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 absence 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 were 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 ng/mg prot) than jJ rats (15 +/- 3) (p less than 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 less than 0.05). PGF2 alpha was also significantly higher in the outer medulla of jj rats with and without aspirin administration (p less than 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 less than 0.01); increased serum creatinine (p less than 0.05); and increase in outer medullary histopathologic lesions (p less than 0.005 compared to either sham-treated jj or aspirin-treated jJ). These results suggest that enhanced prostaglandin synthesis contributes to maintenance of renal function and morphological integrity, and that inhibition of prostaglandin synthesis may lead to pathological renal medullary lesions and deterioration of renal function.     

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.     

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.     

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.     

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

The effects of prostaglandin (PG) E1, E2, A1, F1alpha, F2alpha or D2 on the rat renal cortical, outer medullary and inner medullary adenylate cyclase-cyclic AMP 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 similar 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.     

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.     

Zonal heterogeneity of prostaglandin and thromboxane release in the dog kidney

The release of prostaglandin(PG) and thromboxane(TX) was examined in the six different areas of the normal dog kidney, i.e., renal arterial and venous strips(RA and RV), superficial and deep cortical slices (SC and DC) and outer and inner medullary slices(Om and IM). These tissues were incubated in Krebs-bicarbonate buffer(pH 7.4, 37°C), and the released PGE2, PGF2α, 6-keto-PGF1α and TXB2(as stable metabolites of PG12 and TXA2, respectively) were determined by radioimmunoassay. In RA, RV, SC and DC, 6-keto-PGF1α was predominant, however, there were no quantitative differences between RA and RV, or SC and DC. The release of 6-keto-PGF1α reached a maximum in IM, similar to findings on the release of PGE2 and PGF2α. The release of TXB was uniform in OM and IM. The amount of PGE2, PGF2α, 6-keto-PGF1α and TXB2 released from IM was 2800, 400, 60 and 50 times higher, respectively, than the extent of the release from the cortical slices.These results suggest that PG12 as well as PGE2 and PGF2α, may be involved in renal PG, and that TXA2 is biosynthesized in the normal dog kidney.     

Inhibition of compensatory renal growth by indomethacin

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

Prostaglandin E2 production by renal inner medullary tissue slices: effect of metabolic inhibitors

Increasing oxygen from 5 to 95% has previously been shown to increase prostaglandin (PG) production in renal inner medullary slices. The possible role of oxidative phosphorylation in this process was investigated. The oxidative phosphorylation inhibitors, dinitrophenol (DNP), oligomycin, and cyanide were evaluted for their effects on PGE2 production and ATP levels. None of the inhibitors affected PGE2 synthesis, although they lowered ATP levels at the concentrations tested. In contrast, incubation of inner medullary tissue slices with 0% oxygen resulted in decreases both in PGE2 and ATP levels. This suggests that the effect of oxygen on prostaglandin synthesis may be due to substrate limiting effects rather than an effect on oxidative phosphorylation. When 22 mM 2-deoxyglucose was added to the incubation medium or when glucose was omitted, PGE2 levels increased. Sodium fluoride, presumably acting as a glycolytic inhibitor, increased PGE2 levels, with a maximal effect at 10 mM. ATP levels were 37% of control values with 20 mM NaF. This indicates that glucose may inhibit prostaglandin synthesis. These results indicate that oxygen (substrate) availability can limit inner medullary PGE2 production. In view of the low pO2 in the inner medulla, especially during antidiuresis, oxygen can potentially regulate prostaglandin production in this tissue.     

Thromboxane receptor blockade improves cyclosporine nephrotoxicity in rats

Cyclosporine A (CyA) nephorotoxicity is associated with impaired renal hemodynamic funtion and increased production of the vasoconstrictor eicosanoid thromboxane A₂ (TxA₂). In CyA toxic rats, renal dysfunction cna be partially reversed by inhibitors of thromoboxane sysnthase. However, interpretation of these results is complicated since inhibitance of thromboxane synthase may cause accumulation of prostaglandin endoperoxides that can act as partial agonists at the TxA₂ receptor and may blunt the efficacy of treatment. Furthermore, these endoperoxides may be used as substrate for production of vasodilator prostaglandins causing beneficial effects on hemodynamics which are independent of thromboxane inhibition. To more specially examine the role of TxA₂ in CyA toxicity, we investigated the effects of the thromboxane receptor antagonist GR32191 on renal hemodynamics in a rat model of CyA nephrotoxicity. In this model, administration of CyA resulted in a significant decrease in glomerular filtration rate (GFR) 2.85±0.26 [CyA] vs 6.82±0.96 ml/min/kg [vehicle]; p<0.0005) and renal blood flow (RBF) (21.6±2.31 [CyA] vs 31.8±3.60 ml/min/kg [vehicle]; p<0.025). Renal vascular resistance (RVR) was significantly higher in rats given CyA compared to animals treated with CyA vehicle (5.32±0.55 [cyCyA] vs 3.54±0.24 mm Hg/min/ml/kg [vehicle]; p<0.05). These hemodynamic alterations were associated with a significant increase in urinary excretion of unmetabolized, “native” thromboxane B₂ (TxB₂ (103±18 [CyA] vs 60±16 pg/hour [vehicle]; p<0.05). Only minimal histomorphologic changes were apparent by light microscopic examination of kidneys from both CyA and vehicle treated animals. However, with immunoperoxidase staining, a significantly greater number of cells experssing the rat common leukocyte antigen was found in the renal interstitium of rats given CyA^*. There was no detectable increase in monocytes/macrophages in the kidneys of CyA toxic animals. In rats treated with CyA, intraarterial infusion of GR32191 at maximally tolerated doses significanlty increased GFR and RBD, and decreased RVR. Although both RBF and RVR were restored to levels not different from controls, GFR remained significantly reduced following administration of GR32191. These data suggest that the potent vasoconstrictor TxA₂ plays an important role in mediating renal dysfunction in CyA nephrotoxicity. However, other factors may be important in producing nephrotoxicity associated with CyA.     

Prostaglandin receptors in rat kidney

The physiological effects of prostaglandins (PGs) are mediated through their interactions with specific binding sites (receptors) on effector cells. Since such receptors potentially regulate the action of PGs on the kidney, the distribution and properties of renal PG receptors in the rat were examined. The distribution of PGE2, PGE1, and PGF2 alpha receptors along the nephron was not uniform; the outer medulla had by far the greatest density of sites, followed by the inner medulla and cortex. Receptors were found exclusively in the particulate fractions, of which the 40,000g pellet had the highest specific activity. In the outer medulla, receptor density calculated from Scatchard plots was 2.12 pmol/mg for PGE2, 1.12 for PGE1, and 0.44 for PGF2 alpha; the KD's were similar for all prostaglandins. The conditions for optimal in vitro binding of PGE2 and PGF2 alpha by outer medullary membranes were investigated. In vivo administration of 16,16'-dimethyl-PGE2 resulted in a dose-dependent "down" regulation of PGE2 binding to outer medullary membranes due to changes in both the number and affinities of receptors. Changes in the numbers and/or properties of PG receptors may be an important mechanism for regulating the effects of PGs and renal function under normal and pathologic conditions.     

The effect of sodium intake on renal prostaglandin production

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

Effects of indomethacin on renal inner medullary plasma flow

The effects of the prostaglandin system on renal hemodynamics were studied by treating rats with a single intraperitoneal dose of indomethacin, an inhibitor of prostaglandin synthesis. Medullary plasma flow was significantly reduced 30–45 minutes after indomethacin, but was elevated 3–6 hours after indomethacin. These changes in medullary plasma flow correlated well with circulating levels of prostaglandins A and E. Total renal blood flow decreased following indomethacin treatment, but returned to normal levels within an hour. These results indicate that the inhibition of prostaglandin synthesis following a single intraperitoneal dose of indomethacin is short-lived and is followed by a significant elevation in prostaglandin synthesis. It is likely that prostaglandin levels play an important role in the control of renal medullary plasma flow.     

Sex differences in gastric mucosal protection after 16, 16-dimethyl PGE2 and lithium chloride

While the incidence of duodenal ulcer disease has been documented to be greater in men than in women, this observation has not been previously noted in animal studies of the upper gastrointestinal tract. In this study, we questioned whether the cytoprotective properties of 16, 16-dimethyl PGE₂ were sex-related by comparing the degree of ethanol-induced hemorrhagic gastritis in male and female rats pretreated with 16,16-dimethyl PGE₂ or lithium chloride. Animals receiving 16,16-dimethyl PGE₂ or lithium chloride had significantly less ethanol-induced hemorrhagic gastritis (1.17±0.15 and 1.24±0.13, respectively, p<0.001) when compared with controls (2.69±0.10). Female rats treated with 16,16-dimethyl PGE₂ had 59% less hemorrhagic gastritis than male rats treated similarly (0.76±0.14 vs 1.86±0.19 respectively, p<0.001). This sex-related difference in hemorrhagic gastritis was not noted in male and female rats receiving lithium chloride (1.24±0.15 vs 1.23±0.27, respectively). However, female rats treated with 16, 16-dimethyl PGE₂ had significantly less hemorrhagic gastritis when compared with female rats receiving lithium chloride (0.76±0.14 vs 1.24±0.15 respectively, p<0.05).These findings suggest that the protective properties of 16, 16-dimethyl PGE₂ are sex-related while those of lithium chloride are not.     

Indomethacin inhibits cell proliferation in the oxyntic epithelium of the rat

The aim of this investigation was to examine the action of parenteral indomethacin and oral prostaglandin E₂ on cell proliferation in the rat oxyntic mucosa. Groups of Sprague Dawley rats were treated with either 1.5 mg/kg indomethacin subcutaneously, 5 mg/kg oral prostaglandin E₂ or placebo, twice daily during 5 days. All rats were killed exactly 4 hours after mitotic arrest with vincristine, and a biopsy specimen from the oxyntic mucosa was processed for routine microscopic evaluation.Mitotic figures were distributed cluster-like along the oxyntic mucosa alternating with mitosis-free areas. The total number of mitotic figures in 8 mm of mucosa was significantly reduced by administration of indomethacin (p<0.05). In rats given indomethacin, 32.5% of the examined mucosa did not have mitotic figures, which is significantly higher than 14.3% as observed in placebo-treated rats (p<0.05). Both rats treated with indomethacin and with prostaglandin E₂ had fewer microscopic fields containing 5–6 mitotic figures than placebo-treated animals (p<0.05). The maximal length of mitosis-free areas was 0.6 (0.6–0.9) mm in rats given indomethacin which is significantly larger than 0.4 (0.2–0.4) mm observed in controls (p<0.05). Indomethacin produced epithelial atrophy as shown by a significant reduction of the epithelial height observed in those rats compared to controls (p<0.05).The inhibition of cell proliferation observed in the oxyntic mucosa of rats treated with the cyclooxygenase blocker indicates that an important physiological role of endogenous prostaglandin is to maintain the proliferative activity of the epithelium at a high level.     

Mesenchymal Stem Cells Improve Medullary Inflammation and Fibrosis after Revascularization of Swine Atherosclerotic Renal Artery Stenosis

Atherosclerotic renal artery stenosis (ARAS) raises blood pressure and can reduce kidney function. Revascularization of the stenotic renal artery alone does not restore renal medullary structure and function. This study tested the hypothesis that addition of mesenchymal stem cells (MSC) to percutaneous transluminal renal angioplasty (PTRA) can restore stenotic-kidney medullary tubular transport function and attenuate its remodeling. Twenty-seven swine were divided into three ARAS (high-cholesterol diet and renal artery stenosis) and a normal control group. Six weeks after ARAS induction, two groups were treated with PTRA alone or PTRA supplemented with adipose-tissue-derived MSC (10×10⁶ cells intra-renal). Multi-detector computed tomography and blood-oxygenation-level-dependent (BOLD) MRI studies were performed 4 weeks later to assess kidney hemodynamics and function, and tissue collected a few days later for histology and micro-CT imaging. PTRA effectively decreased blood pressure, yet medullary vascular density remained low. Addition of MSC improved medullary vascularization in ARAS+PTRA+MSC and increased angiogenic signaling, including protein expression of vascular endothelial growth-factor, its receptor (FLK-1), and hypoxia-inducible factor-1α. ARAS+PTRA+MSC also showed attenuated inflammation, although oxidative-stress remained elevated. BOLD-MRI indicated that MSC normalized oxygen-dependent tubular response to furosemide (-4.3±0.9, −0.1±0.4, −1.6±0.9 and −3.6±1.0 s⁻¹ in Normal, ARAS, ARAS+PTRA and ARAS+PTRA+MSC, respectively, p<0.05), which correlated with a decrease in medullary tubular injury score (R² = 0.33, p = 0.02). Therefore, adjunctive MSC delivery in addition to PTRA reduces inflammation, fibrogenesis and vascular remodeling, and restores oxygen-dependent tubular function in the stenotic-kidney medulla, although additional interventions might be required to reduce oxidative-stress. This study supports development of cell-based strategies for renal protection in ARAS.     

Localization of 125I-atrial natriuretic factor (ANF)-binding sites in rat renal medulla. A light and electron microscope autoradiographic study

Using light and electron microscope autoradiography in vivo, the localization of 125I-(Arg 101-Tyr 126) atrial natriuretic factor (ANF)-binding sites was studied in the renal medulla of rats. At the light microscopic level, the autoradiographic reaction was mainly distributed in patches in the outer medulla, and followed the tubular architecture in the innermost part of the inner medulla. At the electron microscopic level, binding sites were mainly found in the outer medullary descending vasa recta and inner medullary collecting ducts. These results suggest that, in rats, the renal medulla may participate in the natriuresis and diuresis produced by ANF through vascular and tubular effects; the former by changing medullary blood flow at the level of descending vasa recta and the latter by acting on electrolyte and water transport at the level of collecting ducts.     

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

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

The “interleukin 1 receptor antagonist” is a partial agonist of prostaglandin synthesis by human decidual cells

In many systems the interleukin-1 receptor antagonist opposes the effects of interleukin-1β. We considered that it might block interleukin-1β-stimulated prostaglandin production from human decidual cells. Very high levels of interleukin-1 receptor antagonist (>1000 pg/ml) had limited inhibitory effects on IL-1β-stimulated PGE2 synthesis, and lower levels of antagonist (<1000 pg/ml) increased the effects of IL-1β. Low concentrations of the antagonist alone (1–100 pg/ml) increased basal PGE2 production, whereas higher levels (10–100 ng/ml) had less effect. It seems, therefore, that in human decidua the “antagonist” is more accurately described as a partial agonist. It has been suggested that the IL-1 receptor antagonist could be used to inhibit decidual prostaglandin synthesis and thereby prevent preterm labor, but this report shows that caution should be exercised before using the receptor antagonist.     

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.