Peritubular Bath Research Articles

Epidermal Growth Factor Reduces Collecting Duct Water Permeability by Inhibiting Aquaporin-2 Phosphorylation at Ser269

Prior studies showed that epidermal growth factor (EGF) inhibits vasopressin-stimulated osmotic water permeability in the renal collecting duct. Here, we investigated the underlying mechanism of this response. Using the Burg isolated perfused tubule technique in microdissected rat inner medullary collecting ducts (IMCDs), we found that addition of 0.1 μM EGF to the peritubular bath significantly decreased 0.1 nM 1‐deamino‐8‐D‐arginine vasopressin (dDAVP)-stimulated water permeability, confirming prior observations. The inhibitory effect of EGF on dDAVP-stimulated water permeability was associated with a reduction in intracellular cyclic AMP levels and protein kinase A (PKA) activity. Using phospho-specific antibodies and immunoblotting in IMCD suspensions, we showed that EGF significantly reduces dDAVP-stimulated aquaporin-2 (AQP2) phosphorylation at S264 and S269. This effect was absent when membrane-permeable 8-cpt-cAMP (0.1 mM) was used to stimulate AQP2 phosphorylation, suggesting that EGF’s effect was on a pre-cAMP step. Immunofluorescence labeling of microdissected IMCDs showed that EGF significantly reduced apical AQP2 abundance in the presence of dDAVP. To address what protein kinase might be responsible for S269 phosphorylation, we used Bayesian analysis to integrate multiple -omic datasets. Thirteen top ranked protein kinases were subsequently tested by in vitro phosphorylation experiments for their ability to phosphorylate AQP2 peptides using a mass spectrometry readout. The results show that the PKA catalytic-α subunit increased phosphorylation at S256, S264, and S269. None of the other kinases phosphorylated S269. Additionally, PKA inhibitors, H-89 and PKI, strongly inhibited dDAVP-stimulated AQP2 phosphorylation at S269. These results indicate that EGF decreases the water permeability of the collecting duct by inhibiting cAMP production, thereby inhibiting PKA and decreasing AQP2 phosphorylation at S269, a site previously shown to regulate AQP2 endocytosis. This work was funded by NHLBI project ZIA-HL001285 and ZIA-HL006129, M.A.K. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Collecting duct water permeability inhibition by EGF is associated with decreased cAMP, PKA activity, and AQP2 phosphorylation at Ser269.

Prior studies showed that epidermal growth factor (EGF) inhibits vasopressin-stimulated osmotic water permeability in the renal collecting duct. Here, we investigated the underlying mechanism. Using isolated perfused rat inner medullary collecting ducts (IMCDs), we found that the addition of EGF to the peritubular bath significantly decreased 1-deamino-8-d-arginine vasopressin (dDAVP)-stimulated water permeability, confirming prior observations. The inhibitory effect of EGF on water permeability was associated with a reduction in intracellular cAMP levels and protein kinase A (PKA) activity. Using phospho-specific antibodies and immunoblotting in IMCD suspensions, we showed that EGF significantly reduces phosphorylation of AQP2 at Ser264 and Ser269. This effect was absent when 8-cpt-cAMP was used to induce AQP2 phosphorylation, suggesting that EGF's inhibitory effect was at a pre-cAMP step. Immunofluorescence labeling of microdissected IMCDs showed that EGF significantly reduced apical AQP2 abundance in the presence of dDAVP. To address what protein kinase might be responsible for Ser269 phosphorylation, we used Bayesian analysis to integrate multiple-omic datasets. Thirteen top-ranked protein kinases were subsequently tested by in vitro phosphorylation experiments for their ability to phosphorylate AQP2 peptides using a mass spectrometry readout. The results show that the PKA catalytic-α subunit increased phosphorylation at Ser256, Ser264, and Ser269. None of the other kinases tested phosphorylated Ser269. In addition, H-89 and PKI strongly inhibited dDAVP-stimulated AQP2 phosphorylation at Ser269. These results indicate that EGF decreases the water permeability of the IMCD by inhibiting cAMP production, thereby inhibiting PKA and decreasing AQP2 phosphorylation at Ser269, a site previously shown to regulate AQP2 endocytosis.NEW & NOTEWORTHY The authors used native rat collecting ducts to show that inhibition of vasopressin-stimulated water permeability by epidermal growth factor involves a reduction of aquaporin 2 phosphorylation at Ser269, a consequence of reduced cAMP production and PKA activity.

Transcellular and paracellular pathways of transepithelial fluid secretion in Malpighian (renal) tubules of the yellow fever mosquito Aedes aegypti

Isolated Malpighian tubules of the yellow fever mosquito secrete NaCl and KCl from the peritubular bath to the tubule lumen via active transport of Na(+) and K(+) by principal cells. Lumen-positive transepithelial voltages are the result. The counter-ion Cl(-) follows passively by electrodiffusion through the paracellular pathway. Water follows by osmosis, but specific routes for water across the epithelium are unknown. Remarkably, the transepithelial secretion of NaCl, KCl and water is driven by a H(+) V-ATPase located in the apical brush border membrane of principal cells and not the canonical Na(+), K(+) -ATPase. A hypothetical cation/H(+) exchanger moves Na(+) and K(+) from the cytoplasm to the tubule lumen. Also remarkable is the dynamic regulation of the paracellular permeability with switch-like speed which mediates in part the post-blood-meal diuresis in mosquitoes. For example, the blood meal the female mosquito takes to nourish her eggs triggers the release of kinin diuretic peptides that (i) increases the Cl(-) conductance of the paracellular pathway and (ii) assembles V(1) and V(0) complexes to activate the H(+) V-ATPase and cation/H(+) exchange close by. Thus, transcellular and paracellular pathways are both stimulated to quickly rid the mosquito of the unwanted salts and water of the blood meal. Stellate cells of the tubule appear to serve a metabolic support role, exporting the HCO(3)(-) generated during stimulated transport activity. Septate junctions define the properties of the paracellular pathway in Malpighian tubules, but the proteins responsible for the permselectivity and barrier functions of the septate junction are unknown.

Tissue kallikrein permits early renal adaptation to potassium load

Tissue kallikrein (TK) is a serine protease synthetized in renal tubular cells located upstream from the collecting duct where renal potassium balance is regulated. Because secretion of TK is promoted by K+ intake, we hypothesized that this enzyme might regulate plasma K+ concentration ([K+]). We showed in wild-type mice that renal K+ and TK excretion increase in parallel after a single meal, representing an acute K+ load, whereas aldosterone secretion is not modified. Using aldosterone synthase-deficient mice, we confirmed that the control of TK secretion is aldosterone-independent. Mice with TK gene disruption (TK-/-) were used to assess the impact of the enzyme on plasma [K+]. A single large feeding did not lead to any significant change in plasma [K+] in TK+/+, whereas TK-/- mice became hyperkalemic. We next examined the impact of TK disruption on K+ transport in isolated cortical collecting ducts (CCDs) microperfused in vitro. We found that CCDs isolated from TK-/- mice exhibit net transepithelial K+ absorption because of abnormal activation of the colonic H+,K+-ATPase in the intercalated cells. Finally, in CCDs isolated from TK-/- mice and microperfused in vitro, the addition of TK to the perfusate but not to the peritubular bath caused a 70% inhibition of H+,K+-ATPase activity. In conclusion, we have identified the serine protease TK as a unique kalliuretic factor that protects against hyperkalemia after a dietary K+ load.

Roles of basolateral solute uptake via NKCC1 and of myosin II in vasopressin-induced cell swelling in inner medullary collecting duct

Collecting duct cells swell when exposed to arginine vasopressin (AVP) in the presence of a transepithelial osmolality gradient. We investigated the mechanisms of AVP-induced cell swelling in isolated, perfused rat inner medullary collecting ducts (IMCDs) using quantitative video microscopy and fluorescence-based measurements of transepithelial water transport. We tested the roles of transepithelial water flow, basolateral solute entry, and the cytoskeleton (actomyosin). When a transepithelial osmolality gradient was imposed by addition of NaCl to the bath, AVP significantly increased both water flux and cell height. When the osmolality gradient was imposed by addition of mannitol, AVP increased water flux but not cell height, suggesting that AVP-induced cell swelling requires a NaCl gradient and is not merely dependent on the associated water flux. Bumetanide (Na-K-2Cl cotransporter inhibitor) added to the bath markedly diminished the AVP-induced cell height increase. AVP-induced cell swelling was absent in IMCDs from NKCC1-knockout mice. In rat IMCDs, replacement of Na, K, or Cl in the peritubular bath caused significant cell shrinkage, consistent with a basolateral solute transport pathway dependent on all three ions. Immunocytochemistry using an antibody to NKCC1 confirmed basolateral expression in IMCD cells. The conventional nonmuscle myosin II inhibitor blebbistatin also diminished the AVP-induced cell height increase and cell shape change, consistent with a role for the actin cytoskeleton and myosin II. We conclude that the AVP-induced cell height increase is dependent on basolateral solute uptake via NKCC1 and changes in actin organization via myosin II, but is not dependent specifically on increased apical water entry.

Role of NKCC1 in vasopressin‐induced cell swelling in renal collecting duct cell

Vasopressin (AVP) increases both water permeability (Pf) and the cell height of isolated perfused renal collecting ducts. The mechanism of AVP-induced cell swelling remains unclear. We aimed to determine whether NKCC1 is necessary for the AVP-induced cell swelling. The presence of NKCC1 mRNA and protein in rat inner medullary collecting ducts (IMCD) were confirmed by RT-PCR and immunoblotting. For functional studies, IMCDs were microdissected and perfused in vitro. Cell height was measured using differential interference contrast microscopy. Pf was measured under an imposed 200 mOsm bath-to-lumen osmolality gradient (addition of NaCl) using fluorescein sulfonate as a volume marker. AVP increased cell height by 23% of the control condition, which can be inhibited by 100 uM bumetanide in the peritubular bath. This is consistent with the presence of bumetanide-sensitive transporter in the basolateral membrane of the IMCD cell. When IMCD was perfused under a 200 mOsm osmolality gradient by mannitol addition, AVP did not increase cell height, even though Pf increased from 74±12 to 371±33 μm/s, suggesting that AVP-induced cell swelling is dependent on a favorable NaCl gradient, and is not a necessary concomitant of increased lumen-to-bath osmotic water flux. Isolated perfused IMCDs dissected from NKCC1 null mice revealed that AVP did not increase the cell height. These results show that NKCC1 plays a key role in AVP-induced cell swelling in IMCD cell.

Calmodulin Is Required for Vasopressin-stimulated Increase in Cyclic AMP Production in Inner Medullary Collecting Duct

Calmodulin plays a critical role in regulation of renal collecting duct water permeability by vasopressin. However, specific targets for calmodulin action have not been thoroughly addressed. In the present study, we investigated whether Ca2+/calmodulin regulates adenylyl cyclase activity in the renal inner medullary collecting duct. Rat inner medullary collecting duct suspensions were incubated in the presence or absence of 0.1 nM vasopressin and the calmodulin inhibitors, monodansylcadaverine, W-7, and trifluoperazine, followed by measurement of cAMP. Vasopressin-stimulated cAMP elevation was significantly attenuated in the presence of calmodulin inhibitors. Analysis of transglutaminase 2 knock-out mice confirmed that these compounds were not acting through inhibition of transglutaminase 2 activity. Calmodulin inhibitors also blocked both cholera toxin- and forskolin-stimulated cAMP accumulation. In isolated perfused tubules, W-7 reversibly blocked vasopressin-stimulated urea permeability, a process that requires a rise in intracellular cAMP but does not appear to involve protein trafficking to the apical plasma membrane. These results suggest that calmodulin is required for vasopressin-stimulated adenylyl cyclase activity in the intact inner medullary collecting duct. Reverse transcription-PCR, immunoblotting, and immunohistochemistry revealed the presence of the calmodulin-sensitive adenylyl cyclase type 3 in the rat collecting duct, an isoform previously not known to be expressed in the collecting duct. Long-term treatment of Brattleboro rats with a vasopressin analog markedly decreased adenylyl cyclase type 3 protein abundance, providing an explanation for long-term down-regulation of vasopressin response in the collecting duct. These studies demonstrate the importance of calmodulin in the regulation of collecting duct adenylyl cyclase activity and transport function.

Oxytocin as an antidiuretic hormone. I. Concentration dependence of action.

Circulating concentrations of oxytocin increase to 10-40 pM in rats in response to osmotic stimuli, suggesting that oxytocin could play a role in regulation of water balance. The present studies tested whether oxytocin at such concentrations increases osmotic water permeability (Pf) in isolated perfused terminal inner medullary collecting ducts (IMCD). In IMCD segments from Sprague-Dawley rats, 20 pM oxytocin added to the peritubular bath caused a two- to threefold increase in Pf, whereas 200 pM oxytocin increased Pf by five- to sixfold (n = 8, P < 0.01). IMCD from Brattleboro rats, which manifest central diabetes insipidus, exhibited a 2.8-fold increase in Pf in response to 20 pM oxytocin and a 4.7-fold increase in response to 200 pM oxytocin. However, in Brattleboro rats, the response to 20 pM oxytocin was dependent on prior water restriction of the rats. Immunoblotting showed no change in the expression of the aquaporin-CD water channel in Brattleboro rats in response to water restriction. Nevertheless, immunofluorescence studies of inner medullary tissue from Brattleboro rats revealed a marked redistribution of the aquaporin-CD water channels to a predominantly apical and subapical localization in IMCD cells in response to water restriction, similar to the redistribution seen in response to vasopressin. Mathematical modeling studies revealed that the measured increase in Pf in response to oxytocin is sufficient to generate a concentrated urine. We conclude that oxytocin can function physiologically as an antidiuretic hormone, mimicking the short-term action of vasopressin on water permeability, albeit with somewhat lower potency.

Renal transepithelial phosphate secretion: luminal membrane voltage and Ca2+ dependence.

The role of apical membrane electrical potential, the possibility of K+ channel involvement, and the role of extracellular Ca2+ in transepithelial P(i) secretion were examined in primary monolayer cultures of flounder renal proximal tubule cells in Ussing chambers. Exposure to 200 nM thapsigargin (TG) significantly increased net P(i) secretion. In TG-stimulated tissues, substitution of 100 mM KCl for 100 mM NaCl in the luminal medium depolarized the apical membrane potential from -64 +/- 2.8 to -26 +/- 3.9 mV and strongly inhibited net P(i) secretion. In 32P(i)-preloaded tissues, cell-to-lumen exit of 32P(i) was significantly decreased to approximately 50% of control by high luminal K+ while cell-to-peritubular bath movement was unchanged. Addition of BaCl2 (2 mM) or charybdotoxin (20 nM) to the luminal surface significantly reduced TG-stimulated net P(i) secretion. The elevation of bath Ca2+ from 2 to 5 mM significantly increased secretory flux and decreased reabsorptive flux. The effect of TG on net P(i) secretion was reduced by the Ca2+ channel blocker verapamil (VE, 100 microM) to 65% of control and by calmodulin antagonist W-7 (20 microM) to 35% of control but it was not blocked by the protein kinase inhibitor H-7 (100 microM). VE also significantly inhibited the P(i) secretion induced by acidification of the peritubular bathing medium. The data indicate that transepithelial P(i) secretion induced by TG is significantly influenced by apical membrane electrical polarity, which may be regulated in part by Ca(2+)-activated K+ channels.

Mathematical models of tubular transport.

Mathematical models of the renal tubule are classified as epithelial, tubular, or multitubular. The simplest epithelial models are single equations that represent the overall transepitheiiai solute and water fluxes as functions of the luminal and peritubular bath conditions. More detailed models represent both luminal and peritubular cell membranes, in parallel with a tight junction, all in series with an epithelial basement membrane. In these models, the presence of transport components in series renders the cell and interspace concentrations unknown variables that must be determined via solution of a set of conservation equations. The tubular models allow prediction of the effect of epithelial transport to modify the luminal solution and, conversely, the effect of altered luminal composition on transepithelial fluxes. Here the conservation equations constitute a set of ordinary differential equations, with initial data that must be integrated along the tubule length. The lining epithelium may be represented by single flux equations, or by a compart­ )

Regulation of epithelial shunt conductance by the peptide leucokinin

Isolated Malpighian tubules of the yellow fever mosquito Aedes aegypti spontaneously secrete NaCl, KCl and water across an epithelium of modest transepithelial resistance (40-80 omega cm2) and high transepithelial voltage (30-70 mV, lumen positive). Transepithelial electrochemical potentials indicate that Na and K are secreted by active and Cl by passive transport mechanisms. The addition of synthetic leucokinin-VIII (LK-VIII, insect myotropic peptide) to the peritubular bath significantly increases the rates of transepithelial NaCl, KCl and water secretion. In parallel, LK-VIII depolarizes the transepithelial voltage from 59.3 to 5.7 mV, decreases the transepithelial resistance from 57.7 to 9.9 omega cm2, and renders the basolateral and apical membrane voltages nearly equipotential (approximately -90 mV). Unilateral step changes of the [Cl] in the peritubular bath or tubule lumen elicit small transepithelial Cl diffusion potentials in the absence of LK-VIII but large transepithelial Cl diffusion potentials, up to 85% of Nernst equilibrium potentials, in the presence of LK-VIII. In Malpighian tubules treated with dinitrophenol for estimates of the shunt resistance Rsh, LK-VIII reduces Rsh from 52.5 to 5.8 omega cm2. Bilateral reductions of the Cl concentration in tubule lumen and peritubular bath fully restore Rsh to 55.8 omega cm2 in the presence of LK-VIII. LK-VIII has no effects when presented from the luminal side. These results suggest that LK-VIII increases the Cl conductance of the epithelial shunt via a receptor located at the basolateral side of the epithelium.

In vitro perfusion of chinchilla thin limb segments: urea and NaCl permeabilities

We measured the urea and NaCl permeabilities (Purea and PNaCl, respectively) of the following nephron segments from chinchilla: the upper part of the long-loop descending limb (from outer medulla, LDLu), the middle part of the long-loop descending limb (from outer 30% of the inner medulla, LDLm), the lower part of the long-loop descending limb (from deep inner medulla, LDLl), and the thin ascending limb (from deep inner medulla, ATL). We found that Purea (x10(-5) cm/s) was relatively low in the LDLu (3.3), but that the value was larger in the inner medullary thin descending limb (16.8 for LDLm and 47.6 for LDLl). The ATL had an even higher value (170). Phloretin, 0.25 mM, added to the peritubular bath had no effect on Purea of these segments, suggesting that the rapid transport rate is not due to a phloretin-sensitive facilitated transport pathway like that seen in the inner medullary collecting duct. PNaCl (x10(-5) cm/s) also increased with distance along the length of the thin descending limb (LDLu, 11.7; LDLm, 41.2; LDLl, 98.4; and ATL, 321). Calculations from NaCl dilution potential measurements showed that LDLu was Na+ permselective, whereas LDLl and ATL were Cl- permselective. High solute permeabilities in the inner medullary thin descending limb contradict a major requirement of the passive model of urinary concentration developed previously (J. P. Kokko and F. C. Rector, Jr. Kidney Int. 2: 214-223, 1972; and J. L. Stephenson. Kidney Int. 2: 85-94, 1972).

Secretory renal proximal tubules in seawater- and freshwater-adapted killifish

A population of proximal tubules when isolated from the glomerular kidneys of seawater-adapted (SW) and freshwater-adapted (FW) killifish (Fundulus heteroclitus) spontaneously secrete fluid. Regardless of SW or FW adaptation, Na and Cl are the dominant electrolytes in secreted fluid. Mg concentrations in fluid secreted by both tubules are significantly greater than those in the peritubular bath, and Mg concentrations are inversely related to Na concentrations. Proximal tubules from either SW or FW fish exhibit low transepithelial voltage (-1 to -2 mV) and low transepithelial resistances (20-30 omega.cm2) typical of other vertebrate proximal tubules. Transepithelial diffusion potentials for Na, Cl, Mg, and SO4 suggest that the paracellular pathway is Na selective and impermeable to divalent ions. Consideration of transepithelial electrochemical potential differences for Na, Cl, Mg, and SO4 suggests active transport of Mg, SO4, and Cl in proximal tubules isolated from SW- and FW-adapted fish. The similarities in the functional properties of secretory proximal tubules isolated from SW- and FW-adapted killifish are striking and raise questions about the in vivo role of these tubules in the renal adaptations to seawater and freshwater.

Diffusion resistances between ADH-induced vacuoles and the extracellular space in rabbit collecting duct: evidence that mos vacuoles are intracellular, endocytic compartments

Large vacuoles form in the renal collecting duct following the onset of antidiuretic hormone (ADH)-stimulated water reabsorption. The aim of the present study was to test two alternative hypotheses regarding the origins of these structures: (1) the vacuoles constitute basilar, extracellular spaces that dilate as water flows through these spaces from cells into the peritubular compartment; or (2) the vacuoles represent intracellular, endocytic compartments that dilate during water reabsorption due to enhanced fluid phase endocytosis. Fluorescence-digital imaging microscopy was used to visualize the uptake into vacuoles of a hydrophilic fluorochrome (6 methoxy-N-[3 sulfopropyl] quinolinium) whose fluorescence is markedly quenched by halides. During their formation, most vacuoles (67%) accumulated the fluorochrome from the peritubular bath and trapped the dye well after (greater than 60 min) washing it from the bath. The spatial pattern of fluorescence within individual vacuoles indicated that the dye was trapped within these structures as a fluid-phase marker and was not bound to the vacuole margins. The fluorescence of dye trapped within vacuoles was virtually unaltered by changes in peritubular Cl- or Br- concentration that elicit dramatic quenching of dye-fluorescence in bulk solution, as expected if there exists a high diffusion resistance between the interiors of these structures and the peritubular space. These results indicate that most ADH-induced vacuoles represent endocytic compartments that are not directly connected to the extracellular space.

Urea gradient-associated fluid absorption with sigma urea = 1 in rat terminal collecting duct

It has been proposed that inner medullary collecting ducts (IMCDs) can absorb fluid in the absence of a transepithelial osmolality gradient if a perfusate-to-bath urea gradient is present. Such a process has been suggested to be caused by a nonunity reflection coefficient for urea (sigma urea less than 1). However, our recent measurements of sigma urea yielded values not significantly different from 1.0. The present study was done to readdress the possibility of direct coupling of water and urea transport in the rat IMCD. Isolated rat terminal IMCD segments were studied in the presence of 10(-10) M vasopressin with the osmolality of the perfusate equal to that of the peritubular bath but with a perfusate-to-bath urea gradient (bath osmolality balanced with NaCl). We measured both fluid absorption rate and urea concentration in collected fluid and calculated the osmolality of the collected fluid. We observed rapid fluid absorption associated with substantial urea absorption. The urea absorption caused a large fall in the osmolality of the collected fluid with respect to the bath. Simulations with a mathematical model of an isolated perfused tubule revealed that the transepithelial osmolality gradient generated along the length of tubule (caused by urea absorption) was large enough to account for the fluid absorption. Measurement of sigma urea with the "zero-flux" (or null point) method revealed a value of 1.00 +/- 0.02. Thus we conclude that the observed fluid absorption is the result of a transepithelial osmolality gradient generated by rapid urea absorption and does not require sigma urea less than one.

Ionic conductive properties of rabbit proximal straight tubule basolateral membrane

The ionic conductive properties of the nonperfused rabbit proximal straight tubule (S2) basolateral membrane were assessed by microelectrode techniques. The response of the basolateral membrane electrical potential difference, Vbl, to rapid changes in the peritubular bath concentration of K, HCO3, Na, and Cl were monitored with microelectrodes. The control steady-state Vbl averaged -41 mV (cell negative). An increase in peritubular bathing medium K concentration from 5 to 40 mM resulted in an instantaneous and sustained depolarization of +14.6 mV (27% of delta EK). Addition of barium (2 mM) depolarized the Vbl by +15.8 mV and abolished the Vbl response to the high-K medium. In other studies, reduction of peritubular bicarbonate at constant pH from 25 to 2.5 mM instantaneously and transiently depolarized Vbl by +15.8 mV (26% of delta EHCO3). In these same tubules reduction of peritubular Na from 126 to 2.2 mM resulted in an instantaneous and paradoxical depolarization of Vbl of +21.5 mV. Both depolarization transients resulting from reduction of Na and HCO3 were simultaneously inhibited by the addition of 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS; 0.5 mM), consistent with the presence of a SITS-sensitive Na-HCO3-coupled conductive pathway. In the absence of the bicarbonate buffer, reduction of Na resulted in a small sustained hyperpolarization of -5.8 mV (5% of delta ENa). Reduction of peritubular Cl from 120 to 4 mM resulted in an instantaneous and sustained depolarization of Vbl of +5.3 mV (6% of ECl) and was not affected by the addition of bumetanide (0.1 mM). It is concluded that the basolateral membrane of the nonperfused proximal straight tubule is characterized by a major barium-sensitive K conductance and a SITS-sensitive Na-coupled HCO3 conductance that carries net negative charge. These pathways are paralleled by relatively minor, but important, Na-conductive and Cl-conductive pathways.

Sodium entry routes in principal and intercalated cells of the isolated perfused cortical collecting duct

Transmembrane sodium transport pathways were studied in principal and intercalated cells of the isolated perfused rabbit cortical collecting duct. Intracellular electrolyte concentrations in individual collecting duct cells were measured by electron microprobe analysis during blockage of basolateral Na-K-ATPase by ouabain and simultaneous inhibition of sodium entry across the apical and/or basolateral cell membrane. In principal cells the ouabain-induced rise in cell sodium concentration could only partially be blocked by amiloride (10(-4) mol/l) in the perfusion fluid. Amiloride (10(-3) mol/l) added to the bathing solution produced a further, significant reduction of sodium influx. In principal cells the ouabain-induced increase in sodium concentration was completely prevented by amiloride in the perfusion solution in combination with omission of sodium from the peritubular bathing solution. In intercalated cells ouabain caused a less pronounced increase in sodium concentration than in principal cells. Neither amiloride in the perfusate, nor amiloride in both bathing and perfusion solution, significantly reduced the ouabain-induced rise in intercalated cell sodium concentration. These results indicate that in principal cells amiloride-sensitive sodium channels constitute the predominant pathway for sodium entry across the apical cell membrane. In addition, substantial amounts of sodium enter principal cells across the basolateral cell membrane, probably via Na-H exchange. Finally, the data suggest that in intercalated cells sodium channels and the Na-H exchange are sparse or even absent.

Concentration dependence of urea and thiourea transport in rat inner medullary collecting duct

The vasopressin-dependent urea permeability of the rat terminal inner medullary collecting duct (IMCD) is much greater than can be explained by lipid-phase permeation or paracellular diffusion, suggesting the presence of vasopressin-stimulated facilitated transport pathway. We used the isolated perfused tubule technique to test whether the urea transport pathway exhibits saturation characteristics consistent with a facilitated pathway. When the luminal urea concentration was varied between 0 and 800 mM (no urea in peritubular bath), the relationship between the urea flux and the luminal concentration was linear with a y-axis intercept that was not significantly different from zero, indicating an absence of saturation in this concentration range. Higher concentrations of urea could not be tested due to technical limitations. However, when thiourea (a urea analogue that shares the urea transport pathway with urea) was substituted for urea in similar experiments, the apparent thiourea permeability fell with increasing thiourea concentration in the range 10-200 mM, indicative of saturation of the urea-thiourea transporter. When the urea concentration was varied in both bath and lumen, the lumen-to-bath urea flux approached a limiting value at 400-500 mM urea, consistent with saturation of the transporter. However, nonspecific inhibition of urea transport by bath urea could not be ruled out in those experiments. We conclude that the urea and thiourea transport pathway in the terminal IMCD exhibits saturation characteristics. However, the urea concentration required to saturate the pathway is apparently high, at least 400-500 mM in one set of experiments and probably greater than 800 mM in another.

Use of fluorescent dye BCECF to measure intracellular pH in cortical collecting tubule.

The compound 2'-7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF) is being extensively used to measure intracellular pH (pHi) in a variety of tissue preparations. Use of this dye in the isolated perfused rabbit cortical collecting tubule (CCT) revealed two previously unreported findings. Apical incubation via luminal perfusion with the acetoxymethyl ester of BCECF (BCECF-AM) resulted in intense uptake into a minority cell population. Basolateral incubation via the peritubular bathing solution resulted in apparent homogenous uptake into all cells. The minority cells were identified as intercalated cells by the use of fluorescent probes specific for intercalated cells. Minority cell pHi was 7.34 +/- 0.06 (n = 9); majority cell pHi was 7.41 +/- 0.05 (n = 6). In addition, prolonged excitation of BCECF resulted in adverse effects. Intense continuous excitation for 1-3 min resulted in a fall in apparent pHi of 0.53 +/- 0.05 pH units (n = 6, P less than 0.001). After reloading with fresh BCECF-AM, the calculated pHi was 0.05 +/- 0.07 pH units higher than before prolonged excitation (P = NS), suggesting that the apparent decrease was due to changes in the pH sensitivity of BCECF as a result of the prolonged excitation. Prolonged excitation of cells with pHi clamped at 7.50 resulted in a decline in apparent pHi at the rate of 0.15 +/- 0.02 pH units/min (n = 4).(ABSTRACT TRUNCATED AT 250 WORDS)

ANF inhibits NaCl and fluid absorption in cortical collecting duct of rat kidney

Atrial natriuretic factor (ANF) is a peptide hormone that causes a large increase in urinary sodium chloride and water excretion when its plasma concentration rises above basal levels. As yet, there is no consensus regarding the chief site of action of ANF in the kidney. We microdissected and perfused rat cortical collecting ducts in vitro to determine whether ANF-(1-28) can directly inhibit net sodium and fluid absorption. ANF decreased both net sodium absorption and vasopressin-stimulated net fluid absorption by 50-90% when added to the peritubular bath solution. Approximately 50% inhibition of net fluid absorption occurred at 0.1 nM ANF, a level equivalent to plasma concentrations in volume-expanded rats. The action of ANF was mimicked by the addition of exogenous guanosine 3',5'-cyclic monophosphate. If ANF has a similar action on the cortical collecting duct in vivo, it could account for a substantial part of the ANF-mediated increase in urinary sodium and water excretion.