Urinary excretion of prostaglandin E2 and prostaglandin F2α in potassium-deficient rats

Potassium-deficiency was induced in rats by dietary deprivation of potassium. The animals became polyuric and urine osmolality decreased more then three-fold compared to controls. Urinary excretion of prostaglandin E₂ (PGE₂) and prostaglandin F_2α (PGF_2α) did not increase during 2 weeks of potassium depletion. Partial inhibition of renal prostaglandin synthesis by meclofenamate did not increase the urine osmolality after water deprivation. These results make unlikely the hypothesis that the polyuria of potassium-deficiency, is the result of enhanced renal synthesis of prostaglandins with subsequent antagonism of the hydro-osmotic effect of vasopressin. Male animals consistently excreted less PGE₂ than female animals.     

Radioimmunological and biological measurement of prostaglandins in rabbit urine : Decrease of PGE2 excretion at high NaCl intake

The estimation of prostaglandin (PG) E₂ and of PGF_2α by radioimmunoassay is described in detail. PGE₂ was measured after conversion to either PGB₂ or PGF_2α and the results compared to bioassay. The methods were used to follow the excretion of PGE₂ and PGF_2α after salt loading in rabbits. A marked reduction of PGE₂ levels was observed at high NaCl intake, while PGF_2α excretion remained unchanged.     

Interaction between prostaglandin E2 and leukotriene D4 on the excretion of electrolytes by the dog kidney in vivo

Recent experiments indicate that prostaglandin E₂ potentiates the vasodilatory properties of leukotrienes in the skin microcirculation. The present experiments were undertaken to study the effect of leukotriene D₄ and prostaglandin E₂ on renal hemodynamics and urinary electrolytes in the dog. Experiments were performed in three groups of anesthetized Mongrel dogs: the first group was studied under hydropenia, whereas the two remaining groups were studied during water diuresis with (Group 3) or without indomethacin (Group 2). LTD₄ (100ng/min) and PGE₂ (3ug/min) were infused in the left renal artery to minimize systemic effects of these compounds. LTD₄ alone failed to influence urinary sodium excretion in all 3 groups. In Group 1, urinary sodium increased from 77 ± 6 to 393 ± 74uEq/min during PGE₂, and further increased to 511 ± 52uEq/min during LTD₄ + PGE₂. No change occured in the contralateral right kidney. In this group, glomerular filtration as well as renal plasma flow were not statistically influenced. In Group 2, the same phenomenon was observed for urinary sodium. The combined infusion of LTD₄ + PGE₂ increased urinary sodium without significant changes in glomerular filtration and renal plasma flow. Finally, in Group 3, indomethacin was shown to reduce the natriuretic effects of LTD₄ and PGE₂: during PGE₂ alone, urinary sodium increased from 90 ± 14 to 260 ± 66uEq/min, and only rose from 80 ± 10 to 175 ± 19uEq/min during the combined infusion of LTD₄ and PGE₂. In groups 2 and 3, free water clearance was utilized as an index of sodium chloride reabsorption in the thick ascending limb: this parameter increased from 2.35 ± 0.25 to 4.70 ± 0.30ml/min, while urinary volume was increasing from 3.55 ± 0.25 to 10.05 ± 0.65ml/min, during LTD₄ + PGE₂. Indomethacin, administered in Group 3, (3mg/kg/hr) again abolished the effect of combined PGE₂ + LTD₄. These results indicate a potentiating effect of leukotriene D₄ on the PGE₂-induced natriuresis in the anesthetized dog. These phenomena occured in the absence of significant changes in renal hemodynamics, therefore suggesting a direct tubular effect of these arachidonic acid metabolites. Finally, the water diuresis experiments suggest a proximal site of action of PGE₂ and LTD₄.     

The effect of suppression of prostaglandin synthesis on renal function in rats with intact and reduced renal mass

The present study was undertaken to assess the role of prostaglandin system in the compensatory response to reduced nephron population, respective to renal function and electrolyte excretion. Intact and nephrectomized rats were divided in 4 groups: 1) rats pretreated with indomethacin, 2) rats pretreated with the vehicle of indomethacin, 3) rats pretreated with sulindac, and 4) rats pretreated with the vehicle of sulindac.In normal rats, indomethacin administration resulted in a mild decrease in creatinine clearance and a significant reduction of the urinary Na excretion. In the rats with reduced renal mass treated with indomethacin, the creatinine clearance did not differ from that in the control group. The 24 h urinary sodium excretion and the fractional excretion of sodium, however, were significantly lower in the indomethacin treated animals than in the control rats. No change in the creatinine clearance or in the sodium excretion was observed in all groups pretreated with sulindac.The urinary PGE₂ and thromboxane excretion was significantly lower in the indomethacin treated intact rats and the rats with reduced renal mass. Sulindac induced a slight decrease in urinary excretion of PGE₂ in intact rats. No significant change in urinary excretion of PGE₂ or thromboxane was seen after sulindac in the rats with reduced renal mass.The antinatriuretic effect of indomethacin was dissociated from changes in urine flow in all groups of animals, suggesting that the increase in Na reabsorption tool place in a water impermeable segment of nephron.These results suggest that the compensatory increase in urinary Na excretion per nephron in rats with reduced nephron population at least partly depends on an intact prostaglandin synthesis.     

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.     

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.     

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.     

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.     

Application of high performance liquid chromatography and gas chromatography-mass spectrometry to analysis of prostaglandin E1 in biological media.

A method for the quantitation of prostaglandin (PG) E₁ in biological samples of gas chromatography—mass spectrometry has been developed. PGE₁ was separated from PGE₂, 13,14-dihydro-PGE₂, and other potentially interfering prostaglandins by reversed phase high performance liquid chromatography. After conversion of PGE₁ to PGB₁ by treatment with methanolic KOH, PGB₁ was derivatized to the methyl ester trimethylsilyl ether and analyzed by selected ion monitoring using hexadeutero-PGE₁ as an internal standard. Measurable levels of PGE₁ were found in human and rat urine and in incubates of rat and rabbit renal papilla. PGE₁ excretion and production by renal slices was blocked by treatment with indomethacin. A complete mass spectrum of derivatized PGE₁ was obtained from PGE₁ generated by rabbit renal papillary slices.     

Impaired renal production of prostaglandin E2: A newly identified lesion in human essential hypertension

To test the hypothesis that impaired renal prostaglandin production may accompany the hypertensive state, we have measured urinary PGE₂ by radio-immunoassay in 52 normotensive and 50 hypertensive subjects. PGE₂ levels were lower in females, and were not affected by Na⁺ intake or age. Patients with essential hypertension had significantly lower PGE₂, particularly those with low-renin hypertension. Forty percent of the hypertensives excreted less than 70 ng/24 hr, values never observed in normotensives except after receiving indomethacin, a well-known prostaglandin synthetase inhibitor. It appears that impaired renal prostaglandin production is commonly encountered in patients with essential hypertension, perhaps contributing to their increased renal resistance. The data further suggest a role for renal prostaglandins in the pathogenesis of low-renin hypertension.     

High urine flow rate increases prostaglandin E excretion in the conscious dog

Although previous studies from this and other laboratories have shown that urinary prostaglandin E excretion (U_PGEV) can vary independent of urine flow rate, recent studies during water diuresis in the conscious dog have suggested that high urine flow rate per se may increase U_PGEV. To examine the effect of urine flow rate on U_PGEV we administered either mannitol, chlorothiazide or Ringer's solution to mongrel dogs and measured U_PGEV. During anesthesia neither mannitol or chlorothiazide increased U_PGEV. There was, however, a consistent increase with all three agents in awake animals. This increase in U_PGEV was independent of alterations in glomerular filtration rate. There was a consistent increase in urinary sodium excretion and decrease in urinary osmolality with all three agents. The changes in PGE, however, were similar to those found during water diuresis when no increase in sodium excretion was found. It is not presently clear whether these findings reflect a true increase in renal PGE synthesis due to some change in flow or pressure within the renal medulla or rather represent unchanged PGE synthesis by renal tubular cells, the high tubule fluid flow rate causing increased entry into the tubular lumen in contrast to the renal interstitium.     

Dietary arachidonic acid suppresses bone turnover in contrast to low dosage exogenous prostaglandin E2 that elevates bone formation in the piglet

This study was designed to compare the effects of dietary arachidonic acid (AA) versus prostaglandin E₂ (PGE₂) on bone cell metabolism and bone mass. Twenty-eight piglets from 7 litters were randomized to 1 of 4 treatments for 15 days: fatty acid supplemented formula (FA: 0.8% of total fatty acids as AA and 0.1% of total fatty acids as DHA)+PGE₂ injections (0.1 mg/kg/day), FA+saline injections, standard formula (STD: n-6:n-3 of 8:1) + PGE₂ injections or STD+saline injections. PGE₂ resulted in elevated osteoblast activity as indicated by plasma osteocalcin and also reduced urinary calcium excretion. Dietary FA resulted in reduced bone resorption as indicated by urinary N-telopeptide and reduced bone PGE₂. Both PGE₂ and FA treatments independently lead to elevated femur mineral content, but the combined treatment caused a reduction. Thus the mechanisms by which PGE₂ and FA lead to enhanced bone mass are distinct.     

Evidence for an extra-renal origin of urinary prostaglandin E2 in healthy men

In order to verify the validity of the assumption that male urinary Prostaglandin (PG) E₂ reflects its renal production, PGE₂ and PGF_2α concentrations were measured by radioimmunoassay in the renal venous plasma (RVP) and urine (U) of 12 male and 4 female healthy volunteers. While women had a similar PGE₂/PGF_2α ratio in RVP (0.59 ± 0.18) and U (0.41 ± 0.06), men had a significantly (p< 0.05) higher ratio in U (1.43 ± 1.72) as compared to RVP (0.54 ± 0.16). This was largely due to considerably higher and more variable U-PGE₂ concentrations (roughly 6 times higher than female values), despite almost identical RVP levels. The possibility of an increased U excretion of a cross-reacting member of the PG-system, as a cuase of such apparently high PGE₂-like immunoreactivity (LI), was ruled out by TLC characterization of PGE₂-LI with three different anti-PGE₂ sera. Thus, male U-PGE₂ may variably reflect an extra-renal source, such as contamination with trace amounts of seminal fluid. It is concluded that, unless such a contamination can be monitored and corrected for, measurement of male U-PGE₂ should be considered of questionable relevance to renal PG-synthesis.     

The role of renal metabolism of PGE2 in determining its activity as a renal vasodilator in the dog

Since the mammalian renal cortex avidly metabolizes prostaglandin E₂ (PGE₂), we examined the importance of renal metabolism of PGE₂ in determining its renal vascular activity in the dog. We used 13, 14 dihydro PGE₂ (DHPGE₂) as a model compound to study this because DHPGE₂ retains similar activity to the parent prostaglandin, PGE₂, but is a poorer substrate than PGE₂ for both the metabolism and the cellular uptake of the prostaglandins. Using dog renal cortical slices, we found that under similar experimental conditions, PGE₂ was metabolized several-fold faster than DHPGE₂. Both prostaglandins were metabolized to the 15 keto 13, 14 dihydro PGE₂, which was positively identified using GC-MS. In vivo, we infused increasing concentrations of DHPGE₂ into the renal artery of dogs and measured renal hemodynamic changes using radioactive microspheres. DHPGE₂ was a potent renal vasodilator beginning at an infusion rate of 10⁻⁹g/kg/min. When compared to PGE₂, DHPGE₂ was about 10 times more potent in affecting renal vasodilation. The intrarenal redistribution of blood flow towards the inner cortex seen with DHPGE₂ was identical to that seen with PGE₂. We conclude that renal catabolism of PGE₂ is very important in limiting the in vivo biological activity of PGE₂, but regional differences in metabolism of PGE₂ within the cortex are an unlikely determinant of the pattern of redistribution of renal blood flow.     

Effect of prostaglandins on uterine contractions in the estrous ewe.

Administration of exogenous prostaglandins at the time of mating may improve fertility via their effects on uterine contractility. The present study was undertaken to compare the effects of three prostaglandins that affect either the male or female reproductive uterine contractility. Contractions in the uterine body of anesthetized ewes during estrus were studied before, during and after a 5 min interval of systemic infusion of prostaglandin F_2α-THAM salt (PGF_2α; 5 mg), prostaglandin E₁ (PGE₁; 5 mg), prostaglandin E₂ (PGE₂; 5 mg) or vehicle. Pressure changes were detected by the use of an open-ended intrauterine catheter and a transducer. Each of the three prostaglandins initially caused a single prolonged contraction that lasted about 10 minutes and had a maximum pressure of 50 mm Hg. Prior to the prolonged contraction, PGE₁ and E₂ caused a relaxation for about 1 minute. In addition, PGE₁ and E₂ caused more secondary contractions (15–20) during the prolonged contraction than did PGF_2α (7–9). The effects of prostaglandin (PG) treatment lasted for 20–30 minutes. The authors conclude that with the dose used the three prostaglandins studied do not have greatly different effects on uterine contractility in estrous ewes.     

Effects of prostaglandin E1 and isoproterenol on cyclic AMP content of human fibroblasts modified by time and cell density in subculture

In confluent cultures of “young” (< 30 generations) human fibroblasts, maximally effective concentrations of prostaglandin E₁ (5.6 μM) and isoproterenol (2 μM) increased cyclic AMP content several hundred-fold and approximately 30-fold, respectively. On the first day after initiation of cultures at either low (approx. 3 · 10⁵ cells) or high (approx. s · 10⁶ cells) cell density the magnitude of the isoproterenol effect was similar to that in confluent cultures. It increased during the next few days, reaching a maximum around day 2–3, and then declined. On any day during the period of subculture, the magnitude of the isoproterenol effect was inversely related to cell density. Alterations in response to prostaglandin E₁ as a function of time in subculture or cell density were less dramatic. The effects of prostaglandin E₁ were, however, smaller at some point during the first few days of subculture than after day 7, and when effects of prostaglandin E₁ were minimal, those of isoproterenol were maximal and approached those of prostaglandin E₁. On any day of subculture, cells in cultures of higher density tended to accumulate more cyclic AMP in response to prostaglandin E₁ than did those in low density cultures. The effects of prostaglandin E₁ and isoproterenol on cyclic AMP content were qualitatively similar in “young” and in “old” (> 60 generations in culture) human fibroblasts although the changes associated with duration of subculture and cell density tended to be less marked with “old” cells. In the “young” fibroblasts responsiveness to isoproterenol and prostaglandin E₁ appears to correlate with cell morphology and with the fractional rate of growth in subcultures. It is suggested that the capacities of the fibroblasts to respond to these two agents may be altered independently during growth of human fibroblasts.     

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.     

Prostaglandin (PG) analysis in urine of humans and rats by different radioimmunoassays: Effect on PG-excretion by PG-synthetase inhibitors, laparotomy and furosemide

Thw radioimmunological (RIA) determination of prostaglandin (PG) E₂ and of PGF_2α in urine humans and rats is described in detail. After extraction and chromatography PGE₂ was determined by using a PGE specific antibody or by using either PGB or PGF_2α specific antibodies after the respective conversion procedures. The three different RIA procedures were compared to each other. PGF_2α was determined by a specific antibody to PGF_2α. Basal excretion of PGE₂ and of PGF_2α in healthy women on free diet was 9.3 ng/hour ± 0.96 and 18.3 ng/hour ± 2.5 respectively. Furosemide increased the excretion of PGE₂ and of PGF_2α in humans significantly, while PG-excretion rates decreased on indomethacin. In rat urine PGE₂ and PGE_2α increased markedly from 46.2 pg/min ± 9.3 and 27 ± 3.4 to 253.8 ± 43.3 and 108 ± 12.6 pg/min (per one kidney) in the anesthetized-laparotomized animal. This increase was abolished after giving two different PG synthetase inhibitors.     

The effect of adrenergic stimulation on urinary prostaglandin E2 and 6 keto PGF1α in man

To evaluate the details of the adrenergic stimulation of urinary prostaglandins in man, ten normal volunteers were given various agonists and antagonists. The effect of 4 hour IV infusions of norepinephrine (NE), NE + phentolamine (PHT), NE + phenoxybenzamine (PHB), NE + prazosin (PZ), isoproterenol (ISO), and PHT alone on urinary PGE₂ and PGI₂ (6 keto PGF_1α) were determined. PGE₂ and 6 keto PGF_1α were measured by radioimmunoassay from 4 hour urine samples. NE stimulated both PGE₂ (196±40 to 370±84 ng/4 hrs/g creatinine and 6 keto PGF_1α(184±30 to 326±36), both p<0.01. In contrast, ISO had no effect on either PGE₂ or 6 keto PGF_1α excretion. Alpha blockade with PHT. PHB, or PZ inhibited the NE induced systemic pressor effect. However, the effect of the alpha blockers on the NE induced stimulation of PGE₂ and 6 keto PGF_1α varied. PHT did not alter the NE stimulated PGE₂ or 6 keto PGF_1α release (370±84 vs. 381±80) PGE₂ and (326±50 vs. 315±40) 6 keto PGF_1α, both p>0.2). PHT alone stimulated only 6 keto PGF_1α. PHB and the specific α₁ antagonist PZ similarly eliminated the NE induced prostaglandin release. These results suggest that adrenergically mediated urinary prostaglandin release in man is via an alpha receptor with α₁ characteristics.     

Kinetic changes in rat renal 15-hydroxy-prostaglandin dehydrogenase induced by chronic ethanol exposure

Several lines of investigation have suggested that exposure to ethanol may lead to alterations in both the synthesis and degradation of the E and F series of prostaglandins (PG). It has been suggested that these changes in PG metabolism underlie cartain of the pathophysiological consequences of chronic alcoholism but few data re availalbe as to the mechanism resonsible for these changes. We now report that chronic exposure to ethanol in moderate doses (17% total dietary calories as ethanol) and high doses (35% total dietary calories as ethanol) results in a concentration dependent loss of renal 15-hydroxy-prostaglandin dehydrogenase for the NAD mediated reactioins. Soluble fractions of kidney homogenates in teh presnet of > 10 K_m concentratons of NAd exhibited dose dependent loss of specific and total organ PG dehydrogenase activity toward PGE₂ and F_2α. A similar dose dependent decrease in the V_max of the NAD mediated reaction was measured for the oxidation of PGE₁, E₂, and F_2α. Moderate doses of ethanol resulted in an increase in the K_m for PGE₂ and F_2α. K_m values for the NADP mediated reactions were not significantly influenced by exposure to high doses of ethanol other than for PGE₁. These data suggest that chronic ethanol consumption results in a dose dependent, selective inhibition of the metabolism of PGs of the “2” series by the renal PGDH enzyme which utilizes NAD.