Endogenous Endothelins Mediate Increased Acidification in Remnant Kidneys

Animals, Diet, and Study Protocol

We used male or female Munich-Wistar rats (190 to 219 g; Harlan Sprague-Dawley, Houston, TX), which ate a minimal-electrolyte diet with 20% protein (ICN Nutritional Biochemicals, Cleveland, OH) and drank distilled water ad libitum. In preliminary studies, Nx and similar-weight control animals ate 17.8 ± 0.9 and 20.4 ± 0.8 g/d, respectively (n = 4, P = 0.07); therefore, all animals received 17 g/d, to ensure similar diet intakes. Some animals received bosentan (Hoffman-LaRoche, Basel, Switzerland), a nonpeptide ET_A/B receptor antagonist (14), mixed with the diet at 100 mg/kg body wt per d. This oral dose blocks the action of pressor doses of intravenously administered big ET-1 for > 24 h (14).

Renal Mass Reduction

Nx was induced by surgical removal of approximately five-sixths of the renal mass, in two stages (15). Briefly, the left kidney of anesthetized animals was exposed through a flank incision, the main renal artery and vein were temporarily occluded, and both renal poles were removed with scissors, leaving approximately one-third of the single-kidney mass. Bleeding was controlled with thrombin applied to the cut surface, the remnant kidney was returned to the abdominal cavity, and the animal was allowed to recover. The right kidney was removed 1 wk later, through a flank incision, and the animal was allowed to recover. Sham-treated control subjects underwent left kidney exteriorization, followed 1 wk later by exteriorization of the right kidney and return of the kidney to the abdomen. An indwelling carotid arterial catheter was placed for blood sampling. Nx and control animals were studied 4 to 5 wk after the second procedure, with the animals eating the described diet.

Microdialysis for Comparison of Renal Cortical ET-1 Contents

We compared renal cortical ET-1 contents in Nx and control animals 4 wk after surgery by using microdialysis (16), as performed in our laboratory (13). The microdialysis apparatus was placed in the remnant Nx kidney and in the same area of the left kidney of sham-treated control animals during Nx surgery. Three consecutive 20-min collections, with perfusion of lactated Ringer's solution into the microdialysis apparatus, were performed for measurements of ET-1 addition to the dialysate, using groups (of eight each) of calm, conscious, gently restrained Nx and control animals (13). In vitro recoveries of ¹²⁵I-ET-1 (ICM Biomedicals, Irvine, CA) with four identically constructed probes were 64 ± 2%.

Urinary NAE

Daily NAE was measured (17) in 24-h urine samples collected on day 28 of the protocol from groups (of eight each) of Nx and control animals maintained in metabolic cages. We examined the effect of ET receptor blockade on urinary NAE in separate groups (of eight each; four not ingesting and four ingesting bosentan) of Nx and control animals.

Plasma and Blood Parameters

After urine collection for NAE measurements, 1.0-ml samples of carotid arterial blood were collected from conscious, gently restrained, calm animals for analysis of pH, partial pressure of carbon dioxide. HCO₃^- concentration, base excess, and hematocrit level (IRMA blood analysis system; Diametrics Medical, St. Paul, MN). Additional blood samples were used for measurement of plasma creatinine levels in an autoanalyzer (model 1800; Ilab, Lexington, MA).

Micropuncture Protocol

Animals were prepared for micropuncture of accessible proximal (18) and distal (19) tubules. Timed free-flow collections from the late segment and then the early segment of the same distal tubule were performed with oil blocks for in situ deliveries (17). We collected late proximal tubular fluid without an oil block, to minimize increases in proximal tubule flow attributable to tubuloglomerular feedback, which artifactually increase proximal tubule HCO₃^- concentrations (18,20). The late proximal tubular fluid flow in situ was estimated by dividing the single-nephron GFR (SNGFR) at the early distal tubule (this collection site avoids stimulation of tubuloglomerular feedback) by the tubular fluid/plasma inulin ratio at the late proximal tubule (18). The calculated flow rate at the late proximal tubule was multiplied by the measured tubular fluid HCO₃^- concentration (19) for calculation of in situ HCO₃^- delivery. Early distal tubule SNGFR were 56.2 ± 3.5 and 29.4 ± 2.6 nl/min for Nx and control animals (n = 8 each), respectively. Proximal tubules from Nx and control animals were pair-perfused at 55 or 30 nl/min, in random sequence, to approximate in situ flow rates. In situ early distal tubule flow rates were 14.4 ± 0.8 and 6.4 ± 0.4 nl/min for Nx and control animals (n = 8 each), respectively. Distal tubules from both Nx and control animals were pair-perfused at 6 or 15 nl/min, in random sequence, to approximate in situ flow rates. Microperfusions were performed with a Hampel pump (Frankfurt, Germany) (19).

Plasma HCO₃^- concentrations were 19.7 ± 1.0 and 21.0 ± 0.5 mM for Nx and control animals, respectively, undergoing micropuncture; therefore, the HCO₃^- concentration of the proximal tubule-perfusing solution was 20 mM (Table 1). The Na⁺, Cl^-, and K⁺ concentrations of solution 1 approximated plasma levels in Munich-Wistar rats undergoing micropuncture. We did not measure the transepithelial potential difference in proximal tubules because it is small (21) and contributes minimally to HCO₃^- transport in this segment (22). We determined the perfused tubule length by producing a latex cast after micropuncture and measuring the cast after acid digestion of the kidney (19). We measured HCO₃^- concentrations in stellate vessel plasma (19) for calculation of the peritubular blood-to-lumen HCO₃^- gradient, for measurement of passive transepithelial H⁺/HCO₃^- permeability. Diet, but not water, was withheld the evening before micropuncture, to yield higher baseline HCO₃^- reabsorption (23), as described previously (19).

The in situ early distal tubule HCO₃^- concentrations were 7.7 ± 0.7 and 5.3 ± 0.5 mM in Nx and control animals, respectively; therefore, the standard distal tubule-perfusing solution (solution 2) contained 5 mM HCO₃^-. We measured the distal tubule transepithelial potential difference for calculation of the blood-to-lumen HCO₃^- permeability (19). We also perfused distal tubules with two other solutions, to identify components of net HCO₃^- reabsorption that mediated changes in net HCO₃^- reabsorption (19). We determined passive blood-to-lumen H⁺/HCO₃^- permeability with the use of solution 3 (no HCO₃^- and no Cl^-, with acetazolamide) to inhibit transtubule H⁺/HCO₃^- transport (19). We used the permeability determined with solution 3 to calculate passive blood-to-lumen HCO₃^- secretion during perfusion with the HCO₃^--containing solution (solution 2) (19). In addition, we measured Cl^--dependent luminal HCO₃^- accumulation by perfusing distal tubules with solution 4 (no HCO₃^- but containing Cl^-), to allow Cl^--dependent HCO₃^- secretion (19). Solution 4 also permitted determination of an “apparent” blood-to-lumen HCO₃^- permeability, for calculation of distal tubule H⁺ and HCO₃^- secretion during perfusion with the HCO₃^--containing solution (solution 2) (19). The latter value for HCO₃^- secretion represents “total” HCO₃^- secretion, whereas “net” HCO₃^- secretion is total HCO₃^- secretion minus the passive component (calculated by using the permeability determined with solution 3). All perfusing solutions contained raffinose, to minimize fluid transport, and gluconate was substituted for Cl^- when necessary (19).

Calculations

Urinary NAE was recorded as the mean for all animals in each group on day 28. ET-1 addition to the microdialysate was recorded as the mean of three collection periods. The perfusion rate (19), HCO₃^- transport in free-flow collections (18), and HCO₃^- transport in perfused tubules (19) were calculated as described. Net HCO₃^- reabsorption in microperfusion studies was recorded as HCO₃^- transport during perfusions with HCO₃^--containing solutions (solutions 1 and 2), with the recognition that tubule transport is bidirectional (19,22). Luminal HCO₃^- accumulation was measured as HCO₃^- appearance (collected minus initial values) during perfusion with initially HCO₃^--free solutions. Bicarbonate secretion was calculated as blood-to-lumen HCO₃^- transport during distal tubule perfusion with the HCO₃^--containing solution (solution 2). Passive luminal HCO₃^- accumulation was that measured during perfusion with solution 3. Passive and apparent blood-to-lumen HCO₃^- permeabilities were calculated for perfusions with the HCO₃^--free solutions (solutions 3 and 4, respectively) (19). Distal tubule H⁺ secretion was calculated for distal tubule perfusions with solution 2, by subtraction of the calculated total secretion (a negative value) from the measured net HCO₃^- reabsorption (19).

Statistical Analyses

The data were expressed as means ± SEM. Paired perfusions of the same tubule were compared using paired t tests; otherwise, ANOVA was used for multiple group comparisons. We used the Bonferroni method for multiple comparisons of the same parameter among groups (P < 0.05).

Animal Growth and Urine Volume

Nx and control animals not ingesting bosentan exhibited similar body weights at the beginning of the 4-wk period after surgery (201 ± 5 versus 206 ± 6 g), but Nx animals gained less weight during the period (91 ± 3 versus 116 ± 4 g, P < 0.001). The daily urine volume was higher for Nx animals than for control animals (38.0 ± 8.8 versus 15.5 ± 2.2 ml, P < 0.001). Weight gains among bosentan-ingesting animals, compared with noningesting animals, were similar for Nx (83 ± 3 versus 91 ± 3 g, P = 0.08) and control (122 ± 5 versus 116 ± 4 g, P = NS) animals. Daily urine volumes were also similar for bosentan-ingesting versus noningesting Nx (36.1 ± 6.7 versus 38.0 ± 8.8 ml, P = NS) and control (12.9 ± 2.1 versus 15.5 ± 2.2 ml, P = NS) animals.

ET-1 Urinary Excretion and Dialysate Addition

Nx animals exhibited greater ET-1 urinary excretion (346 ± 79 versus 125 ± 24 fmol/d, P < 0.02) and renal cortical dialysate addition (681 ± 91 versus 290 ± 39 fmol/min, P < 0.002) than did control animals (both groups without bosentan), as shown in Figure 1.

• Download figure
• Open in new tab
• Download powerpoint

Figure 1.

Endothelin-1 (ET-1) urinary excretion and addition to renal cortical dialysate in sham-treated control animals and animals that had undergone a 5/6 nephrectomy (Nx). ^*, P < 0.05 versus control.

Urinary NAE

Table 2 indicates that total urinary NAE was not different between Nx animals and control animals but Nx animals exhibited lower urinary excretion of NH₄⁺ and HCO₃^-. Bosentan had no effect on NAE in control animals, as demonstrated in Figure 2 (top). In contrast, Figure 2 (bottom) indicates that bosentan-ingesting Nx animals, compared with noningesting Nx animals, exhibited lower total urinary NAE (394 ± 99 versus 788 ± 121 μM/d, P < 0.05), which was mediated by lower excretion of NH₄⁺ (252 ± 31 versus 491 ± 66 μM/d, P < 0.02) and higher excretion of HCO₃^- (287 ± 69 versus 85 ± 41 μM/d, P < 0.05). Figure 2 also demonstrates no difference in the urinary excretion of titratable acid between the groups. Urinary pH values were not different between bosentan-ingesting and noningesting Nx (6.75 ± 0.32 versus 6.24 ± 0.31, P = NS) or control (7.25 ± 0.30 versus 7.11 ± 0.31, P = NS) animals.

• Download figure
• Open in new tab
• Download powerpoint

Figure 2.

Urinary excretion of titratable acidity, NH₄⁺, HCO₃^-, and total acid in sham-treated control animals (top) and Nx animals (bottom), without (Baseline) and with (+ Bosentan) chronic ingestion of the ET_A/B receptor antagonist bosentan. ^*, P < 0.05 versus without bosentan.

Plasma Parameters for Conscious Control and Nx Animals

Table 3 demonstrates that Nx animals exhibited higher plasma creatinine levels than did control animals, consistent with lower GFR. In addition, Nx animals exhibited lower hematocrit values, which likely reflect CRF. There were no differences in plasma acid-base parameters between Nx and control animals not receiving bosentan. Table 4 indicates that there was no difference in the plasma creatinine concentration, pH, partial pressure of carbon dioxide, HCO₃^- concentration, or hematocrit level between bosentan-ingesting and noningesting control and Nx animals. In contrast, Figure 3 demonstrates lower blood base excess in bosentan-ingesting, compared with noningesting, Nx but not control animals.

• Download figure
• Open in new tab
• Download powerpoint

Figure 3.

Blood base excess in sham-treated control animals and Nx animals, without (Baseline) and with (+ Bosentan) chronic ingestion of the ET_A/B receptor antagonist bosentan. ^*, P < 0.05 versus without bosentan.

Plasma Parameters for Anesthetized Control and Nx Animals during Micropuncture

Table 5 indicates that plasma parameters were not different between Nx and control animals, or between animals in the Nx and control groups ingesting or not ingesting bosentan, during micropuncture. Mean BP was higher in Nx animals than in control animals but was lower in bosentan-ingesting Nx animals than in noningesting Nx animals. Bosentan had no effect on the mean BP of control animals.

In Situ HCO₃^- Deliveries to Proximal and Distal Tubules

Flow rates in the late proximal, early distal, and late distal tubules were higher in Nx animals than in control animals but did not differ within either group with bosentan, as demonstrated in Table 6. The tubular fluid HCO₃^- concentrations at the respective nephron sites did not differ between control and Nx animals. Bosentan increased the tubular fluid HCO₃^- concentration at each nephron site in Nx animals but had no effect on HCO₃^- concentrations at these sites in control animals. Nx animals, compared with control animals, exhibited greater HCO₃^- delivery to each nephron site, predominantly because of higher fluid flow rates. Bosentan increased HCO₃^- delivery to each nephron site in Nx animals, because of increased tubular fluid HCO₃^- concentrations. In contrast, bosentan had no effect on HCO₃^- delivery to any examined nephron site in control animals.

In Situ HCO₃^- Reabsorption by Proximal and Distal Tubules

The nephron-filtered HCO₃^- load was higher in Nx animals than in control animals (1107.2 ± 77 versus 617.4 ± 49 pmol/min, P < 0.001), as mediated by higher SNGFR in Nx animals (56.2 ± 3.5 versus 29.4 ± 2.6 nl/min, P < 0.001). SNGFR were not different in bosentan-ingesting, compared with noningesting, control (30.2 ± 2.7 nl/min, P = NS versus noningesting) or Nx (57.7 ± 3.7 nl/min, P = NS versus noningesting) animals. Figure 4 demonstrates that Nx animals exhibited greater baseline in situ net HCO₃^- reabsorption than did control animals, in both the proximal (972.3 ± 77 versus 482.6 ± 42.4 pmol/min, P < 0.001) and distal (62.7 ± 6.7 versus 24.3 ± 2.5 pmol/min, P < 0.001) tubules. Figure 4 (top) demonstrates lower in situ proximal tubule HCO₃^- reabsorption in bosentan-ingesting, compared with noningesting, Nx animals (541.9 ± 37.3 versus 972.3 ± 51.1 pmol/min, P < 0.001) but not control animals (526.1 ± 45.7 versus 482.6 ± 42.4 pmol/min, P = 0.5). In contrast, Figure 4 (bottom) demonstrates that in situ distal tubule HCO₃^- reabsorption did not differ between bosentan-ingesting and noningesting control or Nx animals. Figure 4 (bottom) also demonstrates that in situ distal tubule HCO₃^- reabsorption was higher in Nx animals than in control animals when both groups ingested bosentan. Because bosentan-ingesting, compared with noningesting, Nx animals exhibited greater HCO₃^- delivery to the distal tubules (Table 6), fractional HCO₃^- reabsorption by the distal tubules of Nx animals was lower in those ingesting bosentan, compared with those that did not (36.9 ± 2.7 versus 56.5 ± 3.9%, P < 0.002).

• Download figure
• Open in new tab
• Download powerpoint

Figure 4.

In situ net HCO₃^- reabsorption in proximal (top) and distal (bottom) tubules of sham-treated control animals and Nx animals, without (Baseline) and with (+ Bosentan) chronic ingestion of the ET_A/B receptor antagonist bosentan. ^*, P < 0.05 versus control; †, P < 0.05 versus group without Bosentan.

Proximal Tubule Microperfusion Studies

The following studies examined whether increased in situ proximal tubule acidification in Nx animals depended on their increased filtered HCO₃^- load and whether decreased acidification mediated the bosentan-induced increase in in situ HCO₃^- delivery to the late proximal tubules in these animals. Proximal tubules were microperfused with solution 1 at 30 or 55 nl/min, to approximate the SNGFR of control and Nx animals, respectively. As indicated in Figure 5 (bottom), proximal tubule net HCO₃^- reabsorption was higher in Nx animals than in control animals with perfusion at 55 nl/min (280.3 ± 24.7 versus 169.3 ± 14.8 pmol/mm per min, P < 0.01); however, Figure 5 (top) demonstrates no difference with perfusion at 30 nl/min (170.5 ± 15.1 versus 133.1 ± 12.3 pmol/mm per min, P = 0.3). Figure 5 (bottom) demonstrates lower net HCO₃^- reabsorption in bosentan-ingesting, compared with noningesting, Nx (185.3 ± 13.9 versus 280.3 ± 24.7 pmol/mm per min, P < 0.05) but not control (169.3 ± 14.4 versus 165.3 ± 13.0 pmol/mm per min, P = NS) animals with perfusion at 55 nl/min. In contrast, Figure 5 (top) indicates no difference in proximal tubule net HCO₃^- reabsorption between bosentan-ingesting and noningesting Nx (141.1 ± 13.7 versus 170.5 ± 15.1 pmol/mm per min, P = NS) and control (128.7 ± 11.6 versus 133.1 ± 12.3 pmol/mm per min, P = NS) animals when their proximal tubules were perfused at 30 nl/min. The data indicated that greater proximal tubule HCO₃^- reabsorption occurred when Nx animals underwent perfusion at the rate comparable to their in situ SNGFR and that this increased acidification did not require an increase in the filtered HCO₃^- load.

• Download figure
• Open in new tab
• Download powerpoint

Figure 5.

Net HCO₃^- reabsorption in proximal tubules microperfused at 30 nl/min (top) and 55 nl/min (bottom), in sham-treated control and Nx animals undergoing perfusion with 20 mM HCO₃^--containing perfusing solution (solution 1). Animals were studied without (Baseline) and with (+ Bosentan) chronic ingestion of the ET_A/B receptor antagonist bosentan. ^*, P < 0.05 versus respective control. +, P < 0.05 versus respective baseline value (without bosentan).

Distal Tubule Microperfusion Studies

The following studies examined whether increased distal tubule acidification mediated increased in situ distal tubule HCO₃^- reabsorption in Nx animals and whether decreased acidification mediated the bosentan-induced increase in in situ HCO₃^- delivery to the late distal tubules in Nx animals. The distal tubules of control and Nx animals were perfused with solution 2. Distal tubule net HCO₃^- reabsorption was higher in Nx animals than in control animals with perfusion at both 6 nl/min (27.7 ± 2.1 versus 14.4 ± 2.0 pmol/mm per min, P < 0.002) and 15 nl/min (33.3 ± 2.6 versus 18.9 ± 2.2 pmol/mm per min, P < 0.004). Furthermore, Nx animals exhibited lower transepithelial potential differences at both 6 nl/min (-10.3 ± 1.1 versus -16.9 ± 1.4 pmol/mm per min, P < 0.01) and 15 nl/min (-8.2 ± 1.0 versus -15.5 ± 1.4 mV, P < 0.005). We next determined whether the increased distal tubule net HCO₃^- reabsorption in Nx animals was mediated by decreased passive blood-to-lumen HCO₃^- permeability. To examine this issue, we perfused distal tubules with solution 3. Nx and control animals exhibited similar levels of passive luminal HCO₃^- accumulation with perfusion at 6 nl/min (-6.8 ± 0.7 versus -4.7 ± 0.5 pmol/mm per min, P = NS) or 15 nl/min (-19.3 ± 2.1 versus -16.0 ± 1.8 pmol/mm per min, P = NS). In addition, Nx and control animals exhibited similar calculated passive blood-to-lumen HCO₃^- permeabilities with perfusion at 6 nl/min (0.54 ± 0.07 versus 0.40 ± 0.5 × 10^-7 cm²/s, P = NS) or 15 nl/min (1.52 ± 0.17 versus 1.03 ± 0.14 × 10^-7 cm²/s, P = NS). The data support the concept that the increased distal tubule net HCO₃^- reabsorption in Nx animals, compared with control animals, was not mediated by decreased passive HCO₃^- transport into the distal tubules. We subsequently examined whether the increased distal tubule net HCO₃^- reabsorption in Nx animals, compared with control animals, was attributable to reduced Cl^--mediated HCO₃^- transport into the distal tubules. We examined this issue by perfusing the distal tubules with solution 4 in both groups. Nx and control animals that underwent perfusion with solution 4 exhibited similar levels of luminal HCO₃^- accumulation, with perfusion at 6 nl/min (-10.0 ± 0.9 versus -8.2 ± 0.9 pmol/mm per min, P = NS) or 15 nl/min (-36.8 ± 4.2 versus -29.9 ± 2.8 pmol/mm per min, P = NS). In addition, Nx and control animals exhibited similar calculated passive blood-to-lumen HCO₃^- permeabilities, with perfusion at 6 nl/min (0.77 ± 0.08 versus 0.68 ± 0.6 × 10^-7 cm²/s, P = NS) or 15 nl/min (2.90 ± 0.29 versus 2.42 ± 0.26 × 10^-7 cm²/s, P = NS). Figure 6 presents calculated net HCO₃^- secretion (which does not include passive HCO₃^- secretion), total HCO₃^- secretion (which includes passive HCO₃^- secretion), and H⁺ secretion during perfusion with solution 2. Net H⁺ secretion in Nx animals, compared with control animals, was higher in distal tubules perfused at 6 nl/min (-36.8 ± 3.8 versus -21.7 ± 2.2 pmol/mm per min, P < 0.02) or 15 nl/min (-68.2 ± 5.5 versus -45.8 ± 5.0 pmol/mm per min, P < 0.04), but net and total HCO₃^- secretion values were not different. Taken together, the data demonstrate that the greater distal tubule net HCO₃^- reabsorption in Nx animals, compared with control animals, in mediated by increased distal tubule H⁺ secretion.

• Download figure
• Open in new tab
• Download powerpoint

Figure 6.

Calculated net HCO₃^- secretion, total HCO₃^- secretion, and H⁺ secretion in distal tubules of sham-treated control and Nx animals undergoing perfusion at 6 nl/min (top) and 15 nl/min (bottom) with 5 mM HCO₃^--containing perfusing solution (solution 2). ^*, P < 0.05 versus control.

The final series of microperfusion studies investigated whether reduced distal tubule acidification mediated the bosentan-induced increase in HCO₃^- delivery to the late distal tubules of Nx animals in situ (Table 6). Bosentan-ingesting Nx animals exhibited lower distal tubule net HCO₃^- reabsorption than did noningesting Nx animals during perfusion with solution 2 (HCO₃^--containing) at 6 nl/min (19.0 ± 1.8 versus 27.7 ± 2.1 pmol/mm per min, P < 0.05) or 15 nl/min (25.2 ± 2.2 versus 33.3 ± 2.6 pmol/mm per min, P < 0.05). To determine whether the bosentan-induced decrease in distal tubule net HCO₃^- reabsorption was mediated by increased passive blood-to-lumen HCO₃^- permeability, we measured luminal HCO₃^- accumulation and calculated the HCO₃^- permeability in the distal tubules of Nx animals undergoing perfusion with solution 3. Bosentan-ingesting and non-bosentaningesting Nx animals exhibited similar levels of luminal HCO₃^- accumulation, with perfusion at 6 nl/min (-7.3 ± 0.5 versus -6.8 ± 0.7 pmol/mm per min, P = NS) or 15 nl/min (-20.3 ± 2.2 versus -19.3 ± 2.1 pmol/mm per min, P = NS). Also, bosentan-ingesting and non-bosentan-ingesting Nx animals exhibited similar calculated passive blood-to-lumen HCO₃^- permeabilities, with perfusion at 6 nl/min (0.60 ± 0.7 versus 0.54 ± 0.07 × 10^-7 cm²/s, P = NS) or 15 nl/min (1.76 ± 0.19 versus 1.52 ± 0.17 × 10^-7 cm²/s, P = NS). We next examined whether the bosentan-induced decrease in net HCO₃^- reabsorption in the distal tubules was attributable to increased Cl^--mediated blood-to-lumen HCO₃^- permeability, by perfusing distal tubules with solution 4. Bosentan-ingesting Nx animals exhibited higher levels of luminal HCO₃^- accumulation than did noningesting Nx animals with perfusion at 6 nl/min (-19.9 ± 2.0 versus -10.0 ± 0.9 pmol/mm per min, P < 0.002) but not with perfusion at 15 nl/min (-51.7 ± 6.0 versus -36.8 ± 4.2 pmol/mm per min, P = 0.23). In contrast, bosentan-ingesting and noningesting Nx animals exhibited higher calculated passive blood-to-lumen HCO₃^- permeabilities at both 6 nl/min (1.76 ± 0.19 versus 0.77 ± 0.08 × 10^-7 cm²/s, P < 0.001) and 15 nl/min (4.70 ± 0.49 versus 2.90 ± 0.29 × 10^-7 cm²/s, P < 0.03). Figure 7 demonstrates that bosentan-ingesting, compared with noningesting, Nx animals exhibited higher levels of calculated net HCO₃^- secretion (i.e., minus the passive component) at both 6 nl/min (-13.0 ± 1.4 versus -2.7 ± 0.3 pmol/mm per min, P < 0.001) and 15 nl/min (-30.6 ± 3.2 versus -16.3 ± 1.7 pmol/mm per min, P < 0.005). Bosentan-ingesting, compared with noningesting, Nx animals exhibited increased total HCO₃^- secretion (i.e., including the passive component) in tubules perfused at 6 nl/min (-32.5 ± 3.4 versus -9.1 ± 1.0 pmol/mm per min, P < 0.001) but not at 15 nl/min (-48.9 ± 5.0 versus -34.3 ± 3.6 pmol/mm per min, P = 0.13). Bosentan had no effect on calculated H⁺ secretion in the distal tubules of Nx animals, with perfusion at either rate, and had no effect on the components of distal tubule acidification in control animals (data not shown). Therefore, bosentan decreases distal tubule net HCO₃^- reabsorption in Nx animals by increasing net HCO₃^- secretion.

• Download figure
• Open in new tab
• Download powerpoint

Figure 7.

Calculated net HCO₃^- secretion, total HCO₃^- secretion, and H⁺ secretion in distal tubules of Nx animals undergoing perfusion at 6 nl/min (top) and 15 nl/min (bottom), not ingesting (Nx) or chronically ingesting (Nx + Bosentan) the ET_A/B receptor antagonist bosentan. Tubules were perfused with 5 mM HCO₃^--containing perfusing solution (solution 2). ^*, P < 0.05 versus Nx (without bosentan).