Mechanism of hyperreninemia in the potassium-depleted rat

Increased dietary potassium and magnesium attenuate experimental volume dependent hypertension possibly through endogenous sodium-potassium pump inhibitor

We and others have shown that inhibition of cardiovascular muscle (CVM) cell Na+,K-ATPase activity (NKPTA) due to increased level of endogenous sodium potassium pump inhibitor (SPI) is involved in the mechanism of volume expanded (VE) experimental and human essential hypertension (HT). Since diets fortified with very high potassium (K) or very high magnesium (Mg) decrease blood pressure (BP), we have examined the effect of a moderate increase in dietary K alone and a moderate increase in dietary K and Mg on plasma levels of SPI, CVM cell NKPTA, and BP in reduced renal mass (RRM)-salt HT rats, a classical model of VE HT. Seventy Percent-RRM rats were divided in four dietary groups, (1) Na free and normal K and Mg (0Na-K-Mg); (2) normal Na, K and Mg (Na-K-Mg); (3) normal Na and high K (2 x normal), and normal Mg (Na-2K-Mg); and (4) normal Na and high K (2 x normal), and high Mg (2 x normal) (Na-2K-2Mg). As expected, compared to control 0Na-K-Mg rats, Na-K-Mg rats developed HT. Blood pressure increased significantly less in Na-2K-Mg rats whereas, BP did not increase in Na-2K-2Mg rats. Hypertension in NA-K-Mg rats was associated with an increase in plasma SPI and digitalis like factor (DIF) and a decrease in renal and myocardial NKPTA. However, doubling the Mg along with K in the diet (Na-2K-2Mg) normalized SPI and DIF and increased myocardial and renal NKPTA, compared to control 0Na-K-Mg rats. Also, compared to 0Na-K-Mg rats, water consumption, urine excretion, urinary sodium excretion urinary potassium excretion (U(Na)V), and (U(K)V) increased in the other three groups, more so in Na-2K-2Mg rats. These data show that K and Mg have additive effects in preventing an increase in SPI, thus probably preventing the BP increase in RRM rats.

Angiotensin II type 1 receptor blockade ameliorates tubulointerstitial injury induced by chronic potassium deficiency

BACKGROUND

Chronic potassium (K+) deficiency, one of the well-known causes of renal tubulointerstitial injury, is associated with an alteration in vasoactive mediators including persistent generation of renal cortical angiotensin (Ang) II despite the suppression of plasma Ang II, and suppression of urinary nitrite/nitrate excretion. We tested the hypothesis that K+-deficiency-induced renal tubulointerstitial injury could be mediated by Ang II or a reduction in nitric oxide.

METHODS

Rats were fed a K+-deficient diet (0.01% K+) alone, or with either losartan or l-arginine (L-Arg) in drinking water. Control rats were fed with a normal K+ diet (0.36% K+). At the end of 10 weeks, kidneys were excised and renal injury was evaluated.

RESULTS

Serum K+ was similarly depressed in all three groups receiving the K+-deficient diet. Rats on the K+-deficient diet alone developed renal hypertrophy and tubulointerstitial fibrosis with an increase in tubular osteopontin expression, macrophage infiltration and type III collagen deposition. Administration of losartan significantly reduced renal hypertrophy and prevented tubulointerstitial injury in the cortex, although some medullary injury occurred. In contrast, administration of L-Arg did not attenuate tubulointerstitial injury in the cortex, despite a complete recovery of urinary nitrate excretion. Mild but significant improvement of tubular osteopontin expression and macrophage infiltration were observed in the medulla of L-Arg-treated hypokalemic rats.

CONCLUSIONS

These results indicate that hypokalemic renal injury is mediated, at least in part, by Ang II via the Ang II type 1 receptor, with a lesser contribution mediated by a reduction in nitric oxide. Losartan may be beneficial in preventing hypokalemic tubulointerstitial injury.

Altered potassium balance and aldosterone secretion in a mouse model of human congenital long QT syndrome

The voltage-dependent K(+) channel responsible for the slowly activating delayed K(+) current I(Ks) is composed of pore-forming KCNQ1 and regulatory KCNE1 subunits, which are mutated in familial forms of cardiac long QT syndrome. Because KCNQ1 and KCNE1 genes also are expressed in epithelial tissues, such as the kidneys and the intestine, we have investigated the adaptation of KCNE1-deficient mice to different K(+) and Na(+) intakes. On a normal K(+) diet, homozygous kcne1(-/-) mice exhibit signs of chronic volume depletion associated with fecal Na(+) and K(+) wasting and have lower plasma K(+) concentration and higher levels of aldosterone than wild-type mice. Although plasma aldosterone can be suppressed by low K(+) diets or stimulated by low Na(+) diets, a high K(+) diet provokes a tremendous increase of plasma aldosterone levels in kcne1(-/-) mice as compared with wild-type mice (7.1-fold vs. 1.8-fold) despite lower plasma K(+) in kcne1(-/-) mice. This exacerbated aldosterone production in kcne1(-/-) mice is accompanied by an abnormally high plasma renin concentration, which could partly explain the hyperaldosteronism. In addition, we found that KCNE1 and KCNQ1 mRNAs are expressed in the zona glomerulosa of adrenal glands where I(Ks) may directly participate in the control of aldosterone production by plasma K(+). These results, which show that KCNE1 and I(Ks) are involved in K(+) homeostasis, might have important implications for patients with I(Ks)-related long QT syndrome, because hypokalemia is a well known risk factor for the occurrence of torsades de pointes ventricular arrhythmia.

Chronic potassium depletion induces renal injury, salt sensitivity, and hypertension in young rats

BACKGROUND

Chronic hypokalemia has been associated with renal hypertrophy, interstitial disease, and hypertension in both adult animals and humans. However, the effects of potassium (K(+)) depletion on the rapidly growing infant have not been well studied. The purpose of this study was to determine the effects of severe chronic dietary K(+) depletion on blood pressure (BP) and renal structural changes in young rats.

METHODS

Sprague-Dawley rats (50 +/- 5 g) were fed either a control or a potassium-deficient diet (<0.05% K(+)) for 14 to 21 days. At the end of this period, the blood pressure (BP) was measured in all rats, and six rats in each group were sacrificed to determine changes in renal histology and renin-angiotensin system (RAS) activity. The remaining rats in each group were then switched to a high-salt (6% NaCl)--normal-K(+) (0.5%) diet or were continued on their respective control or K(+)-deficient diet for an additional six days. Blood pressure measurements were done every three days until the end of the study.

RESULTS

K(+)-depleted animals had significant growth retardation and increased RAS activity, manifested by high plasma renin activity, recruitment of renin-producing cells along the afferent arterioles, and down-regulation of angiotensin II receptors in renal glomeruli and ascending vasa rectae. K(+)-depleted kidneys also showed tubulointerstitial injury with tubular cell proliferation, osteopontin expression, macrophage infiltration, and early fibrosis. At week 2, K(+)-depleted rats had higher systolic BP than control rats. Switching to a high-salt (6% NaCl)--normal-K(+) diet resulted in further elevation of systolic BP in K(+)-depleted rats, which persisted even after the serum K(+) was normalized.

CONCLUSION

Dietary potassium deficiency per se increases the BP in young rats and induces salt sensitivity that may involve at least two different pathogenic pathways: increased RAS activity and induction of tubulointerstitial injury.

Mechanism of antihypertensive effect of dietary potassium in experimental volume expanded hypertension in rats

Dietary potassium supplementation lowers blood pressure (BP) and attenuates complications in hypertensive subjects, particularly those with the low renin volume expanded (LRVE) variety. We and others have shown that the plasma level of a digitalis like substance (DLS) is elevated in this type of hypertension. We therefore, examined the effect of increases in dietary potassium on the plasma level of endogenous DLS, myocardial and renal Na+, K+-ATPase (NKA) activities, BP, and renal excretory function in reduced renal mass (RRM)-salt hypertension in the rat, a classical model of LRVE hypertension. 70% RRM rats were divided in 4 groups, namely those consuming: 1) a sodium free and normal potassium (1.3% as KCl) diet (RRM-0 Na), 2) a normal sodium and normal potassium diet (RRM-NaK), 3) a normal sodium and high potassium (2 X normal) diet (RRM-Na2K), and 4) a normal sodium and 4 times normal potassium diet (RRM-Na4K). At the end of 4 weeks of dietary treatment, direct BP was recorded, plasma level of DLS determined by bioassay and with a radioimmunoassay for digoxin (DIF) and myocardial and renal NKA activities were measured. As expected, compared to RRM-0Na rats, RRM-NaK rats developed hypertension. BP increased significantly less in RRM-Na2K, whereas BP did not increase in RRM-Na4K rats. Hypertension in RRM-NaK rats was associated with an increase in plasma DLS and DIF and decrease in renal and myocardial NKA activities. DLS was increased (DIF was not changed) and myocardial NKA also decreased in rats consuming double potassium. However, quadrupling potassium in the diet (RRM-Na4K) normalized DLS and DIF and increased myocardial and renal NKA activities, compared to RRM-0Na rats. Also compared to RRM-0Na, water consumption, urinary volume excretion, sodium, and potassium increased in the other 3 groups, more so in RRM-Na4K rats. These data show that quadrupling the potassium in the diet prevents the BP increase in RRM rats and this is associated with diuresis/natriuresis and normalization of DLS, perhaps because the diuresis/natriuresis normalizes blood volume.

Role of dietary potassium in the hyperaldosteronism and hypertension of the remnant kidney model

The remnant kidney model of progressive renal disease is marked by arterial hypertension, especially when produced by nephrectomy and partial infarction. Hyperaldosteronism sustains much of the hypertension, but the stimuli to the increased aldosterone levels are uncertain. It is hypothesized that the hyperaldosteronism attending this model stems from the combination of fixed dietary potassium load in the face of reduced filtration on the one hand, and persistent renin secretion from the scarred remnant kidney on the other. This hypothesis predicted that dietary potassium restriction would lower aldosterone and BP in this model. To test this prediction, two groups of rats with a remnant kidney were studied. Group 1 consumed 0.4 +/- 0.06 mEq (mean +/- SD) of potassium chloride daily, and group 2 ate 4.8 +/- 1.0 mEq daily. Two sham-operated groups with intact kidneys also were studied. Group 3 consumed 1.7 +/- 0.2 mEq daily and group 4 ate 15.2 +/- 1.4 mEq daily. These levels of intake were designed to provide at least as much potassium per liter of GFR in the sham groups as in the remnant kidney rats. Systolic BP (SBP), 24-h protein excretion, plasma aldosterone levels, 24-h urinary aldosterone excretion, and plasma renin activity (PRA) were determined in all groups at 2 wk. At 4 wk, after SBP and protein excretion measurements, remnant kidneys were perfusion-fixed for morphometric analysis. SBP was normal in both sham-operated groups and was not different between the groups (113 +/- 13 versus 117 +/- 2 mmHg, group 3 versus group 4). In the remnant animals, SBP at 2 wk followed potassium intake: Group 1 had a lower SBP than group 2 (140 +/- 26 versus 170 +/- 34 mmHg, P = 0.005). The same SBP pattern persisted at 4 wk (153 +/- 25 versus 197 +/- 27 mmHg, group 1 versus group 2, P = 0.0006). However, 24-h urinary protein excretion was not different between the two groups with remnant kidneys at either 2 or 4 wk. Both plasma and 24-h urinary aldosterone excretion at 2 wk followed potassium intake (120 +/- 124 versus 580 +/- 442 pg/ml for plasma aldosterone, group 1 versus group 2, P = 0.03, and 2.6 +/- 1.8 versus 23.2 +/-9.8 ng/d for urinary aldosterone, group 1 versus group 2, P = 0.0001). PRA, however, followed a reverse pattern in which dietary potassium restriction resulted in higher levels (16 +/- 6 versus 6 +/- 3 ng angiotensin I/ml per h, group 1 versus group 2, P = 0.01). A similar pattern for PRA and aldosterone excretion was also observed in the sham groups, in which lower potassium intake also resulted in a significantly higher PRA and lower aldosterone excretion. The constancy of BP in the sham groups likely reflects their lack of nephron reduction and greater sodium excretory capacity. Morphometric analysis in remnant animals revealed no significant difference between the two dietary groups in the prevalence of glomerular sclerosis, glomerular volume, or interstitial volume. It is concluded that dietary potassium is a potent determinant of hypertension in the remnant kidney model probably through the actions of aldosterone and that the high aldosterone secretion in this model is a function of the dietary potassium load. In this model, reduction in nephron number is also critical in promoting hypertension in conjunction with hyperaldosteronism.

K depletion stimulates in vivo HCO3 reabsorption in surviving rat distal tubules

To evaluate whether K depletion enhances in vivo bicarbonate reabsorption (JtCO2) in surviving distal tubules (DT), we compared DT JtCO2 in five-sixths nephrectomized rats (Nx) with and without dietary K depletion (Nx-K). Furthermore, to identify possible mechanisms of increased JtCO2, we perfused inhibitors of proton secretion in both Nx and Nx-K rats. JtCO2 (102 +/- 8 pmol.min-1.mm-1) was significantly increased in Nx-K vs. Nx rats (65 +/- 7 pmol.min-1.mm-1, P < 0.05) but unaffected by 10(-6) M losartan perfusion (94 +/- 6 pmol.min-1.mm-1, P = not significant). Although 10(-5) M Sch-28080 also had no significant effect, 5 x 10(-9) M concanamycin A perfusion significantly decreased JtCO2 in Nx-K rats to 65 +/- 8 pmol.min-1. mm-1 (P < 0.05). Morphometric evaluation and H(+)-ATPase immunogold labeling of Nx-K A-type intercalated cells revealed cellular hypertrophy, elaborated apical microplicae, and enhanced H(+)-ATPase apical polarization. Accordingly, these combined studies confirm that K depletion enhances JtCO2 in surviving DT by stimulating H(+)-ATPase activity, independent of the AT1 receptor.

The effects of potassium depletion and supplementation on blood pressure: a clinical review

Nonpharmacologic treatment currently is recognized as an important part in the treatment of hypertension, and the role of dietary potassium intake in blood pressure (BP) control is becoming quite evident. Clinical studies have examined the mechanism by which hypokalemia can increase BP and the benefit of a large potassium intake on BP control. Epidemiologic data suggest that potassium intake and BP are correlated inversely. In normotensive subjects, those who are salt sensitive or who have a family history of hypertension appear to benefit most from the hypotensive effects of potassium supplementation. The greatest hypotensive effect of potassium supplementation occurs in patients with severe hypertension. This effect is pronounced with prolonged potassium supplementation. The antihypertensive effect of increased potassium intake appears to be mediated by several factors, which include enhancing natriuresis, modulating baroreflex sensitivity, direct vasodilation, or lowering cardiovascular reactivity to norepinephrine or angiotensin II. Potassium repletion in patients with diuretic-induced hypokalemia improves BP control. An increase in potassium intake should be included in the nonpharmacologic management of patients with uncomplicated hypertension.

Ischemia increases neutrophil retention and worsens acute renal failure: role of oxygen metabolites and ICAM 1

The role of neutrophils in acute renal failure (ARF) is controversial. Although ARF occurs in neutropenic subjects, we found that ischemic kidneys activated neutrophils to cause ARF in isolated perfused rat kidneys. To further define the interaction between neutrophils and renal ischemia, we performed quantitative assessment of neutrophil accumulation during renal ischemia. Non-ischemic and ischemic rat kidneys were perfused by the isolated kidney technique with unstimulated, primed, or fully activated, indium-labeled neutrophils. Neutrophil accumulation was quantitated by measuring indium retention after 60 minutes of perfusion. In non-ischemic kidneys, only activated neutrophils were retained while after 20 minutes of renal ischemia, unstimulated as well as primed neutrophils were retained. Following 10 minutes of ischemia, primed neutrophils (but not unstimulated neutrophils) were retained. In the presence of neutrophil retention, there were decreases in GFR and tubular sodium reabsorption. To determine the role of ICAM 1 in ischemic injury, rats were treated with anti-ICAM 1 prior to ischemia and ischemic kidneys were reperfused with unstimulated neutrophils and anti-ICAM 1. After ischemia, the neutrophil component of reperfusion injury in isolated kidneys was prevented with anti-ICAM 1. Oxygen metabolites have been shown to induce EC expression of ICAM 1. To determine the role of ICAM 1 in oxidant-mediated renal injury, ischemic isolated kidneys were reperfused with catalase (CAT) and non-ischemic kidneys were perfused with hydrogen peroxide. Following ischemia, reperfusion with CAT prevented neutrophil retention and injury. In non-ischemic kidneys, hydrogen peroxide caused primed neutrophil retention, activation and renal injury which were completely prevented with anti-ICAM 1.

IN CONCLUSION

(1) Ischemic kidneys cause neutrophil retention, activation, and worsening of renal injury in isolated kidneys; and 2) neutrophil retention is dependent on the state of neutrophil activation, duration of renal ischemia and is mediated by oxygen metabolites and ICAM 1. This synergism could account for the high frequency of ARF in conditions such as sepsis where there is both renal hypoperfusion and neutrophil priming.

Renal vasodilation to histamine in vitro: roles of nitric oxide, cyclo-oxygenase products and H2 receptors

The aim of this study was to evaluate the roles of nitric oxide (NO) and prostanoids in vasodilation to histamine in the preconstricted isolated perfused rat kidney. Kidneys were excised from Hypnorm/Hypnovel-anaesthetised Wistar rats and perfused at constant flow in vitro. Renal perfusion pressure was elevated similarly with methoxamine (3 microM) or modified Krebs Henseleit solution containing high KCl (30 mM) and vasodilation to histamine (10, 30 nmol) and papaverine (30, 100 nmol) was then examined before and during perfusion with the NO synthase inhibitor, NG-nitro-L-arginine methyl ester (L-NAME, 0.3 mM) or the cyclo-oxygenase inhibitor, indomethacin (10 microM). Furthermore, the vasodilator response to 30 nmol histamine was examined in the presence of the H2 receptor antagonist, ranitidine (0.1-10 microM). Vasodilation to histamine (10, 30 nmol) was found to be unaffected by L-NAME (0.3 mM) or indomethacin (10 microM), while ranitidine (0.1-10 microM) antagonised vasodilation to 30 nmol histamine with an estimated pA2 of 6.67. Vasodilation to histamine in the isolated perfused rat kidney is therefore probably independent of NO and prostanoids and mediated by H2 receptors.

Mild renal ischemia activates primed neutrophils to cause acute renal failure

The role of neutrophils (PMN) in acute renal failure (ARF) is controversial. Although the development of acute renal failure (ARF) frequently occurs in situations where there is partial activation of PMN (primed PMN) and mild renal ischemia, the interaction between primed PMN and ischemic organs has not been studied in any biological system. To define the interaction between primed PMN and mild renal ischemia, kidneys were made ischemic for 10 minutes in situ and reperfused by the isolated kidney technique with untreated PMN or PMN primed with low concentrations of lipopolysaccharide (LPS) or phorbol myristate acetate (PMA). We found that primed PMN had no effect on control (non-ischemic) kidneys and that untreated PMN did not cause injury to kidneys previously subjected to mild ischemia. However, addition of primed PMN to mildly ischemic kidneys caused severe injury. To determine the nature of renal injury, ischemic kidneys were reperfused with primed PMN and catalase (CAT) or the elastase inhibitor, Eglin C. In ischemic kidneys reperfused with LPS-primed PMN, Eglin C (but not CAT) was partially protective while in ischemic kidneys reperfused with PMA-primed PMN, CAT (but not Eglin C) was partially protective. Reperfusion with both CAT and Eglin C completely prevented the damaging effects of either LPS- or PMA-primed PMN. In conclusion, addition of primed but not untreated PMN causes ARF in mildly ischemic kidneys by PMN oxidant- and/or protease-mediated mechanisms. This synergism could account for the high frequency of ARF in conditions associated with prerenal azotemia and primed PMN.

Role of neutrophil derived oxidants and elastase in lipopolysaccharide-mediated renal injury

Gram-negative bacterial sepsis is frequently associated with acute renal failure but the specific effects of lipopolysaccharide (LPS) and other bacterial products on kidney function are not known. Since either LPS or formyl-methionyl-leucyl-phenylalanine (FMLP)--a chemotactic peptide from bacterial cell walls--activate neutrophils (PMN) to release a number of potentially toxic factors in vitro, we determined the effect of adding PMN with LPS and/or FMLP to isolated perfused rat kidneys. Isolated rat kidneys perfused with LPS alone or LPS and normal PMN had normal glomerular filtration rates (GFR) and tubular Na reabsorption (TNa). Kidneys perfused with FMLP alone or FMLP and normal PMN also had normal GFR and TNa. In contrast, addition of PMN with both FMLP and LPS caused progressive renal dysfunction. For example, after 60 minutes of perfusion, GFR was reduced from 610 +/- 31 to 147 +/- 17 microliters/min/g and TNa from 97 +/- 1 to 72 +/- 2%, both P less than 0.01. Perfusion with the O2 metabolite scavengers catalase or dimethylthiourea afforded no protection while perfusion with the neutrophil elastase inhibitor Eglin C conferred substantial, but not complete, protection: GFR 492 +/- 34 microliters/min/g; TNa 91 +/- 3%. However, perfusion with both Eglin C and catalase completely prevented the toxic effects of LPS and FMLP-treated PMN on renal function. We conclude that in isolated kidneys, 1) the toxic effects of LPS requires FMLP-treated PMN and that 2) LPS and FMLP treated PMN cause progressive renal injury which is mediated by both O2 metabolites and neutrophil elastase.

Effects of experimental potassium depletion on renal function and urinary prostanoid excretion in normal women during hypotonic polyuria

During hypotonic polyuria renal function studies by the clearance (cl.) method, and urinary PGE2, 6-keto-PGF1 alpha and TxB2 determinations were performed on 14 healthy women in normal potassium balance (N) and 14 healthy women in sustained potassium depletion (KD) induced by low dietary potassium intake (less than or equal to 10 mmol day-1) and natriuretic treatment. By using different depletive patterns, two groups with estimated cumulative potassium deficits of 160 +/- 43 mmol (KD1, n = 8) and 198 +/- 22 mmol (KD2, n = 6), respectively, were obtained. (1) In both the KD1 and KD2 groups as compared to normal potassium balance (N), plasma potassium concentration and urinary potassium excretion were significantly lower; plasma renin activity was significantly higher. (2) Only in KD2 did significant changes appear in renal function and urinary prostanoid excretions. Besides a decrease in creatinine cl. and the urinary flow rate, an increase in fractional chloride excretion and a reduction in distal fractional chloride reabsorption were manifest. The plasma chloride concentration was reduced too. Urinary prostanoid excretions were significantly (6-keto-PGF1 alpha, TxB2) or tendentially (PGE2) lower. (3) Indomethacin treatment resulted in changes in mean arterial pressure (increase) and creatinine cl. (decrease) which were not significantly different in normal potassium balance and KD groups. Only in KD2 did the drug significantly reduce the fractional salt and water excretions and the fractional sodium and chloride deliveries to the diluting segments. However, indomethacin was unable to correct the inhibition of distal fractional chloride reabsorption. Therefore, the potassium depletion attained in the KD2 group was efficacious in depressing renal prostanoid synthesis. This fact, in the presence of high levels of angiotensin II, induced a reduction of the glomerular filtration rate thus contributing to renal ability to retain chloride and potassium.

Effect of potassium depletion on two-kidney, one-clip renovascular hypertension in the rat

There is considerable controversy about the hemodynamic effect of potassium in hypertension. To determine if K depletion could alter the control of blood pressure, studies were performed in rats with 2-kidney, 1-clip renovascular hypertension (RVH) after 3 to 6 wks of severe and moderate K depletion. After application of a 0.23 mm clip to the left renal artery, rats were placed on a K-replete (KR) (240 mEq/kg), a moderately K-depleted (KDM) (59 mEq/kg), or a severely K-depleted (KDS) (5 mEq/kg) diet. After 3 wks, mean arterial pressure (MAP) reached 154 +/- 3 in KR but only 121 +/- 2 in KDM (P less than 0.01) and 106 +/- 4 mm Hg in KDS (P less than 0.001). After 6 wks, MAP was 160 +/- 8 in KR, but only 132 +/- 5 in KDM (P less than 0.01) and 129 +/- mm Hg in KDS (P less than 0.01). Plasma K at 3 wks was 4.1 +/- .1 in KR, but only 3.5 +/- .1 in KDM (P less than 0.05) and 2.3 +/- .1 mEq/liter in KDS (P less than 0.001). This was associated with an 8% decrease in muscle K in KDM and a 16% decrease in muscle K in KDS. Although KDS animals did not grow during the 6 wks of study, KDM rats gained 60% as much weight at 3 wks, and, by 6 wks, weight gain was comparable in KDM (101 +/- 9) and KR (110 +/- 9 g) animals (P = NS).(ABSTRACT TRUNCATED AT 250 WORDS)

Captopril enhances aminoglycoside nephrotoxicity in potassium-depleted rats

We demonstrated that potassium depletion significantly increased gentamicin nephrotoxicity in Sprague-Dawley rats (100 mg X kg-1 X day-1). To determine whether this enhanced toxicity was mediated by renin secretion, we evaluated the effect of a converting enzyme inhibitor in this model. When we administered the combination of captopril (100 mg X kg-1 X day-1) and gentamicin in potassium-depleted rats, we observed a surprising and significant adverse effect of this combination on the clearances of inulin (CIn) and PAH (CPAH) and renal blood flow (RBF). Pretreatment with indomethacin significantly improved CIn and CPAH, and potassium repletion abolished this effect entirely. In potassium-depleted animals that received both gentamicin and captopril, the intra-arterial administration of imidazole, a thromboxane synthetase inhibitor, significantly reduced urinary TXB2 excretion and significantly improved RBF and CIn in vivo. In the same group of animals, administration of the kallikrein antagonist aprotinin also significantly increased both RBF and CIn. To measure total renal thromboxane B2 production (TXB2), we perfused kidneys ex vivo with cell-free perfusate. Three groups of animals were studied: potassium-repleted control animals, potassium-depleted control animals, and potassium-depleted animals treated with gentamicin alone, captopril alone, or the combination of gentamicin and captopril. We measured TXB2 in renal venous effluent by radioimmunoassay. Ex vivo perfused kidneys from potassium-depleted control animals produced significantly more TXB2 than potassium-repleted controls. Kidneys from potassium-depleted animals that received both gentamicin and captopril produced significantly greater amounts of TXB2 than did kidneys from potassium-depleted animals treated with captopril alone, gentamicin alone, or control potassium-depleted kidneys. The administration of imidazole ex vivo at a rate equivalent to in vivo administration (10 microM/min) reduced TXB2 production by potassium-depleted kidneys that received the combination of gentamicin and captopril to that of potassium-repleted control kidneys. These results suggest that the deleterious effect of captopril in potassium-depleted rats that received gentamicin is due at least in part to kinin-stimulated renal TXB2 production.

Role of vasopressin in support of blood pressure in potassium deficient rats

Arginine vasopressin (AVP) has been found to contribute to the maintenance of blood pressure (BP) in the rat. Since potassium deficiency results in alterations in systemic hemodynamics, the role of AVP in the control of BP was studied after 14 to 21 days of dietary potassium deficiency. When potassium deficient and control rats were allowed free access to water, plasma osmolality (301.4 +/- 1 vs. 293.4 +/- 3 mOsm/kg; P less than 0.02) and plasma AVP (3.5 +/- 0.2 vs. 2.4 +/- 0.2 pg/ml; P less than 0.02) were increased in potassium deficient animals. To determine the role of this increase in AVP in the maintenance of BP, BP was determined in rats made polydipsic by adding glucose to the drinking water. In both control and potassium deficient rats, increased fluid intake resulted in increased urine output, decreased urinary and plasma osmolality, and a decrease in plasma AVP. While there was no change in BP in control rats when fluid intake was increased, BP fell from 103.9 +/- 1.8 to 96 +/- 2.6 mm Hg (P less than 0.05) in potassium deficient rats with increased fluid intake. To confirm that the decrease in plasma AVP caused the decrease in BP in potassium deficient rats, an AVP pressor antagonist was employed. Following the administration of the AVP pressor antagonist, there was no change in BP in control animals. In contrast, BP fell from 104.3 +/- 1.9 to 98.3 +/- 2.5 mm Hg; P less than 0.05 in potassium deficient rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolic alkalosis in the rat. Evidence that reduced glomerular filtration rather than enhanced tubular bicarbonate reabsorption is responsible for maintaining the alkalotic state

Maintenance of chronic metabolic alkalosis might occur by a reduction in glomerular filtration rate (GFR) without increased bicarbonate reabsorption or, alternatively, by augmentation of bicarbonate reabsorption with a normal GFR. To differentiate these possibilities, free-flow micropuncture was performed in alkalotic Munich-Wistar rats with a glomerular ultrafiltrate total CO2 concentration of 46.5 +/- 0.9 mM (vs. 27.7 +/- 0.9 mM in controls). Alkalotic animals had a markedly reduced single nephron GFR compared with controls (27.4 +/- 1.5 vs. 51.6 +/- 1.6 nl/min) and consequently unchanged filtered load of bicarbonate. Absolute proximal bicarbonate reabsorption in alkalotic animals was similar to controls (981 +/- 49 vs. 1,081 +/- 57 pmol/min), despite a higher luminal bicarbonate concentration, contracted extracellular volume, and potassium depletion. When single nephron GFR during alkalosis was increased toward normal by isohydric volume expansion or in another group by isotonic bicarbonate loading, absolute proximal bicarbonate reabsorption was not substantially augmented and bicarbonaturia developed. To confirm that a fall in GFR occurs during metabolic alkalosis, additional clearance studies were performed. Awake rats were studied before and after induction of metabolic alkalosis associated with varying amounts of potassium and chloride depletion. In all cases, the rise in blood bicarbonate concentration was inversely proportional to a reduction in GFR; filtered bicarbonate load remained normal. In conclusion, a reduction in GFR is proposed as being critical for maintaining chronic metabolic alkalosis in the rat. Constancy of the filtered bicarbonate load allows normal rates of renal bicarbonate reabsorption to maintain the alkalotic state.

Hemodynamic effects of alterations in potassium

Potassium is the major intracellular cation. Despite this fact, the systemic and renal hemodynamic effects of alterations in either serum K or in total body K are only partially understood. In isolated preparations acute K excess causes vasodilation while acute K deficiency results in vasoconstriction. Although chronic K excess may decrease arterial pressure in experimental models of hypertension, no definitive conclusions can be stated on the effect of K excess in hypertensive patients. In normotensive animals, chronic K depletion is associated with decreased systemic vascular resistance and increased renal vascular resistance. Although a number of studies have shown that K depletion ameliorates experimental hypertension, no definitive conclusions can be stated on the effect of K depletion in hypertensive patients. The vasodilatory effect of K depletion appears to be a direct effect on vascular smooth muscle since it is associated with an increase in total body Na as well as an increase in cardiac output and in renin ane arginine vasopressin levels. Although renin levels are increased in K deficient rats to a value comparable to na-depleted rats, angiotensin antagonism results in a substantially smaller decrease in arterial pressure than in Na-depleted rats (11 +/- 1.6 vs 24 +/- 3.4 mm Hg, p less than 0.01). This relative resistance to the pressor effect of angiotensin also results in a blunted pressor sensitivity to exogenous angiotensin II. Since changes in K balance appear to have a major effect on the control of hemodynamics, further studies are warranted to determine whether alterations in K balance would be useful in the treatment of hypertension.

Mechanism of the decreased renal blood flow in the potassium-depleted conscious rat

Although chronic potassium deficiency is a common clinical problem, the hemodynamic consequences of chronic sustained potassium depletion have not been clearly delineated. In this study, the hemodynamic consequences of chronic potassium depletion were evaluated in the conscious rat. Potassium-depleted rats had a decrease in mean arterial pressure which was caused by a decrease in systemic vascular resistance. In association with these changes in systemic hemodynamics, renal blood flow (RBF) was also decreased. The decreased renal blood flow was caused by an increased renal vascular resistance (RVR). Because plasma renin activity was increased the role of angiotensin II as a renal vasoconstrictor was evaluated by utilizing two angiotensin antagonists. Although the administration of saralasin to potassium-depleted rats did not alter systemic hemodynamics, RVR was decreased and RBF was increased. Similar results were obtained with the converting enzyme inhibitor teprotide. Because products of endoperoxide metabolism may cause renal vasoconstriction, the role of prostaglandins and thromboxanes as renal vasoconstrictors were evaluated by utilizing cyclo-oxygenase and thromboxane synthetase inhibitors. None of these agents altered systemic hemodynamics. Following the administration of indomethacin, RVR was decreased and RBF was increased in potassium-depleted rats. Similar results were obtained with another cyclo-oxygenase inhibitor, meclofenamate, and with imidazole, an inhibitor of thromboxane synthetase. Because neither angiotensin II nor products of endoperoxide metabolism could alone account for the increased renal vascular resistance of potassium depletion, studies were performed in potassium-depleted rats treated with indomethacin plus either saralasin or teprotide. In these potassium-depleted animals, renal blood flow was restored to normal. In conclusion, the decrease in renal blood flow and the increase in renal vascular resistance in potassium depletion is mediated by angiotensin II and a product of prostaglandin endoperoxide metabolism, most likely, thromboxane.