N-Methyl-2-pyridone-5-carboxamide is 1-methylnicotinamide metabolite of low cyclooxygenase-dependent vasodilating activity

1-Methylnicotinamide (MNA) is a primary metabolite of nicotinamide recently proven to cause systemic increase in PGI(2) plasma levels in an unknown mechanism. Our present study was aimed at verifying whether the increased production of PGI(2), a vasodilating prostanoid, in response to MNA, its metabolite N-methyl-2-pyridone-5-carboxamide (Met2PY), and nicotinamide may be reproduced under in vitro conditions. Since prostacyclin is a vasodilating prostanoid, we also performed the functional tests in the ex vivo model of coronary vascular bed perfusion to evaluate the vasoactive properties of those compounds. We did not observe any significant effect of the tested drugs on either PGI(2) or PGE(2) secretion in our in vitro model. Nicotinamide at the concentrations of 10 and 100 μmol/l and 100 μmol/l Met2PY slightly but significantly increased coronary flow in rat heart. These increases, however, remained very low when compared to that induced by the reference compound, bradykinin (100 nmol/l). Perfusion of rat hearts with Met2PY in the presence of 50 μmol/l indomethacin resulted in decreased coronary flow, which proves that the effect is cyclooxygenase dependent. We conclude that MNA metabolites should be more carefully addressed in reference to pro-prostacyclin activity and that systemic mechanism of MNA-induced PGI(2) production needs further clarification.     

Abnormal response of urinary eicosanoid system to norepinephrine infusion in patients with essential hypertension.

To define the role of the renal eicosanoid system in sustaining renal homeostasis in hypertension, we investigated the alterations in urinary excretions of 6-keto-prostaglandin F1 alpha (6-keto-PGF1 alpha), a stable metabolite of vasodepressor prostacyclin, and thromboxane B2 (TXB2), a stable metabolite of vasoconstrictor TXA2, when norepinephrine was continuously infused for 90 min in hypertensive (n = 13) and normotensive subjects (n = 14). There was no difference in plasma norepinephrine concentration after the infusion between the hypertensive and the normotensive subjects. Moreover, the percent changes in renal vascular resistance elicited by norepinephrine in the hypertensives were equal to those of the normotensive subjects. In the normotensive subjects, the norepinephrine infusion significantly increased urinary 6-keto-PGF1 alpha excretion and decreased urinary excretion of TX, both of which are beneficial for sustaining renal function. In fact, the greater the production of renal 6-keto-PGF1 alpha was, the less the reduction of renal blood flow and urinary sodium excretion was. In the hypertensive subjects, however, these normal responses of the renal eicosanoid system, seen in the normotensives, were abolished; urinary 6-keto-PGF1 alpha was unaltered and thromboxane generation was rather increased. Thus, the renal eicosanoid system dysfunctions in hypertensive subjects when the renal circulation is challenged by norepinephrine. These abnormal responses are likely to cause sodium retention and could contribute, in part, to the hypertensive mechanism in patients with essential hypertension.     

The effect of PGI2 on canine renal function and hemodynamics.

The effect of prostaglandin I2 (prostacyclin) on renal and intrarenal hemodynamics and function was studied in mongrel dogs to elucidate the role of this novel prostaglandin in renal physiology. Starting at a dose of 10(-8) g/kg/min, PGI2 decreased renal vascular resistance and redistributed the blood flow away from the outer cortex (zone 1) and towards the juxtamedullary cortex (zone 4). At 3 X 10(-8) g/kg/min, the renal vascular resistance decreased even further, but at this dose the mean arterial blood pressure also declined 13% indicating recirculation of this prostaglandin. PGI2 infusion at a vasodilatory dose resulted in natriuresis and kaliuresis. With a decline in filtration fraction, these changes were most likely secondary to the hemodynamic effects of this prostaglandin. Unlike PGE2, PGI2 had no direct effect on free water clearance indicating lack of activity at the collecting duct. PGI2 may be the important renal prostaglandin involved in modulating renal vascular resistance and intrarenal hemodynamics as well as influencing systemic blood pressure.     

Cyclooxygenase inhibition with acetylsalicylic acid unmasks a role for prostacyclin in erythropoietin-induced hypertension in uremic rats

We previously reported that thromboxane (TX)A2 synthesis and receptor blockade prevented recombinant human erythropoietin (rhEPO)-induced hypertension in chronic renal failure rats. The present study was designed to investigate the effect of a cyclooxygenase inhibitor, acetylsalicylic acid (ASA), on blood pressure, renal function, and the concentration of eicosano?ds and endothelin-1 (ET-1) in vascular and renal tissues of rhEPO-treated or rhEPO-untreated uremic rats. Renal failure was induced by a 2-stage 5/6 renal mass ablation. Rats were divided into 4 groups: vehicle, rhEPO (100 U/kg, s.c., 3 times per week), ASA (100 mg x kg(-1) x day(-1), and rhEPO + ASA; all animals were administered drugs for 3 weeks. The TXA2- and prostacyclin (PGI2)-stable metabolites (TXB2 and 6-keto-PGF1alpha, respectively), as well as ET-1, were measured in renal cortex and either the thoracic aorta or mesenteric arterial bed. The uremic rats developed anemia, uremia, and hypertension. They also exhibited a significant increase in vascular and renal TXB2 (p < 0.01) and 6-keto-PGF1alpha (p < 0.01) concentrations. rhEPO therapy corrected the anemia but aggravated hypertension (p < 0.05). TXB2 and ET-1 tissue levels further increased (p < 0.05) whereas 6-keto-PGF1alpha was unchanged in rhEPO-treated rats compared with uremic rats receiving the vehicle. ASA therapy did not prevent the increase in systolic blood pressure nor the progression of renal disease in rhEPO-treated or rhEPO-untreated uremic rats, but suppressed both TXB2 and 6-keto-PGF1alpha tissue concentrations (p < 0.05). ASA had no effect on vascular and renal ET-1 levels. Cyclooxygenase inhibition had no effect on rhEPO-induced hypertension owing, in part, to simultaneous inhibition of both TXA2 and its vasodilatory counterpart PGI2 synthesis, whereas the vascular ET-1 overproduction was maintained. These results stress the importance of preserving PGI2 production when treating rhEPO-induced hypertension under uremic conditions.     

The effects of an infusion of prostacyclin on their endotoxin shock in rabbits.

30 rabbits received an infusion of lipopolysaccharide B (75 micrograms/kg.h) over 4 hours (groups E, EI, EA; n = 10 each). Saline was given to a control group (C; n = 8). In group EI, prostacyclin (PGI2; 500 ng/kg.min) was given simultaneously to endotoxin. Into group EA animals, aspirin (20 mg/kg) was injected before the endotoxin infusion was started. PGI2 and aspirin both improved survival of animals (6/10 each vs. 2/10 in group E). The drop of platelet counts was significantly reduced by PGI2, while leukocyte depletion was similar in all endotoxin groups. PGI2 preserved the functional capacity of platelets as indicated by collagen stimulated aggregation and thromboxane formation. PGI2 but not aspirin significantly reduced renal fibrin deposition.     

Prostacyclin and steroidogenesis in goat ovarian cell types in vitro

Granulosa, theca and corpus luteum cells of the goat ovary were isolated and incubated separately for 6 hours, with or without various modulators. Arachidonic acid (AA, 10 ng to 100 micrograms/ml), the precursor for prostaglandin synthesis, produced a dose-dependent increase in progesterone (P4) and estradiol-17 beta (E2) production by all the cell types. Prostaglandin synthetase inhibitors, aspirin (10(-6)-10(-3)M) and indomethacin (100 ng-1 mg/ml), produced a dose-dependent decrease in arachidonic acid-stimulated (100 micrograms/ml) steroid production. Prostacyclin synthetase stimulators, trapidil (1.6 micrograms- 1 mg/ml) and dipyridamole (10(-6)-10(-3)M), when added alone or along with AA, did not affect steroid production. Up to 100 micrograms/ml of U-51605 (9,11-azoprosta-5,13-dienoic acid), a prostacyclin synthetase inhibitor, did not inhibit basal or AA-stimulated steroid production. Prostacyclin (PGI2) and its stable analog 6 beta PGI1 (0.01-10 micrograms/ml) produced a dose-dependent increase in P4 and E2 production in all the three cell types. Increase at 1 and 10 micrograms/ml was significant in all cases. 6-keto-PGE1 (an active metabolite of PGI2 in certain systems) produced an increase in steroid production which was significant in theca at greater than or equal to 1 microgram/ml concentrations but had no significant effect on granulosa and corpus luteum cells at any dose level. 6-keto-PGF1 alpha (stable metabolite of PGI2) was without effect in the present system. The lack of effect of PGI2 at lower concentrations was not altered by either differentiation of the cells with FSH and testosterone or addition of steroid precursors, testosterone and pregnenolone. The present results indicate that AA-stimulated steroid production in the goat ovarian cell type is mediated by prostaglandins other than PGI2 though PGI2 itself can positively modulate the steroid production.     

Effect of intrarenal adenosine on urinary excretion of prostaglandins and leukotrienes in the anesthesized dog

Adenosine is a renal vasoconstrictor that plays an important role in mediating renal adaptive responses to decreases in renal perfusion pressure. It is known that adenosine acts on the metabolism of arachidonic acid, but the direct repercussions of adenosine in the production of renal prostaglandins and leukotrienes have not been studied. This study was undertaken to evaluate the effect of the intrarenal infusion of adenosine upon the urinary elimination of arachidonic acid derivatives. Samples of urine were collected with lysine acetylsalicylate and determination of prostaglandins (PGs) and leukotrienes (LTs) was performed by radioimmunoassay of samples previously separated by HPLC. The infusion of adenosine decreases the urinary excretion of 6-keto-PGF1 alpha and TxB2 significantly. There was no significant change in urinary excretion of PGE2 while LTB4 and LTC4 showed a tendency to increase. These results suggest that a fall in the synthesis of PGI2 along with an increase in LTC4, which is a constrictor of mesangial cells, could be responsible for the renal vasoconstriction phase of adenosine. Therefore, it was concluded that adenosine vasoconstriction is mediated through the inhibition of the cyclo-oxygenase pathway, diminishing the synthesis of PG vasodilators.     

Modulation of renal hemodynamics by renal eicosanoids during vasopressor infusions in man

Pressor doses of norepinephrine (NE) (n = 8) and angiotensin II (A II) (n = 5) were infused in normal volunteers to determine whether the systemic administration of vasopressor hormones influence renal eicosanoid production and whether, in turn, the eicosanoids produced could modulate renal hemodynamics and electrolyte excretion. At the doses administered, both pressor substances induced the expected rise in blood pressure, a significant decrease (P less than 0.05) in renal blood flow and a proportionally smaller fall in glomerular filtration rate, resulting in a consistent augmentation in filtration fraction. Fractional sodium excretion was concomitantly reduced. NE infusion produced only slight modifications in urinary prostaglandin (PG)E2, 2,3-dinor-6-keto-PGF1 alpha and thromboxane (TX)B2, while urinary 6-keto-PGF1 alpha and PGF2 alpha were increased by 38% and 176% respectively. The increase in urinary 6-keto-PGF1 alpha (the non-enzymatic degradation product of PGI2, predominantly of cortical origin) was proportional to the level of circulating NE (r = 0.78, P less than 0.05) and to the renal vascular resistance (r = 0.85, P less than 0.01), suggesting an immediate compensatory role for PGI2 in response to the NE-induced pressor stimulus. The renal production of PGE2 and PGF2 alpha (predominantly medullary) was inversely correlated with the filtration fraction: the greater the increase in PGE2 and PGF2 alpha the lower the elevation in filtration fraction or the decline in renal blood flow upon NE administration. All infusion variably stimulated the renal eicosanoid production: PGE2, 41%; PGF2 alpha, 102%; 6-keto-PGF1 alpha, 38%; 2,3-dinor-6-keto-PGF1 alpha, 38%; and TXB2, 25%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Aglomerular kidney function when challenged with exogenous MgSO4 loading or environmental MgSO4 depletion

The goal of this study was to investigate the role of MgSO4 in aglomerular kidney function, independent of changes in NaCl. The renal handling of MgSO4 was manipulated by intravenous infusion of an isoosmotic solution containing 80 mmol/L MgSO4 or through exposure to an environment that was reduced in MgSO4 concentration by 90%. Intravenous infusion resulted in a transient increase in circulating Mg2+ and SO4 (2-) levels; however, the concentration of both divalent ions in the urine remained elevated throughout the entire infusion period. Infusion also resulted in a transient increase in urine flow rate and apparent glomerular filtration rate, measured using the glomerular filtration rate marker, [3H] PEG 4000. Exposure to MgSO4-depleted conditions resulted in a significant decrease in plasma and urine concentrations of Mg2+ and in the urine concentrations of SO4 (2-); correspondingly, urine flow rate was significantly depressed. The urinary excretion of both Mg2+ and SO4 (2-) demonstrated nonlinear saturation kinetics. The urinary excretion of Mg2+ was significantly correlated with plasma Mg2+ concentration (r=0.75, P=0.04) and yielded a Michealis constant (Km) of 1.67+/-1.43 mmol/L; P=0.26 and a maximal velocity (Vmax) of 117.4+/-47.0 micromol/kg/hr; P=0.046. The urinary excretion of SO4 (2-) was significantly correlated with plasma SO4 (2-) concentration (r=0.94, P<0.02) with a Km of 0.76+/-0.54; P=0.26 and a Vmax of 59.3+/-13.1; P=0.02.     

The in vitro effects of nicotine and cotinine on prostacyclin and thromboxane biosynthesis

The comparative effects of nicotine and cotinine on the biosynthesis of prostacyclin (PGI2) and thromboxane A2 (TXA2) in the horse aorta and platelet microsomes were studied. TXB2 and 6-keto PGF1a stable metabolites of TXA2 and PGI2 respectively were determined by radioimmunoassay. TXA2 production in the presence of either nicotine or cotinine treatment was not altered. However, a dose dependent inhibition of PGI2 biosynthesis, and a dose dependent stimulation of PGI2 biosynthesis, was observed in the presence of nicotine and cotinine respectively. Moreover, cotinine (10b3 M) was able to prevent the inhibitory effect of nicotine on PGI2 synthetase when preincubated with horse aorta microsomes. It appears that cotinine, the major nicotine metabolite resulting from a breakdown process, could be useful for the organism, at least for the cardiovascular system.     

Epoprostenol in patients with Raynaud's disease

Prostaglandin metabolism and the clinical effect of epoprostenol (prostacyclin, PGI2) infusions were studied in thirteen patients with Raynaud's disease. Epoprostenol was infused at 5 ng/kg/min for six hours daily for two consecutive five day periods, separated by a two day interval. No beneficial effects either during or after infusion could be detected in terms of frequency of severity of attacks or on skin temperature measurement. Raynaud's patients had significantly lower serum thromboxane B2 levels than normal controls though plasma levels of thromboxane B2, 6-oxo-PGF1 and the bicyclic metabolite of PGE2 did not differ between the two groups. Platelets from Raynaud's patients had a significantly lower conversion rate of arachidonic acid into thromboxane B2 and HHT and a significantly higher rate of HETE production than platelets from controls.     

Endothelial vasodilator production by uterine and systemic arteries. VIII. Estrogen and progesterone effects on cPLA2, COX-1, and PGIS protein expression.

During ovine pregnancy, when both estrogen and progesterone are elevated, prostacyclin (PGI2) production by uterine arteries and the key enzymes for PGI2 production, phospholipase A2 (cPLA2), cyclooxygenase 1 (COX-1), and prostacyclin synthetase (PGIS), are increased. This study was conducted to determine whether exogenous estradiol-17beta (E2beta) with or without progesterone (P4) treatment would increase cPLA2, COX-1, and PGIS protein expression in ovine uterine, mammary, and systemic (renal, mental, and coronary) arteries. Nonpregnant ovariectomized sheep received vehicle (n = 10), P(4) (0.9-g controlled internal drug release vaginal implants; n = 13), E2beta (5 microg/kg bolus followed by 6 microg x kg(-1) x day(-1); n = 10), or P4 + E2beta (n = 12). Arteries were procured on Day 10, and cPLA2, COX-1, and PGIS protein were measured by Western immunoblot analysis in endothelial isolated proteins and vascular smooth muscle (VSM). The levels of cPLA2 was increased in uterine artery endothelium in ewes treated with P4 + E2beta but was not altered by any steroid treatment in renal, coronary, mammary, or omental artery endothelium or in VSM of any evaluated artery. Similarly, COX-1 was increased in uterine artery endothelium with P4 + E2beta but was not significantly altered by treatment in other endothelium or VSM. E2beta treatment increased PGIS protein in uterine and renal artery endothelium but did not alter PGIS in other endothelial tissue. P4 increased PGIS expression in the uterine, mammary, omental, and renal artery VSM, and E2beta increased PGIS expression in the uterine and omental artery VSM. Both E2beta and P4 treatments differentially alter protein expression of the key enzymes involved in PGI2 production in different artery types and may play an important role in the control of blood flow redistribution during hormone replacement therapy.     

Angiotensin II mediates systemic rebound hypertension after cessation of prostacyclin infusion in sheep

Prostacyclin(or epoprostenol), an arachidonic acid metabolite, is aneffective treatment for patients with primary pulmonary hypertension.Interruption of chronic prostacyclin infusion can result in recurrentsymptoms of dyspnea and fatigue. The etiology of this phenomenon isunknown. We hypothesized that sympathoadrenal activation could lead toincreased vascular tone after abrupt termination of the infusion. Toevaluate this effect, we monitored six chronically instrumented, awakesheep during and after infusion of prostacyclin. Prostacyclin decreasedmean arterial pressure (MAP) by 14% and increased cardiac output by33%. After the infusion ceased, MAP rebounded 23% above baseline, andcardiac output decreased by 28% from peak values within 10 min. Wewere unable to demonstrate an increase in norepinephrine levels aftercessation of prostacyclin, nor did -adrenergic blockade affectpostinfusion hemodynamics. However, plasma renin activity increased>10-fold at peak infusion and remained elevated for up to 2 h afterdiscontinuation of prostacyclin. Coinfusion of the angiotensinII-receptor antagonist L-158,809 resulted in complete abrogation of thepostcessation rise in MAP. We conclude that renin-angiotensin systemactivation is primarily responsible for systemic hypertension occurringafter abrupt cessation of prostacyclin infusion in sheep and thatangiotensin II receptor blockade prevents this response. Our data donot support a role for sympathetic nervous system activation in thesystemic pressor response after prostacyclin infusion.

     

Enhancement of anaphylactic mediator release from guinea-pig perfused lungs by fatty acid hydroperoxides.

Fragments of chopped lung from indomethacin treated guinea-pigs had an anti-aggregating effect when added to human platelet rich plasma (PRP), probably due to the production of prostacyclin (PGI2) since the effect was inhibited by 15-hydroperoxy arachidonic acid (15-HPAA, 10 micrograms ml(-1)). Both 15-HPAA (1-20 micrograms ml(-1) min (-1)) and 13-hydroperoxy linoleic acid (13-HPLA, 20 micrograms ml(-1) min(-1)) caused a marked enhancement of the anaphylactic release of histamine, slow-reacting substance of anaphylaxis (SRS-A) and rabbit aorta contracting substance (RCS) from guinea-pig isolated perfused lungs. This enhancement was not reversed by the concomitant infusion of either PGI2 (5 micrograms ml(-1) min (-1)) or 6-oxo-prostaglandin F1alpha (6-oxo-PGF1alpha, 5 micrograms ml(-1) min(-1)). Anaphylactic release of histamine and SRS-A from guinea-pig perfused lungs was not inhibited by PGI2 (10 ng - 10 microgram ml(-1) min(-1)) but was inhibited by PGE2 (5 and 10 micrograms ml(-1) min (-1)). Antiserum raised to 5,6-dihydro prostacyclin (PGI1) in rabbits, which also binds PGI2, had no effect on the release of anaphylactic mediators. The fatty acid hydroperoxides may enhance mediator release either indirectly by augmenting thromboxane production or by a direct effect on sensitized cells. Further experiments to distinguish between these alternatives are described in the accompanying paper (27).     

Combined inhaled nitric oxide and inhaled prostacyclin during experimental chronic pulmonary hypertension.

Inhaled nitric oxide (NO) and inhaled prostacyclin (PGI2) produce selective reductions in pulmonary vascular resistance (PVR) through differing mechanisms. NO decreases PVR via cGMP, and PGI2 produces pulmonary vasodilation via cAMP. As a general pharmacological principle, two drugs that produce similar effects via different mechanisms should have additive or synergistic effects when combined. We designed this study to investigate whether combined inhaled NO and PGI2 therapy results in additive effects during chronic pulmonary hypertension in the rat. Monocrotaline injected 4 wk before study produced pulmonary hypertension in all animals. Inhaled NO (20 parts/million) reversibly and selectively decreased pulmonary artery pressure (Ppa) with a mean reduction of 18%. Four concentrations of PGI2 were administered via inhalation (5, 10, 20, and 80 microg/ml), both alone and combined with inhaled NO. Inhaled PGI2 alone decreased Ppa in a dose-dependent manner with no change in mean systemic arterial pressure. Combined inhaled NO and PGI2 selectively and significantly decreased Ppa more did than either drug alone. The effects were additive at the lower concentrations of PGI2 (5, 10, and 20 microg/ml). The combination of inhaled NO and inhaled PGI2 may be useful in the management of pulmonary hypertension.     

Alteration of vascular thromboxane in rats with subtotal renal ablation

To assess the roles of vascular prostaglandins in the hypertension of chronic renal failure, the release of prostacyclin and thromboxane (TX) from aorta was evaluated in male Sprague-Dawley rats, the renal mass of which was reduced by removing one kidney and two-thirds of the contralateral kidney ("5/6 nephrectomy"). Five-sixths nephrectomy was followed by significant rises in serum creatinine to 0.55 +/- 0.03 mg/dl and urea nitrogen to 42.9 +/- 3.8 mg/dl, with a concomitant rise in mean blood pressure from 121.6 +/- 1.6 mmHg to 155.3 +/- 8.4 mmHg. In 5/6 nephrectomized rats, the release of TX A2 from aorta, as measured by its stable metabolite TX B2, increased by 60% (p less than 0.01) and prostacyclin, as measured by its stable metabolite 6-keto-prostaglandin, F1 alpha (6-keto-PG F1 alpha) increased by 51% (p less than 0.05). The amounts of both TX B2 and 6-keto-PG F1 alpha released from aorta were closely related to the height of mean blood pressure. These results suggest that the enhanced vasoconstrictor TX production in the vascular walls may be relevant to hypertension in rats with subtotal renal ablation. The adaptive increase in prostacyclin production in the vascular walls may compensate for the elevation of blood pressure due to chronic renal failure in this animal model.     

Effect of prostacyclin on pulmonary vascular response to thrombin in awake sheep

We determined the effects of infusion of prostacyclin (PGI2) and 6-alpha-carba-PGI2 (6-cPGI2), a stable PGI2 analogue, on pulmonary transvascular fluid and protein fluxes after intravascular coagulation induced by thrombin. Studies were made in control awake sheep prepared with lung lymph fistulas (n = 6) and in similarly prepared awake sheep pretreated with either 6-cPGI2 (n = 5) or PGI2 (n = 5). Both prostacyclin compounds (500 ng X kg-1 X min-1) were infused intravenously. All groups were challenged with 80 U/kg thrombin. Pulmonary arterial pressure (Ppa), pulmonary vascular resistance (PVR), pulmonary lymph flow (Qlym), lymph protein clearance (Qlym X lymph/plasma protein concentration ratio), and neutrophil and platelet counts were determined. In vitro tests assessed sheep neutrophil chemotaxis and chemiluminescence and platelet aggregation. In both 6-cPGI2 and PGI2 groups, the increases in Qlym after thrombin were less than those in the control group. The increase in lymph protein clearance in the 6-cPGI2 group was the same as that in control, whereas the increase in clearance in the PGI2 group was reduced. PVR and Ppa increased to a greater extent in the 6-cPGI2 group than in the control group, whereas the increases in PVR and Ppa were inhibited in the PGI2 group. Neutrophil and platelet counts decreased after thrombin in PGI2 and 6-cPGI2 groups, as they did in the control group. Neither 6-cPGI2 altered neutrophil chemotaxis induced by thrombin and chemiluminescence induced by opsonized zymosan. Both prostacyclin compounds inhibited platelet aggregation induced by ADP or thrombin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Epigallocatechin gallate increase the prostacyclin production of bovine aortic endothelial cells

We describe the effect of (-) epigallocatechin gallate (EGCg), one of catechins known in tea, on the prostacyclin (PGI) production by bovine aortic endothelial cells. The amounts of 6-keto-PGF(1alpha) and Delta(17)-6-keto-PGF(1alpha), stable metabolites of PGI(2) and PGI(3), released in culture medium were measured using gas chromatography/selected ion monitoring (GC/SIM). The prostacyclin production of endothelial cells was increased by EGCg in a dose- and time-dependent manner. The effect by EGCg was stronger than any other catechins (catechin, epicatechin, epigallocatechin, and epicatechin gallate). When endothelial cells incubated with EGCg and arachidonic acid (AA) or eicosapentaenoic acid (EPA), PGI(2), and PGI(3) production were increased greater than those incubated with AA or EPA alone. Furthermore, gallic acid, that also has a pyrogallol structure, increased PGI(2) production. These observations indicate that catechins increase the prostacyclin production and that the pyrogallol structure is significant to this function.     

Vascular eicosanoid production in experimental hypertensive rats with different mechanisms

This study investigated the release of prostacyclin (PGI2) and thromboxane A2 (TXA2) from the aortic walls of various experimental hypertensive rats, e.g. spontaneously hypertensive rats (SHR), Dahl salt-sensitive (Dahl S) rats, deoxycorticosterone (DOCA)-salt hypertensive rats and renovascular (2-kidney, 1-clip (2K1C) and 1-kidney, 1-clip (1K1C] hypertensive rats. The PGI2 generation was increased significantly in these hypertensive models, irrespective of the hypertensive mechanisms, when they developed established hypertension. Dahl S rats, having an impaired PGI2 production on a low salt diet, restored PGI2 generating capacity to the control level of Dahl salt-resistant rats when they were fed a high salt diet and developed salt-induced hypertension. On the other hand, the TXA2 generation in the vascular walls was enhanced particularly in rat models for genetic hypertension, and this system was unaltered in the models for secondary hypertension, e.g. DOCA-salt and renovascular hypertension. Thus, it is suggested that the elevation of blood pressure is associated with an increase in vascular PGI2 production, and that the increased vascular TXA2 production is a characteristic feature of genetic hypertension.     

Lack of prostaglandin effect on sodium balance and hyperreninemia in adrenalectomized rats.

Glucocorticoids are known inhibitors of prostaglandin production. Prostaglandin E2 (PGE2) and prostacyclin (PGI2) are promoters of natriuresis and renin release. Excessive prostaglandin production, therefore, might contribute to the altered sodium balance and renin release observed in primary adrenal insufficiency. To test this hypothesis, sodium balance and prostaglandin production were measured in adrenalectomized rats and in animals receiving prostaglandin inhibitors or replacement dexamethasone. Compared to sham-operated controls, adrenalectomized rats had decreased two-day sodium balance and elevated plasma renin concentration (PRC), renal PGE2 production, and renal 6-ketoprostaglandin F1 alpha (6kPGF1 alpha, the nonenzymatic metabolite of PGI2); however, no appreciable change in aortic 6kPGF1 alpha production was observed. Dexamethasone given to adrenalectomized rats normalized PRC but had no effect on sodium balance or prostaglandin production. Likewise, prostaglandin inhibitors did not alter the sodium balance or decrease the PRC post adrenalectomy. These data confirm renal prostaglandin production is increased in adrenalectomized rats, but suggest that the elevation is not due directly to glucocorticoid deficiency. Further, PRC levels in adrenal insufficiency do not appear to be prostaglandin mediated. In conclusion, excessive renal prostaglandin production does not contribute to altered sodium balance or increased PRC in adrenalectomized rats.