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.     

Effect of chronic salt loading on renal Na-K-ATPase activity in the rat

The effect of chronic salt loading in rats fed regular chow diet on renal Na-K-ATPase was studied. The high salt intake was associated with increased filtered load of sodium (control: 126 +/- 3.9 mueq/min, salt loaded: 146 +/- 2.5, mueq/min, P less than 0.001), increased net reabsorption of sodium (control: 125.3 +/- 3.9 mueq/min, salt load: 134.8 +/- 2.4 mueq/min, P less than 0.05), increased urinary excretion of potassium (control: 2.4 +/- 0.09 mueq/min/min; salt loaded: 3.0 +/- 0.1 mueq/min, P less than 0.001) and increase in single kidney weight (control: 0.798 +/- 0.010 g, salt loaded: 0.937 +/- 0.015 g, P less than 0.001). The above mentioned changes were associated with significant increase in renal microsomal and whole homogenate medullary Na-K-ATPase activity in the salt loaded group (microsomes: control 74.1 +/- 4.9 mumole Pi/mg prot/hr, salt loaded 112.7 +/- 6.0 mumole Pi/mg prot/hr, P less than 0.001; whole homogenate: control 22.7 +/- 1.0 mumole Pi/mg prot/hr, salt load 29.4 +/- 1.6 mumole Pi/mg prot/hr, P less than 0.005), while cortical and papillary Na-K-ATPase activity remained unchanged. Taken together, these results show that increased filtered and reabsorbed load of sodium, which follows high salt intake, is associated with an increased renal Na-K-ATPase activity. The preferential rise in medullary enzymatic activity may be interpreted as suggesting that these changes may stem from increased delivery and reabsorption of sodium in the ascending limb of Henle's loop.     

Bicarbonate-activated ATPase activity in renal cortex of chronically acidotic rats.

The effect of chronic NH4Cl-induced acidosis on the activity of a bicarbonate-activated component of ATPase was studied in homogenates of renal tissue from Wistar rats. This particular component of ATPase, which is maximally stimulated by 50 mM bicarbonate, and is insensitive to the action of ouabain, has been implicated in the active transport of bicarbonate in various tissues. The activity of this enzyme in cortical homogenates from an acidotic group of animals was 4.3 +/- 0.4 mumol Pi/mg protein per hour compared with 5.8 +/- 0.3 mumol Pi/mg protein per hour in a control group (p less than 0.02). No significant change in bicarbonate ATPase activity was observed in medullary homogenates, and NaK-ATPase activity remained the same in cortex and medulla of both groups. Subcellular fractionation of the cortical tissue homogenates revealed that bicarbonate ATPase activity in a microsomal fraction from acidotic animals was 6.5 +/- 1.1 mumol Pi/mg protein per hour compared with 9.4 +/- 1.2 mumol Pi/mg protein per hour in control animals (p less than 0.02). Bicarbonate ATPase activity in other subcellular fractions was not different in the two groups of animals. These findings are compatible with the hypothesis that a certain percentage of bicarbonate reabsorption in the nephron is mediated by a bicarbonate-activated component of ATPase.     

The role of alpha-adrenergic receptors in the vasoconstrictor response induced by indomethacin in the kidney.

The effect of indomethacin, an inhibitor of prostaglandin (PG) synthesis, was studied on the renal circulation, Na+ and water excretion in anaesthesized dogs during alpha-receptor inhibition. Indomethacin decreased cortical blood flow (CBFcontr, 454 +/- 142; CBFindo, 332 +/- 51 ml per min per 100 g; p less than 0.02) as well as medullary blood flow (OMBFcontr, 339 +/- 95; OMBFindo, 183 +/- 46 ml per min per 100 g; p less than 0.001), salt and water excretion, further it caused a shift in the intrarenal blood flow distribution toward the cortex. Alpha-blockade prevented the indomethacin-induced vasoconstriction in the cortex (CBF alpha inhibition + indo, 455 +/- 76 ml per min per 100 g) but not in the medullar (OMBF alpha inhibition + indo, 259 +/- 102 ml per min per 100 g, p less than 0.05). Alpha-blockade failed to prevent the indomethacin-induced antidiuresis, antinatriuresis and the intrarenal blood flow redistribution. GFR remained unaffected in all three series of studies. Our experimental findings are in line with the presumption that alpha-receptors are involved in the renal circulatory changes caused by indomethacin, probably as a result of an enhanced NE release during the inhibition of PG production. A NE--PG feed back mechanism is suggested in the regulation of renal circulation. The reduction of salt and water output induced by indomethacin appears to be independent of the alterations in renal haemodynamics, and seems rather to be the result of enhanced Na+ reabsorption, predominantly at the distal segment of the nephron, in the absence of PG, and/or a direct action of indomethacin.     

Effect of saline infusion on kidney and collecting duct function in atrial natriuretic peptide (ANP) gene "knockout" mice.

Atrial natriuretic peptide (ANP) is thought to play a role in renal regulation of salt balance by reducing tubular reabsorption of sodium and chloride. Therefore, in the chronic absence of this hormone, a defect of salt excretion should be evident. We used an ANP gene deletion model to test this premise. F2 homozygous mutant mice (-/-) and their wild-type littermates (+/+) were fed an 8% NaCl diet prior to an acute infusion of isotonic saline. Arterial blood pressures, renal excretions of salt and water, as well as collecting duct transport of fluid and electrolytes were measured. Pressures were significantly higher in -/- compared with +/+ mice (139 +/- 4 vs. 101 +/- 2 mmHg; 1 mmHg = 133.3 Pa). There was no difference in glomerular filtration rate (-/- = 0.84 +/- 0.06; +/+ = 0.81 +/- 0.04 mL x min(-1) x g(-1) kidney weight). In the collecting duct, sodium and chloride reabsorptions were significantly higher in the -/- group than in the +/+ group. As a result, natriuresis and chloruresis were relatively reduced (U(Na)V: -/- = 8.6 +/- 1.1; +/+ = 14.0 +/- 1.1; U(Cl)V: -/- = 10.1 +/- 1.4; +/+ = 16.0 +/- 1.1 micromol x min(-1) x g(-1) kidney weight). We conclude that the absence of endogenous ANP activity in mice on a high-salt diet subjected to acute saline infusion causes inappropriately high reabsorption of sodium and chloride in the medullary collecting duct, resulting in a relative defect in renal excretory capacity for salt.     

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.     

(Na-K)ATPase activity along the nephrons in normal and adrenalectomized rats measured by quantitative cytochemistry

A cytochemical method was used to measure total, ouabain insensitive and specific (Na-K)ATPase activities along the rat nephron. Enzyme activity was expressed as per cent of mean integrated extinction with reference to a calibrated filter. The lowest mean values of total, ouabain-insensitive, and (Na-K)ATPase activities were found in the proximal convoluted tubule (PCT). In the distal convoluted tubule (DCT), total and ouabain-insensitive activities (77.8 per cent and 45.8 per cent, respectively) were significantly higher than in the medullary thick ascending limb (MAL) (66.0 per cent and 24.6 per cent, respectively). Mean values of (Na-K)ATPase activity were significantly lower in DCT than in MAL (32.0 per cent and 41.3 per cent, respectively). Using Lineweaver-Burk plots, the KM ATP value for total ATPase activity was found to be 2.33, 1.79, and 3.63 mM in DCT, MAL, and PCT respectively. Maximal velocity was lower in PCT than in MAL and DCT. For (Na-K)ATPase, the smallest KM value was found in MAL (0.95 mM) and was 2.73 and 5.71 mM in DCT and PCT respectively. Maximal velocity was the highest in MAL (49.3 per cent), lower in DCT (36.1 per cent) and least in PCT (22.5 per cent). ATPase was measured in the MAL and DCT from rats fed a normal (N-Na+) or a high (Hi-Na+) sodium diet, and from Hi-Na+ rats one week after adrenalectomy (ADX). In the MAL, (Na-K)ATPase tended to be higher in Hi-Na+ than in rats, but was significantly lower in ADX than in Hi-Na+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of renal medullary H2O2 on salt-induced hypertension and renal injury

Dahl salt-sensitive (SS) and consomic, salt-resistant SS-13(BN) rats possess substantial differences in blood pressure salt-sensitivity even with highly similar genetic backgrounds. The present study examined whether increased oxidative stress, particularly H2O2, in the renal medulla of SS rats contributes to these differences. Blood pressure was measured using femoral arterial catheters in three groups of rats: 1) 12-wk-old SS and consomic SS-13(BN) rats fed a 0.4% NaCl diet, 2) SS rats fed a 4% NaCl diet and chronically infused with saline or catalase (6.9 microg x kg(-1) x min(-1)) directly into the renal medulla, and 3) SS-13(BN) fed high salt (4%) and infused with saline or H2O2 (347 nmol x kg(-1) x min(-1)) into the renal medullary interstitium. After chronic blood pressure measurements, renal medullary interstitial H2O2 concentration ([H2O2]) was collected by microdialysis and analyzed with Amplex red. Blood pressure and [H2O2] were both significantly higher in SS (126 +/- 3 mmHg and 145 +/- 17 nM, respectively) vs. SS-13(BN) rats (116 +/- 2 mmHg and 56 +/- 14 nM) fed a 0.4% diet. Renal interstitial catalase infusion significantly decreased [H2O2] (96 +/- 41 vs. 297 +/- 52 nM) and attenuated the hypertension (146 +/- 2 mmHg catalase vs. 163 +/- 4 mmHg saline) in SS rats after 5 days of high salt (4%). H2O2 infused into the renal medulla of consomic SS-13(BN) fed high salt (4%) for 7 days accentuated the salt sensitivity (145 +/- 2 mmHg H2O2 vs. 134 +/- 1 mmHg saline). [H2O2] was also increased in the treated group (83 +/- 1 nM H2O2 vs. 44 +/- 9 nM saline). These data show that medullary production of H2O2 may contribute to salt-induced hypertension in SS rats and that chromosome 13 of the Brown Norway contains gene(s) that protect against renal medullary oxidant stress.     

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.     

Effect of angiotensin II infusion in rats on Na,K-ATPase activity in renal cortical microsomal preparations

Direct dose-dependent effects of angiotensin II on renal tubular sodium reabsorption have been demonstrated. Alterations in tubular sodium reabsorption may occur via modulation of renal Na,K-ATPase activity. Thus, these experiments were undertaken to ascertain whether angiotensin II could influence renal cortical Na,K-ATPase activity. Angiotensin II, 495 ng/microliters/h, or vehicle (controls) was infused for 24 h via miniosmotic pumps 48 h after rats were adrenalectomized and implanted with osmotic pumps containing 12.5 micrograms/microliters corticosterone (Treatment I) or both corticosterone and 0.2 microgram/microliter aldosterone (Treatment II), and in rats receiving 3% NaCl in their food (sodium loaded, Treatment III). Rats receiving Treatments I and III received saline to drink. Renal cortical microsomal membranes were prepared, and the effects of angiotensin II infusion on the K1/2 and Vmax for Na, K, and ATP determined. Angiotensin II infusions were associated with (i) a decrease (P less than 0.001) in the K1/2 for Na activation of Na,K-ATPase from 14 +/- 3 to 6 +/- 1 (n = 4 experiments), 16 +/- 1 to 12 +/- 1 (n = 5), and 12 +/- 3 to 7 +/- 1 (n = 5) mM (means +/- SE) for treatments I, II, and III, respectively; (ii) no changes in the K1/2 for K activation or the Km for ATP; (iii) no changes in the Vmax for Na, K, or ATP; and (iv) no change in Mg-ATPase activity. We conclude that angiotensin II infusion is associated with a decrease in the K1/2 of renal cortical Na,K-ATPase activity for sodium. This action of angiotensin II on the enzyme activity may contribute to the regulation of tubular sodium transport.     

Na-K-dependent ATPase in red cells and thyroid status

The Relationship between ouabain-sensitive ATPase (Na-K ATPase) activity in erythrocytes and the thyroid status was studied in 36 patients with Graves' disease and 58 patients receiving L-thyroxine (T4) replacement therapy. Forty normal children served as control. Total ATPase activity in 4 untreated hypothyroid patients was significantly reduced (11.0 +/- 4.6 vs 17.3 +/- 4.1 micrograms-P/h/mg-protein, P less than 0.01), and Na-K ATPase was undetectable, both of which were normalized after 4 weeks of L-T4 therapy. Na-K ATPase in hyperthyroid patients was also decreased (0.9 +/- 0.8 vs. 4.0 +/- 2.7, P less than 0.01), but was gradually normalized after 3 months of euthyroid state. Clinically euthyroid children treated with L-T4 were divided into 2 groups with regard to Na-K ATPase activity, normal and low. Analysis of the possible factors producing this difference revealed that, in primary hypothyroidism, the factor appeared to be the endogenous T4 level, while in patients with dwarfism, the secretory capacity of TSH or TSH-releasing hormone (TRH) was contributory. Thus Na-K ATPase activity in red cells remains within the normal range after L-T4 replacement in the presence of a severe degree of primary hypothyroidism or in association with secondary or tertiary hypothyroidism. Other factors such as the L-T4 dose, duration of the therapy, serum T4 and T3 concentrations, were not significantly different in the two groups. These results indicate that (1) Na-K ATPase in red cells is decreased in hyper- or hypothyroid state, (2) restoration of normal activity requires 1-3 months of euthyroid period, and (3) it is a sensitive index of peripheral thyroid status over the preceding few months.     

Natriuretic effect of atrial natriuretic peptide in diabetes insipidus rats

Washout of the solute concentration gradient in the renal medullary interstitium has been suggested to play a role in mediating the natriuretic response to atrial natriuretic peptide (ANP). The purpose of this study was to determine the effects of ANP 8-33 on sodium excretion in Brattleboro diabetes insipidus (DI) rats, in which medullary tonicity is known to be decreased as compared to Long-Evans (LE) control rats. Basal urine osmolality (Uosm) was significantly lower in DI rats as compared to LE rats (123 +/- 6 vs 673 +/- 38 mOsm/kg). Infusion of ANP 8-33 at a rate of 4 micrograms/kg/hr for 60 min resulted in a significantly greater increase in UnaV (delta 6.1 +/- 1.2 vs delta 2.9 +/- 0.7 microEq/min) and urine flow (delta 40 +/- 12 vs delta 8 +/- 7 microliter/min) in the LE rats than in the DI rats. The greater natriuresis occurred in the LE rats despite no significant change in Uosm. Fractional lithium reabsorption (an indicator of proximal sodium reabsorption) decreased similarly in both groups. Infusion of ANP had no effect on mean arterial pressure in LE and DI groups. In summary, infusion of ANP in the DI rat resulted in a significant natriuresis, albeit less than in LE rats. The natriuresis in the LE rats occurred despite no significant change in Uosm. These data suggest that mechanisms other than medullary washout are responsible for the natriuretic effects of ANP.     

Salt intake and intestinal dopaminergic activity in adult and old Fischer 344 rats

We have earlier shown that the renal dopaminergic system failed to respond to high salt (HS) intake in old (24-month-old) Fisher 344 rats (Hypertension 1999;34:666-672). In the present study, intestinal Na+,K+-ATPase activity and intestinal dopaminergic tonus were evaluated in adult and old Fischer 344 rats during normal salt (NS) and HS intake. Basal intestinal Na+,K+-ATPase activity (nmol Pi/mg protein/min) in adult rats (142+/-6) was higher than in old Fischer 344 rats (105+/-7). HS intake reduced intestinal Na+,K+-ATPase activity by 20% (P<0.05) in adult, but not in old rats. Dopamine (1 microM) failed to inhibit intestinal Na+,K+-ATPase activity in both adult and old Fischer 344 rats (NS and HS diets). In adult animals, co-incubation of pertussis toxin with dopamine (1 microM) produced a significant inhibitory effect in the intestinal Na+,K+-ATPase activity. L-DOPA and dopamine tissue levels in the intestinal mucosa of adult rats were higher (45+/-9 and 38+/-4 pmol/g) than those in old rats (27+/-9 and 14+/-1 pmol/g). HS diet did not change L-DOPA and DA levels in both adult and old rats. DA/L-DOPA tissue ratios, an indirect measure of dopamine synthesis, were higher in old (1.1+/-0.2) than in adult rats (0.6+/-0.1). Aromatic L-amino acid decarboxylase (AADC) activity in the intestinal mucosa of old rats was higher than in adult rats. HS diet increased the AADC activity in adult rats, but not in old rats. It is concluded that intestinal dopaminergic tonus in old Fisher 344 rats is higher than in adult rats and is accompanied by lower basal intestinal Na+,K+-ATPase activity. In old rats, HS diet failed to alter the intestinal dopaminergic tonus or Na+,K+-ATPase activity, whereas in adult rats increases in AADC activity were accompanied by decreases in Na+,K+-ATPase activity. The association between salt intake, increased dopamine formation and inhibition of Na+,K+-ATPase at the intestinal level was not as straightforward as that described in renal tissues.     

Renal denervation chronically lowers arterial pressure independent of dietary sodium intake in normal rats

The present study was designed to test the hypothesis that renal nerves chronically modulate arterial pressure (AP) under basal conditions and during changes in dietary salt intake. To test this hypothesis, continuous telemetric recording of AP in intact (sham) and renal denervated (RDNX) Sprague-Dawley rats was performed and the effect of increasing and decreasing dietary salt intake on AP was determined. In protocol 1, 24-h AP, sodium, and water balances were measured in RDNX (n = 11) and sham (n = 9) rats during 5 days of normal (0.4% NaCl) and 10 days of high (4.0% NaCl) salt intake, followed by a 3-day recovery period (0.4% NaCl). Protocol 2 was similar with the exception that salt intake was decreased to 0.04% NaCl for 10 days after the 5-day period of normal salt (0.04% NaCl) intake (RDNX; n = 6, sham; n = 5). In protocol 1, AP was lower in RDNX (91 +/- 1 mmHg) compared with sham (101 +/- 2 mmHg) rats during the 5-day 0.4% NaCl control period. During the 10 days of high salt intake, AP increased <5 mmHg in both groups so that the difference between sham and RDNX rats remained constant. In protocol 2, AP was also lower in RDNX (93 +/- 2 mmHg) compared with sham (105 +/- 4 mmHg) rats during the 5-day 0.4% NaCl control period, and AP did not change in response to 10 days of a low-salt diet in either group. Overall, there were no between-group differences in sodium or water balance in either protocol. We conclude that renal nerves support basal levels of AP, irrespective of dietary sodium intake in normal rats.     

Ouabain binding to renal tubules of the rabbit

It is well known that ouabain, a specific inhibitor of Na-K ATPase-dependent transport, interferes with renal tubular salt reabsorption. In this study, we employed radiochemical methods to measure the kinetics of [3H]ouabain binding to slices of rabbit renal medulla and high resolution quantitative autoradiography to determine the location and number of cellular binding sites. The kinetics obeyed a simple bimolecular reaction with an association constant of 2.86 +/- 0.63 SD x 10(3) M-1 min-1 and a dissociation constant of 1.46 x 10(-3) min-1, yielding an equilibrium binding constant of 0.51 x 10(-6) M. Binding was highly dependent upon temperature. At a concentration of 10(-6) M, the rate of accumulation between 25 degrees C and 35 degrees C exhibited a Q10 of 1.8. At 0 degree C the rate of ouabain dissociation was negligible. The specificity of binding was demonstrated with increasing potassium concentrations. At a concentration of 1 microM, 6 mM, and 50 mM K+ produced a 2.5- and 7-fold decrease, respectively, in the rate of ouabain accumulation observed at zero K+. Binding was completely inhibited by 1 mM strophanthin K. The major site of ouabain binding was the thick ascending limb; little or no binding was observed in thin limbs and collecting ducts. Moreover, binding was confined to the basolateral membranes. From autoradiographic grain density measurements, it was estimated that each cell contains over 4 x 10(6) ouabain binding sites or Na-K ATPase molecules. These results taken together with physiological and biochemical observations suggest that Na-K ATPase plays a key role in salt reabsorption by this segment.     

Enalapril treatment restores the decreased proximal tubule reabsorption in response to acute volume expansion in diabetic rats

The renin-angiotensin system (RAS) plays an important role in the regulation of blood pressure, fluid and electrolyte homeostasis. The RAS is activated and renal interstitial hydrostatic pressure (RIHP) is decreased in diabetic rats. The objective of this study was to evaluate the roles of proximal tubule reabsorption and RAS in the decreased RIHP and blunted natriuretic and diuretic responses to acute saline volume expansion (VE) in diabetic rats. Enalapril was utilized to inhibit angiotensin II (AII) formation. Diabetes mellitus (DM) was induced by a single intraperitoneal (i.p.) injection of streptozotocin (STZ, 65 mg/kg). RIHP was measured by a polyethylene (PE) matrix that was chronically implanted in the left kidney. Fractional excretion of phosphate (FE(Pi)) and fractional excretion of lithium (FE(Li)) were used as indexes for proximal tubule reabsorption. VE significantly increased both FE(Li) and FE(Pi) in all groups of rats studied. However, the increase in FE(Li) (DeltaFE(Li)=17.26+/-3.83%) and FE(Pi) (DeltaFE(Pi)=7.38+/-2.37%) in diabetic rats (DC, n=12) were significantly lower as compared with those in nondiabetic control rats (NC, n=8; DeltaFE(Li)=32.15+/-4.71% and DeltaFE(Pi)=20.62+/-3.27%). The blunted increases in FE(Li) and FE(Pi) were associated with an attenuated increase in RIHP (DeltaRIHP) in DC (1.8+/-0.4 mm Hg) compared with NC rats (4.3+/-0.3 mm Hg). Enalapril treatment (25 mg/kg/day in drinking water) had no effect on nondiabetic rats (NE, n=8) as compared with untreated NC rats, but significantly improved RIHP response (DeltaRIHP) to VE in diabetic rats (DE, n=9; 2.8+/-0.5 mm Hg). Both DeltaFE(Li) and DeltaFE(Pi) were restored by enalapril treatment in diabetic rats and no significant differences were found in DeltaFE(Li) and DeltaFE(Pi) between DE (DeltaFE(Li)=26.81+/-4.94% and DeltaFE(Pi)=10.45+/-4.67%) and NC groups of rats in response to VE. These data suggest that the activated RAS and the decrease in RIHP may play an important role in the increased proximal tubule reabsorption, and the attenuated natriuretic and diuretic responses to acute volume expansion in diabetic rats.     

Effects of low-potassium diet on N-ethylmaleimide-sensitive ATPase in the distal nephron segments.

The present study was undertaken to investigate whether or not potassium deficiency influences N-ethylmaleimide (NEM)-sensitive ATPase in the distal nephron segments of the rat. One group of animals was fed a low-K diet, whereas the normal K-group was given the same diet after supplementation with KCl. The nephron segments examined were: the medullary and cortical thick ascending limbs, the distal convoluted tubule, and the cortical, outer and inner medullary collecting ducts. NEM-sensitive ATPase activity in microdissected segments was measured by a fluorometric microassay. The plasma K+ concentration in the low-K group was 3.1 +/- 0.3 mEq/l compared with 4.2 +/- 0.1 mEq/l in the normal-K group. NEM-sensitive ATPase activity in the outer medullary collecting duct of low-K diet animals was significantly greater than in normal-K animals. There was no significant difference in NEM-sensitive ATPase activity between the two groups of animals in the other nephron segments examined. It is suggested that NEM-sensitive H-ATPase activity in the outer medullary collecting duct is modulated by the potassium status of the animal.     

Digoxin-like immunoreactive factor in rat plasma: effect of sodium and calcium intake

Studies have been performed in rats to determine whether an endogenous material capable of binding to digoxin antibodies is present in the plasma. Such a material has been shown in other species and has been hypothesized to represent an endogenous ligand for the receptor on Na-K ATPase through which cardiac glycosides act. In rats consuming a normal rodent chow (1% calcium by weight) and drinking deionized water, endogenous binding of digoxin antibody in radioimmunoassay amounted to 23.1 +/- 4.6 fM digoxin equivalents/100 microliter of plasma (mean +/- SEM, n = 8). Since a hypothetical role for such an endogenous ligand is the regulation or renal sodium excretion by inhibition of renal Na-K ATPase, the effect of increased sodium intake on plasma levels of this digoxin-like immunoreactive factor (DLIF) was studied. Animals consuming the same chow, but drinking 0.5% NaCl solution in place of water for a 4 week period showed significantly greater DLIF in plasma which was measured at 109.2 +/- 20.3 fM digoxin equivalents/100 microliter of plasma (p less than 0.001). Because DLIF has been implicated in the pathogenesis of hypertension we also studied the effects of calcium intake on plasma levels of DLIF. In previous studies we have shown that rats allowed to drink 0.5% saline develop a moderate hypertension which can be reversed with calcium supplementation. In the present studies, 3 dietary calcium subgroups (0.01% Ca, 1.0% Ca and 4% Ca) were formed among animals drinking water or 0.5% saline for 4 weeks. No effect of low calcium intake on plasma DLIF was found either in water or saline drinkers. However, calcium supplementation produced a significant reduction in plasma DLIF in both water and saline drinking animals.     

Effects of alpha-adrenergic blockade on sodium excretion in normal and chronic salt retaining dogs.

The alpha-adrenergic blocking agent phenoxybenzamine (PBA) was administered intravenously (10 mug kg-1 min-1) during a steady state water diuresis under pentothal anesthesia to six normal dogs, six dogs with chronic throacic inferior vena cava constriction and ascites (caval dogs) and seven dogs chronically salt depleted by sodium restriction and furosemide administration. In normal dogs urinary sodium excretion increased significantly from 265+/56 (SEM) to 370+/65 muequiv./min, whereas no increase in sodium excretion was noted in either caval dogs or salt depleted animals after PBA. In all three groups urine volume, fractional free water clearance and distalsodium load did not change significantly. In normal dogs, tubular sodium reabsorption decreased significantly from 73.4+/2.8% to 63.1+/4.0%, whereas no change was noted in caval or salt depleted dogs. Blood pressure and renal hemodynamics were not significantly altered by PBA administration in any group. These data demonstrate a natriuretic effect of alpha-adrenergic blockade in normal dogs with the major effect in the water clearing segment of the nephron. The absence of any effect in chronic caval or salt depleted dogs suggests that increased alpha-adrenergic activity does not play a significant role in the sodium retention of these animals.     

Role of NO and COX pathways in mediation of adenosine A1 receptor-induced renal vasoconstriction

The mechanism of adenosine A1 receptor-induced intrarenal vasoconstriction is unclear; it depends on sodium intake and may be mediated by changing the intrarenal activity of the nitric oxide (NO) and/or cyclooxygenase (COX) pathway of arachidonic acid metabolism. The effects of 2-chloro-N(6)-cyclopentyl-adenosine (CCPA), a selective A1 receptor agonist, on renal hemodynamics were examined in anesthetized rats maintained on high sodium (HS) or low sodium (LS) diet. Total renal (i.e., cortical) blood flow (RBF) as well as superficial cortical (CBF), outer medullary (OMBF), and inner medullary (IMBF) flows were determined by laser-Doppler. In HS rats, suprarenal aortic infusions of 8-40 nmol/kg/hr CCPA decreased IMBF (15%) and other perfusion indices (22%-27%); in LS rats, IMBF increased 3% (insignificant) and other indices decreased 13%-24%. In LS rats, pretreatment with N-nitro-L-arginine methyl ester prevented the A1 receptor-mediated decrease in RBF and CBF but not OMBF; the response in IMBF was not altered. Pretreatment with indomethacin prevented the decreases in RBF, CBF, and OMBF and did not change the response of IMBF. Thus, within the cortex the vasoconstriction that follows A1 receptor activation results both from inhibition of NO synthesis and from stimulation of vasoconstrictor products of the COX pathway. In the outer medulla, the latter products seem exclusively responsible for CCPA-induced vasoconstriction. The observation that in LS rats IMBF was not affected by stimulation of adenosine A1 receptors suggests that limiting salt intake may help protect medullary perfusion against vasoconstrictor stimuli which have the potential to disturb long-term control of arterial pressure.