Transepithelial Osmotic Water Permeability Research Articles

Transepithelial water and urea permeabilities of isolated perfused Munich-Wistar rat inner medullary thin limbs of Henle's loop

To better understand the role that water and urea fluxes play in the urine concentrating mechanism, we determined transepithelial osmotic water permeability (Pf) and urea permeability (Purea) in isolated perfused Munich-Wistar rat long-loop descending thin limbs (DTLs) and ascending thin limbs (ATLs). Thin limbs were isolated either from 0.5 to 2.5 mm below the outer medulla (upper inner medulla) or from the terminal 2.5 mm of the inner medulla. Segment types were characterized on the basis of structural features and gene expression levels of the water channel aquaporin 1, which was high in the upper DTL (DTLupper), absent in the lower DTL (DTLlower), and absent in ATLs, and the Cl-(1) channel ClCK1, which was absent in DTLs and high in ATLs. DTLupper Pf was high (3,204.5 ± 450.3 μm/s), whereas DTLlower showed very little or no osmotic Pf (207.8 ± 241.3 μm/s). Munich-Wistar rat ATLs have previously been shown to exhibit no Pf. DTLupper Purea was 40.0 ± 7.3 × 10(-5) cm/s and much higher in DTLlower (203.8 ± 30.3 × 10(-5) cm/s), upper ATL (203.8 ± 35.7 × 10(-5) cm/s), and lower ATL (265.1 ± 49.8 × 10(-5) cm/s). Phloretin (0.25 mM) did not reduce DTLupper Purea, suggesting that Purea is not due to urea transporter UT-A2, which is expressed in short-loop DTLs and short portions of some inner medullary DTLs close to the outer medulla. In summary, Purea is similar in all segments having no osmotic Pf but is significantly lower in DTLupper, a segment having high osmotic Pf. These data are inconsistent with the passive mechanism as originally proposed.

The thick ascending limb and water channels: half-full or half-empty

the thick ascending limb of the loop of Henle plays a central role in urine concentration and dilution (reviewed in Ref. 7). The thick ascending limb actively reabsorbs NaCl but has an extremely low transepithelial osmotic water permeability, even in the presence of vasopressin (6). This combination of NaCl reabsorption without water reabsorption serves two vital functions: it provides NaCl to increase the osmolality of the medullary interstitium, tubules, vasculature, and collecting ducts; and it dilutes the luminal fluid within the thick ascending limb. During diuretic conditions, vasopressin levels are low, the collecting duct is virtually water impermeable, and the dilute luminal fluid is excreted as dilute urine. In contrast, during antidiuretic conditions when vasopressin levels are high, the collecting duct becomes highly water permeable, water is reabsorbed osmotically into the hypertonic medullary interstitium, and concentrated urine is excreted. Thus, active NaCl reabsorption without water reabsorption in the thick ascending limb sets up conditions permitting the production of either concentrated or dilute urine, depending on the presence or absence of vasopressin. While the thick ascending limb does not support transepithelial water reabsorption, the basolateral membrane is exposed to changes in interstitial osmolality. The volume of thick ascending limb cells changes in response to changes in interstitial osmolality (2–4). In an issue of the American Journal of Physiology-Renal Physiology, Cabral and Herrera (1) provide an elegant explanation for this apparent contradiction between the lack of transepithelial water reabsorption and the need for cell volume regulation. They propose that a water channel (or aquaporin) must be present in the basolateral plasma membrane to explain the ability of the cells to volume regulate, but not in the apical membrane to explain the lack of transepithelial water transport. Cabral and Herrera (1) provide molecular and functional data establishing the presence of aquaporin-1 (AQP1) in the basolateral plasma membrane and in the intracellular compartment, but not in the apical membrane. An important aspect of this paper is that it is the first demonstration of AQP1 expression in the thick ascending limb. This is particularly significant since previous studies reported that no aquaporins are expressed in the thick ascending limb (reviewed in Ref. 5). The lack of an aquaporin in the thick ascending limb was not questioned since there is no transepithelial water reabsorption in this segment. However, Cabral and Herrera (1) questioned this conventional wisdom. They reasoned that cell volume regulation does require the presence of an aquaporin, and then went on to show that AQP1 is expressed in the basolateral membrane. Cabral and Herrera (1) went to great lengths to prove that AQP1 is expressed in the basolateral membrane. In particular, their use of isolated thick ascending limbs was critical to their success. AQP1 is expressed in other structures in the cortex and outer medulla, including the proximal tubules, descending limbs, and vasa recta. Thus, its expression may have been missed when studies were performed using whole cortical or outer medullary lysates, or by the use of histochemistry of kidney tissue. In their study, Cabral and Herrera (1) begin to address the physiological importance of AQP1 in the basolateral membrane of the thick ascending limb. Their study of AQP1 knockout mice shows that about half of the basolateral membrane water permeability is mediated by AQP1. Their study did not elucidate the mechanism for the other 50%. One might expect that if AQP1 in the basolateral membrane is essential for cell volume regulation by thick ascending limb cells, then its loss could lead to osmotic damage. However, the AQP1 knockout mouse is a global knockout and has a urine-concentrating defect. Thus, osmotic shifts in the outer medulla will be reduced, mitigating the loss of AQP1 from the basolateral membrane, and hence any osmotic damage. Cabral and Herrera (1) raise a number of intriguing questions that will need to be addressed in future studies, including the mechanism for the 50% of basolateral membrane water flux that is not mediated by AQP1. Their study emphasizes the importance of using kidney tubules from animals and of questioning scientific dogma when it does not explain the physiology. Their study is important as it shows, for the first time, that AQP1 is expressed in the basolateral membrane of the thick ascending limb, but not in the apical membrane. Thus, in terms of AQP1, the thick ascending limb is either half-full (basolateral membrane) or half-empty (apical membrane). Both the half-full and half-empty portions serve key but different physiological roles in the thick ascending limb.

Very high aquaporin-1 facilitated water permeability in mouse gallbladder

Water transport across gallbladder epithelium is driven by osmotic gradients generated from active salt absorption and secretion. Aquaporin (AQP) water channels have been proposed to facilitate transepithelial water transport in gallbladder and to modulate bile composition. We found strong AQP1 immunofluorescence at the apical membrane of mouse gallbladder epithelium. Transepithelial osmotic water permeability (Pf) was measured in freshly isolated gallbladder sacs from the kinetics of luminal calcein self-quenching in response to an osmotic gradient. Pf was very high (0.12 cm/s) in gallbladders from wild-type mice, cAMP independent, and independent of osmotic gradient size and direction. Although gallbladders from AQP1 knockout mice had similar size and morphology to those from wild-type mice, their Pf was reduced by approximately 10-fold. Apical plasma membrane water permeability was greatly reduced in AQP1-deficient gallbladders, as measured by cytoplasmic calcein quenching in perfluorocarbon-filled, inverted gallbladder sacs. However, neither bile osmolality nor bile salt concentration differed in gallbladders from wild-type vs. AQP1 knockout mice. Our data indicate constitutively high water permeability in mouse gallbladder epithelium involving transcellular water transport through AQP1. The similar bile salt concentration in gallbladders from AQP1 knockout mice argues against a physiologically important role for AQP1 in mouse gallbladder.

Asymmetry in the Osmotic Response of a Rat Cortical Collecting Duct Cell Line: Role of Aquaporin-2

Transition from antidiuresis to diuresis exposes cortical collecting duct cells (CCD) to asymmetrical changes in environment osmolality, inducing an osmotic stress, which activates numerous membrane-associated events. The aim of the present work was to investigate, either in the presence or not of AQP2, the transepithelial osmotic water permeability (P(osm)) following cell exposure to asymmetrical hyper- or hypotonic gradients. For this purpose, transepithelial net volume fluxes were recorded every minute in two CCD cell lines: one not expressing AQPs (WT-RCCD(1)) and another stably transfected with AQP2 (AQP2-RCCD(1)). Our results demonstrated that the rate of osmosis produced by a given hypotonic shock depends on the gradient direction (osmotic rectification) only in the presence of apical AQP2. In contrast, hypertonic shocks elicit P(osm) rectification independently of AQP2 expression, and this phenomenon may be linked to modulation of basolateral membrane permeability. No asymmetry in transepithelial resistance was observed under hypo- or hypertonicity, indicating that rectification cannot be attributed to a shunt through the tight junction path. We conclude that osmotic rectification may be explained in terms of dynamical changes in membrane permeability probably due to activation/incorporation of AQPs or transporters to the plasma membrane via some mechanism triggered by osmolality.

Colon water transport in transgenic mice lacking aquaporin-4 water channels.

Transgenic null mice were used to test the hypothesis that water channel aquaporin-4 (AQP4) is involved in colon water transport and fecal dehydration. AQP4 was immunolocalized to the basolateral membrane of colonic surface epithelium of wild-type (+/+) mice and was absent in AQP4 null (-/-) mice. The transepithelial osmotic water permeability coefficient (P(f)) of in vivo perfused colon of +/+ mice, measured using the volume marker (14)C-labeled polyethylene glycol, was 0.016 +/- 0.002 cm/s. P(f) of proximal colon was greater than that of distal colon (0.020 +/- 0.004 vs. 0. 009 +/- 0.003 cm/s, P < 0.01). P(f) was significantly lower in -/- mice when measured in full-length colon (0.009 +/- 0.002 cm/s, P < 0. 05) and proximal colon (0.013 +/- 0.002 cm/s, P < 0.05) but not in distal colon. There was no difference in water content of cecal stool from +/+ vs. -/- mice (0.80 +/- 0.01 vs. 0.81 +/- 0.01), but there was a slightly higher water content in defecated stool from -/- mice (0.68 +/- 0.01 vs. 0.65 +/- 0.01, P < 0.05). Despite the differences in water permeability with AQP4 deletion, theophylline-induced secretion was not impaired (50 +/- 9 vs. 51 +/- 8 microl. min(-1). g(-1)). These results provide evidence that transcellular water transport through AQP4 water channels in colonic epithelium facilitates transepithelial osmotic water permeability but has little or no effect on colonic fluid secretion or fecal dehydration.

Reduced water permeability and altered ultrastructure in thin descending limb of Henle in aquaporin-1 null mice.

It has been controversial whether high water permeability in the thin descending limb of Henle (TDLH) is required for formation of a concentrated urine by the kidney. Freeze-fracture electron microscopy (FFEM) of rat TDLH has shown an exceptionally high density of intramembrane particles (IMPs), which were proposed to consist of tetramers of aquaporin-1 (AQP1) water channels. In this study, transepithelial osmotic water permeability (Pf) was measured in isolated perfused segments (0.5-1 mm) of TDLH in wild-type (+/+), AQP1 heterozygous (+/-), and AQP1 null (-/-) mice. Pf was measured at 37 degrees C using a 100 mM bath-to-lumen osmotic gradient of raffinose, and fluorescein isothiocyanate (FITC)-dextran as the luminal volume marker. Pf was (in cm/s): 0.26 +/- 0.02 ([+/+]; SE, n = 9 tubules), 0.21 +/- 0.01 ([+/-]; n = 12), and 0.031 +/- 0.007 ([-/-]; n = 6) (P < 0.02, [+/+] vs. [+/-]; P < 0.0001, [+/+] vs. [-/-]). FFEM of kidney medulla showed remarkably fewer IMPs in TDLH from (-/-) vs. (+/+) and (+/-) mice. IMP densities were (in microm-2, SD, 5-12 micrographs): 5,880 +/- 238 (+/+); 5,780 +/- 450 (+/-); and 877 +/- 420 (-/-). IMP size distribution analysis revealed mean IMP diameters of 8.4 nm ([+/+] and [+/-]) and 5.2 nm ([-/-]). These results demonstrate that AQP1 is the principal water channel in TDLH and support the view that osmotic equilibration along TDLH by water transport plays a key role in the renal countercurrent concentrating mechanism. The similar Pf and AQP1 expression in TDLH of (+/+) and (+/-) mice was an unexpected finding that probably accounts for the unimpaired urinary concentrating ability in (+/-) mice.

Defective proximal tubular fluid reabsorption in transgenic aquaporin-1 null mice.

To investigate the role of aquaporin-1 (AQP1) water channels in proximal tubule function, in vitro proximal tubule microperfusion and in vivo micropuncture measurements were done on AQP1 knockout mice. The knockout mice were generated by targeted gene disruption and found previously to be unable to concentrate their urine in response to water deprivation. Unanesthetized knockout mice consumed 2.8-fold more fluid than wild-type mice and had lower urine osmolality (505 +/- 40 vs. 1081 +/- 68 milliosmolar). Transepithelial osmotic water permeability (Pf) in isolated microperfused S2 segments of proximal tubule from AQP1 knockout [-/-] mice was 0.033 +/- 0.005 cm/s (SE, n = 6 mice, 37 degreesC), much lower than that of 0.15 +/- 0.03 cm/s (n = 8) in tubules from wild-type [+/+] mice (P < 0.01). In the presence of isosmolar luminal perfusate and bath solutions, spontaneous fluid absorption rates (nl/min/mm tubule length) were 0.31 +/- 0.12 (-/-, n = 5) and 0.64 +/- 0.15 (+/+, n = 8). As determined by free-flow micropuncture, the ratios of tubular fluid-to-plasma concentrations of an impermeant marker TF/P in end proximal tubule fluid were 1.36 +/- 0. 05 (-/-, n = 8 mice [53 tubules]) and 1.95 +/- 0.09 (+/+, n = 7 mice [40 tubules]) (P < 0.001), corresponding to 26 +/- 3% [-/-] and 48 +/- 2% [+/+] absorption of the filtered fluid load. In collections of distal tubule fluid, TF/P were 2.8 +/- 0.3 [-/-] and 4.4 +/- 0.5 [+/+], corresponding to 62 +/- 4% [-/-] and 76 +/- 3% [+/+] absorption (P < 0.02). These data indicate that AQP1 deletion in mice results in decreased transepithelial proximal tubule water permeability and defective fluid absorption. Thus, the high water permeability in proximal tubule of wild-type mice is primarily transcellular, mediated by AQP1 water channels, and required for efficient near-isosmolar fluid absorption.

MATURATIONAL CHANGES IN RABBIT RENAL BRUSH BORDER MEMBRANE VESICLE (BBMV) OSMOTIC WATER PERMEABILITY (Pf) † 1680

Proximal tubule water transport is transcellular. The neonatal rabbit proximal tubule has a higher transepithelial osmotic water permeability (Pf) than the adult segment (Quigley & Baum, AJP;271:F871,1996). This maturational change in transepithelial water transport could be due to differences in the apical or basolateral membrane or the intracellular compartment. The present study examined the maturational changes of the proximal tubule apical membrane by measuring the Pf of renal brush border membrane vesicles (BBMV).

Adaptation of inner medullary collecting duct to dehydration involves a paracellular pathway

Prolonged fluid restriction in rats is accompanied by functional modifications of the terminal part of the inner medullary collecting duct (IMCD) revealed by a sustained increase in arginine vasopressin (AVP)-independent transepithelial osmotic water permeability (PTE) in vitro. The cellular basis of this adaptation was explored in isolated and perfused terminal IMCDs of Sprague-Dawley rats using video and fluorescence microscopy. Basolateral membrane osmotic water permeability (Posm), transcellular Posm, and PTE were measured in quick sequence in every tubule. They were expressed per unit area of basolateral membrane corrected for infoldings, based on previous stereological studies and assuming no major change in membrane surface area between hydrated and dehydrated animals. Compared with IMCDs of rats with a high water intake, IMCDs of rats deprived of fluid for 36 h displayed a significantly higher basal PTE (24.9 +/- 5.1 vs. 6.1 +/- 0.6 microns/s), a similar basolateral Posm, and a higher transcellular Posm, implying a higher permeability of the apical membrane, despite the absence of exogenous AVP. However, when IMCDs of thirsted rats were exposed to AVP in vitro, their transcellular Posm (36.0 +/- 2.4 microns/s) was significantly smaller than their PTE determined simultaneously (51.8 +/- 7.1 microns/s), suggesting that part of the water flow may follow a paracellular route. A change in paracellular pathways was supported by higher apparent permeabilities to [14C]sucrose (0.85 +/- 0.27 vs. 0.28 +/- 0.04 x 10(-5) cm/s) and to [methoxy-3H]inulin (0.25 +/- 0.04 vs. 0.14 +/- 0.03 x 10(-5) cm/s) in IMCDs of thirsted rats. The nonelectrolyte permeabilities were affected neither by AVP nor by urea-rich bathing solutions. We conclude that in vivo factors related to dehydration produce a conditioning effect on terminal IMCD, which includes stabilization of the apical membrane in a state of high Posm and opening up of paracellular pathways revealed by a higher permeability to water and nonelectrolytes. The role of these adaptive phenomena remains unclear but may pertain to the sudden transitions between antidiuresis and diuresis.

Transepithelial Osmolality Differences, Hydraulic Conductivities, and Volume Absorption in the Proximal Tubule

The weight of current evidence indicates that the proximal tubule has a high transepithelial osmotic water permeability in the range of 3500-6000 microns/sec, which is attributable in large part to the high water permeabilities of the cell membranes. Water movement through these membranes may occur through specialized, proteinaceous channels that can be blocked by sulfhydryl reagents. The water channels probably exclude even the smallest solutes and allow only single file movement of the water molecules as do the water channels previously described in the red blood cell and vasopressin-responsive epithelia. If a significant fraction of the water flow also occurs through the junctional complexes, it seems likely that these junctions could be a site for solute solvent coupling which would contribute to solute absorption by solvent drag and which would be responsible for non-unity reflection coefficients for some solutes such as Na+ and Cl-. This possibility is still a matter of vigorous debate. Since the transepithelial water permeability is high, only a very small osmolality difference (1-10 mOsM) is required to drive normally observed rates of volume absorption both in vivo and in vitro. The osmolality difference is produced at least in part by dilution of the luminal fluid and is possibly augmented by the development of interstitial hyperosmolality because of the rapid transport of preferentially absorbed solutes. In the future it is likely that the most important work in this field will relate to the factors that alter transepithelial water permeability and the solute and water permeabilities of the junctional complexes. Investigation in this area is essential in understanding how changes in capillary and interstitial hydrostatic and colloid osmotic pressure may affect volume absorption.

Polarization of gelsolin and actin binding protein in kidney epithelial cells.

Vasopressin regulates transepithelial osmotic water permeability in the kidney collecting duct and in target cells in other tissues. In the presence of hormone, water channels are inserted into an otherwise impermeable apical plasma membrane and the apical surface of these cells is dramatically remodelled. Because cytochalasin B and D greatly reduce the response of these cells to vasopressin, actin filaments are believed to participate in the events leading to an increase in transepithelial water permeability. Modulation of the actin filamentous network requires the concerted action of specific actin regulatory proteins, and in the present study we used protein A-gold immunocytochemistry to localize two important molecules, gelsolin and actin binding protein (ABP), in epithelial cells of the kidney inner medulla. Gelsolin and, to a lesser extent, ABP were concentrated in clusters in the apical cell web of principal cells of the collecting duct. Aggregates of gold particles were often associated with the cytoplasmic side of plasma membrane regions forming surface extensions or microvilli. The basolateral plasma membrane was labeled to a much lesser extent than the apical plasma membrane. In the thin limbs of Henle, ABP was localized over the apical plasma membrane in ascending limbs, but gelsolin labeling was weak in these cells. In thin descending limbs, the pattern of labeling was completely reversed, with abundant apical gelsolin labeling but only weak ABP immunolabeling. Although the significance of the distribution of actin regulatory proteins in thin limbs is unknown, the abundance and the predominantly apical polarization of both ABP and gelsolin in principal cells of the collecting duct is consistent with a role of the actin cytoskeleton in the mechanism of vasopressin actin.

Osmotic gradient dependence of osmotic water permeability in rabbit proximal convoluted tubule.

To assess steady-state transepithelial osmotic water permeability (Pf), rabbit proximal convoluted tubules were perfused in vitro with the impermeant salt, sodium isethionate at 26 degrees C. Osmotic gradients (delta pi) were established by varying the bath concentration of the impermeant solute, raffinose. When lumen osmolality was 300 mOsm and bath osmolality was 320, 360 and 400 mOsm, apparent Pf decreased from 0.5 to 0.10 to 0.08 cm/sec, respectively. Similar data were obtained when lumen osmolality was 400 mOsm. Five possible causes of the delta pi dependence of apparent Pf were considered experimentally and/or theoretically: (1) external unstirred layer (USL); (2) cytoplasmic USL; (3) change in surface area; (4) saturation of water transport; (5) down-regulation of Pf. Apparent Pf was inhibited 83% by p-chloromercuribenzene sulfonate (pCMBS) at 20 mOsm, but not at 60 mOsm delta pi, suggesting presence of a serial barrier resistance to water transport. Increases in perfusate or bath solution flow rate and viscosity did not alter apparent Pf, ruling out an external USL. A simple cytoplasmic USL, described by a constant USL thickness and solute diffusion coefficient, could not account for the delta pi dependence of apparent Pf according to a mathematical model. The activation energy (Ea) for apparent Pf increased from 7.0 to 12.5 kcal/mol when delta pi was increased from 20 to 60 mOsm, not consistent with a simple USL or a change in membrane surface area with transepithelial water flow. These findings are most consistent with a complex cytoplasmic USL, where the average solute diffusion coefficient and/or the area available for osmosis decrease with increasing delta pi. These results (1) indicate that true Pf (at physiologically low delta pi) is very high (greater than 0.5 cm/sec) in the rabbit proximal tubule; (2) provide an explanation for the wide variation in Pf values reported in the literature using different delta pi, and (3) suggest the presence of a flow-dependent cytoplasmic barrier to water flow.

Evidence for transcellular osmotic water flow in rat proximal tubules.

To determine the predominant pathway for transepithelial osmotic water flow, the transepithelial osmotic water permeability [Pf(TE)] and the apparent dimensions of paracellular pores and slits were determined in rat proximal convoluted tubules microperfused in vivo. To measure Pf(TE), tubules were perfused with a hyposmotic, cyanide-containing solution. Pf(TE), calculated from the observed volume flux in response to the measured log mean osmotic gradient, was 0.12-0.15 cm/s, assuming sigmaNaCl equal to 1.0-0.7, respectively. The dimensions of the paracellular pathways were determined using measured sucrose and mannitol permeabilities (nonelectrolytes confined to the extracellular space). These were 0.43 and 0.87 X 10(-5) cm/s, respectively. By using the ratio of these permeabilities, their respective free solution diffusion coefficients and molecular radii, and the Renkin equation, the radius of the nonelectrolyte-permeable pores and the total pore area/cm2 surface area/channel length were calculated to be 1.4 nm and 3.56 cm-1, respectively. Similar calculations for slits yielded a slit half-width of 0.8 nm and a total slit area/cm2 surface area/channel length of 3.16 cm-1. The osmotic water permeability of these nonelectrolyte-permeable pathways was calculated by Poiseuille's law to be 0.0018 cm/s (pores) or 0.0014 cm/s (slits), at most 2% of Pf(TE). We conclude that the nonelectrolyte-permeable pathway in the tight junctions is not the major route of transepithelial osmotic water flow in the rat proximal tubule.

Axial heterogeneity in the rat proximal convoluted tubule. II. Osmolality and osmotic water permeability.

To assess whether proximal luminal fluid becomes hypotonic with respect to plasma, free-flow micropuncture measurements were made sequentially from the end-proximal tubule to Bowman's space in 10 tubules of hydropenic Munich-Wistar rats. Osmolality in Bowman's space was 2.8 +/- 0.3 mosmol less than in plasma. Tubular fluid osmolality fell along the tubule and by the end-proximal tubule was 7.5 +/- 0.7 mosmol/kg less than in plasma or 4.7 mosmol/kg less than in Bowman's space. Since luminal fluid became hypotonic, the reabsorbate was hypertonic. The transepithelial osmotic water permeability (Pf) was calculated using simultaneously measured water reabsorption rates. The osmotic gradient responsible for water reabsorption was assumed to be either lumen-to-reabsorbate or lumen-to-peritubular plasma, with a reflection coefficient for sodium chloride of 0.7-1.0. The Pf was then estimated to be between 0.2 and 2.0 cm/s in the first millimeter of tubule and to have fallen to 0.1-0.2 cm/s by the end of the tubule. In conclusion, luminal hypotonicity develops in the rat proximal convoluted tubule and must be considered as part of the osmotic driving force for water reabsorption.

Cell osmotic water permeability of isolated rabbit proximal straight tubules.

Proximal straight tubules were dissected and mounted in a chamber with their lumina occluded. The well-stirred bath could be 95% changed within 84 ms to set up osmotic gradients (delta Coi) across the peritubular cell aspect. Volume changes (less than or equal to 10 pl/mm) were estimated from continuous records of diameter changes (error less than 0.1 micrometers). delta Coi greater than or equal to 2-3 mosM could be discerned. delta Coi values from 10 to 44 mosM were used to evaluate Posc, the cell osmotic water permeability coefficient, and extrapolated to delta Coi = 0. Posc = 25.1 (+/- 2.3) X 10(-4) cm3.s-1.osM-1.cm2 tubular surface area-1. These values are lower than those reported for Pose, the transepithelial osmotic water permeability coefficient, and become lower if corrected for the real (infolded) peritubular cell surface area. Thus, for a given osmotic difference, transcellular water flow finds a higher resistance than paracellular water flow. Experiments were also performed with delta Coi greater than 100 mosM, but interpretation of these data is difficult because of the presence of volume regulatory phenomena and other undesirable effects.

Functional Profile of the Isolated Uremic Nephron

Resistance of the chronically diseased kidney to vasopressin has been proposed as a possible explanation for the urinary concentrating defect of uremia. The present studies examined the water permeability and adenylate cyclase responsiveness of isolated cortical collecting tubules (CCT) from remnant kidneys of uremic rabbits to vasopressin. In the absence of vasopressin the CCTs of both normal and uremic rabbits were impermeable to water. At the same osmotic gradient, addition of a supramaximal concentration of vasopressin to the peritubular bathing medium led to a significantly lower net water flux per unit length (and per unit luminal surface area) in uremic CCTs than in normal CCTs. Transepithelial osmotic water permeability coefficient, P(f), was 0.0232 +/-0.0043 cm/s in normal CCTs and 0.0059+/-0.001 cm/s in uremic CCTs (P < 0.001). The impaired vasopressin responsiveness of the uremic CCTs was observed whether normal or uremic serum was present in the bath. Basal adenylate cyclase activity per microgram protein was comparable in normal and uremic CCTs. Stimulation by NaF led to equivalent levels of activity in both, whereas vasopressin-stimulated activity was 50% lower in the uremic than in the normal CCTs (P < 0.025). The cyclic AMP analogue, 8-bromo cyclic AMP, produced an increase in the P(f) of normal CCTs closely comparable to that observed with vasopressin. In contrast, the P(f) of uremic CCTs was only minimally increased by this analogue and was not further stimulated by theophylline. These studies demonstrate an impaired responsiveness of the uremic CCT to vasopressin. This functional defect appears to be a result, at least in part, of a blunted responsiveness of adenylate cyclase to vasopressin. The data further suggest that an additional defect in the cellular response to vasopressin may exist, involving a step (or steps) subsequent to the formation of cyclic AMP.A unifying concept of the urinary concentrating defect of uremia is proposed which incorporates a number of hitherto unexplained observations on the concentrating and diluting functions of the diseased kidney.