The effect of the plasma bicarbonate level on proximal tubule sodium reabsorption in NH4Cl-loaded dogs.

In an attempt to examine the effects of mild and severe chronic metabolic acidosis on proximal tubule sodium reabsorption, 6 dogs were given 10 mEq. per kilogram per day and 5 dogs were given 20mEq. per kilogram per day of ammonium chloride for 3 days and compared to 12 normal dogs during a steady-state water diuresis and following the administration of ethacrynic acid (EA) intravenously (2 mg. per kilogram) utilizing standard clearance methodology, In the severely acidotic group (pH decrease is greater tthan 0.2) plasma pH was 7.08 +/- 0.06 and plasma bicarbonate was 6.3 +/- 1.0 Eq. per liter compared to a pH of 7.33 +/-0.02 and bicarbonate of 13.4 +/- 0.7 in mild acidosis (pH decrease is less than 0.2). During a steady-state water diuresis urine flow was 14.2 +/- 0.9 in severely acidotic compared to 10.5 +/-0.7 ml. per minute per 100 ml. glomerular filtration rate (GFR) in normal dogs (p is less than 0.01). Following EA sodium clearance increased 38.4 +/- 3.5 in severely acidotic dogs and 27.6 +/- 2.0 ml. per minute per 100 ml. GFR in normal dogs (p is less than 0.02). In mild acidosis, steady-state fractional urine flow and the increase in fractional sodium clearance following EA were not significantly different than normal dogs. We conclude that chronic metabolic acidosis leads to an increase in distal solute load and enhanced natriuretic effect of EA secondary to a decrease in proximal tubule sodium reabsorption which may be dependent upon the degree of reduction in the plasma bicarbonate level.     

Renal bicarbonate reabsorption in the rat. III. Distal tubule perfusion study of load dependence and bicarbonate permeability.

Using continuous microperfusion techniques, we studied the load dependence of bicarbonate reabsorption along cortical distal tubules of the rat kidney and their bicarbonate permeability. Net bicarbonate transport was evaluated from changes in tracer inulin concentrations and total CO2 measurements by microcalorimetry. Bicarbonate permeability was estimated from the flux of total CO2 along known electrochemical gradients into bicarbonate-and chloride-free perfusion solution containing 10(-4) M acetazolamide. Transepithelial potential differences were measured with conventional glass microelectrodes. Significant net bicarbonate reabsorption occurred at luminal bicarbonate levels from 5 to 25 mM, and at perfusion rates from 5 to 30 nl/min. Bicarbonate reabsorption increased in a load-dependent manner, both during increments in luminal bicarbonate concentration or perfusion rate, reaching saturation at a load of 250 pmol/min with a maximal reabsorption rate of approximately 75 pmol/min.mm. Rate of bicarbonate reabsorption was flow dependent at luminal concentrations of 10 but not at 25 mM. During chronic metabolic alkalosis, maximal rates of reabsorption were significantly reduced to 33 pmol/min.mm. The bicarbonate permeability was 2.32 +/- 0.13 x 10(-5) cm/s in control rats, and 2.65 +/- 0.26 x 10(-5) cm/s in volume-expanded rats. Our data indicate that at physiological bicarbonate concentrations in the distal tubule passive bicarbonate fluxes account for only 16-21% of net fluxes. At high luminal bicarbonate concentrations, passive bicarbonate reabsorption contributes moderately to net reabsorption of this anion.     

Renal bicarbonate reabsorption in the rat. II. Distal tubule load dependence and effect of hypokalemia.

We studied two groups of rats acutely loaded with bicarbonate, control rats on a standard diet and rats kept on a K-free diet for 3 wk. Compared with controls, K-depleted rats had reduced fractional excretion of bicarbonate despite their elevated filtered bicarbonate load. Distal bicarbonate reabsorption increased in K-depleted rats. In the presence of almost identical early distal bicarbonate loads (481 +/- 40 pmol/min in controls and 444 +/- 50 pmol/min in K depletion), distal bicarbonate reabsorption was significantly enhanced in K depletion (247 +/- 17 pmol/min) as compared with controls (179 +/- 18 pmol/min). These values are significantly different from each other, and both are severalfold higher than bicarbonate reabsorption in nonloaded conditions. In conclusion, distal bicarbonate reabsorption is load dependent, and distal bicarbonate reabsorption is stimulated in K depletion.     

An in vivo microperfusion study of distal tubule bicarbonate reabsorption in normal and ammonium chloride rats.

For many years it has been thought that distal nephron hydrogen ion secretion can be importantly modulated by factors such as sodium delivery, sodium avidity, and potassium stores. Free flow micropuncture studies have also indicated that the rate of bicarbonate delivery may also alter the rate of bicarbonate reabsorption. The present studies were undertaken to examine possible luminal influences on total CO2 reabsorption in microperfused distal tubules in the rat in vivo. Tubules from normal and acidotic rats were perfused with five solutions in a manner that induced changes in bicarbonate load, sodium and potassium fluxes (JNa, JK), and luminal sulfate concentration. in each collected perfusate, simultaneous analyses were undertaken to determine water reabsorption, Na, and K concentrations using graphite furnace atomic absorption spectroscopy and total CO2 by microcalorimetry. Using factorial analysis of covariance to account for confounding effects on total CO2 flux (JtCO2) such as water reabsorption, distal tubules of acidotic rats reabsorbed CO2 in the range of 50-112 pmol X min-1 X mm-1 X These JtCO2 values were not significantly correlated with HCO3 load, JNa, or JK despite changes in the latter from net reabsorption to net secretion. Distal tubules of rats with normal acid-base status had JtCO2 values which were neither significantly different from zero nor correlated with changes in JK and JNa. Further, doubling the load from 250-500 pmol/min (by doubling the perfusion rate of 25-mM HCO3 solutions) did not stimulate JtCO2 in these normal animals. Accordingly, these acute in vivo microperfusion studies indicate for the first time that neither load nor potassium or sodium fluxes are important modulators of distal tubule bicarbonate reabsorption.     

Distal tubule bicarbonate accumulation in vivo. Effect of flow and transtubular bicarbonate gradients.

We have performed microperfusion studies on distal tubules of normal and alkalotic rats in an attempt to demonstrate in vivo bicarbonate secretion. All perfusion solutions were free of phosphate and other nonbicarbonate buffers. In both normal and alkalotic rats, distal perfusions elicited significant tCO2 entry only at high flow (24 nl/min). Even when perfusate tCO2 concentration closely matched plasma tCO2 concentration (30 mM tCO2), significant tCO2 entry again occurred at high flow. This was associated with a rise of the perfusate tCO2 concentration, which indicated net entry of tCO2 against a concentration gradient. In this "symmetrical" perfusion situation, acetazolamide blockade prevented tCO2 entry. Accordingly: distal tubule tCO2 entry is demonstrable in both alkalotic and normal rats at high flow rates; increasing perfusate tCO2 concentration can suppress tCO2 entry; and entry can occur in the absence of a gradient and this effect can be blocked by acetazolamide.     

Renal bicarbonate reabsorption in the rat. IV. Bicarbonate transport mechanisms in the early and late distal tubule.

Bicarbonate transport was studied in vivo by separate microperfusion experiments of early and late distal tubules. Total CO2 was measured by microcalorimetry and fluid absorption by 3H-inulin. Significant bicarbonate absorption was observed in all experimental conditions. Bicarbonate transport was load-dependent upon increasing the luminal bicarbonate concentration from 15 to 50 mM in both early and late distal tubule segments and remained constant at higher concentrations at a maximum rate of 100-110 pmol/min per mm. At low lumen bicarbonate concentrations (15 mM), higher rates of bicarbonate absorption were observed in early (32.9 +/- 4.57 pmol/min per mm) as compared to late distal tubules (10.7 +/- 3.1 pmol/min per mm). Amiloride and ethyl-isopropylamiloride both inhibited early but not late distal tubule bicarbonate absorption whereas acetazolamide blocked bicarbonate transport in both tubule segments. Fluid absorption was significantly reduced in both tubule segments by amiloride but only in early distal tubules by ethyl-isopropylamiloride. Substitution of lumen chloride by gluconate increased bicarbonate absorption in late but not in early distal tubules. Bafilomycin A1, an inhibitor of H-ATPase, inhibited late and also early distal tubule bicarbonate absorption, the latter at higher concentration. After 8 d on a low K diet, bicarbonate absorption increased significantly in both early and late distal tubules. Schering compound 28080, a potent H-K ATPase inhibitor, completely blocked this increment of bicarbonate absorption in late but not in early distal tubule. The data suggest bicarbonate absorption via Na(+)-H+ exchange and H-ATPase in early, but only by amiloride-insensitive H+ secretion (H-ATPase) in late distal tubules. The study also provides evidence for activation of K(+)-H+ exchange in late distal tubules of K depleted rats. Indirect evidence implies a component of chloride-dependent bicarbonate secretion in late distal tubules and suggests that net bicarbonate transport at this site results from bidirectional bicarbonate movement.     

Parathyroid hormone directly inhibits tubular reabsorption of bicarbonate in normocalcaemic rats with chronic hyperparathyroidism

The hypothesis that chronic metabolic acidosis encountered in some patients with primary hyperparathyroidism is due to inhibition of proximal HCO3 reabsorption has recently been challenged. Indeed, this action of parathyroid hormone (PTH) has only been observed in acute studies, whereas in animal models of chronic hyperparathyroidism a metabolic alkalosis has been induced, probably owing to the release of alkaline salts from bone tissue, and to the stimulation of tubular acid secretion by hypercalcaemia. Studies were, therefore, performed to determine the effect of PTH on the renal handling of HCO3 in an animal model in which changes in plasma calcium and phosphate, and nephrocalcinosis, all known to affect tubular acidification, did not occur. Thyroparathyroidectomized (TPTX) rats were infused with synthetic bovine hormone fragment bPTH 1-34 via Alzet minipumps at the rate of 0.7 U h-1 to simulate normal endogenous production of PTH (group I) and at the three-fold higher rate of 2.1 U h-1 (group II). In order to prevent changes in serum calcium and phosphate, and nephrocalcinosis, animals of group II were fed a Ca- and P-free diet prior to TPTX (compared with a regular diet for group I) and both groups were treated with dichloromethylene-diphosphonate (Cl2MDP, 10 mg kg-1 day-1) and a Ca-free diet during PTH infusion. During the course of PTH infusion both groups of animals had stable and normal levels of plasma calcium and phosphate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Control of proximal tubule fluid reabsorption in experimental glomerulonephritis.

We have recently shown that in the early autologous phase of nephrotoxic serum nephritis (NSN) single nephron glomerular filtration rate is unchanged from values in normal hydropenic control rats, but that single nephron filtration fraction and efferent arteriolar oncotic pressure (piE) are reduced because of a marked reduction in the glomerular capillary ultrafiltration coefficient. The present study was undertaken to examine the influence of this decline in piE as well as the other known determinants of peritubular capillary fluid exchange on absolute proximal fluid reabsorption (APR) in NSN. The findings indicate that APR and proximal fractional reabsorption are reduced significantly in NSN, relative to values in a separate group of age and weight-matched normal hydropenic control rats studied concurrently. In addition to the measured decline in piE, efferent arteriolar plasma flow (Qe) and peritubular capillary hydraulic pressure (Pc) were found to increase significantly, while interstitial oncotic pressure, estimated from hilar lymph, was not significantly different from values in control rats. Using a mathematical model of peritubular capillary fluid uptake we found that, assuming that the capillary permeability-surface area product and interstitial hydraulic pressure are unchanged in NSN, the observed changes in piE and Pc are sufficient to offset the effect of the increase in QE, yielding a calculated reduction in APR of approximately 4 nl/min, in excellent agreement with the observed mean decline of 4.1 nl/min. These findings suggest that control of APR in NSN is mediated by the same factors that regulate APR under normal physiological conditions, namely, the imbalance of forces governing peritubular capillary uptake of isotonic reabsorbate.     

Effect of acute hypercapnia on renal bicarbonate reabsorption in the dog

The increased plasma bicarbonate concentration seen in hypercapnia implies that tubular bicarbonate reabsorption must be increased in the presence of an elevated Paco2. In contrast to early reports, more recent experimental data in acute hypercapnia have been interpreted to show that the observed increment in tubular reabsorption of bicarbonate factored for glomerular filtration rate (THCO3/GFR) is largely related to the concurrent changes in renal sodium reabsorption and to the increment in the filtered load of bicarbonate, and that acute hypercapnia per se causes little or no change in the tubular handling of bicarbonate. We reexamined this question by observing the changes in renal function occurring in the presence of a moderate elevation of plasma bicarbonate concentration in two groups of dogs. In group I, the elevation occurred as a result of acute hypercapnia during the administration of an "isometric" solution; in group II, it was caused by the infusion of identical amounts of an isotonic solution with the same concentration of sodium as in group I, but a higher bicarbonate concentration, in the presence of eucapnia. A subset of group II provided controls for the decrease in renal perfusion pressure that occurred spontaneously in group I. With increasing filtered loads of bicarbonate, fractional excretion (FE) of HCO3 increased in group II, whereas it dropped markedly in group I. Furthermore, the relative reabsorption rate of HCO3 compared with that of Cl (assessed by changes in fractional reabsorption (FR) of HCO3/Cl) decreased in group II, whereas it increased in group I. Although FENa also decreased in group II, the opposite changes in FR(HCO3/Cl) could not be attributed solely to concurrent changes in sodium handling, indicating that in the presence of acute hypercapnia there is a preferential reabsorption of bicarbonate that tends to perpetuate the increase in plasma bicarbonate concentration. By contrast, THCO3/GFR rose in both groups. The data are interpreted to reveal that acute hypercapnia, although causing a drop in renal perfusion pressure and in natriuresis, also has an additional specific effect on raising preferential bicarbonate reabsorption. This effect can be detected best by monitoring changes in the anionic composition of tubular reabsorbate, whereas it may not be unveiled by following changes in THCO3/GFR. Changes in THCO3/GFR may not yield useful information regarding the integrated response of the kidney to acid-base perturbations, and the conclusions of previous studies based on changes in this parameter must be carefully reexamined.     

Sodium bicarbonate treatment and ubiquitin gene expression in acidotic human subjects with chronic renal failure

BACKGROUND: In chronic renal failure, metabolic acidosis is associated with increased whole body protein degradation. In rats this effect of acidosis occurs in skeletal muscle and is associated with increased ubiquitin mRNA expression. This has not been demonstrated in humans. MATERIALS AND METHODS: Six patients with chronic renal failure and acidosis underwent muscle biopsy before and after 1 month's treatment with sodium bicarbonate. RNA was extracted from the biopsy, and the expression of the genes for ubiquitin and the proteasome component, C2, were measured by Northern blotting. RESULTS AND CONCLUSIONS: There was no significant difference in the expression of ubiquitin or C2 after bicarbonate treatment. This is contrast with results from animal models of acidosis and some other catabolic conditions in humans. This may reflect the complexity of the ubiquitin-dependent pathway, and it may be that changes in ubiquitin expression are only seen with more severe and/or acute changes in pH.     

Evidence for enhanced distal tubule sodium reabsorption in chronic salt-depleted dogs.

In order to assess the renal tubular site(s) at which sodium reabsorption is enhanced in chronic sodium-depletion, seven normal dogs, six salt-depleted dogs, and three normal dogs receiving aldosterone were studied during a steady-state water diuresis under Pentothal anesthesia and during progressive hypotonic saline diuresis. For both maintenance of the water diuresis and progressive hypotonic saline diuresis 0.45% NaCl was used. During the steady state water diuresis delivery of sodium to the diluting segment of the nephron as approximated by solute-free water clearance + sodium clearance/glomerular filtration rate (CH2O + CNa/GFR) was significantly lower in salt-depleted dogs compared to normal dogs with or without aldosterone. During progressive hypotonic saline infusion fractional free water excretion (CH2O/GFR) was similar in all three groups as CH2O + CNa/GFR increased up to 12-14 ml/min-100 ml GFR. Thereafter, CH2O/GFR continued to rise in virtually a straight line in salt-depleted dogs but leveled off in normal dogs with or without aldosterone. These data demonstrate that enhanced sodium reabsorption in the diluting segment of the nephron is an important determinant of the renal sodium retention in chronic extracellular volume contraction in dogs in addition to confirming the presence of increased proximal tubule sodium reabsorption in these animals.     

Effect of formate on volume reabsorption in the rabbit proximal tubule.

Studies on microvillus membrane from rabbit kidney cortex suggest that chloride absorption may occur by chloride/formate exchange with recycling of formic acid by nonionic diffusion. We tested whether this transport mechanism participates in active NaCl reabsorption in the rabbit proximal tubule. In proximal tubule S2 segments perfused with low HCO-3 solutions, the addition of formate (0.25-0.5 mM) to the lumen and the bath increased volume reabsorption (JV) by 60%; the transepithelial potential difference remained unchanged. The effect of formate on JV was completely reversible and was inhibited both by ouabain and by luminal 4,4'-diisothiocyanostilbene-2,2'-disulfonate. Formate (0.5 mM) failed to stimulate JV in early proximal convoluted tubules perfused with high HCO-3 solutions. As measured by miniature glass pH microelectrodes, this lack of formate effect on JV was related to a less extensive acidification of the tubule fluid when high HCO-3 solutions were used as perfusate. These data suggest that chloride/formate exchange with recycling of formic acid by nonionic diffusion represents a mechanism for active, electroneutral NaCl reabsorption in the proximal tubule.     

Increased sodium reabsorption in the proximal and distal tubule of caval dogs

The effects of water diuresis, hypotonic NaCl, and hypotonic mannitol diuresis on renal sodium and water excretion were examined in normal dogs and in dogs with chronic constriction of the thoracic inferior vena cava and ascites (caval dogs). During all three diuretic states, the capacity to excrete solute-free water relative to the supply of sodium to the water clearing segment of the nephron was significantly greater in the caval dog. This finding was most evident during hypotonic NaCl diuresis but was also striking during hypotonic mannitol diuresis despite the more unfavorable gradient for sodium reabsorption at the distal tubule produced by this agent in caval dogs. In addition, fractional distal sodium load was significantly smaller in caval dogs during water diuresis and could not be increased as readily as in normal dogs by hypotonic NaCl or mannitol infusion. The data indicate that fractional sodium reabsorption is increased at the water clearing segment and the proximal tubule in caval dogs.     

Proximal bicarbonate reabsorption during Ringer and albumin infusions in the rat.

Several studies have clearly shown that extracellular volume expansion is associated with suppression of whole kidney bicarbonate reabsorption, although little is known concerning the single nephron correlates of this response. More recently, attention has also been focussed on bicarbonate transport in attempts to identify a possible role for this ion in enhancing the rate of net fluid efflux by proximal tubules. To further explore proximal tubular bicarbonate handling in the rat, we carried out recollection micropuncture studies to assess the effects of infusions of modified Ringer or salt-poor hyperoncotic human albumin. With stable levels of arterial PCO2, plasma [HCO3-] or plasma [K+], marked suppression of fractional HCO3- reabsorption occurred: during Ringer infusion fractional reabsorption fell by 31% (P less than 0.001) while during albumin infusion a decrease of 20% (P less than 0.001) was observed. Despite this, absolute net HCO3- reabsorptive rates did not change significantly. Simple and partial correlation analysis of single tubular responses revealed strong linkage effects between changes in absolute net reabsorptive rates for HCO3- and H2O in both types of infusion; the partial r was 0.91 (P less than 0.001) and 0.94 (P less than 0.001) during Ringer and albumin infusions, respectively. We conclude that under these free-flow conditions, Ringer and albumin infusions do not suppress absolute net HCO3- reabsorption by proximal tubules, and that strongly linked changes in absolute HCO3- and H2O fluxes are characteristic of both protocols.     

Luminal chloride modulates rat distal tubule bidirectional bicarbonate flux in vivo.

The effects of replacing luminal chloride with gluconate on distal tubule bicarbonate transport were studied in vivo in normally fed rats, overnight-fasted rats, and rats made mildly alkalotic by administration of desoxycorticosterone acetate (DOCA). In paired microperfusions of the same tubule with 0 or 55 mM Cl at 25 nl/min, net secretion of bicarbonate by distal tubules of fed rats was inhibited by chloride replacement. Zero chloride perfusion in DOCA rats also resulted in an inhibition of net bicarbonate secretion at 25 nl/min. In contrast, replacement of 45 mM chloride also perfused at 25 nl/min in fasted rats caused an increase in net bicarbonate reabsorption. To further characterize the effects of changes in luminal chloride, experiments were undertaken in fasted rats with 0, 45, and 100 mM chloride-containing solutions perfused at 8 and 25 nl/min. Perfusion with zero Cl resulted in net bicarbonate reabsorption at 8 nl/min that increased markedly with high flow, whereas bicarbonate reabsorption did not change significantly during perfusion at high flow with a 45-mM Cl perfusate. In marked contrast, perfusion with a 100-mM Cl solution resulted in only minimal bicarbonate reabsorption at 8 nl/min with significant secretion observed at high flow. Thus, chloride-free perfusates inhibit bicarbonate secretion and enhance bicarbonate reabsorption, while high chloride perfusates elicit net bicarbonate secretion in usually reabsorbing distal tubules.     

Renal ammonia production from the nitrogens of glutamine in intact acidotic dogs before and after bicarbonate infusions

Renal ammonia is produced from the amide nitrogen of glutamine, approximately 33-50%. The remainder derives from the amino nitrogen of glutamine and other non amide sources, probably the amino nitrogens of other amino acids. We investigated the acute effects of acid-base perturbations on ammonia production from amide and non amide nitrogen sources to determine how they interrelate. Infusions of glutamine were given to some intact dogs to vary the renal load. Following an acute alkali challenge to dogs in metabolic acidosis, ammoniagenesis from the amide nitrogens decreased significantly when the presentation of glutamine to the kidney was normal or relatively low, but changed less or even increased when the glutamine load was relatively high. In contrast, ammonia from the non amide sources consistently decreased during acute alkalotic challenge at any glutamine load-high or low. Since decreased glutamine deamination leading to glutamate accumulation is generally associated with decreased deamidation in dogs with normal plasma glutamine concentrations, we explain the discrepancy of deamidation at high glutamine loads to an unmasking of a separate effect on the glutaminase (phosphate-dependent) pathway by the acute acid-base changes. Accordingly, our results indicate more than one influence from acute acid-base changes in vivo on renal ammonia formation, one stimulatory and other inhibitory. Nevertheless, the influence of glutamate removal predominates over the other effect on the phosphate-dependent glutaminase pathway at physiological concentrations of glutamine in the intact dog.     

Renal acidification defect induced by lithium in control and acidotic rats

1. The aim of this work was to contribute to a better understanding of the mechanism by which Li+ administration impairs renal tubular acidification. 2. The kinetics of tubular acidification in the mid-proximal and distal convoluted tubules were studied by measuring intratubular pH using Sb microelectrodes during stopped-flow microperfusion with Krebs-Ringer bicarbonate (30 mmol/l) buffer. Four groups of male Wistar rats were utilized in this study: control, control plus lithium (C + Li+; one intraperitoneal injection of LiCl of 4 mmol l-1 day-1 kg-1 for 4 days), acidotic and acidotic plus lithium (A + Li+). 3. In C + Li+ rats, the half-time of acidification was significantly higher than in control rats (P less than 0.01), in both the mid-proximal tubule (11.3 +/- 0.34 vs 6.73 +/- 0.22 s) and the distal convoluted tubule (17.5 +/- 0.31 vs 11.5 +/- 1.02 s), and net HCO3- reabsorption was lower in both the mid-proximal tubule and the distal convoluted tubule. The effects of Li+ on tubular acidification kinetics were similar in acidotic rats. 4. A net Na+ flux, as measured by the Gertz split-droplet method, was significantly decreased in the mid-proximal tubule (P less than 0.01) in C + Li+ rats compared with control rats (2.14 +/- 0.17 vs 4.07 +/- 0.39 nmol s-1 cm-2). 5. The transepithelial potential difference in the distal convoluted tubule was significantly lower (P less than 0.01) in C + Li+ rats than in control rats (-7.50 +/- 1.50 vs -20.5 +/- 1.12 mV).(ABSTRACT TRUNCATED AT 250 WORDS)