Intracellular solute gradients during osmotic water flow: an electron-microprobe analysis

Structural correlates of the transepithelial water transport

Transepithelial permeability is one of the fundamental problems in cell biology. Epithelial cell layers protect the organism from its environment and form a selective barrier to the exchange of molecules between the lumen of an organ and an underlying tissue. This chapter discusses some problems and analyzes the participation of intercellular junctions in the paracellular transport of water, migration of intramembrane particles in the apical membrane during its permeability changes for isotonic fluid in cells of leaky epithelia, insertion of water channels into the apical membrane and their cytoplasmic sources in cells of tight epithelia under ADH (antidiuretic hormone)-induced water flows, the osmoregulating function of giant vacuoles in the transcellular fluxes of hypotonic fluid across tight epithelia, and the role of actin filaments and microtubules in the transcellular transport of water across epithelia.

Regulatory volume decrease in a renal distal tubular cell line (A6). II. Effect of Na+ transport rate

A6 epithelia, a cell line originating from the distal tubular part of the kidney of Xenopus laevis, were cultured on permeable supports and mounted in an Ussing-type chamber. Cell thickness (Tc), short-circuit current (Isc) and transepithelial conductance (Gt) were recorded while tissues were bilaterally incubated in NaCl solutions and the transepithelial potential was clamped to zero. Effects of inhibition and stimulation of transepithelial Na+ transport on cell volume and on its regulation during a hyposmotic challenge were investigated. Under control conditions a slow spontaneous decrease of Tc described by a linear baseline was recorded. The reduction of the apical osmolality from 260 to 140 mosmol/kg did not alter cell volume significantly, demonstrating a negligible water permeability of the apical barrier. The inhibition of Na+ uptake by replacing apical Na+ by N-methyl-d-glucamine (NMDG+) did not affect cell volume under isotonic conditions. An increase of Tc by 12.1% above the control baseline was recorded after blocking active transport with ouabain for 60 min. The activation of Na+ transport with insulin or oxytocin, which is known to activate the apical water permeability in other epithelia, did not alter cell volume significantly. The insensitivity of cell volume to alterations in apical Na+uptake or Na+ pump rate confirms the close coupling between apical and basolateral transport processes. The blockage of basolateral K+ channels by 5 mM Ba2+ elicited a significant increase in Tc of 16.3% above control. Quinine, a potent blocker of volume-activated K+ channels, did not change Tc significantly. Basolateral hypotonicity elicited a rapid rise in Tc followed by a regulatory volume decrease (RVD). An RVD was also recorded after blocking apical Na+ uptake as well as after stimulating apical Na+ uptake with oxytocin or insulin. Inhibition of active transport with ouabain as well as blocking K+ efflux at the basolateral side with Ba2+ or quinine abolished the RVD. The inhibition of the RVD by ouabain seems to be caused by a depletion of cellular K+, whereas the effects of Ba2+ and quinine are most likely due to the blockage of the basolateral K+ pathway.

Effects of ADH on the apical and basolateral membranes of toad urinary bladder epithelial cells

Short-circuited urinary bladders from Bufo marinus were supported on their apical surface by an agar mounting method and impaled with microelectrodes via their basolateral membrane. This arrangement provided stable and long-lasting impalements of epithelial cells and yielded reliable membrane potentials and voltage divider ratios (Ra/Rb), where Ra and Rb are apical and basolateral membrane resistances respectively. The membrane potential under short-circuit conditions (Vsc) was -51.4 +/- 2.2 mV (n = 59), while under open-circuit conditions apical membrane potential (Va) and basolateral membrane potential (Vb) were -31.0 +/- 2.4 and 59.5 +/- 2.4 mV, respectively. This yields a "well-shaped" potential profile across the toad urinary bladder, where Va is inversely related to the rate of transport, Isc. Antidiuretic hormone (ADH) produced a hyperpolarisation of Vsc and Vb but had no significant effect on Va. In addition, Ra/Rb was significantly increased by ADH (4.6 +/- 0.5 to 10.2 +/- 3.6). Calculation of individual membrane resistances following the addition of amiloride showed that ADH produced a parallel decrease in Ra and Rb membrane resistance, with the observed increase in Ra/Rb being due to a greater percentage decrease in Rb than in Ra. The ability of ADH to effect parallel changes in apical and basolateral membrane conductance helps to maintain a constant cellular volume despite an increase in transepithelial transport.

Changes in intracellular sodium during the hydroosmotic response to vasopressin

During vasopressin (VP)-induced water movement, toad urinary bladder epithelial cells undergo unique morphological changes. The osmolality within these responding cells remains relatively stable despite the large transcellular transport of water. We hypothesized that the hydroosmotic response to VP may be associated with a net increase in sodium either as an aid in maintaining the intracellular osmolality or as part of a Na-Ca exchange process. Changes in intracellular sodium (Nai) were monitored over time in individual hemibladders using 23Na NMR. Hemibladders were mounted as bags on glass pipets and filled with deionized water. During NMR studies, the serosal bath consisted of aerated 2.4 mM HCO3 amphibian Ringer's (pH 8.1) made up with 15% D2O containing the shift reagent, dysprosium tripolyphosphate (1 mM). This reagent allowed for visualization of Nai by shifting the extracellular Na signal; it did not affect basal or VP stimulated water flow, short-circuit current, or high energy phosphate metabolism as seen by 31P NMR. Changes in Nai were determined by integrating the area under the unshifted Na peak at each measurement and expressing differences as a ratio relative to baseline. The initial Nai signal from unstimulated hemibladders remained stable in these tissues over at least 180 minutes. Within 30 minutes of VP (20 mU/ml) exposure, however, the Nai peak increased 2.47 times above pretreatment baseline (N = 16, P less than 0.001). The Nai signal returned toward baseline values with removal of VP from the serosal bath but only after approximately 90 minutes. When change in cell shape and water movement were prevented by having isotonic sorbitol in the mucosal bath, VP produced no change in the Nai signal (N = 10).(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of potassium-free media and ouabain on epithelial cell composition in toad urinary bladder studied with X-ray microanalysis

The technique of X-ray microanalysis was used to study the composition of toad urinary bladder epithelial cells incubated in Na Ringer's and K-free medium, with and without ouabain. Following incubation under short-circuit conditions, portions of tissue were coated with an external albumin standard and plunge-frozen. Cryosections were freeze-dried and analyzed. In Na Ringer's, granular and basal cells, and also the basal portion of the goblet cells, had similar water and ion compositions. In contrast, mitochondria-rich cells contained less Cl and Na. On average, the granular cells and a subpopulation of the basal cells lost K and gained Na after ouabain and in K-free medium alone. However, there was considerable variation from cell to cell in the responses, indicating differences between cells in the availabilities of ion pathways, either as a consequence of differences in the numbers of such pathways or in their control. In contrast, the compositions of both the low Cl, mitochondria-rich cells and a sub-population of the basal cells were little affected by the different incubation conditions. This is consistent with a comparatively low Na permeability of these cells. The results also indicate that (i) much, if not all, of the K in the dominant cell type, the granular cells, is potentially exchangeable with serosal medium Na, and (ii) Na is accumulated from the serosal medium under K-free conditions. They also provide information about the role of the (Na-K)-ATPase in the maintenance of cellular K in K-free medium, being consistent with other evidence that removal of serosal medium K inhibits transepithelial Na transport by decreasing Na entry to the cells from the mucosal medium, rather than solely by inhibiting the basolateral membrane (Na-K)-ATPase.

Structural changes induced by osmotic water flow in rabbit proximal tubule

When a transepithelial osmotic difference was imposed in perfused proximal straight tubules (270 mOsm/kg H2O in the lumen and 290 in the bath) in the absence of bath colloid, a severe vacuolation (appearance of lucent spaces) developed within the epithelium such that view of the lumen border was obscured within 5 +/- 1 min (N = 13 tubules at 23 degrees C). This vacuolation was less severe if the bath was hypotonic to the lumen or if the magnitude of the osmotic difference was reduced. If colloid (6% wt/vol of either bovine serum albumin or 70,000 molecular wt dextran) was included in the bathing medium, vacuolation was either not observed or was minimal, but became severe upon removal of the colloid and obscured the lumen within 6 +/- 1 min (N = 8 for albumin and N = 4 for dextran at 23 degrees C). At 38 degrees C, vacuolation obscured the lumen within 4 +/- 1 min following the removal of albumin (N = 5). ANOVA suggests that none of the times for vacuolation to occur differed. The rate of passive volume flow due to the osmotic difference was unaffected by vacuolation (0.9 +/- 0.1 nl.min-1.mm-1 with albumin to 0.8 +/- 0.1 without albumin and vacuolated, N = 8 at 23 degrees C, P greater than 0.2 using a paired t-test). Electron microscopic examination of tubules fixed after vacuolation showed lucent spaces within the cytoplasm. These results suggest that the presence of serosal colloid protected the epithelial cells from injury during rapid transepithelial water flow. The mechanism for this protective effect is not apparent, but may be related to effects of colloid in maintaining normal volume absorption in the proximal nephron.

The measurement of water distribution in frozen specimens

There are three techniques to measure local water fractions in the cryomicroscope. First, water content may be measured by a direct analysis of oxygen in bulk samples using a windowless detector. Secondly, mass thickness may be estimated in frozen-hydrated, then frozen-dried sections. This technique offers unrivalled spatial resolution, especially if the radiation dose in the frozen-hydrated state is kept low by the use of electron scattering techniques instead of an X-ray microanalytical background determination. External water content standards can be used instead of frozen-hydrated sections and the whole analysis can even be performed exclusively on frozen-dried sections at room temperature. Thirdly, local water fractions can be evaluated from X-ray microanalytical measurements of element concentrations per mass in the frozen-hydrated and frozen-dried state. Corrections necessary for the other techniques cancel out. However, the high radiation dose required for a fully quantitative analysis excludes the use of these methods in thin or ultrathin sections.

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.

Differential effects of aldosterone and ADH on intracellular electrolytes in the toad urinary bladder epithelium

Quantitative electron microprobe analysis was employed to compare the effects of aldosterone and ADH on the intracellular electrolyte concentrations in the toad urinary bladder epithelium. The measurements were performed on thin freeze-dried cryosections utilizing energy dispersive x-ray microanalysis. After aldosterone, a statistically significant increase in the intracellular Na concentration was detectable in 8 out of 9 experiments. The mean Na concentration of granular cells increased from 8.9 +/- 1.3 to 13.2 +/- 2.2 mmol/kg wet wt. A significantly larger Na increase was observed after an equivalent stimulation of transepithelial Na transport by ADH. On average, the Na concentration in granular cells increased from 12.0 +/- 2.3 to 31.4 +/- 9.3 mmol/kg wet wt (5 experiments). We conclude from these results that aldosterone, in addition to its stimulatory effect on the apical Na influx, also exerts a stimulatory effect on the Na pump. Based on a significant reduction in the Cl concentration of granular cells, we discuss the possibility that the stimulation of the pump is mediated by an aldosterone-induced alkalinization. Similar though less pronounced concentration changes were observed in basal cells, suggesting that this cell type also participates in transepithelial Na transport. Measurements in mitochondria-rich cells provided no consistent results.