? 1, SvO₂ = SO₂. If A_c/A_r > 1, SvO₂ = SO₂/(A_c/A_r). OC = M _nutr (SaO₂ ?? SvO₂) in p.u. · %O₂, where M _nutr is the nutritive blood flow value in p.u. M _nutr = M/SI, where SI is the shunting index of blood flow in microvessels. The perfusion, OE, and OC values were higher in the skin with AVAs than in the skin without AVAs. The perfusion and oxygen saturation values were more variable in the skin with AVAs. The oxygen diffusing from the tiniest arterioles and capillaries is the most important for tissue metabolism. The contribution of the total perfusion and the oxygen diffusion from arterioles to tissue metabolism increased under the tissue ischemia conditions.     

In Vivo Availability of Pro-Resolving Lipid Mediators in Oxazolone Induced Dermal Inflammation in the Mouse

The activation and infiltration of polymorphonuclear neutrophils (PMN) are critical key steps in inflammation. PMN-mediated inflammation is limited by anti-inflammatory and pro-resolving mechanisms, including specialized pro-resolving lipid mediators (SPM). We examined the effects of 15-epi-LXA₄ on inflammation and the biosynthesis of pro-inflammatory mediators, such as prostaglandins, leukotriene B₄ and various hydroxyeicosatetraenoic acids and SPM, in an oxazolone (OXA)-induced hypersensitivity model for dermal inflammation. 15-epi-LXA₄ (100 μM, 5 μL subcutaneously injected) significantly (P < 0.05) reduced inflammation in skin, 24 hours after the OXA challenge, as compared to skin treated with vehicle. No significant influence on the biosynthesis of prostaglandins or leukotriene B₄ was observed, whereas the level of 15S-hydroxy-eicosatetraenoic acid was significantly (P < 0.05) lower in the skin areas treated with 15-epi-LXA₄. In spite of the use of a fully validated analytical procedure, no SPM were detected in the biological samples. To investigate the reason for the lack of analytical signal, we tried to mimic the production of SPM (lipoxins, resolvins, maresin and protectin) by injecting them subcutaneously into the skin of mice and studying the in vivo availability and distribution of the compounds. All analytes showed very little lateral distribution in skin tissue and their levels were markedly decreased (> 95%) 2 hours after injection. However, docosahexaenoic acid derivatives were biologically more stable than SPM derived from arachidonic acid or eicosapentaenoic acid.     

The effect of prostaglandins A2,E1,E2,15 methyl E2, 16, 16 dimethyl E2 and F2α on erythropoiesis

Prostaglandins A₂, E₁, E₂, methylated E₂s and F₂α affected erythropoiesis and/or erythropoietin (Ep) production. This action is indicated in the exhypoxic, polycythemic mouse where radioiron incorporations into RBC increased after administration of these compounds. The kidney and liver have been indicated through previous studies, to actively participate in Ep production. By the removal of one of these active sites in a murine system treated with prostaglandins it is shown that a response is reflected in Ep levels. Interference of the action of prostaglandins (PG) is altered by the removal of one of these target sites of Ep production. The erythropoietic responses elicited by PGA₂, E₁, and perhaps the methylated PGE₂s act through the liver whereas PGE₂ may operate through a renal pathway for its response. PGF_2α reveals no effect on erythropoietic activity and is no different than that observed for vehicle-treated controls. The prostaglandins tested appear to act primarily through the kidney or liver but the possibility exists that some yet undetermined organ site may also be involved.     

Effect of prostaglandins F2α and E2 on milk ejection, blood pressure and blood flow through the mammary artery in the cow

The influence of prostaglandins (PG) F₂α and E₂ on milk ejection, mammary artery blood flow and arterial blood pressure was studied in lactating cows. Injections of both PG in the jugular vein or the carotid artery induced milk ejection after a relatively long latency period. The minimal effective dose amounted to 1 to 5 μg and to 100 to 300 μg for PGF₂α and PGE₂ respectively. In several cases with PGF₂α and once with PGE₂ milk ejection was accompanied with a simultaneous increase in blood flow through the mammary artery whereas arterial blood pressure remained unchanged. Both routes of administration showed the same response. It was suggested that the effect of the PG on the bovine myoepithelium is indirect, possibly secondary to a release of oxytocin from the neurohypophysis.     

Effect of prostaglandins E2 and F2α on umbilical blood flow and fetal hemodynamics

The hemodynamic effects of PGF_2α, PGE₂, and norepinephrine injected into the umbilical arterial circulation were compared in nine fetal lambs in utero. Umbilical blood flow was measured with radioactive microspheres and an electromagnetic flow transducer implanted on the distal aorta of the fetus after ligation of external iliac arteries and other accessible distal aortic branches.PGF_2α and norepinephrine increased fetal arterial pressure and umbilical blood flow while umbilical vascular resistance increased slightly (PGF_2α) or not at all (norepinephrine). PGE₂ increased fetal arterial pressure, decreased umbilical blood flow, and exerted a profound active vasoconstrictor effect on the fetal placental bed. Our data taken together with the observations of others suggest that prostaglandins may play a role in the circulatory adaptations of the fetus at birth and that PGE₂ in high concentrations is likely to have deleterious hemodynamic consequences in the fetus in utero.     

Myocardial actions of prostaglandins in isolated cat cardiac tissue.

The inotropic responses to prostaglandins (PG) A₁, E₁, E₂ and F_2α were studied in isolated cat myocardial tissue. PGA₁ and F_2α exhibited no significant inotropic effects, whereas, PGE₂ and PGE₁ produced negative inotropic effects at concentrations of 2.8 × 10⁻⁷ and 2.8 × 10⁻⁶ M in isolated cat papillary muscles.In isolated perfused cat hearts, PGE₁ (2.8 × 10⁻⁶M) produced a negative inotropic effect along with a significant increase in coronary flow. As flow declined, the negative inotropic effect became more severe. PGE₁ at 2.8 × 10⁻⁹ M produced a sustained increase in coronary flow and oxygen consumption with no inotropic effect. PGE₂ and F_2α did not exert significant changes in coronary flow or contractile force.Thus prostaglandins do not appear to exert significant positive inotropic effects at physiologic or at generally accepted pharmacologic concentrations in isolated cat heart preparations. At extremely high concentrations, prostaglandins E₁ and E₂ exert a negative inotropic effect; however, this would not explain the protective effect of these prostaglandins in circulatory shock.     

Measurement of blood flow in the skin and oral mucosa of the rhesus monkey (Macaca mulatta) using laser doppler flowmetry

• 1.1. It is generally assumed that oral blood flow is higher than that of skin, and invasive methods to measure blood flow support this view.
• 2.2. However, it was not known whether this finding would be confirmed by laser Doppler flowmetry, which is a noninvasive method to measure blood flow.
• 3.3. The purpose of this study was to compare blood flow in oral and skin regions of the rhesus monkey using laser Doppler flowmetry.
• 4.4. The results demonstrated that blood flow was significantly higher in oral regions as compared to facial skin (P < 0.05).
• 5.5. This finding is most likely related to the more abundant capillary supply in oral mucosa as compared to skin.

     

Somatostatin,prostaglandin E2 and atropine inhibition of the gastric actions of bombesin in the dog

Bombesin, acetylcholine, prostaglandins and somatostatin are all thought to be involved in the regulation of gastrin release and gastric secretion. We have studied the effects of low doses of atropine, 16-16(Me)₂-prostaglandin E₂ (PGE₂) and somatostatin-14 on bombesin-stimulated gastrin release and gastric acid and pepsin secretion in conscious fistula dogs. For reference, synthetic gastrin G-17 was studied with and without somatostatin. Bombesin, in a dose-related manner, increased serum gastrin, which in turn stimulated gastric acid and pepsin secretion in a serum gastrin, concentration-dependent manner. Somatostatin inhibited gastrin release by bombesin as well as the secretory stimulation by G-17; the combination of sequential effects resulted in a marked inhibition of bombesin-stimulated gastric acid and pepsin secretion. PGE₂ also strongly inhibited gastrin release and acid and pepsin secretion. Atropine had no significant effect on gastrin release, but greatly inhibited gastric secretion. Thus somatostatin and PGE₂ inhibited at two sites, gastrin release and gastrin effects, while atropine affected only the latter.