Dissociation of hyperreninemia and renal prostaglandin synthesis in the adrenalectomized rat

The aim of this study was to determine whether hyperreninemia in the adrenalectomized (ADX) rat is dependent on renal prostaglandin synthesis, as has been suggested for two other hyperreninemic conditions, Bartter's syndrome and chronic liver disease.Plasma renin concentration (PRC) in anesthetized, ADX rats was significantly increased (Δ +480%; p < 0.001) compared to sham-operated controls. , indomethacin (10 mg/kg i.v.) significantly reduced PRC of anesthetized, ADX rats after both 45 min (Δ −34%; p < 0.05) and 90 min (Δ −47%; p < 0.05). renin release from renal cortical slices of ADX rats was also significantly greater (Δ +130%; p < 0.05) than from sham-operated control cortical slices. Renin release from cortical slices of ADX rats given dexamethasone (10 μg/kg/day) for 4 days prior to sacrifice did not differ from sham-operated control values.Prostaglandin E₂ (PGE₂) release from cortical slices of ADX rats did not differ significantly from controls. However, PGE₂ synthesis in glomeruli microdissected from ADX rats was significantly increased (Δ +110%; p < 0.001) compared to controls. PGE₂ synthesis in glomeruli of dexamethasone-treated ADX rats remained significantly elevated compared to controls. Ibuprofen (10⁻⁶ M) decreased PGE₂ synthesis in cortical slices by 80%. However, prostaglandin synthesis inhibition had no effect on renin release from either ADX or control renal cortical slices.These results suggest that despite increased glomerular synthesis, prostaglandins do not directly influence renin release in the ADX rat.     

Failure of LH and/or prolactin to prevent PGF2α-induced luteolysis of ovine corpora lutea

Infusions of phosphate buffered saline, LH (4 μg/min or 14 μg/min), prolactin (42 μg/min) or LH (4 μg/min) plus prolactin (42 μg/min) for 12 hr did not prevent luteolysis following intramuscular injections of prostaglandin F₂α-tham salt two and six hr after beginning the infusion. Likewise, these treatments did not delay luteolysis since a similar rate of decline in peripheral plasma progesterone occurred in all groups. It was concluded that elevation of serum concentrations of LH and prolactin to high levels had no effect on PGF₂α-induced luteolysis on day 8 following induced ovulation.     

Long-Term Responses to Loss of Renal Mass: Pathophysiological Aspects: Role of Solute Excretion in Prevention of Norepinephrine-Induced Acute Renal Failure

Infusion of 0.75 μ g/kgbw/min norepinephrine (NE), for 40 minutes, into one renal artery in anesthetized dogs, induced acute renal failure (ARF). Subsequently there was nearly complete reversal of function within 8 weeks. Isotonic saline volume expansion, or renal vasodilation plus diuresis by acetylcholine (into renal artery: 20 μg/min) did not protect against this type of ARF. Volume expansion with either 5 or 20 percent mannitol partly prevented the fall of GFR 3 hours after NE, this protection being correlated with the magnitude of the osmolar clearance at the time of the insult. IV furosemide (10 mg/kg + 10 mg/kg/h; fluid losses replaced) afforded an even better protection. Proximal tubular necrosis in the “protected” kidneys was as severe as in non-protected kidneys. Glomerular cell morphology (scanning electron microscopy) was not altered by the 40-minute NE infusions. Functional “protection” appeared to depend on solute diuresis at the time of insult.     

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.     

Corticosteroids inhibit prostaglandin release from perfused mesenteric blood vessels of rabbit and from perfused lungs of sensitized guinea pig

Infusion of norephinephrine (NE) (1 – 3 μg/ml/min) into the isolated mesenteric vascular preparation of rabbit resulted in a rise in perfusion pressure, which was associated with the release of a prostaglandin E-like substance (PGE) at a concentration of 2.81 ± 0.65 ng/ml in terms of PGE₂. Indomethacin (3 μg/ml) abolished the NE-induced release of PGE. Arachidonic acid (0.2 μg/ml) in the presence of indomethacin did not restore the NE-induced release of PGE. Hydrocortisone (10 – 30 μg/ml) and dexamethasone (2 – 5 μg/ml) also inhibited the NE-induced release of PGE. The inhibitory action of both corticosteroids was abolished by arachidonic acid (0.2 μg/ml). Antigen-induced release of a prostaglandin-like substance(PGs) (43.1 ± 3.8 ng/ml in terms of PGE₂ and a rabbit aorta contracting substance (RCS) from perfused lungs of sensitized guinea pigs was completely abolished by indomethacin (5 μg/ml) or by hydrocortisone (100 μg/ml). Indomethacin, however, increased histamine release up to 280% of the control level, which was 470 ± 54 ng/ml, while hydrocortisone diminished histamine release down to 30% of the control level. A superimposed infusion of arachidonic acid (1 μg/ml) into the pulmonary artery reversed the hydrocortisone-induced blockade of the release of RCS and PGs. It may be concluded that corticosteroids neither inhibit prostaglandin synthetase nor influence prostaglandin transport through the membranes but they do impair the availability of the substrate for the enzyme.     

Corticosteroids inhibit prostaglandin release from perfused mesenteric blood vessels of rabbit and from perfused lungs of sensitized guinea pig

Infusion of norephinephrine (NE) (1 – 3 μg/ml/min) into the isolated mesenteric vascular preparation of rabbit resulted in a rise in perfusion pressure, which was associated with the release of a prostaglandin E-like substance (PGE) at a concentration of 2.81 ± 0.65 ng/ml in terms of PGE₂. Indomethacin (3 μg/ml) abolished the NE-induced release of PGE. Arachidonic acid (0.2 μg/ml) in the presence of indomethacin did not restore the NE-induced release of PGE. Hydrocortisone (10 – 30 μg/ml) and dexamethasone (2 – 5 μg/ml) also inhibited the NE-induced release of PGE. The inhibitory action of both corticosteroids was abolished by arachidonic acid (0.2 μg/ml). Antigen-induced release of a prostaglandin-like substance (PGs) (43.1 ± 3.8 ng/ml in terms of PGE₂ and a rabbit aorta contracting substance (RCS) from perfused lungs of sensitized guinea pigs was completely abolished by indomethacin (5 μg/ml) or by hydrocortisone (100 μg/ml). Indomethacin, however, increased histamine release up to 280% of the control level, which was 470 ± 54 ng/ml, while hydrocortisone diminished histamine release down to 30% of the control level. A superimposed infusion of arachidonic acid (1 μg/ml) into the pulmonary artery reversed the hydrocortisone-induced blockade of the release of RCS and PGs. It may be concluded that corticosteroids neither inhibit prostaglandin synthetase nor influence prostaglandin transport through the membranes but they do impair the availability of the substrate for the enzyme.     

Considerations into the mechanism of estrogen-stimulated uterine prostaglandin synthesis

Progesterone priming of the ovariectomized rat, followed by a single injection of estradiol-17β (10 μg) is followed by an increased uterine synthesis of both PGF and PGE. The administration of an estrogen antagonist (MER-25; 10 mg) concomitantly with estradiol had no effect on uterine prostaglandin synthesis. Similarly, the administration of either Actinomycin D or cycloheximide, antibiotics demonstrated to inhibit mRNA and protein synthesis, respectively, is without effect on estrogen-stimulated uterine prostaglandin synthesis. These results are considered with regard to the classic receptor theory of estrogen action and are a preliminary indication that estrogen-stimulated uterine prostaglandin synthesis may not require those receptor mediated events.     

The role of protein synthesis in the stimulation by LH of prostaglandin accumulation in rat preovulatory follicles

Preovulatory follicles isolated from immature rats, treated with pregnant mare's serum gonadotropin, were incubated and the accumulation of prostaglandin E measured. The addition of luteinizing hormone (5 μg/ml) increased this accumulation, after a lag period of 3 hours. This delay suggested the involvement of macromolecular synthesis in the mechanism of prostaglandin stimulation by luteinizing hormone. When the synthesis of protein was inhibited by the addition of puromycin (100 μM), the luteinizing hormone stimulation of prostaglandin E in these follicles was completely abolished. This inhibition was not seen with an analogue of puromycin, which does not inhibit protein synthesis, puromycin amino-nucleoside. These data suggest that concomitant protein synthesis is required for the luteinizing hormone stimulation of prostaglandin accumulation in rat follicles.     

Dose response relation of the renal effects of PGA1, PGE2, and PGF2α in dogs

The effects of the three prostaglandins A₁, E₂, and F_2α on renal blood flow, glomerular filtration rate (GFR), fluid excretion, and urinary output of Na, K, Ca, Cl, and solutes were evaluated at a dose range of 0.01 – 10 μg/min. The prostaglandins were infused into the renal artery of dogs. GFR was not significantly altered by the PGs. PGA₁ increased renal blood flow by approximately of the control at 0.01 μg/min without dose dependence at higher infusion rates. It had only little effects which were not dose dependent on fluid and electrolyte output. The effects of PGE₂ on renal blood flow, fluid, sodium, and chloride excretion were dose dependent with a steep slope of the dose response curve between 0.1 and 1.0 μg/min. Blood flow was increased maximally by 80 %, urine volume by more than 400 %. PGF_2α had no effect on renal blood flow, whereas urinary output was increased to approximately the same maximal level as by E₂ although ten times higher doses were needed. Potassium excretion was less influenced than the excretion of Na and Cl and osmolar clearance was less increased than urine volume by all three prostaglandins.It is concluded that if a PG is involved in the regulation of the renal fluid or electrolyte excretion it is likely to be of the PGE-type. A PGA could only be involved in regulation of renal hemodynamics, whereas PGF although effective in the kidney exerts its effects at doses too high to have physiological significance.     

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.     

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 × 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.     

Induction of renin release by exogenous prostaglandins in hyporeninemic hypoaldosteronism

A deficiency in renal prostaglandin synthesis has been proposed as the cause of the syndrome of hyporeninemic hypoaldosteronism. To determine if renin release could be stimulated by pharmacologic infusions of PGA₁, we infused PGA₁ 0.075 to 0.60 μg/kg/min to nine patients with the syndrome. Total renal PGE production as measured by urinary PGE excretion was normal (650 ± 169 vs 400 ± 55 ng/24hr in normal subjects). Renin (PRA) was markedly depressed in all patients despite stimulation with upright posture and furosemide (1.0 ± 0.4 vs 9.3 ± 0.7 ng/ml/hr, p<0.001). But in two patients PGA₁ induced an increase in renin similar to that of normal subjects. PRA increased to a lesser degree in two other patients and plasma aldosterone slightly increased. Five showed no response. Infusions of nitroprusside in doses and duration that mimicked the hypotensive effects of PGA₁ failed to increase PRA or aldosterone. The data suggest that total renal PGE production is normal in patients with the syndrome of hyporeninemic hypoaldosteronism. Although orthostasis, furosemide and nitroprusside do not increase renin, prostaglandin A₁ infusion appears to be a potent stimulus to renin release in some of the patients.     

Effect of indomethacin and 7-oxa-13-prostynoic acid on luteinization of transplanted rat ovarian follicles induced by luteinizing hormone and prostaglandin E2

The ability of prostaglandin E₂ (PGE₂) to initiate luteinization was demonstrated using a system of in vitro incubation of ovarian follicles followed by transplantation. Follicles from diestrous rats were incubated with 0.05 to 50 μg/ml PGE₂, 10 μg/ml luteinizing hormone (LH), or alone in Krebs-Ringer bicarbonate buffer plus glucose for 2 hr. Then follicles were transplanted under the kidney capsules of hypophysectomized recipients, with follicles exposed to PGE₂ on one side and those exposed to LH or buffer only on the other side. As determined at autopsy 4 days later and confirmed by histological examination, follicles exposed to PGE₂ at concentrations of 0.5 μg/ml or greater, or to LH, transformed into corpora lutea, but control follicles regressed. Incubation of follicles with LH in the presence of indomethacin, an inhibitor of prostaglandin synthesis, significantly reduced the incidence of luteinization. Prostaglandin E₂ (10 μg/ml) was able to override the inhibition of luteinization by indomethacin (150 μg/ml). The prostaglandin analogue 7-oxa-13-prostynoic acid (100 μg/ml) failed to prevent luteinization in response to either 5 μg/ml LH or 1 μg/ml PGE₂. Results with PGE₂ and with indomethacin suggest a role for prostaglandins in the luteinizing action of LH.We have reported previously that in vitro exposure of diestrous rat follicles to luteinizing hormone (LH) will result in transformation of the follicles to corpora lutea following transplantation under the kidney capsules of hypophysectomized rats. Dibutyryl cyclic AMP (DBC) mimics this effect of LH, and transplants produce progesterone in measurable amounts after both LH and DBC exposure when prolactin is administered in vivo to recipients.Kuehl et al. have suggested that prostaglandins may act as obligatory intermediates in the effect of LH on the ovary, acting between LH and adenylate cyclase. Preliminary results indicated that prostaglandin E₂ (PGE₂) could induce luteinization in our system. The extent of prostaglandin involvement in luteinization was further investigated in this work, using two reported antagonists of prostaglandin action, indomethacin and 7-oxa-13-prostynoic acid. Indomethacin has been found to inhibit synthesis of prostaglandins E₂ and F_2α; 7-oxa-13-prostynoic acid, which acts as a competitive antagonist of prostaglandins, prevented the effect of LH and prostaglandins E₁ and E₂ on cyclic AMP production in mouse ovaries.     

Prostaglandins and renin release: II. Assessment of renin secretion following infusion of PGI2, E2 and D2 into the renal artery of anesthetized dogs

The influence of intra-renal infusions of prostaglandin (PG) I₂, PGE₂ and PGD₂ on renin secretion and renal blood flow was investigated in renally denervated, beta-adrenergic blocked, indomethacin treated dogs with unilateral nephrectomy. All three prostaglandins when infused at doses of 10⁻⁸ g/kg/min and 10⁻⁷ g/kg/min resulted in marked renal vasodilation. Renin secretory rates increased significantly with both PGI₂ and PGE₂ at the 10⁻⁸ g/kg/min and 10⁻⁷ g/kg/min infusion rates in a dose dependent manner. However, PGD₂ was inactive. At 10⁻⁷ g/kg/min, PGI₂ infusions resulted in systemic hypotension indicating recirculation of this prostaglandin. These findings suggest that PGI₂ should be included among the cyclooxygenase derived metabolites of arachidonic acid to be considered as possible mediators of renin release.     

Effect of RNA and protein synthesis inhibitors on the release of inflammatory mediators by macrophages responding to phorbol myristate acetate

The interaction of phorbol myristate acetate with resident populations of mouse peritoneal macrophages causes an increased release of arachidonic acid followed by increased synthesis and secretion of prostaglandin E₂ and 6-keto-prostaglandin F_1α. In addition, phorbol myristate acetate causes the selective release of lysosomal acid hydrolases from resident and elicited macrophages. These effects of phorbol myristate acetate on macrophages do not cause lactate dehydrogenase to leak into the culture media. The phorbol myristate acetate-induced release of arachidonic acid and increased synthesis and secretion of prostaglandins by macrophages can be inhibited by RNA and protein synthesis inhibitors, whereas the release of lysosomal hydrolases is unaffected. 0.1 μg/ml actinomycin D blocked the increased prostaglandin production due to this inflammatory agent by more than 80%, and 3 μg/ml cycloheximide blocked prostaglandin production by 78%. Similar results with these metabolic inhibitors were found with another stimulator of prostaglandin production, zymosan. However, these inhibitors do not interfere with lysosomal hydrolase releases caused by zymosan or phorbol myristate acetate. It appears that one of the results of the interaction of macrophages with inflammatory stimuli is the synthesis of a rapidly turning-over protein which regulates the production of prostaglandins. It is also clear that the secretion of prostaglandins and lysosomal hydrolyses are independently regulated.     

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.     

Quantification of the major urinary metabolite of the E prostaglandins by mass spectrometry: Evaluation of the method's application to clinical studies

Measurement of 7α-hydroxy-5,11-diketotetranorprostane-1,16-dioic acid, (PGE-M), the major urinary metabolite of prostaglandin E₁ and E₂ in man provides a useful indicator to monitor prostaglandin biosynthesis. For quantitative analysis of this prostaglandin metabolite the stable-isotope dilution technique of selected ion monitoring (SIM) is employed using gas-liquid chromatography-mass spectrometry. The preparation of the (D₃-methyloxime), -methyl ester of PGE-M containing a tritium tracer in position 2 which was used as internal standard for the SIM method is described. The synthesis of this internal standard includes the biosynthetic conversion of 11-hydroxy-9,15-diketoprostanoic acid to PGE-M by the rabbit. The intra-assay coefficient of variation of this SIM method ranged between 4.0 to 6.7 percent. The recovery of authentic, underivatized PGE-M added to urine was 93 ± 3% (mean ± SEM, n=17).The levels of PGE-M excreted in urine were higher (p<0.001) in males than in females (15.2 ± 1.9 μg/24 hours (n=24) and 3.3 ± 0.3 μg/24 hours (n=17), respectively). These levels were in close agreement with values published previously. No significant difference in excretion of PGE-M between the sexes was observed in the pre-pubertal age-group (male: 2.9 ± 0.8 μg/24 hours, n=5; female: 3.1 ± 0.9 μg/24 hours, n=5) or in the age-group of 45–80 years (male: 9.3 ± 1.1 μg/24 hours, n=21; female: 7.3 ± 0.9 μg/24 hours, n=12). The amount of PGE-M excreted decreased significantly after administration of indomethacin or acetyl salicylic acid in therapeutic doses. The concomitant reduction of the urinary excretion of PGE-M (68 to 85% decrease) and prostaglandin E (73 to 100% decrease) after indomethacin treatment in each case (n=8) is evidence that a diminished urinary PGE-M output reflects a decrease in prostaglandin E biosynthesis.     

A new prostaglandin E1 analogue (CL-115,574) II. Effects on gastric acid secretion in the dog

The efficacy of CL-115,574, a prostaglandin E₁ analogue, as an acid antisecretory agent was evaluated in dogs. CL-115,574 inhibited acid secretion maximally at an oral dose of 20 μg/kg causing 100% inhibition of acid secretion up to one hour after administration, with significant inhibition of secretion (30%) still present nearly four hours after drug administration. The wide disparity between the maximally effective antisecretory dose 20 μg/kg and the dose at which reproducible side effects occurred (1 mg/kg) suggests that this compound may be developed as an antisecretory compound for use in man.     

Refractoriness of ovarian adenylate cyclase to continued hormonal stimulation

Culture of preovulatory rat follicles with luteinizing hormone, folliclestimulating hormone or prostaglandin E₂ for 24 h reduced the subsequent response of adenylate cyclase to the homologous hormone by 80, 50 and 90%, respectively; yet follicles refractory to luteinizing hormone fully responded to follicle-stimulating hormone or prostaglandin E₂, those refractory to follicle-stimulating hormone responded to luteinizing hormone and prostaglandin E₂, and those refractory to prostaglandin E₂ could be stimulated by either gonadotropin. Desensitization of the adenylate cyclase system by luteinizing hormone was achieved by hormone concentrations of 0.8−2.0 μg/ml in the mediem; a lower dose of luteinizing hormone (0.4 μg/ml), though effective in stimulating adenylate cyclase, did not induce refractoriness. Prostaglandin E₂ caused partial refractoriness at dose levels of 0.1–0.25 μg/ml; higher dose levels were more effective. These findings suggest that continued exposure of the preovulatory follicle to elevated levels of hormones may cause perturbations in either the interaction between the hormone and its specific receptor or in a subsequent step essential for activation of adenylate cyclase.     

Prostaglandin synthesis by rheumatoid synovium and its stimulation by colchicine

The synthesis of prostaglandins by rheumatoid synovial tissue in organ culture was studied utilizing radioimmunoassay, with antisera to PGB₁, PGF_1α and PGF_2α. It was established that PGE₂ and PGF_2α were the major prostaglandins formed by analyses of culture media with the two antisera to PGF, before and after alkali treatment. Indomethacin at 5 μg/ml suppressed prostaglandin synthesis, usually to <1% of control cultures. Colchicine, 0.1 μg/ml resulted in marked stimulation of prostaglandin synthesis, in some cases over 10 fold. It is suggested, because of the colchicine effect, that the state of the microtubules may regulate the rate of prostaglandin biosynthesis. It is possible that prostaglandin E₂ produced by rheumatoid synovia may contribute to the pathogenesis of the inflammatory reaction and lead to destruction of juxta-articular bone in rheumatoid arthritis.