Modulation of prostaglandin of the renal vascular action of arginne vasopressin

To determine whether the renal vascular effect of arginine vasopressin (AVP) is modulated by renal prostaglandin E₂ (PGE₂) were determined during the infusion of AVP in dogs during control conditions and after the administration of the inhibitor of prostaglandin synthesis, indomethacin. During control conditions, intrarenal administration for 10 min of a dose of AVP calculated to increase arterial renal plasma AVP concentration by 75 pg/ml produced a slight renal vasodilation (p<0.01) and an increase in renal venous plasma concentration of PGE₂. Renal venous PGE₂ concentration during control and AVP infusion averaged 33 ± 7 and 52 ± 12 pg/ml (p<0.05), respectively. After administration of indomethacin, the same dose of AVP induced renal vasoconstriction (p<0.05) and failed to enhance renal venous PGE₂ concentration (9 ± 1 to 8 ± 1 pg/ml). Intrarenal administration of 20 ng/kg. min of AVP for 10 min induced a marked renal vasoconstriction (p<0.01) and increased renal venous plasma PGE₂. Renal venous PGE₂ during control and AVP infusion averaged 31 ± 10 and 121 ± 31 pg/ml (p<0.01), respectively. Administration of the same dose of AVP following indomethacin produced a significantly greater and longer lasting renal vasoconstriction (p<0.01) and failed to increase renal venous plasma PGE₂ (10 ± 1 to 9 ± 1 pg/ml). These results indicate that a concentration of AVP comparable to that observed in several pathophysiological conditions induces a slight renal vasodilation which is mediated by renal prostaglandins. The results also indicate that higher doses of AVP induce renal vasoconstriction and that prostaglandin synthesis induced by AVP attenautes the renal vasoconstriction produced by this peptide.     

Acute prostaglandin reduction with indomethacin and chronic prostaglandin reduction with an essential fatty acid deficient diet both decrease plasma flow to the renal papilla in the rat

Renal distribution of prostaglandin synthetase is mainly medullary, whereas the major degrading enzyme, prostaglandin dehydrogenase is primarily cortical. This suggests that prostaglandins (PG) released from the renal medulla could affect the medullary blood vessels. In two different experiments we studied the role of PG in the regulation of renal papillary plasma flow in the rat. First study: PG synthesis were stimulated in 34 adult Sprague-Dawley rats by bleeding from the femoral artery 1% of the body weight over a period of 10 minutes. Following this, indomethacin (a PG inhibitor, 10 mg/kg i.v.) was given slowly and then renal papillary plasma flow was measured 25 minutes after the end of infusion. In 17 indomethacin rats the renal papillary plasma flow averaged 18.8 ml/100 g/minute, whereas it averaged 23.0 in 17 non-indomethacin rats given diluent, an 18% reduction (p less than .025). Second study: Male Sprague-Dawley rats were made prostaglandin deficient by fasting rats for one week, followed by 10% dextrose fluid for one week and subsequent institution of an essential fatty acid (EFA) deficient diet for two weeks. With urinary PG excretion in prostaglandin deficient rats 28 ng/24 hours compared to 149 ng in control rats, they could be considered as prostaglandin deficient. When renal papillary plasma flow was measured, the 16 prostaglandin deficient rats had a 16% lower papillary plasma flow than 16 control rats, 21.6 vs 25.6 (p less than .005). These results clearly demonstrate that PG inhibition in rats decreases plasma flow to the papilla, strongly suggesting that PG are vasodilators for the vessels supplying the renal papilla.     

Inhibition of compensatory renal growth by indomethacin

Renal prostaglandins may be important in the modulation of compensatory renal growth. Reductions in renal mass are associated with increased synthesis of these substances by the remaining kidney, and inhibition of prostaglandin synthesis diminishes renal function in partially nephrectomized animals and in patients with reduced functioning renal mass. We examined the effects of uninephrectomy and treatment with indomethacin on renal prostaglandin E₂ and 6-keto prostaglandin F_1α concentrations in adult male Sprague Dawley rats. The renal content of these prostaglandins was significantly increased in the remaining kidney two days following uninephrectomy (p<0.01). Treatment with 5 mg/kg/day of indomethacin over this period abolished the compensatory increase in renal prostaglandin synthesis and significantly attenuated compensatory increases in renal mass, protein and RNA concentration (p<0.05). No alterations in kidney weight, protein or RNA concentrations were found in intact animals treated with the same dose of indomethacin. These findings suggest renal prostaglandins may participate in the biological events leading to compensatory renal growth.     

Renal sodium handling and stimulation of medullary Na---K---ATPase during blockade of prostaglandin synthesis

The effect of suppression of prostaglandin synthesis on renal sodium handling and microsomal Na---K ATPase was studied in control and indomethacin treated intact rats maintained on a normal sodium diet (series A) and chronically salt loaded (series B). Indomethacin administration resulted in a decreased GFR and a significantly depressed urinary excretion and an increased fractional reabsorption of sodium in animals fed the normal sodium diet or chronically salt loaded. In rats maintained on a nomral Na diet, the activity of the renal medullary Na---K ATPase after indomethacin was 206.3±6.4 ug Pi./mg protein, i.e. significantly higher as compared with the enzyme activity in the medullary renal fraction from control animals in which it averaged 148±7.79 ug Pi/mg protein (p<0.001). While after chronic salt load a similar increment in the activity of renal medullary Na---K ATPase was observed, no additional stimulation was elicited by subsequent indomethacin administration. The addition of exogenous PGE₂, mM to microsomal fractions obtained from kidneys of normal rats, was associated with a moderate suppression of the medullary Na---K---ATPase activity, from a basal level of 170±16 to 151.3±13 umol Pi/mg protein/hr (p<0.005. In isolated segments of medullary thick ascending limb of Henle's loop (MTAL) addition of PGE₂ to the incubation medium resulted in a significant inhibition of Na---K--- ATPase from 37.2±2 to 21.25 ± 1.17 × 10⁻¹¹ mol/mm/min (p<0.0001.These findings suggest that the increased renal Na reabsorption after inhibition of PG synthesis might be related, at least partly, to stimulation of medullary Na---K ATPase. In parallel, the reported natriuretic effect of prostaglandins might imply a direct inhibitory effect of these mediators on renal Na---K ATPase.     

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.     

Effects of prostaglandins on the cerebral circulation in the goat

The role of prostaglandins in producing cerebrovasodilation during hypercapnia was tested in goats. Cerebral blood flow (CBF) changes with increasing arterial PCO2 were measured before and after prostaglandin synthesis inhibition with indomethacin or ibuprofen. Both drugs produced significant decreases in CBF under control anesthetized conditions but had no significant effect on the cerebrovascular response to increased arterial PCO2. The effects of direct intracerebrovascular infusion of prostaglandin E₂ (PGE2), prostaglandin F2α (PGF2α) and prostacyclin were also measured. In the dose range tested (0.1–1 ug/min) PGF2α had no significant effect on cerebral blood flow (CBF). Both PGE2 and PGI2 produced an increase in CBF and the increase produced by PGI2 was significantly greater than that produced by PGE2. The effectiveness of each compound in producing cerebrovascular changes is consistent with the endogenous distribution of prostaglandins within the brain. These results suggest that prostaglandins, particularly PGI1, may be important in modulating cerebrovascular tone but have no role in increasing CBF during hypercapnia.     

The effect of prostaglandin synthetase inhibitors on renal function: Studies in normal rats during sodium or water diuresis and in rats with chronic renal insufficiency

The effect of acute infusion of the prostaglandin synthetase inhibitors — meclofenamate or indomethacin — was examined in awake rats. Studies were performed in normal rats undergoing either sodium or water diuresis and in salt-replete rats with chronic renal insufficiency. Prostaglandin synthetase inhibitors had no effect on renal plasma flow, glomerular filtration rate or fractional excretion of sodium in any of the groups. Absolute urinary excretion rates for sodium and potassium decreased only in the normal, salt-replete rats. In contrast, prostaglandin synthetase inhibitors consistently decreased urinary flow and osmolar clearance under all experimental conditions studied. In the normal, salt-replete rats the fall in urine flow was preceded by an increase in urinary excretion of cyclic AMP. These results show that inhibitors of prostaglandin synthesis enhance the ability of the kidney to reabsorb water. This effect may be secondary to increased cyclic AMP generation and to increased urea recirculation resulting in higher urea accumulation in the renal medulla.     

Effects of zomepirac and indomethacin on renal blood flow and electrolyte excretion in anesthetized monkeys

Zomepirac sodium is a new inhibitor of prostaglandin cyclooxygenase with an $\text{in vitro}$ potency equivalent to indomethacin. Since inhibitors of prostaglandin synthesis have marked effects on renal hemodynamics, zomepirac may be expected to reduce renal blood flow (RBF) in a manner similar to indomethacin. This study compares the effects of zomepirac and indomethacin on RBF and electrolyte excretion in anesthetized Rhesus monkeys. Each experiment consisted of a control period followed by 3 or 4 drug treatment periods in which increasing doses of zomepirac (0.5 to 20 mg/kg) or indomethacin (0.5 to 10 mg/kg were given. Indomethacin (5 mg/kg) reduced RBF by 22% and the higher dose (10 mg/kg) reduced RBF by an additional 13%. Zomepirac had little effect on RBF in doses as high as 20 mg/kg. At any given dose the mean plasma concentration of zomepirac was equal to or greater than indomethacin. Peak indomethacin concentration was 48 μg/ml after the 10 mg/kg dose while the peak zomepirac, after 20 mg/kg, was 158 μg/ml. Neither drug had a significant effect on either glomerular filtration rate or excretion rate of sodium or potassium. Thus, zomepirac had only minimal effects on RBF while indomethacin decreased RBF of anesthetized monkeys in a manner qualitatively similar to its effect in other species. The minimal renal effects caused by zomepirac relative to indomethacin in this primate may indicate a therapeutic advantage for zomepirac in man.     

Prostaglandin F2α (PGF2α) and prolactin secretion in rats

Plasma prolactin and F-prostaglandins (PGF) were measured in anesthetized male Sprague-Dawley rats before and at 15, 30, 45 and 60 minutes following i.v. injection of either PGF_2α (4 mg/kg), chlorpromazine, 1 mg/kg or chlorpromazine (1 mg/kg) after pretreatment with i.p. indomethacin (2 mg/kg). Following PGF_2α administration, plasma prolactin levels increased significantly only at 15 and 30 minutes in spite of extremely high PGF levels throughout 60 minutes. Besides the expected rise in plasma prolactin, chlorpromazine caused a transient but statistically significant increase in PGF. Indomethacin blocked the chlorpromazine-induced PGF rise but not prolactin increase. Animals stressed with ether anesthesia showed elevation of plasma prolactin, which was not blocked by indomethacin although PGF concentration fell. These results indicate that PGF_2α can stimulate prolactin release. This effect does not appear to be physiologic since very high PGF levels are required. Furthermore, blockade of prostaglandin synthesis by indomethacin does not prevent the release of prolactin in response to chlorpromazine or stress. Our findings do not support a possible role of PGFs as intermediaries in prolactin release. However, it is possible that PGFs may work through other mechanisms not investigated in our study.     

Prostaglandin biosynthesis in rabbit kidney medulla: Inhibition vs. by aspirin, indomethacin and meclofenamic acid

The non-steroidal anti-inflammatory drugs aspirin, indomethacin and meclofenamic acid were compared for their potency and duration of inhibition of prostaglandin biosynthesis in rabbit kidney medulla. Indomethacin and meclofenamic acid showed equal potency of inhibition (IC₅₀ 0.88 μM and 0.85 μM respectively) while aspirin was a much weaker inhibitor (IC₅₀ 120 μM). , indomethacin was the most powerful inhibitor (ID₅₀ 0.034 mg/kg) followed by meclofenamic acid (0.45 mg/kg) and aspirin (2.35 mg/kg).Studies on the duration of inhibition by these compounds showed the effect of indomethacin and meclofenamic acid to be completely reversed within 4–6 hours. In contrast, return of kidney prostaglandin biosynthetic activity following aspirin inhibition is very slow and significant inhibition is still present 48 hours after a single aspirin injection. The inhibitory effect of aspirin could be blocked by pretreatment with indomethacin, indicating that both drugs interact with related sites on the cyclo-oxygenase enzyme. The irreversible inhibition of the cyclo-oxygenase by aspirin as demonstrated in studies of other investigators suggests that the return of kidney prostaglandin synthetase activity after aspirin inhibition represents synthesis of new cyclo-oxygenase protein.     

In Vivo Indomethacin Treatment Causes Microgial Activation in Adult Mice

The current study was undertaken to study the role of prostaglandins in regulating microglial activation. Mice were treated with indomethacin (2 g/ml) in their drinking water to selectively inhibit cyclooxygenase activity. After 4–8 days, the effect of inhibiting prostaglandin synthesis on microglial activity was evaluated. This was accomplished by analyzing microglial expression of Mac-1 (C3 complement receptor) as an indicator of activation. Mac-1 expression was assessed by immunohistochemistry of fixed brain cryosections, and by flow cytometric analysis of immunostained single cell suspensions. Both methods demonstrated that compared to age-matched, untreated controls, brains of indomethacin-treated mice had increased levels of Mac-1 expression, suggesting an increase in the state of microglial activation. These results demonstrate the importance of prostaglandins in down regulating microglial activity, and that inhibition of prostaglandin synthesis with indomethacin may act to increase the reactivity of the brain's immune system.     

Optimum time for administration of indomethacin to inhibit ovulation in the rabbit

The antiinflammatory agent, indomethacin, inhibits ovulation in mammals by interfering with the synthesis of prostaglandins in preovulatory follicles. To determine the optimum time to administer this inhibitor, indomethacin was given at specific intervals from 10 h before, and up to 9 h after, the ovulatory process had been initiated by hCG (50 I.U./kg). The drug dosage ranged from 1.25 mg/kg to 40 mg/kg. The optimum time to give indomethacin was at 7–8 h after hCG (i.e., 2–3 h before expected rupture of the follicle) at which time the minimum effective dose was 2.5 mg/kg. Since a significant elevation in prostaglandin synthesis occurs as early as 3–5 h after hCG stimulation of rabbit follicles (1), these results reveal that nonsteroidal antiinflammatory agents can interrupt the ovulatory process even the follicle has begun producing substantial amounts of prostaglandins. The data suggest that prostaglandins need to be produced continuouly in the follicle up to the time of actual rupture, or else that indomethacin is interfering with some other aspect of the ovulatory process which transpires after the elevation of prostaglandins.     

Salicylate nephropathy in the Gunn rat: Potential role of prostaglandins

We examined the potential role of prostaglandins in the development of analgesic nephropathy in the Gunn strain of rat. The homozygous Gunn rats have unconjugated hyperbilirubinemia due to the abscence of glucuronyl transferase, leading to marked bilirubin deposition in renal medulla and papilla. These rats are also highly susceptible to develop papillary necrosis with analgesic administration.We used homozygous (jj) and phenotypically normal heterozygous )jJ) animals. Four groups of rats (n = 7) were studied: jj and jJ rats treated either with aspirin 300 mg/kg every other day or sham-treated. After one week, slices of cortex, outer and inner medulla from one kidney wre incubated in buffer and prostaglandin synthesis was determined by radioimmunoassay. The other kidney was examined histologically.A marked corticomedullary gradient of prostaglandin synthesis was observed in all groups, PGE2 synthesis was significantly higher in outer medulla, but not cortex or inner medulla, of jj (38 ± 6 mg/mg prot) than jJ rats (15 ± 3) (p<0.01). Aspirin treatment reduced PGE2 synthesis in all regions, but outer medullary PGE2 remained higher in jj (18 ± 3) than jJ rats (9 ± 2) (p<0.05). PGE2α was also significantly higher in the outer medulla of jj rats with and without aspirin administration (p<0.05). The changes in renal prostaglandin synthesis were accompanied by evidence of renal damage in aspirin-treated jj but not jJ rats as evidenced by: increased incidence and severity of hematuria (p<0.01); increased serum creatinine (p<0.05); and increase in outer medullary histopathologic lesions (p<0.005 compared to either sham-treated jj or aspirin-treated jJ).These results suggest that enhanced protaglandin synthesis contributes to maintenance of renal function and morphological integrity, and that inhibition of protaglandin synthesis may lead to pathological renal medullary lesions and deterioration of renal function.     

Hormone studies inMyxine glutinosa: effects of the eicosanoids arachidonic acid,prostaglandin E1, E2, A2, F2α, thromboxane B2 and of indomethacin on plasma cortisol,blood pressure,urine flow and electrolyte balance

Summary Hagfish,Myxine glutinosa, were used in an investigation of the possible effects of various eicosanoids and the prostaglandin synthetase inhibitor indomethacin, on cortisol production, blood pressure control, urine flow and electrolyte balance.Cortisol levels in plasma of untreated control animals and plasma from animals 1 h following injection of 50 g kg^–1 prostaglandin E₁, E₂, A₂, F₂ TXB₂ and indomethacin were not detectable. However, plasma cortisol levels rose to between 10 and 26 pg ml^–1 1 h following injection of either 50 g kg^–1 arachidonic acid or prostaglandin E₂. This rise was similar in magnitude to that produced 1 h following administration of 50 g kg^–1 porcine ACTH.The resting dorsal aortic blood pressure of between 3.50 and 3.75 mmHg was reduced on average by 50% for 12–15 min when animals received 10 g kg^–1 arachidonic acid, prostaglandin E₁, E₂, A₂, and TXB₂ and was effectively reduced to zero for 20 min or more following 50 g kg^–1 of these eicosanoids. Similar doses of prostaglandin F₂, however, evoked an increase in blood pressure (19–33%) whilst indomethacin was without effect.Control measurements of urine flow inMyxine were estimated to be between 540 and 660 l h^–1 kg^–1. There was a marked reduction in urine output following the arterial vasodepression induced by arachidonic acid, prostaglandin E₁, E₂, A₂ and TXB₂ in doses of 10 g kg^–1, an effect which became even more pronouced following injection of 50 g kg^–1 quantities, leading in some cases to complete anuria. There was no significant change in urine volume following either the vasopressor action of prostaglandin F₂ or following indomethacin.None of the compounds tested in this study significantly influenced the plasma or urine electrolyte status ofMyxine.     

Inhibition of compensatory renal growth by indomethacin

Renal prostaglandins may be important in the modulation of compensatory renal growth. Reductions in renal mass are associated with increased synthesis of these substances by the remaining kidney, and inhibition of prostaglandin synthesis diminishes renal function in partially nephrectomized animals and in patients with reduced functioning renal mass. We examined the effects of uninephrectomy and treatment with indomethacin on renal prostaglandin E2 and 6-keto prostaglandin F1 alpha concentrations in adult male Sprague Dawley rats. The renal content of these prostaglandins was significantly increased in the remaining kidney two days following uninephrectomy (p less than 0.01). Treatment with 5 mg/kg/day of indomethacin over this period abolished the compensatory increase in renal prostaglandin synthesis and significantly attenuated compensatory increases in renal mass, protein and RNA concentrations (p less than 0.05). No alterations in kidney weight, protein or RNA concentrations were found in intact animals treated with the same dose of indomethacin. These findings suggest renal prostaglandins may participate in the biological events leading to compensatory renal growth.     

The effect of sodium intake on renal prostaglandin production

The effect of chronic alterations in dietary sodium intake on renal arachidonic acid (AA) metabolism was studied in male Wistar rats who were maintained for 14 days on a diet consisting of sodium-deficient food and either deionized water (low salt intake, LSI), 1% saline (normal salt intake, NSI), or 2% saline (high salt intake, HSI). 24 h Urinary Sodium (UNaV) and plasma renin activity (PRA) measurements were shown to validate the dietary protocol. Microsomal preparations from the cortices and medullae were incubated with radiolabeled exogenous AA, and endogenous urinary prostaglandin (PG) levels were assayed by RIA to quantify renal PG synthesis. Cortical PGF2 alpha and PGE2 synthesis was found to be the greatest following LSI. In contrast, medullary PGF2 alpha was shown to be the least following LSI and to increase with increased sodium intake. Likewise, urinary PGF2 alpha levels significantly increased with increasing sodium intake. Changes in urinary PGE2 levels showed the same trend as PGF2 alpha but did not achieve statistical significance. These data show that dietary sodium differentially affects renal cortical and medullary PG synthesis and may reflect physiological differences in the regulation of cyclooxygenase in these zones. These data further suggest that the major source of urinary PGs is the renal medulla since the relationship of urinary levels to sodium intake mimics that described for the synthesis of PGs by the medullary tissue.     

Urinary prostaglandin E excretion: Effect of chronic alterations in sodium intake and inhibition of prostaglandin synthesis in the rabbit

On the basis of acute experiments in animals, a role for prostaglandin E (PGE) in the regulation of urinary sodium excretion has been suggested. Limited information is available, however, concerning the possible role of PGE in chronic adjustments to sodium intake. These studies were designed to determine whether chronic changes in sodium balance would modify renal PGE excretion and whether partial inhibition of prostaglandin synthesis would after the ability of the kidney to adjust to an alteration in sodium intake. Thus, we measured sodium and PGE excretion in rabbits on chronic high and low salt diets before and after inhibition of prostaglandin synthesis with indomethacin or meclofenamate. Although the alterations in salt intake resulted in large changes in sodium excretion there was no significant change in urinary PGE excretion. After administration of either indomethacin or meclofenamate for several days there was a significant fall in PGE excretion, but no significant change in sodium excretion. These results suggest that in the rabbit 1) chronic changes in sodium excretion can occur without modifying PGE excretion (and presumably renal PGE synthesis) and 2) inhibition of PGE synthesis does not impair the kidney's ability to adjust to a chronic high or low sodium intake.     

Mechanism of increased renal prostaglandin E2 in uranyl nitrate-induced acute renal failure

We have previously demonstrated that decreased cortical prostaglandin metabolism can contribute significantly to an increase in renal tissue levels and activity of prostaglandin E2 in bilateral ureteral obstruction, a model of acute renal failure. In the present study, we have further investigated whether alterations in prostaglandin metabolism can occur in a nephrotoxic model of acute renal failure. Prostaglandin synthesis, prostaglandin E2 metabolism (measured as both prostaglandin E2-9-ketoreductase and prostaglandin E2-15-hydroxydehydrogenase activity), and tissue concentration of prostaglandin E2 were determined in rabbit kidneys following an intravenous administration of uranyl nitrate (5 mg/kg). No changes in the rates of cortical microsomal prostaglandin E2 and prostaglandin F2 alpha synthesis were noted at the end of 1 and 3 days, while medullary synthesis of prostaglandin E2 fell by 47% after 1 day and 43% after 3 days. Cortical cytosolic prostaglandin E2-9-ketoreductase activity was found to be decreased by 36% and 76% after 1 and 3 days respectively. No significant changes were noted in cortical cytosolic prostaglandin E2-15-hydroxydehydrogenase activity after 3 days. Cortical tissue levels of prostaglandin E2 increased by 500% at the end of 3 days. These data demonstrate that in nephrotoxic acute renal failure, decreased prostaglandin metabolism (i.e., prostaglandin E2-9-ketoreductase activity) can result in increased tissue levels of prostaglandin E2 in the absence of increased prostaglandin synthesis and suggest that alterations in prostaglandin metabolism may be an important regulator of prostaglandin activity in acute renal failure.     

Renal sodium handling and stimulation of medullary Na-K-ATPase during blockade of prostaglandin synthesis

The effect of suppression of prostaglandin synthesis on renal sodium handling and microsomal Na-K ATPase was studied in control and indomethacin treated intact rats maintained on a normal sodium diet (series A) and chronically salt loaded (series B). Indomethacin administration resulted in a decreased GFR and a significantly depressed urinary excretion and an increased fractional reabsorption of sodium in animals fed the normal sodium diet or chronically salt loaded. In rats maintained on a normal Na diet, the activity of the renal medullary Na-K ATPase after indomethacin was 206.3 +/- 6.4 ug Pi/mg protein, i.e. significantly higher as compared with the enzyme activity in the medullary renal fraction from control animals in which it averaged 148 +/- 7.79 ug Pi/mg protein (p less than 0.001). While after chronic salt load a similar increment in the activity of renal medullary Na-K ATPase was observed, no additional stimulation was elicited by subsequent indomethacin administration. The addition of exogenous PGE2, 0.1 mM to microsomal fractions obtained from kidneys of normal rats, was associated with a moderate suppression of the medullary Na-K-ATPase activity, from a basal level of 170 +/- 16 to 151.3 +/- 13 umol Pi/mg protein/hr (p less than 0.005). In isolated segments of medullary thick ascending limb of Henle's loop (MTAL) addition of PGE2 to the incubation medium resulted in a significant inhibition of Na-K ATPase from 37.2 +/- 2 to 21.25 +/- 1.17 x 10(-11) mol/mm/min (p less than 0.0001). These findings suggest that the increased renal Na reabsorption after inhibition of PG synthesis might be related, at least partly, to stimulation of medullary Na-K ATPase. In parallel, the reported natriuretic effect of prostaglandins might imply a direct inhibitory effect of these mediators on renal Na-K ATPase.     

Changes in systolic arterial blood pressure in normal and spontaneously hypertensive rats produced by acute administration of inhibitors of prostaglandin biosynthesis

Six non-steroidal agents having the property of being able to inhibit prostaglandin (PG) biosynthesis or action were tested for their ability to affect systolic blood pressure in unanesthetized normotensive (WKY) and Spontaneously Hypertensive Rats (SHR). In WKY and pre-hypertensive young SHR, s.c. injection of indomethacin (1.0 mg/kg) had no significant effect on blood pressure measured 30 minutes after injection. In older SHR, indomethacin (15 mg/kg) caused a significant pressor response, while in age - matched WKY, this dose had no significant effect. Indomethacin also showed a prohypertensive action in 10–14, 23–38 and 23–27 week old SHR with doses of 1.0 and 3.0 mg/kg, respectively. Tiaramide (5 mg/kg), ETYA (5 mg/kg), tolmetin (25 mg/kg), and meclofanamate (15 mg/kg) caused a significant elevation of blood pressure in mature (7–8 month old) SHR. Age matched WKY showed no significant response to the same doses of these four agents. Fenoprofen (75 mg/kg) caused a significant elevation in pressure in 12–13 week old SHR which persisted for at least 2 hours. Tiaramide had no significant effect on pre-hypertensive SHR. The results are consistent with the concept that inhibition of prostaglandin synthesis may result in a diminished turnover of antihypertensive prostaglandins in SHR which are being elaborated in response to the hypertensive state. In normal rats and pre-hypertensive SHR, inhibition of prostaglandin synthesis or function may not result in a hypertensive response since pro-hypertensive factors either are absent, or other antihypertensive substances may still predominate to help maintain normal blood pressure.