125I derivatives of prostaglandins. A novel approach in prostaglandin analysis by radioimmunoassay.

We report the production of radioactive iodinated (125 I) derivatives of prostaglandins E1, E2, F2alpha and their use in radioimmunological assays. Histamine or tyramine was coupled to the prostaglandins carboxyl group and the iodination was accomplished using the chloramine T method. The high specific radioactivity of these tracers and the resolution of the purification procedure allowed the detection of 0.5 pg of prostaglandins. A comparison with tritiated prostaglandin was made and showed a 10-fold gain in sensitivity. Furthermore in the case of the prostaglandin E1 system using 125I-labelled histamine or tyramine as tracer the cross reaction curves obtained were different from those obtained with [3H]prostaglandin E1; we suggest that the blocking of the carboxyl group alters the prostaglandin E1 structure, modifying its immunoreactivity.     

Synthesis and release of prostaglandins by rat brain synaptosomal fractions.

Abstract— Particulate fractions from rat brain homogenate containing the synaptosomes synthesize and release prostaglandins F and E on aerobic incubation. The prostaglandin of the F-typc released could be further identified as proslaglandin F_2α using specific radioimmunoassays for prostaglandins F_1α, and F_2α-. The metabolite 13,14-dihydro-15-keto-prostaglandin F_2α could not be detected. The amount of prostaglandins released is dependent on incubation time and temperature as well as pH and osmolarity of the incubation medium. Total brain homogenate released more prostaglandins than purified synaptosomes per mg protein, indicating that synaptosomes are probably not a main source of prostaglandins when compared with other subcellular brain fractions. While prostaglandin synthesis was only moderately increased by the addition of the precursor fatty acid arachidonic acid, anti-inflammatory drugs like indomethacin, high concentrations of some local anaesthetics and Δ¹-tetrahydrocannabinol inhibited prostaglandin release. The neurotransmitters noradrenaline, dopamine and 5-hydroxytryptamine did not influence prostaglandin release from the synaptosomal rat brain fractions.     

Biosynthesis and metabolism of prostaglandins in chick epiphyseal cartilage

Microsomal fractions of cells isolated from chick epiphyseal cartilage catalyzed the synthesis of prostaglandins from radiolabeled Δ^8,11,14-eicosatrienoic and from archidonic acids. In addition, the microsomal supernatants contained both 15-hydroxyprostaglandin dehydrogenase and prostaglandin 15-keto Δ^13,14-reductase activities. Two major classes of prostaglandins (E and F) were synthesized; however, a major product which chromatographically behaves as PGA was also isolated. Synthetase activities were analyzed for pH optima and response to known stimulators and inhibitors of prostaglandin synthesis. The different activators had varying stimulatory effects on prostaglandin synthesis; the anti-inflammatory drugs were all strongl inhibitory. Synthetase activity in the growth plate was highest in the zone of hypertrophy, declining substantially in the more heavily calcified regions. Degradative enzyme activities were highest in the zone of maturation and significantly lower in the adjacent hypertrophic zone. The net effect of these opposing activities would be to elevate prostaglandin levels at the zone of hypertrophy, a finding which suggests that prostaglandins may play a role in the modulation of epiphyseal cartillage metabolism.     

Improved sensitivity of iodinated histamine-prostaglandin radioimmunoassay by prostaglandin methyl esters

Use of (¹²⁵I)-labeled histamine-prostaglandin tracer increases the sensitivity of the radioimmunoassays of prostaglandin derivatives. Six different antisera were produced for prostaglandins and their derivatives (prostaglandins E₁, E₂, F_1α, F_2α, 13,14-dihydro-15-ketoprostaglandin E₂, and 13,14-dihydro-15-ketoprostaglandin F_2α) and were investigated with the corresponding tritiated and lodinated tracers. Displacement of iodinated tracers by the methyl esters of the prostaglandin compounds resulted, in most cases, in a three- to fivefold increase in sensitivity compared to unesterified inhibitors. Esterification also caused some alteration in the specificities observed. Our results suggest that conformational changes in the esterified prostaglandins (tracer and inhibitor) could explain these charges.     

Development of a radioimmunoassay for prostaglandin D2 using an antiserum against 11-methoxime prostaglandin D2

A sensitive and specific radioimmunoassay for prostaglandin D₂ has been developed using its stabilized 11-methoxime derivative, which was obtained after treatment of prostaglandin D₂ with methoxamine-HCl. The antiserum was obtained after injection of prostaglandin D₂-methoxamine coupled to bovine serum albumin. A (¹²⁵I)-Histamide prostaglandin D₂-methoxamine tracer was prepared by iodination of the corresponding histamide, followed by thin layer chromatography purification. The sensitivity of the assay was 280 femtomoles per ml at 50% displacement. The cross reactivities were 15% with prostaglandin D₁-methoxamine and less than 0.20% with other prostaglandins. Determination of the half-life of prostaglandin D₂ in a solution containing albumin was also carried out, since it has been shown to catalyze prostaglandin D₂ destruction. The unstability of this prostaglandin is due to the presence of a β-hydroxy ketone group, and all prostaglandins possessing this labile moiety could be stabilized by such a derivatization before developing a radioimmunoassay.     

Evidence for enhanced venous smooth muscle turnover of prostaglandin-like substance in portal veins from spontaneously hypertensive rats

The sensitivity of portal veins from 14 to 18 week-old Okamoto-Aoki spontaneously hypertensive rats to prostaglandins A₂, B₂, D₂ and F_2α were enhanced whereas the sensitivity to prostaglandin E₂ was diminished when compared with responses of veins from normotensive Wistar-Kyoto rats. Inhibition of prostaglandin synthesis with both eicosotetraynoic acid (ETYA) and indomethacin (INDO) abolished the observed differences in sensitivity to prostaglandins. Synthesis of prostaglandin-like substance (with arachidonic acid as precursor) was significantly enhanced in portal veins from spontaneously hypertensive rats. Metabolism of prostaglandins E₂ and F_2α, employing the oil-immersion technique of Kalsner and Nickerson, appeared to be similar in veins from normotensive and hypertensive rats. These findings suggest that prostaglandin synthesis is enhanced in venous smooth muscle from hypertensive rats. The increased concentration of endogenous prostaglandin at the venous smooth muscle cell may modify the responses to exogenously administered prostaglandins thus accounting, in part, for the altered sensitivity to these fatty acids.     

Specific prostaglandine E1 and A1 binding sites in rat a dipocyte plasma membranes

Rat adipocyte plasma membranes sacs have been shown to be a sensitive and specific system for studying prostaglandin binding. The binding of prostaglandin E₁ and prostaglandin A₁ increases linearly with increasing protein concentration, and is a temperature-sensitive process. Prostaglandin E₁ binding is not ion dependent, but is enhanced by GTP. Prostaglandin A₁ binding is stimulated by ions, but is not affected by GTP.Discrete binding sites for prostaglandin E₁ and A₁ were found. Scatchard plot analysis showed that the binding of both prostaglandins was biphasic, indicating two types of binding sites. Prostaglandin E₁ had association constants of 4.9 · 10⁹ 1/mole and 4 · 10⁸ 1/mole, while the prostaglandin A₁ association constants and binding capacities varied according to the ionic composition of the buffer. In Tris-HCl buffer, the prostaglandin A₁ association constants were 8.3 · 10⁸ 1/mole and 5.7 · 10⁷ 1/mole, while in the Krebs—Ringer Tris buffer, the results were 1.2 · 10⁹ 1/mole and 8.6 · 10⁶ 1/mole.Some cross-reactivity between prostaglandin E₁ and A₁ was found for their respective binding sites. Using Scatchard plot analysis, it was found that a 10-fold excess of prostaglandin E₁ inhibited prostaglandin A₁ binding by 1–20% depending upon the concentration of prostaglandin A₁ used. Prostaglandin E₁ competes primarily for the A prostaglandin high-affinity binding site. Similar Scatchard analysis using a 20-fold excess of prostaglandin A₁ inhibited prostaglandin E₁ binding by 10–40%. Prostaglandin A₁ was found to compete primarily for the E prostaglandin low-affinity receptor.All of the bound [³H]prostaglandin E₁, but only 64% of the bound [³H]-prostaglandin A₁ can be recovered unmetabolized from the fat cell membrane. There is no non-specific binding of prostaglandin E₁, but 10–15% of prostaglandin A₁ binding to adipocyte membranes is non-specific. Using a parallel line assay to measure relative affinities for the E binding site, prostaglandin E₁ > prostaglandin A₂ > prostaglandin F_2α. Prostaglandin E₂ and 16,16-dimethyl prostaglandin E₂ were equipotent with prostaglandin E₁, while other prostaglandins had lower relative affinities. 7-Oxa-13-prostynoic acid does not appear to antagonize prostaglandin activity in adipocytes at the level of the receptor.     

Quantitative determination of prostaglandins A,B and E in the sub-nanogram range

Conversion of prostaglandin E(PGE) into the methyl ester, 15-trimethylsilyl ether of either PGA or PGB, makes possible the estimation of PGE in the sub-nanogram range, using vapor-phase analysis. PGE methyl ester can be efficiently converted at sub-nanogram levels to the TMS derivative of PGA by treatment with N,O,-$\text{bis}$-trimethylsilylacetamide in pyridine. The well-known, base-catalysed dehydration and rearrangement of PGE to PGB can similarly be achieved using sub-nanogram levels of prostaglandin. The methyl ester, trimethylsilyl ethers of PGA or PGB are shown to possess excellent properties for vapor-phase analysis, presenting minimal difficulties due to adsorption or thermal degradation, and have mass spectra characterized by only one or two predominant ions, facilitating their quantification into the sub-nanogram range, using mass spectrometry. Quantitative determination, with improved sensitivity into the sub-nanogram range of the derivative of PGB, has also been achieved using the electron capture detector. The same system can be applied to the estimation of PGA in the low nanogram range. These derivatives and analytical methods have the potential to provide quantitative estimation, with excellent sensitivity and specificity, of 9-keto-prostaglandins at low levels in biological samples.     

The effect of prostaglandins E1, E2 and F2 alpha and indomethacin on the sensitivity of glycolysis and glycogen synthesis to insulin in stripped soleus muscles of the rat.

Prostaglandins E1 and E2 increased the sensitivity of glycolysis to insulin in the isolated stripped soleus muscle of the rat, but prostaglandin F2 alpha had no effect. Indomethacin, which inhibits prostaglandin formation, markedly decreased the sensitivity of glycolysis to insulin. These findings suggest that prostaglandins of the E series increase the sensitivity of muscle glycolysis to insulin in vivo.     

LC-MS/MS-analysis of prostaglandin E2 and D2 in microdialysis samples of rats

For the determination of prostaglandins in microdialysis samples, usually immunoassays are used. However, these assays may show cross-reactivity among various prostaglandins. To overcome this problem a specific method for the determination of prostaglandin E2 and D2 in rat microdialysis samples by using liquid chromatography-electrospay ionization-tandem mass spectrometry (LC-ESI-MS/MS) is described. Prostaglandin E2 and D2 were extracted from microdialysis samples with liquid-liquid extraction using deuterated prostaglandin D2, [2H4]-PGD2, as internal standard. Subsequently, prostaglandins were separated with a phenomenex Synergi Hydro-RP column and determined with a PE Sciex API 3000 mass spectrometer equipped with a turbo ion spray interface operating in negative ionization mode. The method showed a LLOQ of 25 pg/ml for prostaglandin E2 and 50 pg/ml for prostaglandin D2. The applicability of the method is shown in rat spinal cord microdialysis samples following peripheral nociceptive stimulation.     

Regulation of prostaglandin synthesis during differentiation of cultured mouse myeloid leukemia cells

Mouse myeloid leukemia cells (Ml) were induced to differentiate into mature macrophages and granulocytes by various inducers. The differentiated Ml cells synthesized and released prostaglandins, whereas untreated Ml cells did not. When the cells were prelabelled with [¹⁴C]arachidonate, the major prostaglandins released into the culture media were found to be prostaglandin E₂, D₂, and F_2α in an early stage of differentiation, but the mature cells produced predominantly prostaglandin E₂. The synthesis and release of prostaglandins were completely inhibited by indomethacin. Dexamethasone, a potent inducer of differentiation of Ml cells, did not induce production of prostaglandins in resistant Ml cells that could not differentiate even with a high concentration of dexamethasone. These results suggest that production of prostaglandins in Ml cells is closely associated with differentiation of the cells. Homogenates of dexamethasone-treated Ml cells converted arachidonate to prostaglandins, but this conversion was scarcely observed with homogenates of untreated Ml cells. Dexamethasone and the other inducers stimulated the release of arachidonate from phospholipids. Therefore, induction of prostaglandin synthesis during differentiation of Ml cells may result from induction of prostaglandin synthesis activity and stimulation of the release of arachidonate from cellular lipids. Lysozyme activity, which is a typical biochemical marker of macrophages, was induced in Ml cells by prostaglandin E₂ or D₂ alone, as well as by inducers of differentiation of the cells, but it was not induced by arachidonate or prostaglandin F_2α. These results suggest that prostaglandin synthesis is important in differentiation of myeloid leukemia cells.     

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.     

Interleukin-1β-stimulated PGE2 production from early first trimester human decidual cells is inhibited by dexamethasone and progesterone

Cytokines are known to increase the production of prostaglandins by human decidual cells, but negative regulators have not been identified. We have examined the effects of dexamethasone and progesterone on prostaglandin (PG) E2 synthesis by cultured human first trimester decidual cells. The numbers of cyclooxygenase (COX) enzyme positive cells were visualised by immunocytochemistry, using antibodies specific for COX-1 and COX-2. Interleukin-1β stimulated the production of prostaglandins E2 and F2α dose-dependently, and this was associated with increased numbers of COX-2 positive cells. Progesterone (10⁻⁷−10⁻⁶ M) and dexamethasone (10⁻⁷−10⁻⁶ M) inhibited basal and interleukin-1β-stimulated prostaglandin production, and decreased the numbers of COX-2 positive cells. Neither interleukin-1β nor the steroids affected numbers of COX-1 positive cells. COX-2 seems to be the main enzyme controlling the synthesis of PGE2 by human decidual cells, and may be negatively regulated by progesterone.     

Regulation of the in vitro anamnestic antibody response by cyclic AMP. IV. Evidence for participation of prostaglandins of the E series in the early events.

The addition of KLH to KLH-primed rabbit lymph node cell cultures induced an anamnestic antibody response. The further addition of prostaglandins of the E series, but not PGF1^α, enhanced this antibody response manifold. The addition to these cultures of prostaglandin synthetase inhibitors together with KLH inhibited antibody production. At the concentration (10^?4) required to inhibit antibody synthesis, by a variety of criteria one of these inhibitors, indomethacin, was shown not to exert its effects through cytotoxicity. By contrast, two other inhibitors of prostaglandin synthesis, Ro-20-5720 and Ro-3-1314, inhibited antibody synthesis because of their cytotoxicity. The inhibition of the antibody response by indomethacin did not occur when PGE1 or PGE2 was added concurrently to these cultures, clearly showing that inhibition was due to a deficiency of prostaglandins. These findings strongly suggest that induction and/or regulation of the in vitro anamnestic antibody response of KLH-primed lymph node cells to 1 and 100 μg KLH requires continued prostaglandin synthesis. Potential mechanisms for the regulation of the antibody response by prostaglandins are discussed.     

Localization and characterization of prostaglandin E1 receptors in rat small intestine

While prostaglandins of the E series are known to affect several small intestinal functions, their cellular mechanisms are poorly understood. The purposes of our study were to determine whether receptors for PGE are present in rat small intestine and to locate and characterize the receptor binding in the subcellular fractions. Small intestinal binding of prostaglandin E1 was significantly higher than that of prostaglandin E2. Highest receptor binding for prostaglandin E1 was found in the plasma membrane fraction of isolated small intestinal enterocytes. Curvilinearity of prostaglandin E1 binding in plasma membranes upon Scatchard analysis indicated two receptor binding sites in rat small intestine. Competitive binding studies demonstrated that receptor binding was highest for prostaglandins of the E series. These studies are the first to demonstrate specific prostaglandin E1 receptors in different subcellular fractions of rat small intestine. We suggest that receptor binding of prostaglandin E may be an important initial step in the mechanism of prostaglandin-E-induced responses in the small intestine.     

Characteristics of prostaglandin E1 interaction with components of biological membranes

To estimate the connection between physico-chemical characteristics and biological activity of prostaglandins the interaction of prostaglandin E1 with biological membrane lipids was studied. It is shown that as a result of prostaglandin interaction with phosphatidylcholine a complex is formed that behaves as an individual component and occupies in the surface layer twice as large area than the complex with prostaglandin F2 alpha. The prostaglandin E1 film collapses earlier than F2 alpha. Both facts indicate that the first is more friable. A difference in morphology of prostaglandin monolayers was revealed by electron microscopy. When studying the catalytic activity of peroxidase incorporated in prostaglandin E1 and F2 alpha monolayers some differences were also revealed. In the second case oxidation with methylblue located under the monolayer proceeds more actively. The results obtained point to the connection between the regulatory function of prostaglandins and their chemical structure. Molecular rearrangements of the monolayer caused by prostaglandin incorporation were recorded.     

Prostaglandin interaction with the renal effects of plasma angiotensin II in the Pekin duck

The present study was designed to determine whether the responses of the avian kidney to circulating angiotensin II, under different osmotic conditions, involve an interaction with prostaglandins. The renal effects of i.v. infusions of angiotensin II at 10, 30 and 90 ng·kg·min^-1 for 30 min were compared in Pekin ducks given maintenance infusions of either 200 mosmol ·l^-1 NaCl or glucose at 0.5 ml·min^-1, with and without prostaglandin inhibition by indomethacin. Birds infused with glucose without indomethacin responded to the two low doses of angiotensin II with dose-dependent reductions in water and sodium excretion, whilst the same doses of angiotensin II in salineloaded birds caused dose-dependent increases in the renal exeretion of salt and fluid. Indomethacin treatment in the animals given glucose had no effect upon the antidiuretic response to the low doses of angiotensin II but did prevent the antinatriuretic effect. In the birds infused with saline, prostaglandin inhibition reversed the natriuretic/diuretic action of angiotensin II, producing renal salt and water conservation. The highest dose of angiotensin II was consistently diuretic/natriuretic and independent of prostaglandin involvement in each case. The results indicate that the antinatriuretic effect of low doses of angiotensin II in glucose-infused birds involves an interaction with prostaglandins, whereas the antidiuretic effect of angiotensin II under this condition is independent of prostaglandins. In salt-loaded birds the diuretic/natriuretic actions of low doses of angiotensin II are mediated by prostaglandins so that inhibition of prostaglandin formation unmasks the normal salt and fluid-retaining actions of systemic angiotensin II.Abbreviations AII angiotensin II - ECFV extracellular fluid volume - PG prostaglandin - PGE prostaglandin E     

Hydrocortisone inhibition of the bradykinin activation of human synovial fibroblasts

Human synovial fibroblasts in culture respond to bradykinin with a 20-fold increment in intracellular cyclic AMP concentrations, however bradykinin does not directly activate adenylate cyclase activity in a particulate fraction derived from these cells. Bradykinin evokes a release of labeled arachidonic acid and prostaglandins E and F from synovial fibroblasts pre-labeled with ³H-arachidonic acid. Hydrocortisone inhibits the bradykinin induced increment in cyclic AMP and the release of arachidonic acid and prostaglandins E and F from synovial fibroblasts. Indomethacin, which also inhibits the cyclic AMP response to bradykinin, has no effect on the release of arachidonic acid from synovial fibroblasts. Indomethacin does, however, inhibit the quantity of prostaglandins released into the medium. These studies support the hypothesis that bradykinin does not activate human synovial fibroblast adenylate cyclase, but presumably activates a phospholipase whose products in turn result in the synthesis of prostaglandins. These and other investigations also suggest that a product(s) of the prostaglandin pathway causes the increment in cyclic AMP.     

Enzymic coupling of acylhydrolase and prostaglandin synthase activities in subcellular fractions from rabbit renal medulla

We have recently shown that mitochondrial and plasma-membrane fractions from kidney medulla possess Ca²⁺-stimulated acylhydrolase and prostaglandin synthase activities. The nature of the enzymic coupling between the Ca²⁺-stimulated arachidonic acid release and its subsequent conversion into prostaglandins was investigated in subcellular fractions from rabbit kidney medulla. Plasma-membrane, mitochondrial and microsomal fractions were found to have similar apparent K_m values for conversion of added exogenous arachidonate into prostaglandins. The rate of prostaglandin biosynthesis (V_max.) from added arachidonic acid in the microsomal fraction was approx. 2-fold higher than in the other subcellular fractions. In contrast, prostaglandin E₂ synthesis from endogenous arachidonate in plasma-membrane and mitochondrial fractions was 3–4-fold higher than in microsomes. Furthermore, Ca²⁺ stimulated endogenous arachidonate deacylation and prostaglandin E₂ generation in the former two fractions but not in microsomes. In mitochondrial or crude plasma-membrane fractions, in which prostaglandin biosynthesis was inhibited with aspirin, arachidonate released from these fractions was converted into prostaglandins by the microsomal prostaglandin synthase. Thus an intracellular prostaglandin generation process that involves inter-fraction transfer of arachidonic acid can operate. Prostaglandin generation by such an inter-fraction process is, however, less efficient than by an intra-fraction process, where arachidonic acid released by mitochondria or crude plasma membranes is converted into prostaglandins by prostaglandin synthase present in the same fraction. This demonstrates the presence of a tight intra-fraction enzymic coupling between Ca²⁺-stimulated acylhydrolase and prostaglandin synthase enzyme systems in both mitochondrial and plasma-membrane fractions.     

In vitro effect of prostaglandins,prostaglandin endoperoxides and thromboxane on rat intestinal alkaline phosphatase and (Ca2+-Mg2+) adenosine triphosphatase

The activity of alkaline phosphate and²⁺-Mg²⁺ adenosine triphosphatase, two of the enzymes involved in limpid and calcium uptake across the intestinal membrane, were increased in experimental atherosclerosis. Administration ofAnnapavala sindhooram, an antiatherosclerotic drug, lowers these enzyme levels to near normal values. Prostaglandin E2 stimulated the enzyme activitiesin vitro, while prostaglandin endoperoxide inhibited the activity. Thromboxane and other prostaglandins had no effect on the enzyme activities. Addition of the antiatherosclerotic drug to thein vitro assay system reversed the effect of both prostaglandin E₂ and prostaglandin endoperoxide.