John A. Haas

Low-Dose Angiotensin II Increases Free Isoprostane Levels in Plasma

Chronic intravenous infusion of subpressor doses of angiotensin II causes blood pressure to increase progressively over the course of several days. The mechanisms underlying this response, however, are poorly understood. Because high-dose angiotensin II increases oxidative stress, and some compounds that result from the increased oxidative stress (eg, isoprostanes) produce vasoconstriction and antinatriuresis, we tested the hypothesis that a subpressor dose of angiotensin II also increases oxidative stress, as measured by 8-epi-prostaglandin F(2alpha) (isoprostanes), which may contribute to the slow pressor response to angiotensin II. To test this hypothesis, we infused angiotensin II (10 ng/kg per minute for 28 days via an osmotic pump) into 6 conscious normotensive female pigs (30 to 35 kg). We recorded mean arterial pressure continuously with a telemetry system and measured plasma isoprostanes before starting the angiotensin II infusion (baseline) and again after 28 days with an enzyme immunoassay. Angiotensin II infusion significantly increased mean arterial pressure from 121+/-4 to 153+/-7 mm Hg (P<0. 05) without altering total plasma isoprostane levels (180.0+/-24.3 versus 147.0+/-29.2 pg/mL; P=NS). However, the plasma concentrations of free isoprostanes increased significantly, from 38.3+/-5.8 to 54.7+/-10.4 pg/mL (P<0.05). These results suggest that subpressor doses of angiotensin II increase oxidative stress, as implied by the increased concentration of free isoprostanes, which accompany the elevation in mean arterial pressure elevation. Thus, isoprostane-induced vasoconstriction and antinatriuresis may contribute to the hypertension induced by the slow pressor responses of angiotensin II.

Increased hypoxia and reduced renal tubular response to furosemide detected by BOLD magnetic resonance imaging in swine renovascular hypertension

Oxygen consumption beyond the proximal tubule is mainly determined by active solute reabsorption, especially in the thick ascending limb of the Loop of Henle. Furosemide-induced suppression of oxygen consumption (FSOC) involves inhibition of sodium transport in this segment, which is normally accompanied by a marked decrease in the intrarenal deoxyhemoglobin detectable by blood oxygen level-dependent (BOLD)-magnetic resonance imaging (MRI). This study tested the hypothesis that the magnitude of BOLD-MRI signal change after furosemide is related to impaired renal function in renovascular hypertension. In 16 pigs with unilateral renal artery stenosis, renal hemodynamics, function, and tubular function (FSOC and fluid concentration capacity) were evaluated in both kidneys using MR and multidetector computerized tomography (MDCT) imaging. Animals with adequate FSOC (23.6 +/- 2.2%, P > 0.05 vs. baseline) exhibited a mean arterial pressure (MAP) of 113 +/- 7 mmHg, and relatively preserved glomerular filtration rate (GFR) of 60 +/- 4.5 ml/min, comparable to their contralateral kidney (66 +/- 4 ml/min, P > 0.05). In contrast, animals with low FSOC (3.1 +/- 2.1%, P = NS vs. baseline) had MAP of 124 +/- 9 mmHg and GFR (22 +/- 6 ml/min) significantly lower than the contralateral kidneys (66 +/- 4 ml/min, P < 0.05). The group with preserved GFR and FSOC showed an increase in intratubular fluid concentration as assessed by MDCT that was greater than that observed in the low GFR group, suggesting better preservation of tubular function in the former group. These results suggest that changes in BOLD-MRI after furosemide can differentiate between underperfused kidneys with preserved tubular function and those with tubular dysfunction. This approach may allow more detailed physiologic evaluation of poststenotic kidneys in renovascular hypertension than previously possible.

Regional Decreases in Renal Oxygenation during Graded Acute Renal Arterial Stenosis: A Case for Renal Ischemia

Ischemic nephropathy describes progressive renal failure, defined by significantly reduced glomerular filtration rate, and may be due to renal artery stenosis (RAS), a narrowing of the renal artery. It is unclear whether ischemia is present during RAS since a decrease in renal blood flow (RBF), O(2) delivery, and O(2) consumption occurs. The present study tests the hypothesis that despite proportional changes in whole kidney O(2) delivery and consumption, acute progressive RAS leads to decreases in regional renal tissue O(2). Unilateral acute RAS was induced in eight pigs with an extravascular cuff. RBF was measured with an ultrasound flow probe. Cortical and medullary tissue oxygen (P(t(O(2)))) of the stenotic kidney was measured continuously with sensors during baseline, three sequentially graded decreases in RBF, and recovery. O(2) consumption decreased proportionally to O(2) delivery during the graded stenosis (19 +/- 10.8, 48.2 +/- 9.1, 58.9 +/- 4.7 vs. 15.1 +/- 5, 35.4 +/- 3.5, 57 +/- 2.3%, respectively) while arterial venous O(2) differences were unchanged. Acute RAS produced a sharp reduction in O(2) efficiency for sodium reabsorption (P < 0.01). Cortical (P(t(O(2)))) decreases are exceeded by medullary decreases during stenosis (34.8 +/- 1.3%). Decreases in tissue oxygenation, more pronounced in the medulla than the cortex, occur despite proportional reductions in O(2) delivery and consumption. This demonstrates for the first time that hypoxia is present in the early stages of RAS and suggests a role for hypoxia in the pathophysiology of this disease. Furthermore, the notion that arteriovenous shunting and increased stoichiometric energy requirements are potential contributors toward ensuing hypoxia with graded and progressive acute RAS cannot be excluded.

Effect of increased peritubule protein concentration on proximal tubule reabsorption in the presence and absence of extracellular volume expansion.

The effect of increased peritubule capillary oncotic pressure on sodium reabsorption by the proximal tubule of the dog was investistigated after extracellular volume expansion (ECVE) with Ringers solution or during continued hydropenia. Control measurements were made after ECVE or during hydropenia and again during renal arterial infusion with hyperoncotic albumin solution. Absolute reabsorption by the proximal tubule was calculated from fractional reabsorption and single nephron filtration rates as determined by micropuncture. Direct measurements of efferent arteriole protein were used to determine efferent arteriolar oncotic pressure. Albumin infused into the renal artery after ECVE significantly increased efferent oncotic pressure by 17.6 plus or minus 5.3 mm Hg. Fractional and absolute reabsorption by the proximal tubule increased from 20 plus or minus 6 to 37 plus or minus 5% and from 22 plus or minus 6 to 36 plus or minus 7 nl/min, respectively. During hydropenia, the albumin infusion significantly increased efferent oncotic pressure by 15.0 plus or minus 4.4 mm Hg. However, in contrast to the effect seen during ECVE, neither fractional nor absolute reabsorption was changed, delta equals 0.3 plus or minus 1.5% and 3 plus or minus 5 nl/min, respectively. Single nephron filtration rates were not significantly different between the groups and were unchanged by the albumin infusion. Peritubule capillary hydrostatic pressures, measured with a null-servo device, were not changed by the albumin infusion in either group. Renal interstitial hydrostatic pressure, measured from chronically implanted polyethylene capsules, was decreased significantly from 7.2 plus or minus 0.9 to 3.4 plus or minus 0.6 mm Hg in the hydropenic group and from 0.6 plus or minus 0.6 to 4.8 plus or minus 0.7 mm Hg in the Ringers expanded group. In the hydropenic group, the increase in efferent oncotic pressure was nearly compensated for by changes in interstitial forces so that the calculated net force for capillary uptake was almost unchanged, 17.8 mm Hg before vs. 21.4 mm Hg during the albumin infusion. The increased efferent oncotic pressure in the Ringers expanded group was not compensated, so that the calculated net force for uptake was increased, 11.9 mm Hg before to 22.2 mm Hg during the albumin infusion. Thus, while the increase in efferent oncotic pressure during albumin infusion was not significantly different between the groups, absolute and fractional reabsorptions were increased only in the animals in which the extracellular volume was expanded. The results suggest that ECVE alters the effect of increased peritubule oncotic pressure on sodium reabsorption by the proximal tubule.

Interactions between vasoconstrictors and vasodilators in regulating hemodynamics of distinct vascular beds.

Abstract—We examined whether interactions between angiotensin II (Ang II), endothelin (ET), nitric oxide (NO), and prostaglandins (PGs) differentially regulate perfusion to distinct vascular beds. For this, we blocked either angiotensin AT1 or ET receptors or both and then sequentially inhibited NO and PG synthesis in anesthetized dogs. Blocking Ang II or ET had similar effects on systemic hemodynamics: Mean arterial pressure fell slightly without altering cardiac output. Blocking both caused a synergistic fall in mean arterial pressure and increased cardiac output. Pulmonary vascular resistance was not altered by blocking Ang II, ET, or both but progressively increased during NO and PG blockade in group 2 (which had unblocked ET receptors), suggesting that endogenous ET exerts pulmonary vasoconstriction that is tempered by NO and PGs. In the kidney, blocking Ang II increased regional blood flow (RBF), glomerular filtration rate (GFR), and fractional excretion of sodium (FENa). In contrast, blocking ET did not alter RBF, and it decreased GFR and FENa. Combined Ang II and ET blockade markedly increased RBF without altering GFR, and FENa was maintained at the levels as when only ET was blocked. Sequentially inhibiting NO and PGs decreased RBF when Ang II or ET were blocked but had little effect when both were blocked. Finally, Ang II or ET blockade did not alter iliac blood flow. Inhibiting NO and PGs decreased iliac blood flow when Ang II or ET but not both were blocked. These results suggest that regional differences in the interactions between endogenous Ang II, ET, NO, and PGs are important determinants in systemic, pulmonary, and regional hemodynamics.

Comparative Effect of PGE2 and PGI2 on Renal Function

Rapid degradation of prostacyclin (PGI2) inherent to its molecular structure has long been a major limitation in assessing the natriuretic effect of this prostaglandin. The recent availability of the stable PGI2 analogue iloprost now allows for a comparative study with prostaglandin E2 (PGE2). In the present study conducted in six anesthetized dogs, the intrarenal effects of two consecutive doses (1 and 4 ng x kg(-1) x min(-1)) of PGE2 on renal blood flow, glomerular filtration rate, and urinary sodium excretion were compared with the effects of two identical doses of iloprost. The selected doses of PGE2 were those producing a maximal natriuretic and vasodilator response without affecting mean arterial pressure. A washout period was allowed between administration of PGE2 and iloprost. PGE2 infusion significantly increased fractional sodium excretion from 0.69+/-0.1 to 2.79+/-1.1% and 4.27+/-1.2%% (P<.05), respectively. These changes in fractional sodium excretion induced by PGE2 were associated with significant increases in renal blood flow from 151.1+/-62 to 185+/-64.3 and 185.6+/-64.3 mL/min (P<.05), respectively; however, no significant alterations were seen in glomerular filtration rate, from 29.5+/-9.4 to 35.2+/-12.2 and 32.7+/-7.8 mL/min (NS), and mean arterial pressure, from 117.6+/-26 to 113.9+/-24.1 and 112.3+/-24.1 mm Hg (NS) during control and PGE2 infusion. At identical doses, sequential infusion of PGI2 had no effect on renal blood floww and glomerular filtration rate, producing natriuresis only at the highest dose, a fractional sodium excretion from 0.69+/-0.1 to 0.8+/-0.28 mm Hg (NS) and 1.05+/-0.34% (P<.05), respectively. In conclusion, the present study confirms that PGE2 exerts a natriuretic effect during increases in renal blood flow. In contrast, PGI2 had no hemodynamic effect, and the natriuresis was markedly blunted.

Autoregulation of Single Nephron Filtration Rate in the Presence and the Absence of Flow to the Macula Densa

Flow of tubule fluid to the macula densa is part of a proposed feedback loop for autoregulation of glomerular filtration rate. In the present study, autoregulation of single nephron filtration rate was tested in the presence and the absence of flow to the macula densa in the rat. Filtration rates were measured at elevated arterial blood pressures caused by carotid occlusion and vagal section and at reduced renal perfusion pressures caused by partial aortic constriction. Measurements of single nephron filtration rate in the presence and the absence of flow to the macula densa were obtained by complete volume collections from the distal nephron beyond the macula densa and from the proximal tubule, respectively. Mean blood pressure was 130 ± 4 (SE) mm Hg for the initial collections, and renal perfusion pressure was 100 ± 1 mm Hg for the repeat collections (nine rats). Distal single nephron filtration rate was 42 ± 1 nliters/min at elevated perfusion pressure and 41 ± 1 nliters/min at reduced perfusion pressure; proximal single nephron filtration rate was 41 ± 1 nliters/min at elevated perfusion pressure and 41 ± 1 nliters/min at reduced perfusion pressure. Similarly, glomerular filtration rate was 4.6 ± 0.4 ml/min kg−1 body weight and 4.7 ± 0.3 ml/min kg−1 body weight at elevated and reduced perfusion pressures, respectively. Additional studies in seven dogs showed good correlation between autoregulation of single nephrons in the absence of flow to the macula densa and autoregulation of the micropunctured kidney. It is concluded that autoregulation of single nephron filtration rate is unaltered by interruption of tubule fluid flow to the macula densa.

Effects of secretin on peritubular capillary physical factors and proximal fluid reabsorption in the rat.

The effects of secretin vasodilation on peritubular capillary Starling forces and absolute proximal reabsorption were examined in the rat. Secretin was infused at 75 mU/kg per min into the aorta above the left renal artery. Efferent plasma flow increased from 125 +/- 28 to 230 +/- 40 nl/min with secretin infusion. Single nephron filtration rate (44 +/- 6 vs. 44 +/- 7 nl/min) and absolute proximal reabsorption (21 +/- 5 vs. 21 +/- 4 nl/min) were not significantly changed. Peritubular capillary and interstitial hydrostatic pressures increased with secretin infusions (from 9 +/- 0.4 to 15 +/- 0.7 mmHg and from 3 +/- 0.2 to 4 +/- 0.2 mmHg, respectively). Both peritubular capillary and interstitial oncotic pressures decreased (from 25 +/- 2 to 20 +/- 2 mmHg and from 10 +/- 1 to 4 +/- 1 mmHg, respectively) during secretin infusion. The net reabsorption pressure for peritubular capillary uptake significantly decreased from 9 +/- 2 to 5 +/- 2 mmHg and the coefficient of reabsorption increased from 3 +/- 1 to 6 +/- 2 nl/min per mmHg. We conclude that although secretin causes a vasodilation and decreases net reabsorption pressure, absolute proximal reabsorption is unchanged. Peritubular capillary uptake is maintained, and since net reabsorption pressure is decreased, the coefficient of reabsorption is increased.

Effect of meclofenamate or ketoconazole on the natriuretic response to increased pressure

Increases in renal interstitial hydrostatic pressure (RIHP) by direct renal interstitial volume expansion (DRIVE) decrease proximal sodium reabsorption and increase urinary fractional sodium excretion (FENa). This natriuretic response is blunted by inhibition of the cyclooxygenase pathway. However, complicating the interpretation of the effects of cyclooxygenase inhibition on sodium excretion are the following: (1) products of the other pathways of arachidonic acid metabolism, such as the cytochrome P-450 metabolites, may be attenuated when cyclooxygenase activity is reduced; (2) the proximal tubule has a high biosynthetic capacity for cytochrome P-450 metabolites of arachidonic acid. Therefore, the purpose of the present study was to compare blockade of the epoxygenase products of the cytochrome P-450 pathway with ketoconazole to blockade of the cyclooxygenase pathway with meclofenamate on the natriuretic response to increased RIHP during DRIVE. RIHP, fractional excretion of lithium (FELi), FENa and glomerular filtration rate (GFR) were measured before and after DRIVE in control (n = 6), meclofenamate-treated (n = 6), and ketoconazole-treated (n = 5) rats. DRIVE was achieved by infusing 100 microL of 2.5% albumin solution directly into the renal interstitium. In control animals, DRIVE significantly increased RIHP (delta 2.8 +/- 0.6 mm Hg), FELi (delta 13.4% +/- 5.2%), and FENa (delta 1.29% +/- 0.31%). In the ketoconazole-treated group, RIHP (delta 3.9 +/- 0.8 mm Hg), FELi (delta 19.3% +/- 2.0%), and FENa (delta 1.73% +/- 0.43%) also significantly increased. However, the natriuretic response to DRIVE was blunted during cyclooxygenase blockade with meclofenamate when compared with control or ketoconazole-treated animals (FELi (delta 2.5% +/- 1.4%, not significant) and FENa (delta 0.07% +/- 0.18%, not significant), even though the response of RIHP was intact (delta 4.5 +/- 0.4 mm Hg, p < 0.001). These results suggest that the natriuretic response to increased RIHP is dependent on the presence of, but not necessarily the increased synthesis of, products of cyclooxygenase rather than the cytochrome P-450 epoxygenase pathway for arachidonic acid metabolism.

Nephron Sites of Adaptation to Changes in Dietary Phosphate

Studies of the renal adaptation to changes in the dietary intake of phosphate have provided important insights into the mechanisms of regulation of phosphate transport by the renal tubule, Troehler, Bonjour and Fleisch (1) and Steele and DeLuca (2) showed that phosphate deprivation results in marked increases in phosphate transport which were independent of plasma phosphate and parathyroid hormone. Further, rats fed a low phosphate diet provide a model of resistance to the Phosphaturic response to PTH (3). Whereas the expected increase in cAMP generation and hypocalciuria occur, there is no increase in phosphate excretion. Studies utilizing several different approaches support the concept that adaptive changes in phosphate transport occur in the proximal tubule. In vivo microperfusion, isolated tubule and isolated renal brush border vesicle studies of proximal tubules all illustrate enhanced phosphate transport in animals fed a low phosphate diet (4, 5, 6, 7). Micropuncture studies in dogs also show enhanced phosphate reabsorption in the proximal tubule in phosphate deprivation (8, 9). Accordingly, adaptation of proximal tubule phosphate transport is very likely. However, the contribution of this altered transport to the urinary excretion of phosphate remains controversial.