Effects of hypothalamic microinjection of PGE2 on body temperature and sympathetic nervous activities in the rabbit

The febrile response and sympathetic nervous response to hypothalamic microinjections of prostaglandin E₂ (PGE₂) were investigated in anesthetized rabbits. Microninjection of PGE₂ (500–1000 ng) caused an increase in rectal temperature of more than 0.3°C in 13 of 50 loci in the preoptic and anterior hypothalamic area (PO/AH). At 8 of these 13 loci, PGE₂ elicited response patterns in the sympathetic nervous system, such as an increase in cutaneous sympathetic nervous activity and decrease in renal sympathetic nervous activity. This pattern of sympathetic nervous responses was induced with a simultaneous increase in rectal temperature of more than 0.5°C. The 8 loci were distributed in the preoptic area, especially in the vicinity of the supraoptic nucleus. Electrolytic lesions of this region were made bilaterally, and intracerebroventricular injection of PGE₂ (8 µg/kg) was found to inhibit fever and sympathetic activity. The results demonstrate that the action of PGE₂ is responsible for the response patterns of sympathetic twigs during fever. The preoptic area, especially in the vicinity of the supraoptic nucleus, is most sensitive to PGE₂ for the patternized response of sympathetic neurons and fever.     

Localization of exaggerated prostaglandin synthesis associated with renal damage

Regional localization of the exaggerated prostaglandin E₂ (PGE₂) synthesis caused by hydronephrosis was studied in unilateral ureteral ligated rabbits. The renal distribution of PGE₂ production was compared in the hydronephrotic and contralateral kidneys. Basal and bradykinin-stimulated PGE₂ synthesis were increased in cortical and medullary slices of the hydronephrotic kidneys. Contralateral (control) cortical slices produced very low levels of PGE₂ and were insensitive to stimulation by bradykinin (BK). The hydronephrotic cortex produced 10 times more PGE₂ than the contralateral cortex and responded to BK stimulation with increased PGE₂ synthesis. Cortical slices from the hydronephrotic kidney exhibited a time-dependent increase in PGE₂ release, presumably as a result of new protein synthesis. The division of the hydronephrotic cortex into outer and inner regions revealed that the inner cortex produced more PGE₂ than the outer cortex. A similar division of the hydronephrotic medulla showed that the inner medulla produced slightly greater amounts of PGE₂ than the outer medulla. The present study demonstrates that hydronephrosis causes increases in prostaglandin synthesis throughout the kidney. We suggest from these results and other studies that a possible explanation for this finding is the involvement of the collecting duct system in this response. The gradient of PGE₂ production detected in the cortex may have a very significant role in the control of renal hemodynamics and could provide an explanation for the large decrease in blood flow to the inner cortex caused by indomethacin treatment.     

Characterisation of the prostanoid receptors mediating contraction of guinea-pig isolated trachea

The receptors mediating prostanoid-induced contraction of guinea-pig isolated trachea have been characterised in terms of a recently proposed general classification of prostanoid receptors. Results obtained on the trachea were compared with those obtained on guinea-pig fundus, which contains a sub-type of PGE₂-sensitive (EP-) receptor termed the EP₁-receptor, and guinea-pig lung strip, which contains a thromboxane-sensitive or TP-receptor. The following agonists were studied, PGE₂, PGF₂α and the thromboxane-like agonists U-46619 and Wy17186. The antagonists studied were SC-19220 which selectivity blocks EP₁-receptors, and AH19437 which selectively blocks TP-receptors. On guinea-pig fundus the rank order of agonist potency was PGE₂ > PGF₂α > Wy17186 U-46619, and responses to all agonists were antagonised by SC-19220 but not by AH19437. On guinea-pig lung strip the rank order of potency was U-46619 > Wy17186 PGF₂α > PGE₂ and responses to all agonists tested were blocked by AH19437 but not by SC-19220. On the trachea, the rank order was PGE₂ = U-46619 > Wy17186 = PGF₂α. SC-19220 antagonised responses to PGE₂ and PGF₂α, but not those to U-46619 or Wy17186. Conversely, AH19437 antagonised responses to U-46619 and Wy17186 but not those to PGE₂ or PGF₂α. It is concluded that prostanoid-induced contractions of guinea-pig trachea can be mediated by both EP₁- and TP-receptors.     

Effects of prostaglandin E1, I2 and isoproterenol on the tissue cyclic AMP content in longitudinal muscle of rabbit intestine

Effects of prostaglandin E₁(PGE₁) and prostaglandin I₂(PGI₂) on the mechanical activity and tissue cyclic AMP content of the longitudinal muscle of rabbit intestine were examined, comparing that of isoproterenol. PGE₁ or PGI₂ caused a contraction and did not affect the tissue cyclic AMP content. Isoproterenol caused a relaxation and increasedtissue cyclic AMP content.     

Action of luteinizing hormone-releasing hormone and synthesis of prostaglandin in the pituitary gland

The possibility that prostaglandin E₂ (PGE₂) may play a role in luteinizing hormone (LH) release was examined using an model. Addition of luteinizing hormone-releasing hormone (LH-RH) to the culture medium stimulated cyclic AMP accumulation and LH-release by incubated hemipituitaries, but did not affect the level of PGE₂ or prostaglandin synthetase activity in the gland. Aspirin and indomethacin reduced both prostaglandin synthetase activity and PGE₂ content in the pituitary, but did not impair the stimulatory action of LH-RH on either cyclic AMP accumulation or LH-release. Flufenamic acid on its own caused LH-release, but the drug abolished the effect of LH-RH on cyclic AMP accumulation. The mechanism of this action of flufenamic acid is not understood.It is concluded that the stimulatory action of LH-RH on pituitary cyclic AMP production and LH release is not mediated by prostaglandins.     

Effects of prostaglandin E2, 16,16-dimethyl prostaglandin E2 and a prostaglandin endoperoxide analogue (U-46619) on gastric secretory volume, [H] and mucus synthesis and secretion in the rat

The effects of orally administered prostaglandin E₂, 16,16-dimethyl prostaglandin E₂ and U-46619, an analogue of the prostaglandin endoperoxide PGH₂, on gastric secretory volume, acid and mucus were studied in the rat. All of the compounds significantly increased the volume of gastric secretion, mucus secretion, measured as N-acetylneuraminic acid and mucus synthesis measured as the incorporation of [³H]-glucosamine into mucosal glycoprotein; however, only PGE₂ and 16,16-dimethyl PGE₂ inhibited acid secretion. U-46619, 1.5 mg/kg provided significant protection against ethanol-induced gastric ulcers, an effect that has been previously shown for the other two compounds. These studies provide additional evidence that prostaglandin induced mucosal protection may by related to an effect on mucus and on stimulation of nonparietal cell gastric secretion. Further study of these parameters may be important in the development of antiulcer drugs for long term clinical use.     

Prostaglandin Biosynthesis from Endogenous Precursors in Rabbit Kidney

THIS report describes the biosynthesis of the naturally occurring renal prostaglandins E₂ (PGE₂) and F_2α (PGF_2α)^1,2 by homogenates and slices of rabbit renal medulla, from endogenous precursors. I have confirmed that rabbit renal cortex contains little prostaglandin and cannot synthesize them from endogenous lipids³. Hamberg has reported that arachidonic acid, which is converted to PGE₂ and PGF_2α by enzymes present in ram seminal vesicles⁴, can be efficiently converted to PGE₂ and PGF_2α by homogenates of rabbit renal medulla³. I have now confirmed that arachidonic acid, added to such medullary homogenates, can increase the quantities of prostaglandins synthesized. There was no evidence that the major prostaglandin biosynthesized, PGE2, was further metabolized to inactive products.     

Further studies on prostaglandin E2 (PGE2)-induced gonadotropin release: Comparison with the effect of 15-methyl PGE2, PGAs, PGBs and prostaglandin endoperoxide analogs

It is known that PGE₂ is a potent stimulus of LH release. To determine if the effect of PGE₂ could be enhanced and/or prolonged by retarding its metabolic degradation, a derivative, 15-methyl PGE₂ (15-E₂) which is more slowly degraded than the natural compound was injected intravenously (i.v.) at various dose levels or into the third ventricle (3rd V) of ether-anesthetized, ovariectomized, estrogen (OVX, Eb)-treated rats and its effect on gonadotropin release was compared with that of PGE₂. Both PGs injected i.v. were equally effective in increasing plasma LH and maintaining the elevated levels, although 15-E₂ induced a larger and more sustained increase in plasma FSH than PGE₂. By contrast, 3rd V PGE₂ was clearly more effective than 3rd V 15-E₂ in releasing LH and to a lesser extent, FSH. The effect of 15-E₂ on LH was similar to that produced by 3rd V PGE₁ injected at a similar dose. However, its effect on FSH was greater than that of PGE₁.To evaluate the effect(s) of prostaglandins of the A and B series on gonadotropin release, PGA₁, PGA₂, PGB₁ or PGB₂ were injected intraventricularly in OVX, Eb-treated rats. PGBs were injected into conscious, free-moving rats. PGA₂ or PGB₂ increased plasma LH concnetrations although much less effectively than PGE₂. Third V PGA₁ or PGB₁ were ineffective. The 3rd V injection of two cyclic esters (U-44069 and U-46619), stable analogs of the PG endoperoxide PGG₂ and PGH₂, induced a small, transient increase in LH levels and did not alter plasma FSH in conscious, free-moving animals. PGE₂ injected intraventricularly at a similar dose was demonstrated to be much more potent than the analogs in stimulating LH and FSH release. The results indicate that: 1) 15-E₂, in spite of its described long-lasting activity, does not appear to be more potent than the natural compound in releasing LH, although when injected i.v., it appeared to induce a more sustained increase in plasma FSH; 2) although PGA₂ and PGB₂ can also act centrally to stimulate LH release, their low potency suggests that this is a pharmacological effect; and 3) the two analogs of PG endoperoxides tested proved to be poor stimuli for gonadotropin release. The significance of these findings is discussed.     

Exogenous ghrelin attenuates endotoxin fever in rats

Ghrelin is a gut-derived peptide that plays a role in energy homeostasis. Recent studies have implicated ghrelin in systemic inflammation, showing increased plasma ghrelin levels after endotoxin (lipopolysaccharide, LPS) administration. The aims of this study were (1) to test the hypothesis that ghrelin administration affects LPS-induced fever; and (2) to assess the putative effects of ghrelin on plasma corticosterone secretion and preoptic region prostaglandin (PG) E₂ levels in euthermic and febrile rats. Rats were implanted with a temperature datalogger capsule in the peritoneal cavity to record body core temperature. One week later, they were challenged with LPS (50 μg/kg, intraperitoneal, i.p.) alone or combined with ghrelin (0.1 mg/kg, i.p.). In another group of rats, plasma corticosterone and preoptic region PGE₂ levels were measured 2 h after injections. In euthermic animals, systemic administration of ghrelin failed to elicit any thermoregulatory effect, and caused no significant changes in basal plasma corticosterone and preoptic region PGE₂ levels. LPS caused a typical febrile response, accompanied by increased plasma corticosterone and preoptic PGE₂ levels. When LPS administration was combined with ghrelin fever was attenuated, corticosterone secretion further increased, and the elevated preoptic PGE₂ levels were relatively reduced, but a correlation between these two variables (corticosterone and PGE₂) failed to exist. The present data add ghrelin to the neurochemical milieu controlling the immune/thermoregulatory system acting as an antipyretic molecule. Moreover, our findings also support the notion that ghrelin attenuates fever by means of a direct effect of the peptide reducing PGE₂ production in the preoptic region.     

Interactions of prostaglandin E1, bradykinin and histamine and the increase of plasma fibrinogen in rats

Considering that tissue injury caused by laparotomy significantly increases the liver synthesis of plasma fibrinogen, and that PGE₁, bradykinini and histamine are released into the injured tissues, the effect of above mentioned inflammatory agents and of adrenal medulla on plasma fibrinogen levels in rats was studied. The subcutaneous administration of PGE₁, bradykinin or histamine does not modify plasma fibrinogen levels acting independently comparing with non-injected animals or injected with the drug vehicle. Bradykinin + histamine did not modify plasma fibrinogen levels either. However the administration of prostaglandin E₁ + bradykinin + histamine reproduced the increase of fibrinogen characteristics of laparotomy. This increase was partially but significantly inhibited in rats that had undergone bilateral removal of the adrenal medulla or administration of PGE₁ + bradykinin + histamine + bupivacaine (a local anesthetic), but it was not modified when the adrenal medullectomy was unilateral. It is concluded that plasma fibrinogen increase is obtained only when PGE₁ acts in presence of bradykinin or histamine and the adrenal medulla should be partially responsible for said increase.     

Effects of prostaglandins on rat renal adenylate cyclase-cyclic AMP systems

The effects of prostaglandin (PG) E₁, E₂, A₁, F_1α, F_2α or D₂ on the rat renal cortical, outer medullary and inner medullary adenylate cyclase-cyclic AM systems were examined. While high concentrations (8X10⁻⁴M) of each prostaglandin stimulated adenylate cyclase activity in each area of the kidney, PGE₁ was the only prostaglandin to stimulate at 10⁻⁷M. PGA's were the only prostaglandins tested besides PGE's which stimulated adenylate cyclase at less than 10⁻⁴M. This effect of PGA's was limited to the outer medulla. PGD₂ was the least stimulatory. Observations with renal slices yielded qualitatively results. The PGE's were the most potent in each area with PGA's only stimulatory in the outer medulla. O₂ deprivation (5% O₂) lowered the slice cyclic AMP content in each area of the kidney. In the cortex and outer medulla, prostaglandin mediated increases in cyclic AMP content were either lower or absent at 5% O₂ compared to 95% O₂. However, in the inner medulla PGE stimulation was observed only at 5% O₂ and not 95% O₂. No other prostaglandins were found to increase inner medullary cyclic AMP content at 95% or 5% O₂. These results illustrate that the adenylate cyclase-cyclic AMP system responds uniquely to prostaglandins in each area of the kidney. Consideration of these results along with correlative observations suggests that inner medullary produced PGE's may act as local modulators of inner medullary adenylate cyclase.     

Comparison of the effects of prostaglandin I2 and prostaglandin E2 stimulation of the rat kidney adenylate cyclase-cyclic AMP systems

Prostacyclin (Prostaglandin I₂) effects on the rat kidney adenylate cyclase-cyclic AMP system were examined. Prostaglandin I₂ and prostaglandin E₂, from 8 · 10^?4 to 8 · ^?7 M stimulated adenylate cyclase to a similar extent in cortex and outer medulla. In inner medulla, prostaglandin I₂ was more effective than prostaglandin E₂ at all concentrations tested. Both prostaglandin I₂ and prostaglandin E₂ were additive with antidiuretic hormone in outer and inner medulla. Prostaglandin I₂ and prostaglandin E₂ were not additive in any area of the kidney, indicating both were working by similar mechanisms. Prostaglandin I₂ stimulation of adenylate cyclase correlated with its ability to increase renal slice cyclic AMP content. Prostaglandin I₂ and prostaglandin E₂ (1.5 · 10^?4 M) elevated cyclic AMP content in cortex and outer medulla slices. In inner medulla, with Santoquin® (0.1 mM) present to suppress endogenous prostaglandin synthesis, prostaglandin I₂ and prostaglandin E₂ increased cyclic AMP content. 6-Ketoprostaglandin F_1α, the stable metabolite of prostaglandin I₂, did not increase adenylate cyclase activity or tissue cyclic AMP content. Thus, prostaglandin I₂ activates renal adenylate cyclase. This suggests that the physiological actions of prostaglandin I₂ may be mediated through the adenylate cyclase-cyclic AMP system.     

Decidual adenylate cyclase and prostaglandin production in vitro

Human decidua contains an active adenylate cyclase, and a number of studies indicate that adenylate cyclase is functionally linked to increased in vitro prostaglandin synthesis. Increased decidual prostaglandin synthesis is associated with parturition, and therefore activation of adenylate cyclase may be involved in the control of human parturition. In this study, third trimester human decidual cells were preincubated for no more than 24 h prior to stimulation with a number of reagents which increase cellular cyclic AMP levels. Forskolin rapidly increased intracellular and extracellular cyclic AMP levels, but there was no increase in prostaglandin E₂ biosynthesis during incubations ranging from 5 min up to 24 h. Dibutyryl cyclic AMP or 8-bromo-cyclic AMP were also without effect on PGE₂ production, which suggests that the adenylate cyclase was not linked to the mechanisms regulating prostaglandin production. Cholera toxin increased basal cyclic AMP and PGE₂ synthesis, and was without effect on IL-1β-stimulated PGE₂ levels. PGE₂ synthesis was increased by 24 h culture with IL-1β in all the cell preparations, indicating that the cells were biologically active, and that the lack of effect of changes in cyclic AMP synthesis on PGE₂ levels could not be attributed to a defect in the prostaglandin synthetic pathway. Our findings did not agree with earlier work which showed that changes in cyclic AMP were correlated with changes in PGE₂ production by human decidual cells. It is clear that in the previous studies the decidual cells were preincubated for 4–7 days prior to stimulation, in contrast with 24 h in our investigation. We suggest that the functional link between cyclic AMP and PGE₂ synthesis reported previously may develop during culture, and not be a part of normal decidual cell function, but further studies are needed to test this hypothesis.     

Marked inhibition of gastric secretion by two prostaglandin analogs given orally to man

Two prostaglandin analogs, 15(S)-15-methyl PGE₂, methyl ester, and 16, 16-dimethyl PGE₂ were administered to human volunteers for their possible effect in inhibiting gastric secretion. Both analogs, given orally, inhibited gastric secretion stimulated by pentagastrin, and the effect was dose dependent. The inhibition lasted for more than 4 hours, and no side-effects were noted at the doses used. When given intraduodenally, through a thin tube swallowed the night before, 15($\text{S}$)-15-methyl PGE₂, methyl ester was more active than 16, 16-dimethyl PGE₂. In view of their oral and prolonged activity, these analogs may have clinical potential in the treatment of peptic ulcer.     

Effect of Prostaglandins on Hepatic Cyclic Nucleotide Concentration,Carbohydrate and Lipid Metabolism

The effects of exogenous prostaglandin E₁ (PGE₁) or prostaglandin E₂ (PGE₂) were studied in the isolated perfused rat liver and in the intact canine liver in order to determine the possible physiological role of prostaglandins on hepatic carbohydrate and lipid metabolism. The data indicate that PGE₁ and PGE₂ did not stimulate cyclic AMP (cAMP) and cyclic GMP (cGMP) concentrations in intact dog liver and PGE₁ failed to stimulate cAMP or cGMP in fed or fasted perfused rat liver. PGE₁ did not promote hyperglycemia, glycogenolysis, lipolysis, or prevent epinephrine-induced hyperglycemia in the isolated perfused rat liver. Other known glycogenolytic agents including glucagon and epinephrine increased cAMP and glycogenolysis in the same perfusion system. This study does not support a physiologic role for PGE₁ on hepatic glycogenolysis or lipolysis. If PGE₁ subsequently is found to influence other metabolic parameters such as lipogenesis, gluconeogenesis, ureogenesis or amino acid transport in isolated perfused liver, such alterations would probably occur independent of changes in cyclic nucleotide activity.     

Intracerebral prostaglandin E2: Effects upon sexual behavior,open field activity and body temperature in ovariectomized female rats

A single 27 gauge implant of PGE₂ into the periventricular region of the hypothalamus resulted in a significant increase in sexual receptivity in estrogen primed, ovariectomized female rats. Open field activity levels were only slightly decreased while rectal body temperature increased significantly over control values. It is postulated that the effects upon sexual receptivity might be mediated by PGE₂ stimulated LRF release.     

Role of prostaglandis in the control of renin secretion in the dog (II)

Infusion of prostaglandin E₁ (PGE₁) into the renal artery of anesthetized dogs (1.03 μg/min) caused increases in urine flow rate (V), renal plasma flow (RPF) and renin secretion rate without any change in mean arterial blood pressure (MABP), whereas infusion of prostaglandin F₂α (PGF_2α), (1.03 μg/min) caused no consistent change in V, RPF, or renin secretion rate. Infusion of prostaglandin E₂ (PGE₂) (1.03 μg/min) into the renal artery of “non-filtering” kidneys caused renin secretion rate to rise from 567.7 ± 152.0 U/min(M ± SEM) during control periods to 1373.6 ± 358.5 U/min after 60 minutes of infusion of PGE₂ (P < 0.01), without significant change in MABP (P > 0.1). The data suggest that PGE₁ and PGE₂ play a role in the control of renin secretion. The data further suggest that PGE may control renin secretion through a direct effect on renin-secreting granular cells.     

Thermoregulatory responses to preoptic-anterior hypothalamic heating and cooling in the bat,Eptesicus fuscus

Summary The central nervous control of temperature regulation in the bat, Eptesicus fuscus, was evaluated by heating the preoptic-anterior hypothalamus (PO/AH) of active, unanaesthetized bats. Because bats are metabolically very variable, change in body temperature was used as the criterion of change in heat balance in response to change in brain temperature and change in wing temperature as an indicator of vasomotor changes.Heating the preoptic-anterior hypothalamic area (PO/AH) of the bat Eptesicus fuscus caused an average increase in wing temperature due to vasodilation of 1.0° C and an average increase in body temperature of 0.4° C. Conversely, cooling the PO/AH led to an average decline in wing temperature due to vasoconstriction of 0.9° C and an average decline in body temperature of 0.4° C.Bats were heat-stressed to augment the responsiveness of the PO/AH. Heat-stress alone causes a rise in body temperature and wing temperature. Release from heat stress causes a fall in body temperature and a fall in wing temperature. When the PO/AH is heated following a period of high heat-stress, the body temperature continues to fall but wing temperature reverses its direction of change and rises. When bats are given a low heat-stress and simultaneous heating of the PO/AH, wing temperature rises in response to PO/AH temperature and the body temperature stabilizes. When the PO/AH is cooled in bats under high heat-stress, body temperature stabilizes and wing temperature falls. When bats are cold-stressed, body temperature and wing temperature fall regardless of heating of the PO/AH.These responses are related to the life habits of the bat.It is concluded that the PO/AH of the bat Eptesicus fuscus may be less thermally sensitive than the PO/AH in other vertebrates studied, and that other central nervous structures have acquired an increased thermoregulatory function.We thank Mrs. Ruth Chalmers for her excellent histological preparstions.This work was supported, in part, by National science Foundation grant GB 6303 and GB 13797.     

Failure of prostaglandins E1 and E2 to alter canine gastric mucosal cyclic nucleotides

The action of prostaglandins and indomethacin on gastric mucosal cyclic nucleotide concentrations was evaluated in 18 anesthetized mongrel dogs. Prostaglandins E₁ (PGE₁) and E₂ (PGE₂) (25 μg/kg bolus, then 2 μg/kg/min) were administered both intravenously (4 experiments; femoral vein) and directly into the gastric mucosal circulation (10 experiments; superior mesenteric artery). The possible synergistic effect of pre-treatment and continuous arterial infusion of indomethacin (5 mg/kg bolus for 5 min, then 5 mg/min), a prostaglandin synthetase inhibitor, with PGE₂ was studied in 4 experiments. Antral and fundic mucosa were biopsied and measured by radioimmunoassay for cyclic nucleotides. Doses of PGE₁ and PGE₂ which inhibited histamine-stimulated canine gastric acid secretion did not significantly alter antral or fundic mucosal cyclic nucleotide concentrations. Concomitant infusion of PGE₂ with indomethacin did not potentiate the mucosal nucleotide response compared to PGE₂ alone. These studies fail to implicate cyclic nucleotides as mediators of the inhibitory acid response induced by PGE₁ or PGE₂ in intact dog stomach.     

Accumulation of adenosine 3',5'-monophosphate in rat brain slices: effects of prostaglandins.

Prostaglandin E₁ and E₂ and 15(S)-15-methyl PGE₂ methyl ester stimulate the accumulation of radioactive cyclic AMP in brain slices from Sprague-Dawley rats, labelled during a prior incubation with [¹⁴C] adenine. Prostaglandins A₁ and B₁ have marginal effects and prostaglandin F_1α has no effect. Relatively high concentrations of about 80 μM PGE₁, PGE₂ and 15(S)-15-methyl PGE₂ are required to elicit a maximal 2–5 fold increase in accumulation of cyclic AMP in slices from cerebrum, but significant increases are elicited by 3.5 μM prostaglandin. Similar increases are elicited in slices from neocortex, striatum or midbrain-thalamus-hypothalamus, while lesser increases pertain in slices from cerebellum, medulla-pons or hippocampus. The accumulation of cyclic AMP elicited by PGE₁ in slices from cerebrum was not blocked by naloxone, propranololphentolamine, tetracaine, theophylline, or by nearly equimolar concentrations of either of two prostaglandin antagonists, 7-oxa-13-prostynoic acid and the dibenzoxazepine hydrazide, SC 19220. Morphine potentiated the effects of PGE₁. The combination of 85 μM PGE₁ with either isoproterenol, norepinephrine, adenosine or veratridin did not increase the accumulation of cycli AMP significantly above those elicited by the isoproterenol, norepinephrine, adenosine or veratridine alone. The combined effect of PGE₁ and norepinephrine in the presence of a β-adrenergic antagonist, sotalol, was, however, additive. The results indicate that PGE₁ stimulates cyclic AMP formation in rat brain slices, but that it either has antagonist activity with respect to accumulations of cyclic AMP-elicited by other agents or has no detectable agonist activity when cyclases are maximally stimulated by other agents.