Quinacrine antagonizes the effects of Na,K-ATPase inhibitors on renal prostaglandin E2 release but not their effects on renin secretion

Previous results have demonstrated that two inhibitors of Na-and-K-activated adenosine triphosphatase (ouabain, vanadate) lead to stimulated prostaglandin E2 release and to inhibited renin secretion in the rat renal cortical slice preparation. It was speculated that stimulation of phospholipase A2 activity accounted for the effect on prostaglandin E2 release. We used the same preparation in the present experiments, and showed that another inhibitor of Na-and-K-activated adenosine triphosphatase (K-free incubation medium) stimulates prostaglandin E2 release and inhibits renin secretion. Quinacrine antagonized the stimulatory effects of ouabain, vanadate, and K-free medium on prostaglandin E2 release (consistent with phospholipase A2 involvement), but did not antagonize their inhibitory effects on renin secretion. Collectively, these observations lend further weight to the argument against a mediatory role of prostaglandin synthesis in the renin secretory process.     

Effect of diltiazem, a calcium antagonist, on renin secretion from rat kidney slices

The purpose of these experiments was to characterize the effects of diltiazem on renin secretion from rat renal cortical slices. Incubation of slices in 60 versus 4 mM K medium almost completely abolished renin secretion. Diltiazem antagonized the inhibitory effect in a concentration-dependent manner but had no effect on secretion of slices incubated in 4 mM K medium. Lowering extracellular Ca enhanced the efficacy of diltiazem. These observations demonstrate that Ca influx through voltage-sensitive Ca channels mediates the inhibitory effect of depolarization and further demonstrate that such channels are not open in the basal state of this preparation. In the presence of a concentration of diltiazem which blocked the inhibitory effects of depolarization, both angiotensin II and antidiuretic hormone (ADH) still inhibited secretion. Therefore, both these peptides inhibit secretion by mechanisms which are independent of the voltage-sensitive Ca channels. These observations confirm and extend previous observations suggesting that Ca plays an inhibitory coupling role in the control of renin secretion.     

Calcium and renin release: inhibition of low sodium-induced renin secretion by high calcium concentration in rat kidney perfusion

The effects of changes in calcium on renin secretion have been studied in the isolated perfused rat kidney. Perfusion with free calcium buffer significantly decreases renin secretion as compared with control experiments (Ca++: 2.5 mM/l). Other calcium concentrations (1.25 mM/l) and 5 mM/l) do not affect basal renin secretion. When the renin release is previously increased by low sodium concentration (Na+: 110 mM/l) however, perfusion with high calcium buffer (Ca++: 5 mM/l) significantly inhibits this stimulation.     

Does decreasing extracellular Na inhibit in vitro renin secretion by affecting NaCa exchange?

It has been shown previously that in vitro renin secretion is inhibited by partial replacement of extracellular NaCl with either mannitol or choline chloride; the inhibitory effect is attributed to an increase in intracellular Ca, resulting from a decreased rate of Ca efflux via Na-Ca exchange. In the present experiments, we confirmed that partially replacing NaCl with choline chloride inhibited renin secretion from rat renal cortical slices, but we found that atropine completely blocked the effect, suggesting cholinergic mediation. Partially replacing NaCl with mannitol also inhibited renin secretion, but the effect could not be attributed specifically to a reduction in extracellular Na. Moreover, the stimulatory effect of Ca chelation on renin secretion was antagonized by either mannitol- or choline chloride -containing incubation media. These results do not support the hypothesis that lowering extracellular Na inhibits renin secretion by a mechanism involving decreased Ca efflux via Na-Ca exchange.     

Effect of captopril on renal vascular resistance, renin, prostaglandins and kinin in the isolated perfused kidney

Vasodilatory and natriuretic effects of captopril were studied in the isolated hog kidney perfused with modified Krebs-Ringer solution. Renal arterial infusion of captopril caused increases in releases of renin, prostaglandins (PGE2, 6-keto-PGF1 alpha and PGF2 alpha) and kinin, and was accompanied by a decrease in the renal vascular resistance and an increase in urinary sodium excretion. Indomethacin administered with captopril diminished the saluretic effect of captopril and evoked an increase in kinin, but was associated with a marked decrease in prostaglandin and renin releases, while renal vascular resistance remained decreased. Indomethacin alone did not alter vascular resistance and kinin; however, renin and prostaglandin releases were decreased. Aprotinin administered with captopril showed a decrease in releases of prostaglandins, renin and kinin without any change in vascular resistance. These results suggest that increased release of kinin induced by captopril contributes to a reduction in renal vascular resistance. Increased prostaglandin release after captopril administration may be caused by an increase in kinin without direct involvement of captopril in prostaglandin synthesis. Renal prostaglandins may enhance sodium excretion and mediate renin secretion in captopril perfusion.     

Functional compartmentalization of arginine-vasopressin-activated cyclic AMP in anterior pituitary gland: the presence of a compartment activated by prostaglandin E2

AVP(10(-8)-10(-6)M) increased ACTH as well as PGE2 release from rat anterior pituitary quarters in vitro in a concentration dependent manner. IBMX (0.1 mM), a phosphodiesterase inhibitor, increased the ACTH response to AVP. The cAMP content in pituitary tissue was increased by AVP. Cyclooxygenase inhibition by indomethacin(1.4 X 10(-5) M) or diclofenac (1.8 X 10(-5)M) led to a potentiation of AVP-evoked ACTH secretion and to a decrease in AVP-stimulated cAMP formation. PGE2(10(-6)M) significantly increased pituitary cAMP content and indomethacin did not affect cAMP levels activated by PGE2. PGE2 attenuated the AVP-induced ACTH release. These results indicate that at least two functional compartments of AVP-activated cAMP responses are involved in the AVP-induced ACTH release. One compartment is directly activated by AVP and participates in the propagation of AVP-induced ACTH release. The second compartment is activated by PGE2. The contribution of the second compartment to the regulation of ACTH secretion is not well understood since PGE2 shows an inhibitory effect on AVP-induced ACTH secretion.     

Prostaglandin biosynthesis does not participate in isoproterenol-induced renin release

Rat renal slices were incubated in two different media. One was a normal K, physiological saline solution and the other a high K medium. Renin release was measured every 15 min in the presence and absence of 10(-6) M isoproterenol and also in the presence and absence of aspirin, 0.8 or 1.6 X 10(-5) M. In all experiments renin release was linear during the 75 min of incubation. Isoproterenol increased renin release by approximately 100%. This was the case even in the presence of aspirin which significantly inhibited prostaglandin release (PGE2, PGF2 alpha and 6-keto-PGF1 alpha). Nor was there any reduction in the basal secretory rate by aspirin alone. These data are taken to indicate that aspirin in pharmacological doses does not interfere with either in vitro basal release rates of renin, nor the response to B agonists. It is also suggested that B agonists do not exert their effect by stimulating prostaglandin secretion.     

Vanadate-induced inhibition of renin secretion is unrelated to inhibition Na,K-ATPase activity

There is evidence that three inhibitors of Na,K-ATPase activity--ouabain, K-free extracellular fluid, and vanadate--inhibit renin secretion by increasing Ca2+ concentration in juxtaglomerular cells, but in the case of vanadate, it is uncertain whether the increase in Ca2+ is due to a decrease in Ca2+ efflux (inhibition of Ca-ATPase activity, or inhibition of Na,K-ATPase activity, followed by an increase in intracellular Na+ and a decrease in Na-Ca exchange) or to an increase in Ca2+ influx through potential operated Ca channels (inhibition of electrogenic Na,K transport, followed by membrane depolarization and activation of Ca channels). In the present experiments, the rat renal cortical slice preparation was used to compare and contrast the effects of ouabain, of K-free fluid, and of vanadate on renin secretion, in the absence and presence of methoxyverapamil, a Ca channel blocker. Basal renin secretory rate averaged 7.7 +/- 0.3 GU/g/60 min, and secretory rate was reduced to nearly zero by 1 mM ouabain, by K-free fluid, by 0.5 mM vanadate, and by K-depolarization (increasing extracellular K+ to 60 mM). Although 0.5 microM methoxyverapamil completely blocked the inhibitory effect of K-depolarization, it failed to antagonize the inhibitory effects of ouabain, of K-free fluid, and of vanadate. A concentration of methoxyverapamil two hundred times higher (100 microM) completely blocked the inhibitory effects of vanadate, but still failed to antagonize the effects of ouabain and of K-free fluid. Collectively, these observations demonstrate that vanadate-induced inhibition of renin secretion cannot be attributed entirely to Na,K-ATPase inhibition, since in the presence of methoxyverapamil, the effect of vanadate differed from the effects of either ouabain (a specific Na,K-ATPase inhibitor) or K-free fluid. Moreover, it cannot be attributed entirely to a depolarization-induced influx of Ca2+ through potential-operated Ca channels, since methoxyverapamil antagonized K-depolarization-induced inhibition of renin secretion much more effectively than it antagonized vanadate-induced inhibition.     

Opiate-prostaglandin interactions in the regulation of insulin secretion from rat islets of Langerhans in vitro

The inadequate insulin secretory response to glucose stimulation in non-insulin dependent diabetes has been attributed to many factors including high PGE2 levels blunting the secretory response, and to the existence of inhibitory opiate activity in vivo. The purpose of the present work was to see if there was a connection between these two independent theories. Radioimmunoassayable PGE2 in islets of Langerhans was found to be proportional to islet number and protein content and was typically 4 to 5pg/micrograms islet protein. Indomethacin (2.8 X 10(-5) M), sodium salicylate (1.25 X 10(-3) M) and chlorpropamide (7.2 X 10(-5) M) all lowered islet PGE2 levels and stimulated insulin release in vitro. Dynorphin (1-13), stimulated insulin release at a concentration of 6 X 10(-9) M, while lowering islet PGE2. Conversely, at a higher concentration, (6 X 10(-7) M), dynorphin had no stimulatory effect on insulin secretion and did not lower PGE2 levels in islets or in the incubation media. The stimulatory effects of dynorphin and sodium salicylate on insulin secretion were blocked by exogenous PGE2 (10(-5) M). PGE2 at a lower concentration (10(-9) M) did not exert any inhibitory effect on dynorphin- or sodium salicylate-induced insulin release. This concentration of exogenous PGE2 stimulated insulin release in the presence of 6mM glucose. Results from these experiments suggest that since an opioid peptide can lower endogenous PGE2 production in islets and since the stimulatory effects of the opioid peptide are reversed by exogenous PGE2 there may be interactions between these two modulators of insulin secretion.     

Inhibition of in vitro renin release by low extracellular K

Renin release from rat renal cortical slices was measured as a function of the concentration of K in the incubation medium. Release was completely abolished within a 30-minute period of exposure to nominally K-free or to 1.0 mM K media. Release tended to increase with increasing K, over the range 2 – 6 mM, although release was near maximal at 2.0 mM K. Omission of Ca from the incubation medium prevented the full inhibitory effect of nominally K-free medium. It is suggested that Ca accumulation, perhaps via Na-Ca exchange, is required to produce the inhibitory effect of low K medium on renin release in vitro.     

Direct inhibitory effect of atriopeptin III on renin release in primate kidney

Patterns of in vitro renal renin release and the ability of atriopeptin to directly inhibit renin release have been examined in the rat, rabbit, and dog, but have been unstudied in the primate kidney. Accordingly, we examined renin release from superficial renal cortical slices of the squirrel monkey (Samiri sciuresus). The average age of the 5 animals was 10.2 +/- 2.5 yr at the time of study. Renin release was stimulated significantly by the beta-adrenergic agonist isoproterenol in concentrations of 10(-5) M (1.67-fold) and 10(-4) M (1.84-fold). Isoproterenol-induced renin release was inhibited by atriopeptin III (ANP, 2 X 10(-8) M) and the adenylate cyclase inhibitor dideoxadenosine (DDA, 10(-5) M). Similarly, the incubation of the superficial cortical slices with arachidonic acid (10(-3) M) resulted in a 4-fold increase in tissue renin release which was blocked by the calcium ionophore A23187 (17 X 10(-6) M) and ANP; interestingly, DDA did not block arachidonic acid-induced renin release. These results suggest that ANP exerts a direct inhibitory effect on B-adrenergic and arachidonic acid-induced renin release in the primate kidney. Further, the inhibitory action of A23187 on renin release suggests, as in other species, an integral role for intracellular calcium in the renin release process. These patterns of renin release in primate kidney are similar to those observed in the rodent kidney in vitro.     

Calcium-dependent inhibition of renin secretion: TMB-8 is a non-specific antagonist

Intracellular Ca (Cai) is an inhibitory second messenger in renin secretion, and it has been hypothesized that some first messengers--especially angiotensin II [A-II] and antidiuretic hormone [ADH], and possibly A1-adenosine receptor antagonists as well--increase Cai and thereby inhibit renin secretion by causing the release or mobilization of Ca from intracellular sites of sequestration. The present experiments were designed to test this hypothesis, by using 3,4,5-trimethoxybenzoic acid 8-(diethylamino)-octyl ester (TMB-8), a putative antagonist of Ca release from intracellular sequestration sites. The rat renal cortical slices preparation was used. Basal renin secretory rate was unaffected by 1 and 10 microM TMB-8, but more than doubled in response to 100 microM TMB-8. Basal renin secretory rate was inhibited by A-II (1 microM), by ADH (200 units/1), by an A1-adenosine receptor agonist (N6-cyclohexyladenosine, or CHA; 0.5 microM), and by an alpha-adrenergic agonist (methoxamine; 10 microM). Only the inhibitory effect of methoxamine was blocked by 1 and 10 microM TMB-8, but these concentrations had no effect on basal secretory rate. At 100 microM, TMB-8 blocked the inhibitory effects of ADH as well as of methoxamine, but failed to block the inhibitory effects of CHA and A-II. However, these observations cannot be taken as evidence that methoxamine and ADH, but not CHA and A-II, inhibit renin secretion by a mechanism involving release of Ca from intracellular sequestration sites, because 100 microM TMB-8 clearly had non-specific effects. Among them, it completely blocked the inhibitory effect of K-depolarization on renin secretion. Collectively, at least three separate actions of TMB-8 must be invoked to explain the present results. Likely candidates are an Na-channel blocking effect and a Ca channel blocking effect in addition to antagonism of the release of Cai.     

Inhibition of gastric acid secretion in rat stomach by PACAP is mediated by secretin, somatostatin, and PGE(2)

Pituitary adenylate cyclase-activating polypeptide (PACAP), existing in two variants, PACAP-27 and PACAP-38, is found in the enteric nervous system and regulates function of the digestive system. However, the regulatory mechanism of PACAP on gastric acid secretion has not been well elucidated. We investigated the inhibitory action of PACAP-27 on acid secretion and its mechanism in isolated vascularly perfused rat stomach. PACAP-27 in four graded doses (5, 10, 20, and 50 microg/h) was vascularly infused to determine its effect on basal and pentagastrin (50 ng/h)-stimulated acid secretion. To study the inhibitory mechanism of PACAP-27 on acid secretion, a rabbit antisecretin serum, antisomatostatin serum, or indomethacin was administered. Concentrations of secretin, somatostatin, PGE(2), and histamine in portal venous effluent were measured by RIA. PACAP-27 dose-dependently inhibited both basal and pentagastrin-stimulated acid secretion. PACAP-27 at 10 microg/h significantly increased concentrations of secretin, somatostatin, and PGE(2) in basal or pentagastrin-stimulated state. The inhibitory effect of PACAP-27 on pentagastrin-stimulated acid secretion was reversed 33% by an antisecretin serum, 80.0% by an antisomatostatin serum, and 46.1% by indomethacin. The antisecretin serum partially reduced PACAP-27-induced local release of somatostatin and PGE(2). PACAP-27 at 10 microg/h elevated histamine level in portal venous effluent, which was further increased by antisomatostatin serum. However, antisomatostatin serum did not significantly increase acid secretion. It is concluded that PACAP-27 inhibits both basal and pentagastrin-stimulated gastric acid secretion. The effect of PACAP-27 is mediated by local release of secretin, somatostatin, and PGE(2) in isolated perfused rat stomach. The increase in somatostatin and PGE(2) levels in portal venous effluent is, in part, attributable to local action of the endogenous secretin.     

Binding of prostaglandin E2 to cultured bovine adrenal chromaffin cells and its effect on catecholamine secretion

We have previously shown that plasma membranes from adrenal medulla possess specific high-affinity binding sites for prostaglandins (PGs) E1 and E2. We have now investigated the binding of PGE2 to intact bovine adrenal chromaffin cells and the effects of prostaglandins on the release of catecholamines from these cells. Adrenal chromaffin cells specifically bound PGE2 with a dissociation constant of 2 nM and a concentration of about 40,000 binding sites per cell. Low concentrations of PGE2 inhibited the nicotine-stimulated release of catecholamines from these cells. The effect of PGE2 was biphasic, the maximal inhibitory effect being observed at a concentration of between 1 and 10 nM. Higher concentrations (1 microM) of PGE2 had minimal inhibitory effects on nicotine-evoked noradrenaline release, but instead had a direct stimulatory effect in the absence of cholinergic agonists. Although the stimulatory effects of high concentrations of PGE2 were reproducibly observed in all cell preparations, only about one-half of the cultures tested responded to the inhibitory effects of this prostaglandin. It is possible that PGE2 plays a modulatory role in the regulation of catecholamine secretion from the adrenal medulla.     

Comparison of the effects of NaCl and KCl at the roots on seedling growth,cell death and the size,frequency and secretion rate of salt glands in leaves of <Emphasis Type="Italic">Limonium sinense</Emphasis>

Twenty days’ exposure to 50 or 100 mM NaCl in the rooting medium substantially increased fresh and dry weights of seedling shoots of the recretohalophyte Limonium sinense while 200 or 300 mM were increasingly inhibitory. KCl treatment was only slightly stimulating (50 mM) or strongly inhibitory (100–300 mM). Lesser effects on leaf area were also seen. Diameter of foliar salt glands was significantly larger than that of controls in 100 and 200 mM NaCl with the effect being reversed at higher concentrations. Gland enlargement was also observed in the presence of 100 mM KCl, while larger concentrations reduced gland size. Generally, gland diameter was larger in the presence of NaCl than in KCl. NaCl and KCl also increased gland number per leaf and secretion rate per gland. At 100 and 200 mM NaCl or KCl, Na⁺ secretion per leaf from NaCl-treated plants exceeded K⁺ secretion rate from KCl-treated plants while at 200 mM, Na⁺ secretion per gland was significantly higher for Na⁺ than for K⁺. Evidence of cell death in leaves of salt-treated plants using Evans blue staining indicates that release of cell contents through loss of membrane integrity contributed to the secretion values. We conclude that the greater tolerance of L. sinenseto to NaCl compared to KCl is linked to the more effective secretion of Na⁺ than of K⁺ and, in turn, to a greater stimulation of salt gland formation and activity and larger gland diameter.     

Dantrolene stimulates renin secretion by rat renal cortical slices but fails to block calcium-dependent inhibition.

Calcium (Ca) is an inhibitory second messenger in renin secretion, and it has been proposed that some first messengers, such as angiotensin II (A-II), antidiuretic hormone (ADH), and N6-cyclohexyladenosine (CHA), increase Ca and thereby inhibit renin secretion by mobilizing Ca from intracellular sequestration sites. The present experiments were designed to test this proposal by using dantrolene, an antagonist of intracellular Ca mobilization. Dantrolene stimulated renin secretion by rat renal cortical slices in a concentration dependent manner; at 0.0, 0.1, and 0.5 mM dantrolene, secretory rates were 8.1 +/- 0.6, 9.4 +/- 0.6 (p less than 0.05), and 14.9 +/- 1.2 (p less than 0.0001) GU/g x hr, respectively. These results could be interpreted to mean that Ca mobilization is occurring at a finite rate during the basal state, and that by antagonizing this process, dantrolene lowers intracellular Ca and thereby stimulates renin secretion. However, 0.1 mM dantrolene failed to antagonize the inhibitory effects on renin secretion of A-II, ADH, and CHA, and only CHA-induced inhibition of renin secretion was antagonized by 0.5 mM dantrolene. We conclude that if A-II, ADH, and CHA inhibit renin secretion by mobilizing Ca from an intracellular storage site, then the site is insensitive to dantrolene.     

Effect of sodium and osmolarity on renin secretion.

The effect of changes in sodium and osmolarity on renin secretion has been studied in the isolated perfused rat kidney. Perfusion with low sodium buffer (110 mM/l) produced a significant increase in renin secretion compared with control experiments (Na+:135 mM/l). Since the presence of tubules seems necessary for such an effect to take place, it suggests that the high renin secretion stimulated by a low sodium buffer centers in the Macula densa. Perfusion with high sodium buffer (170 mM/l; osmolarity 350 mOs/l) induces a stimulation on renin release. However, a greater rise in renin is achieved in control experiments if choline chloride increases the osmolarity from 300 to 350 mOs/l. All this suggests that high sodium buffer, independently of its osmotic effect, has an inhibitory role on renin release.     

Effects of atrial natriuretic factor on blood pressure and the renin-angiotensin-aldosterone system

Atrial natriuretic factor (ANF) antagonizes vasoconstriction induced by numerous smooth muscle agonists and also lowers blood pressure in intact animals. ANF has particularly marked relaxant effects on angiotensin II-contracted vessels in vitro. Sensitivity to the blood pressure-lowering effect of ANF in vivo appears to be enhanced in renin-dependent models of renovascular hypertension compared with other experimental hypertensive models. The depressor action of low, possibly physiological doses of ANF in two-kidney, one-clip Goldblatt rats is due to a decrease in total peripheral resistance. On the other hand, high doses of ANF can lower cardiac output, particularly in volume-expanded models such as deoxycorticosterone-salt hypertension. ANF markedly inhibits renin secretion in intact animals, probably via increased glomerular filtration rate and load of sodium chloride to the macula densa. This effect is masked when renal perfusion is impaired (e.g., via unilateral renal artery constriction), in which case ANF may stimulate renin secretion slightly. ANF also reduces plasma aldosterone in vivo and inhibits basal and agonist-induced aldosterone release from isolated adrenal cortical cells. This effect appears to be especially marked for angiotensin-induced aldosterone production in vivo and in vitro. These findings indicate that ANF has potentially important interactions with the renin-angiotensin-aldosterone system and suggest a role for ANF in the homeostatic control of blood pressure as well as of extracellular fluid volume.     

Sodium Fluoride Mimics the Effect of Prostaglandin E2 on Catecholamine Release from Bovine Adrenal Chromaffin Cells

We have reported recently that prostaglandin E2 (PGE2) stimulated phosphoinositide metabolism in bovine adrenal chromaffin cells and that PGE2 and ouabain, an inhibitor of Na+, K(+)-ATPase, synergistically induced a gradual secretion of catecholamines from the cells. Here we examined the involvement of a GTP-binding protein(s) in PGE receptor-induced responses by using NaF. In the presence of Ca2+ in the medium, NaF stimulated the formation of all three inositol phosphates, i.e., inositol monophosphate, bisphosphate, and trisphosphate, linearly over 30 min in a dose-dependent manner (15-30 mM). This effect on phosphoinositide metabolism was accompanied by an increase in cytosolic free Ca2+. NaF also induced catecholamine release from chromaffin cells, and the dependency of stimulation of the release on NaF concentration was well correlated with those of NaF-enhanced inositol phosphate formation and increase in cytosolic free Ca2+. Although the effect of NaF on PGE2-induced catecholamine release in the presence of ouabain was additive at concentrations below 20 mM, there was no additive effect at 25 mM NaF. Furthermore, the time course of catecholamine release stimulated by 20 mM NaF in the presence of ouabain was quite similar to that by 1 microM PGE2, and both stimulations were markedly inhibited by amiloride, with half-maximal inhibition at 10 microM. Pretreatment of the cells with pertussis toxin did not prevent, but rather enhanced, PGE2-induced catecholamine release over the range of concentrations examined. These results demonstrate that NaF mimics the effect of PGE2 on catecholamine release from chromaffin cells and suggest that PGE2-evoked catecholamine release may be mediated by the stimulation of phosphoinositide metabolism through a putative GTP-binding protein insensitive to pertussis toxin.     

Prostaglandins and renin release: I. Stimulation of renin release from rabbit renal cortical slices by PGI2.

Prostaglandins have been shown to be involved in the mechanism of renin secretion in a variety of situations. Both arachidonic acid and prostaglandin endoperoxide have been shown to release renin from cortical slices and to be converted to PGI2 by cortical microsomes. In the present studies PGI2 was found to cause a time dependent increase in renin release from rabbit renal cortical slices, a system isolated from any indirect effects that result from the administration of prostaglandins in vivo. The stimulation was linear up to 30 minutes and effective over a range of concentrations from 10(7 M to 10(-5) M. At similar concentrations 6-keto-prostaglandin F1alpha was not active on these slices. Thus, it is proposed that PGI2 exerts a direct effect on the release of renin from cortical cells and may be the mediator of arachidonate or prostaglandin endoperoxide stimulated renin secretion.