Renal synthesis of prostacyclin and thromboxane in healthy women: differential effects of a short-term saline loading

It is accepted that the urinary excretions of the stable metabolites of prostaglandin (PG)I2 and thromboxane(Tx) A2, 6-keto-PGF1alpha (6KPGF) and TxB2 respectively, provide an accurate estimate of both basal and stimulated renal synthesis of their precursors. The excretory profile of these metabolites has been evaluated in healthy women submitted to a short-term expansion in extracellular fluid volume. Salt retention (SR group, n=6) was induced by physiological saline (0.9% NaCl) i.v. infusions (2 L per day) over a period of 2 days. On the third day the increase in body weight was 0.92 +/- 0.27 kg (P<0.05). The results of the study have been compared to those previously obtained in normal balance of sodium and potassium (N group, n=20) and in induced salt depletion (SD group, n=14). A common study protocol was used. Basal values of plasma renin activity (PRA) and urinary aldosterone excretion were determined. Renal functional exploration [clearance (cl.) method] was performed during hypotonic polyuria (induced by oral water load) and subsequent moderate antidiuresis (induced by low-dose infusion of an antidiuretic hormone analogue). Urinary 6KPGF and TxB2 concentrations were estimated by RIA method and their urinary excretions were determined at both high and low urinary flow rates. The linear regressions of the urinary metabolite excretions vs. urinary flow rate were estimated by using the data obtained in both hypotonic polyuria and antidiuresis. Salt retention (SR vs. N group) was effective in decreasing the basal values of plasma renin activity and urinary aldosterone excretion. Moreover, during hypotonic polyuria it was effective in increasing the absolute and fractional excretions of sodium and chloride, in the absence of significant variations in mean arterial pressure and creatinine cl. Regarding urinary prostanoid excretions the following results were obtained. 1. Comparative data for hypotonic polyuria. In the SR vs. N group, the urinary excretion of 6KPGF was significantly higher, whereas that of TxB2 was not significantly different. In the SR vs. SD group, the urinary excretion of 6KPGF was not significantly different, whereas that of TxB2 was significantly lower. 2. Comparative data for the regression lines of the urinary prostanoid excretions vs. diuresis. In the SR vs. N group, the regression line slope for 6KPGF excretion was significantly higher, whereas that for TxB2 excretion was not significantly different. In the SR vs. SD group, the regression line slope for 6KPGF excretion was not significantly different, whereas that for TxB2 excretion was significantly lower. 3. Correlative data in the SR group during hypotonic polyuria. The plasma chloride concentration was positively correlated with urinary flow rate, absolute and fractional chloride excretions, and 6KPGF excretion but not with TxB2 excretion. In conclusion, functionally effective salt retention in healthy women induces a selective stimulation of renal synthesis of prostacyclin, unlike salt depletion, in which the synthesis of both PGI2 and TxA2 is upregulated.     

Volume-induced natriuresis in healthy women: renal metabolism of prostacyclin and thromboxane, and physiological role of prostanoids

In healthy women submitted to a short-term expansion in extracellular fluid volume we have evaluated the urinary excretory profile of the stable metabolites of prostaglandin(PG) I2 and thromboxane(TX) A2, 6-keto-PGF1 alpha(6KPGF) and TXB2 respectively, and assessed the physiological role played by the prostanoids in this experimental condition. Salt retention (SR group, n=9) was induced by repeated i.v. infusion of saline solution (0.9% NaCl). At the end of the treatment the body weight had increased by 0.7+/-0.2 kg (mean+/-SEM) (P<0.05). Renal functional exploration [clearance (cl.) method] was performed during hypotonic polyuria (induced by oral water load) and subsequent moderate antidiuresis (induced by low-dose infusion of an antidiuretic hormone analogue). Urinary 6KPGF and TXB2 concentrations were estimated by RIA method during polyuria (P cl. period), early and late antidiuresis (A1 and A2 cl. periods). Paired functional explorations were performed in absence (control study) and presence of indomethacin. Basal values of plasma sodium and potassium concentrations, plasma renin activity (PRA) and urinary aldosterone excretion were determined just before the control study. The results in salt retention were compared to those previously obtained in healthy women submitted to a moderate salt depletion (SD2 group, n=6), in absence and presence of the drug. Women in salt retention received 100 mg i.m. of the drug, whereas salt-depleted women received only a halved dose as in previous studies in salt depletion the full dose produced prolonged anuria. (I) Salt retention vs salt depletion. The basal values of PRA and urinary aldosterone excretion were significantly lower. During polyuria, urinary excretion of 6KPGF, 6KPGF/TXB2 ratio, urinary flow rate, creatinine cl. and absolute and fractional excretions of sodium and chloride were significantly higher. In salt retention during polyuria, significant positive correlations were found between 6KPGF excretion and functional excretory parameters. (II) Indomethacin in salt retention. The following effects were significant: (a) a reduction in prostanoid excretions in P and A1 cl. periods only; (b) during polyuria, an increase in arterial pressure, a reduction in urinary flow rate and creatinine cl. (saluresis showed not significant reduction). During polyuria significant positive correlations occurred between the absolute effects of indomethacin on 6KPGF excretion and those on functional excretory parameters. (III) Comparative effects of indomethacin in salt retention and salt depletion. Despite the double dosage of the drug, the significant reductions in urinary metabolite excretions were not significantly different during P cl. period and significantly lower in A1 cl. period compared to the corresponding significant reductions in salt depletion. During polyuria, the significant increase in arterial pressure was significantly different from the not significant effect in salt depletion; the not significant effect on saluresis was significantly different from the significant reduction in salt depletion. The results suggest the following conclusions: (1) The present model showed the functional pattern of the volume-natriuresis; (2) In salt retention, in contrast with salt depletion, indomethacin induced an increase in arterial pressure consistent with the inhibition of a PG-dependent vasodilator mechanism active at the systemic level; (3) In salt retention, in contrast with salt depletion, indomethacin failed to induce a significant reduction in saluresis. This failure can be attributed to the drug's blunted effectiveness in inhibiting the renal synthesis of saluretic PGs, and probably to the interference of the concurrent increase in arterial pressure in the renal treatment of sodium and chloride.     

Further research on the role of prostanoids in controlling renal function in humans in normal potassium balance and acute experimental potassium depletion. II: Studies of potassium depletion

The renal function was evaluated by clearance (cl.) method during hypotonic polyuria and successive relative antidiuresis induced by lysine-8-vasopressin (LVP) administration. Four 15 min and two 60 min cl. periods were performed during hypotonic polyuria and antidiuresis, respectively. Glomerular filtration rate was estimated by creatinine cl.; the osmotic cl. (Cosm'CH2O), the absolute and fractional excretions of water, sodium, potassium and chloride were determined by usual methods. The urinary PGE2, 6-keto-(-)PGF1 alpha and TxB2 concentrations were determined by RIA method. The study protocol was applied on 22 healthy women in acute potassium depletion obtained by natriuretic treatment combined with replacement on quantitative basis of net salt and water urinary losses either in normal potassium diet intake (50 meq/d) or in a low one (less than or equal to 10 meq/d). In Group D3 (n = 6) in the presence of a greater potassium cumulative deficit (198.4 +/- 22.2 meq), as compared to normal potassium balance, a significant reduction of kaliemia and a significant increase of PRA were present. During hypotonic poliuria, besides a marked renal potassium conservation, a significant decrease of creatinine cl., fractional chloride reabsorption (apparently at the diluting segments) and of urinary 6KPGF and TxB2 excretions, were observed. Urinary PGE2 excretion was n.s. reduced.     

Selective inhibitory effects of experimental potassium depletion on urinary excretion of prostanoids and their possible functional significance

The urinary concentrations of prostaglandins(PG) E2, 6-keto-PGF1 alpha (6KPGF) and thromboxane (Tx) B2 were measured by RIA method during both hypotonic polyuria (oral water load) and subsequent antidiuresis (low-dose infusion of lysine-8-vasopressin). The study was performed on healthy women either in normal potassium balance (N, n = 14) or sustained potassium depletion (D3, n = 6). Potassium depletion (KD) was induced by low potassium dietary intake (less than or equal to 10 mmol/d) and natriuretic treatment over a period of 8 days; the net losses of NaCl and H2O were replaced; the cumulative potassium deficit was 198 +/- 22 mmol. Further studies were performed after indomethacin treatment in both experimental conditions. 1) As compared to normal potassium balance in KD group the urinary prostanoid excretions were reduced even in absence of significant differences in urinary flow rate. The urinary excretion of 6KPGF was more impaired than that of TxB2 in both polyuria and antidiuresis. 2) Indomethacin inhibited the urinary prostanoid excretions in normal potassium balance and KD groups. The urinary excretion of PGE2 was more impaired than that of both 6KPGF and TxB2.     

Role of prostanoids in the control of renal function in normal potassium balance and in acute experimental potassium depletion. 4. Relation of extrarenal parameters, renal function parameters and urinary excretion of prostanoids

The renal function has been evaluated by clearance (cl.) method during hypotonic polyuria and successive moderate antidiuresis induced by a low dose of lysine-8-vasopressin; four 15 min and two 60 min cl. periods were performed, respectively. Glomerular filtration rate was estimated by creatinine cl.; the osmotic cl. (Cosm, CH2O), the absolute and fractional excretions of water, sodium, potassium and chloride were determined by usual methods. The urinary concentrations of PGE2, 6-keto-PGF1 alpha (6KPGF) and TxB2 were measured by RIA. The study protocol was applied in normal potassium balance and experimental potassium balance (KD), both in absence and presence of indomethacin. In KD groups with a potassium cumulative deficit of 198.4 +/- 22.2 meq (D3; n = 6) during polyuria significant correlations are consistent with the hypothesis that the lower the plasma potassium concentration is the higher the urinary chloride excretion and the inhibition of distal fractional chloride reabsorption. Moreover, by utilizing the polyuria and antidiuresis data pool, the effects of urine flow rate changes on PGE2 and 6KPGF urinary excretions are blunted as compared to normal potassium balance (n = 14). After indomethacin treatment (D3.I) the following functional relationships are disclosed: a) the lower the kaliemia is the lower the urinary chloride and potassium excretions and the higher the fractional isosmotic reabsorption; b) the lower the urinary potassium excretion is the lower the urinary chloride excretion. In both D3 and D3.I experimental groups the positive correlation between urinary chloride excretion and urinary potassium excretion is significant.     

Further research on the role of prostanoids in controlling renal function in humans in normal potassium balance and acute experimental potassium depletion. I: Studies of normal potassium balance. Effects of indomethacin

The renal function was studied by clearance (cl.) method during hypotonic polyuria (oral water load followed by 5% dextrose solution infusion) and successive relative antidiuresis induced by lysine-8-vasopressin (LVP) administration (5 microU in bolo followed by continuous infusion at a rate of 0.04 microU/min). Four 15 min and two 60 min clearance (cl.) periods were performed during hypotonic polyuria and antidiuresis, respectively. Glomerular filtration rate was estimated by creatinine cl.; the osmotic cl. (Cosm, CH2O), the absolute and fractional excretions of water, sodium, potassium and chloride were determined by usual methods. The urinary PGE2, 6-keto-PGF1 alpha and TxB2 concentrations were determined by RIA method. Fourteen healthy women submitted to a normal sodium and potassium daily intake were studied; in 6 of them paired studies in absence and in presence of indomethacin (100 mg, i.m.), respectively, were performed. LVP induced a significant reduction of creatinine cl., urinary flow rate and of prostanoid excretion. In hypotonic polyuria, indomethacin significantly reduced the creatinine cl. and the diuretic response to the water load; moreover the urinary PGE2 and 6-keto-PGF1 alpha excretions were significantly lower (85.6 +/- 1.9% and 37.7 +/- 3.2%) while the reduction of urinary TxB2 excretion was not significant (34.4 +/- 13%). Indomethacin did not affect significantly the LVP renal effects in normal potassium balance.     

Further research on the role of prostanoids in controlling renal function in humans in normal potassium balance and acute experimental potassium depletion. III: Effects of indomethacin in potassium depletion

The renal function was evaluated by clearance (cl.) method during hypotonic polyuria and successive relative antidiuresis induced by lysine-8-vasopressin administration. Four 15 min and two 60 min cl. periods were performed in hypotonic polyuria and antidiuresis, respectively. Glomerular filtration rate was estimated by creatinine cl., the osmotic cl. (Cosm' CH2O), the absolute and fractional excretions of water, sodium, potassium and chloride were determined by usual methods. The urinary PGE2, 6-keto-PGF1 alpha and TxB2 excretions were determined by RIA method. The study protocol was applied on 14 healthy women in acute potassium depletion, treated with indomethacin (100 mg i.m. at the end of the oral water load). In Group D3 (n = 6) in the presence of a greater potassium cumulative deficit (198.4 +/- 22.2 meq), in hypotonic polyuria, indomethacin induces significant effects as an increase of fractional hydro-electrolytic reabsorptions and as a decrease of urinary prostanoid excretion. The indomethacin tubular action in potassium depletion differs significantly from that observed in normal potassium balance.     

Urinary prostanoid excretion in healthy women with different degrees of induced potassium depletion.

Plasma renin activity (PRA), urinary excretions of PGE2, 6-keto-PGF1 alpha (6KPGF), TXB2 and renal function were determined in healthy women both in normal potassium balance (N, n = 14) and in experimental potassium depletion (KD). KD was induced by natriuretic treatment--associated to replacement of net NaCl and water losses--in the presence of either normal (congruent to 50 mmol/d) or low (less than or equal to 10 mmol/d) dietary potassium intake. By using different depletive patterns, three groups with estimated cumulative potassium deficit (mean +/- SEM) of 124 +/- 38 (KD0, n = 8), 160 +/- 43 (KD1, n = 8) and 198 +/- 22 mmol (KD2, n = 6), respectively, were obtained. Renal function by the clearance (cl.) method and urinary prostanoid concentrations by the RIA method were estimated during hypotonic polyuria (oral water load) and subsequent moderate antidiuresis induced by a low-dose infusion of lysine-8-vasopressin. 1. In KD0 group the potassium depletive treatment was inefficacious in significantly reducing either the plasma potassium concentration (PK) or the urinary potassium excretion (UKV). The reductions of PK and UKV as well as the enhancement of PRA became significant in KD1 and KD2 groups. 2. The urinary prostanoid excretions were not significantly changed in the KD0 and KD1 groups while in the KD2 group they were reduced, mainly concerning the urinary 6KPGF excretion. 3. Furthermore in the KD2 group, with larger potassium depletion, some of the typical hypokalemic renal dysfunctions appeared. The data suggest that a pathophysiologically critical degree of potassium depletion is associated with an inhibited renal prostanoid synthesis as well as an increased renin secretion.     

Renal function in experimental potassium depletion. II. Indomethacin and effects of lysine-8-vasopressin in hypotonic polyuria

Renal function has been studied by the clearance (cl.) method during hypotonic polyuria--four 15-min cl. periods--and successive antidiuresis--two 60-min cl. periods (A1, A2)--induced by lysine-8-vasopressin (LVP), 5 mU in bolus followed by infusion at a rate of 0.04 mU/min. The endogenous creatinine cl. (Cc) and the osmotic cls. (Cosm, CH2O) were determined by the usual methods as well as the absolute and fractional urinary excretions of water, sodium, chloride and potassium. The urinary concentrations of PGE2, 6-keto-PGF1 alpha and TxB2 were determined by the RIA method. This study protocol has been applied to 20 healthy women submitted to paired functional explorations in both the absence and presence of indomethacin (100 mg i.m.); the drug effects have been evaluated in both normal potassium balance (N2, n = 6) and in two groups of potassium depletion (KD) with potassium cumulative deficit of 160 +/- 43 (D2, n = 8) and 198 +/- 22 meq (D3, n = 6), respectively. As regards the early % effects of LVP, i.e. (A1-P)% of P (mean polyuria), the inhibition of prostanoid synthesis with indomethacin produced significant changes: 1) an enhanced reduction in renal chloride excretion in all experimental groups; 2) a reduction in renal sodium and chloride fractional excretions in both KD groups; 3) an enhanced antidiuretic effect in D3 only, i.e. in the experimental condition with inhibition of prostanoid renal synthesis present during the control study.     

Renal function in experimental potassium depletion. I. Effects of lysine-8-vasopressin in hypotonic polyuria

Renal function has been studied by the clearance (cl.) method during hypotonic polyuria--four 15-min cl. periods--and successive antidiuresis--two 60-min cl. periods (A1, A2)--induced by lysine-8-vasopressin (LVP), 5 mU in bolus followed by infusion at a rate of 0.04 mU/min. The endogenous creatinine cl. (Cc) and the osmotic cls. (Cosm, CH2O) were determined by the usual methods as well as the absolute and fractional urinary excretions of water, sodium, chloride and potassium. The urinary concentrations of PGE2, 6-keto-PGF1 alpha and TxB2 were determined by the RIA method. This study protocol has been applied to 28 healthy women either in normal potassium balance (N, n = 14) or after potassium depletion (KD) induced by low potassium dietary intake (less than or equal to 10 meq/d) plus natriuretic treatment according to two different time patterns: two KD groups were obtained with potassium cumulative deficit of 160 +/- 43 (D2, n = 8) and 198 +/- 22 meq (D3, n = 6). The early % effects of LVP, i.e. (A1-P)% of P (mean polyuria), were significantly different only in D3 as compared to N. Precisely, the LVP-effect to reduce Cc was blunted; moreover a LVP-effect to reduce renal sodium and chloride fractional excretions and a tendentiously enhanced LVP-effect to reduce water fractional excretion were observed. These tubular effects are likely related to the inhibited renal synthesis of prostanoids in the D3 group.     

Renal effects of the acute inhibition of angiotensin-converting enzyme. I. 1) Studies during normal sodium and potassium balance]

We have investigated the effective role of angiotensin II on the renal function and urinary excretion of some prostanoids in healthy women submitted to different conditions of potassium balance. To this aim we have evaluated the effects of an acute inhibition of angiotensin converting enzyme by enalapril (E). The renal function was explored by clearance (cl.) method during induced hypotonic polyuria (oral water load followed by 5% dextrose solution infusion). During 60 min cl. period the urinary PGE2, 6-keto-PGF1 alpha and TxB2 were determined by RIA method. Each subject received paired studies, in absence and presence of E (10 mg administered per os 1 hour before the water load). Basal values of plasma renin activity (PRA) and urinary aldosterone (excreted during the 24 hours before the water load) were also determined by RIA method. This study protocol was applied in normal potassium balance (n = 6) and induced moderate potassium depletion (n = 6). This paper concerns the group in normal potassium balance in both absence (N3) and presence of E (N3.E). All subjects were submitted to normal dietary intake of sodium (150 mmol/d) and potassium (50 mmol/d). The basal values of PRA, urinary aldosterone and plasma electrolytes were in the normal range. The only significant effect produced by E was a reduction in mean arterial pressure, without significant changes in creatinine cl., urinary hydro-electrolyte excretions as well as urinary excretions of prostanoids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Renal function and urinary prostanoid excretions in salt-depleted women: comparative effects of enalapril and indomethacin treatments.

The acute effects on urinary prostanoid excretion and on renal function induced by pharmacological inhibition of either the angiotensin-converting enzyme or of the cyclooxygenase system, respectively, have been studied in healthy salt-depleted women. Two experimental groups were studied during salt depletion, SD1 (n=8) and SD2 (n=6). Salt depletion was obtained by combining a low sodium chloride dietary intake (< or =60 mmol per day) with natriuretic and potassium sparing treatment. Paired studies were performed in the absence and in the presence of enalapril (SD1 group) or indomethacin (SD2 group). In both paired studies renal function was estimated by the clearance (cl.) method and the urinary concentrations of PGE2, 6-keto-PGF1alpha and TXB2 were estimated by RIA during sustained hypotonic polyuria (induced by oral water load). Enalapril did not influence urinary excretion of prostanoids. Its main significant effects were: (a) a reduction in mean arterial pressure (MAP); (b) an increase in free-water cl. (C(H2O)) and a reduction in osmolar cl. (Cosm); (c) a reduction in the absolute and fractional urinary excretions of sodium and chloride; and (d) a reduction in both the plasma concentration and urinary excretion of potassium. The urinary flow rate and the creatinine cl. were not significantly affected. Indomethacin reduced urinary excretion of prostanoids and in addition it produced the following significant effects: (a) a reduction in urinary flow rate, C(H2O) and Cosm values, and in absolute and fractional urinary excretions of sodium and chloride; and (b) an increase in plasma potassium concentration. MAP, creatinine cl. and urinary potassium excretion were not significantly affected. With regard to the main parameters, both enalapril and indomethacin exerted similar effects on urinary sodium and chloride excretion but opposite effects on C(H2O) and plasma potassium concentration. In conclusion, after enalapril in a salt-depleted state, the functional expression of acute angiotensin II deprivation was partially masked by the activation of a homeostatic system responsible both for improvement in renal salt conservation and for facilitated cellular potassium uptake. After indomethacin in the same setting, the results were consistent with a differential role of prostanoids in modulating or mediating the activities of neuro-hormonal agonists.     

Low-dose dopamine as an activator of renal catecholamine receptors of different classes. I. Studies in water-salt depletion

The renal function in healthy man with salt and water depletion induced by natriuretic treatment was explored during steady hypotonic polyuria. Four 15 min clearance (cl.) periods, before, during and after dopamine (DA) infusion in a subpressor dose were performed. The 12 examined subjects showed different renal hemodynamic responses in the early stage of DA infusion, i.e. hyperemic (4 subjects, subgroup A) or ischemic (8 subjects, subgroup B). A decrease in urinary sodium excretion and increase in tubular sodium reabsorption, in particular at the diluting segment level, were induced by DA in both subgroups, at least in the late stage of infusion. During the control cl. period in subgroup A as compared with B the renal plasma flow was lower and the tubular sodium reabsorption higher, suggesting a relatively higher level of renal adrenergic activity.     

Renal effects of the acute inhibition of angiotensin-converting enzyme. I. 2) Studies during moderate potassium depletion]

We have investigated the relative roles of angiotensin II on the renal function and urinary excretion of some prostanoids in healthy women submitted to different conditions of potassium balance. To this aim we have evaluated the effects of an acute inhibition of angiotensin converting enzyme by enalapril (E). The renal function was explored by clearance (cl.) method during induced hypotonic polyuria (oral water load followed by 5% dextrose solution infusion). During 60 min cl. period the urinary PGE2, 6-keto-PGF1 alpha and TxB2 were determined by RIA method. Each subject received paired studies, in absence and presence of E (10 mg administered per os 1 hour before the water load). Basal values of plasma renin activity (PRA) and urinary aldosterone (excreted during the 24 hours before the water load) were also determined by RIA method. This study protocol was applied in normal potassium balance (n = 6) and induced moderate potassium depletion (n = 6). This paper concerns the group in potassium depletion in both absence (D4) and presence of E (D4.E). Potassium depletion was induced by adaptation to a normal sodium (150 mmol/d) and low potassium (< or = 10 mmol/d) dietary intake combined to natriuretic treatment. The water and NaCl net losses were restored by 0.9% NaCl solution infusion. The cumulative potassium deficit achieved at the end of the depletive treatment was 214 +/- 54 mmol. This treatment induced significant decrease in basal plasma potassium concentration and increase in PRA without affecting urinary aldosterone and plasma sodium concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential effects of various vasoactive drugs on basal and stimulated levels of TXB2 and 6-keto-PGF1 alpha in rat brain

Thromboxane B2 and 6-keto-PGF1 alpha (6KPGF1 alpha), the major stable metabolites of thromboxane and prostacyclin, are present in the CNS, where they appear to be mainly produced within and/or acting upon the vascular district. Their concentrations are of few pg/mg protein in rat brain cortex of animals sacrificed by microwave (MW) radiation, procedure which inactivates tissue enzymes and allows the determination of endogenous "basal" levels of eicosanoids. Levels of 6KPGF1 alpha and especially those of TxB2 increase several fold over the basal values in brain cortex of animals sacrificed by decapitation followed by a few minute interval before analysis (post-decapitation ischemia, PDI). Pretreatment of animals with the vasoactive drug papaverine, resulted in elevation of brain basal levels of 6KPGF1 alpha and with the carbochromene derivative AD6 in reduction of basal levels of TxB2, whereas the calcium antagonist nifedipine and dipyridamole did not modify basal levels of the two eicosanoids. Treatments with papaverine and AD6 reduced the accumulation of TxB2 and enhanced that of 6KPGF1 alpha occurring after PDI, to different extents, both resulting, however, in reduction of the TxB2/6KPGF1 alpha ratio. Nifedipine instead, decreased the release of both eicosanoids and resulted in elevation of the TxB2/6KPGF1 alpha ratio, whereas dipyridamole had no effect. In conclusion, the evaluation of the overall effects of drug treatments on the TxB2/6KPGF1 alpha ratio in cerebral tissue, provided useful informations on the pharmacological modulation of vascular eicosanoids in this district.     

Relation between acute changes in diuresis and renal prostaglandins. I: Induced hypotonic polyuria

We have evaluated the effects of indomethacin (I) and of a rich in linoleic acid phosphatidylcholine (E) on the renal function and on the PGE urinary excretion during steady hypotonic polyuria. 5 normal subjects have been studied in the absence of treatment (TA) and after treatment with I, E, E + I. The renal function has been estimated by clearance (cl.) method during hypotonic polyuria induced by oral water loading and i.v. infusion of 5% dextrose solution. The glomerular filtration rate has been estimated by cl. of endogenous creatinine; moreover have been measured the osmotic clearances (Cosm, CH2O), the sodium and potassium clearances (CNa, CK), the mean arterial pressure (PA) and the urinary prostaglandins of E series (PGE) by RIA method. In I condition is observed: a) a trend to a glomerular filtration rate decrement; b) a significant decline of the urinary flow rate, CH2O, UPGV and a significant increment of the urinary osmolarity; c) a trend to an increment of potassium and a decrement of sodium urinary excretions; d) a significant increase of PA. It is possible that the contrary effects observed during the hypotonic polyuria in E condition depend on the stimulating effects of this material on the PG intrarenal synthesis.     

Resistance of 1-deamino-[8-D-arginine]-vasopressin to in vitro degradation as compared with arginine vasopressin

In order to elucidate the mechanism(s) responsible for the prolonged antidiuretic activity of 1-deamino-[8-D-arginine]-vasopressin (dDAVP), antidiuretic activities of dDAVP and arginine vasopressin (AVP) were determined in the rat following either oral administration or incubation with AVP-degrading enzymes and reagents. Oral administration of dDAVP to conscious water-loaded rats resulted in significant antidiuresis while AVP resulted in slight and transient antidiuresis. In the ethanol anesthetized water-loaded rats, antidiuretic activities of 136pg of AVP and 50pg of dDAVP, which were found to be equipotent, were compared after incubation with digestive enzymes (pepsin, trypsin, alpha-chymotrypsin), late pregnancy plasma, or sodium thioglycollate. The antidiuretic activity of AVP was completely destroyed by 30-min incubation with trypsin, alpha-chymotrypsin, or late pregnancy plasma and almost all AVP was inactivated by 0.2 M sodium thioglycollate. On the other hand, the antidiuretic activity of dDAVP was not destroyed by trypsin or pregnancy plasma but was partly destroyed by alpha-chymotrypsin and sodium thioglycollate. Neither the antidiuretic activity of AVP nor that of dDAVP was affected by pepsin. Thus, the antidiuresis observed after oral administration of dDAVP might be brought about by the resistance to digestive enzymes. Furthermore, the resistance of dDAVP to digestive enzymes, late pregnancy plasma and sodium thioglycollate might be responsible for the prolonged antidiuretic action of dDAVP in vivo.     

Renal effects of the acute inhibition of angiotensin-converting enzyme. I. 3) Relative roles of angiotensin II and prostanoids in early hypokalemic dysfunction]

We have investigated the relative roles of some renal prostanoids and angiotensin II in the hypokalemic renal dysfunction. To this aim we have evaluated the renal function in healthy women in induced potassium depletion of moderate degree before and after acute inhibition of cyclooxygenase (indomethacin, I) or angiotensin converting enzyme (enalapril, E). The renal function was explored by clearance (cl.) method during hypotonic polyuria induced by oral water load followed by 5% dextrose solution infusion; the urinary PGE2, 6-keto-PGF1 alpha and TxB2 were determined by RIA method. Potassium depletion was induced in 12 subjects by adaptation to low potassium (< or = 10 mmol/d) and normal sodium (150 mmol/d) dietary intake combined to natriuretic treatment. The water and NaCl net losses were restored by 0.9% NaCl solution infusion. In 6 subjects paired functional studies were performed in absence (D3) and presence of I (D3.I), 100 mg administered i.m. immediately before the water load. In other 6 subjects, paired studies were performed in absence (D4) and presence of E (D4.E), 10 mg administered per os 1 hour before the water load. No significant difference between D3 and D4 was observed as regards the potassium cumulative deficit as well as the basal values of plasma potassium concentration and plasma renin activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Abnormal response of urinary eicosanoid system to norepinephrine infusion in patients with essential hypertension.

To define the role of the renal eicosanoid system in sustaining renal homeostasis in hypertension, we investigated the alterations in urinary excretions of 6-keto-prostaglandin F1 alpha (6-keto-PGF1 alpha), a stable metabolite of vasodepressor prostacyclin, and thromboxane B2 (TXB2), a stable metabolite of vasoconstrictor TXA2, when norepinephrine was continuously infused for 90 min in hypertensive (n = 13) and normotensive subjects (n = 14). There was no difference in plasma norepinephrine concentration after the infusion between the hypertensive and the normotensive subjects. Moreover, the percent changes in renal vascular resistance elicited by norepinephrine in the hypertensives were equal to those of the normotensive subjects. In the normotensive subjects, the norepinephrine infusion significantly increased urinary 6-keto-PGF1 alpha excretion and decreased urinary excretion of TX, both of which are beneficial for sustaining renal function. In fact, the greater the production of renal 6-keto-PGF1 alpha was, the less the reduction of renal blood flow and urinary sodium excretion was. In the hypertensive subjects, however, these normal responses of the renal eicosanoid system, seen in the normotensives, were abolished; urinary 6-keto-PGF1 alpha was unaltered and thromboxane generation was rather increased. Thus, the renal eicosanoid system dysfunctions in hypertensive subjects when the renal circulation is challenged by norepinephrine. These abnormal responses are likely to cause sodium retention and could contribute, in part, to the hypertensive mechanism in patients with essential hypertension.     

Renal effects of long-term leptin infusion and preventive role of losartan treatment in rats

BACKGROUND: Leptin has direct and indirect effects on renal pathophysiological characteristics. In the present study, the effects of long-term leptin infusion on the renal hemodynamics, renal excretory functions, and the expression of transforming growth factor-beta (TGF-beta), plasma endothelin-1 (ET-1) levels, and preventive effects of the angiotensin II type 1 receptor antagonist, losartan, on these renal changes were evaluated. METHODS: The study was performed by using forty Wistar albino rats. On day 0, osmotic mini-pumps filled with leptin or placebo were intraperitoneally placed under sterile conditions. The rats in Group L (Leptin group, n=15) and Group LL (Leptin-losartan group, n=15) were given recombinant murine leptin at a rate of 250 ng per hour for 28 days. Control rats (Group C, n=10) were administered placebo at the same infusion rate. The rats in Group LL were also administered losartan (10 mg kg(-1) d(-1)) perorally for 28 days. On day 28, the rats were placed in metabolic cages, and the food and water intakes were determined, and the urine was collected for 24 h. At the end of the study, systolic blood pressure (SBP), diastolic blood pressure (DBP) were determined directly from the left femoral artery, and renal blood flow (RBF) was recorded indirectly using a laser Doppler flow module. RESULTS: Leptin infusion did not produce any changes in systemic arterial blood pressures and urinary flow rate. The rates of creatinine (Cr), sodium (Na), and protein excretions of the animals infused leptin were significantly increased. The urinary Cr and Na excretions were decreased, while the urinary protein excretion was normalized with the losartan treatment. The rats infused leptin had also higher circulating ET-1 levels. ET-1 levels were also reversed to the normal values with the losartan treatment. Renal TGF-beta1 expression was determined immunohistochemically, and it was more prominent in the renal tubules from the rats treated with leptin. The losartan treatment had no effect on renal TGF-beta1 expression. CONCLUSIONS: Our results indicate that pathophysiological increases in plasma leptin concentrations cause enhanced renal Na, Cr and protein excretions, and high circulating ET-1 levels. Na and Cr excretions were decreased, while proteinuria and plasma ET-1 levels were normalized by losartan treatment, suggesting that renin-angiotensin system activation may have a role in leptin induced renal changes. TGF-beta1 may have an important role in leptin induced nephropathy.