Permeability of Novikoff hepatoma cells to water and monohydric alcohols

Acute effect of ethanol on lens cation homeostasis

This study examined the effect of ethanol on the calcium homeostasis of the bovine lens. After acute exposure of the whole lens to physiologically related ethanol concentration, the calcium content of the lens cortex increased from 0.345 +/- 0.075 to 0.476 +/- 0.047 micromol/g (p < 0.05). In contrast, other cation levels such as sodium, potassium, and magnesium did not change. In the study of the lens calcium transport, ethanol caused an increase in the calcium permeability of the lens lipid membrane by about 12% at 30 mM ethanol. Ethanol did not alter the calcium pump activity at ethanol concentration up to 400 mM. Above 600 mM ethanol, the calcium pump was almost completely inhibited. It has been suggested that moderate to heavy alcohol consumption is a risk factor for cataracts. This study indicates that acute ethanol exposure can cause a loss in the lens calcium homeostasis, which maybe one of the cellular mechanisms to contribute to the cataract development in the alcoholic individual.

Water permeability of isolated endothelial cells at different temperatures

The endothelial cells provide a potential pathway for water movement across the endothelium. The endothelial cell permeability to water can, therefore, be a factor in regulation of the rate of water movement out of the vasculature. Endothelial cells are isolated from calf pulmonary artery and cultured. The cells are removed from culture, and the diffusional water permeability is determined with the linear diffusion technique. The mean membrane permeability coefficients (PDS) determined at 20, 30, 37, and 41 degrees C are 160, 273, 304, and 387 x 10(-5) cm/s, respectively. The temperature dependence of PD is calculated with the Arrhenius equation to be 7.2 kcal/mol. If these values of PD are compared with values we have reported for the osmotic permeability coefficient (PF), the PF/PD is about one at each temperature. The values of PD in the isolated endothelial cells are compared with PD for endothelial cells estimated from whole organ studies and are similar to recently reported values.

Water and nonelectrolyte permeability of isolated rat hepatocytes

We have measured the diffusive permeability coefficients of isolated rat hepatocytes to 3H2O, [14C]urea, [14C]erythritol, [14C]mannitol, [3H]sucrose, and [3H]inulin, employing a technique previously developed for erythrocytes (Redwood et al., J. Gen. Physiol 64:706-729, 1974). Diffusion coefficients for the tracer molecules were measured in packed hepatocytes, supernatant fluid, and intracellular medium (lysed hepatocytes) and were calculated assuming one-dimensional semi-infinite diffusion through a homogeneous medium. By applying the series-parallel pathway model, the following permeability coefficients (10(-5) cm/sec) for the hepatocyte plasma membrane were obtained. 3H2O, 98.6 +/- 18.4; [14C]urea, 18.2 +/- 5.3; [14C]erythritol, 4.8 +/- 1.6; [14C]mannitol, 3.1 +/- 1.4; [3H]sucrose, 0; [3H]inulin, 0. These results indicate that isolated rat hepatocytes are highly permeable to water and polar nonelectrolytes, when compared with other transporting epithelia. This relatively high cellular permeability is consistent with a model in which nonelectrolyte permeation is via an aqueous pathway of equivalent pore diameter of 8-12 A. The finding that [14C]erythritol and [14C]mannitol cross the hepatocyte plasma membrane indicates that these molecules enter the bile canaliculus through the transcellular route. Conversely, the failure of [3H]sucrose and [3H]inulin to permeate the hepatocyte in the isolated condition supports the concept that biliary entry of these large carbohydrates, at least that fraction which cannot be accounted for by a vesicular mechanism, must occur via the transjunctional shunt pathway.

Solute-excluded volumes near the Novikoff cell surface

A differential centrifugation technique, in which all extracellular water except that intimately associated with the cell (pericellular domain) is removed, has been applied to isolated Novikoff hepatoma cells. The pericellular volumes accessible to albumin, inulin, raffinose, and sucrose were inversely related to the molecular weights of the test solutes. This phenomenon was not detectable in erythrocytes or in fat cells. Selective removal of cell surface components by enzymatic treatment produced proportional changes in the relative volumes of distribution accessible to the solutes. This discrimination in the volume accessible to each of the solutes is analogous to that obtained in gel chromatographic separation and represents, in effect, excluded volumes which are inversely related to solute size. This exclusion is associated with components of the Novikoff cell surface, including the surface coat and the microvilli that cover the Novikoff cell. These structures provide an additional level of discrimination for the Novikoff cell not seen in certain other cell types.

Effects of sulfhydryl and other reagents on the diffusional permeability of dog erythrocytes to small solutes

The effects of p-chloromercuriphenylsulfonic acid (PCMBS), 5,5'-dithiobis (2-nitrobenzoic acid) (DTNB), phloretin and thiourea on the diffusional permeability of dog erythrocytes to tritiated water and to small 14C-labeled lipophilic and hydrophilic solutes were measured at 37 degrees C by means of the linear diffusion technique. Permeability to 3HHO was significantly decreased by PCMBS but was not affected by the other reagents. The permeability to the small hydrophilic solutes acetamide and urea was decreased by phloretin and thiourea but only the permeability to acetamide was reduced to a statistically significant extent by PCMBS. The permeability to the lipophilic solutes methanol, ethanol and antipyrine was not affected by any of these agents. We interpret these results as an indication that the small lipophilic solutes probably move through lipid areas, that the small hydrophilic solutes probably move through protein associated areas in the erythrocyte membrane and that pathways for the small hydrophilic solutes are distinct from those for water. While the pathways for water may be associated with membrane protein they do not appear to be associated specifically with band 3 protein as has been suggested for human erythrocytes. Diffusional water movement through the dog erythrocyte occurs by two distinct pathways.

Membrane permeability of isolated lung cells to nonelectrolytes at different temperatures

Membrane permeability coefficients (P0) of rabbit lung cells consisting primarily of alveolar epithelial and endothelial cells and of alveolar macrophages from dog lungs were determined for tritiated water, n-[14C]alcohols, and [14C]antipyrine over the temperature range 10 to 37 degrees C with the series-parallel pathway model. In the mixed cell preparation both the diffusional permeability to water (755 X 10(-5) cm.s-1 at 37 degrees C) and the response to temperature change (apparent activation energy, Ea, 10 kcal.mol-1) are greater than the corresponding values in the macrophages (110 X 10(-5) cm.s-1 and 4.8 kcal.mol-1, respectively). The permeability coefficients for the small alcohols (C1-C3) are similar and considerably higher than for water in both cellular preparations. The values of the permeability coefficients and the temperature dependence for antipyrine and the larger alcohols in the mixed lung cells differ from the values obtained in the macrophages. Comparison of our results with those obtained in erythrocytes and Novikoff hepatoma cells demonstrates the differences in water permeability in each cell preparation and the similarity in permeation for the more lipophilic solutes in the cell preparations. These differences may be important in the comparison of results obtained in isolated cellular systems and in intact tissues and organs.

Osmotic permeability of Novikoff hepatoma cells

The osmotic permeability coefficient (Pf) for water movement across Novikoff hepatoma cells was found to be 82 +/- 3 (S.E.) x 10(-5) cm . s-1 at 20 degrees C. The corresponding diffusional permeability coefficient for 3HHO (Pd) was 97 +/- 10 (S.E.) . 10(-5) cm . s-1, therefore the ratio Pf/Pd is close to unity. The apparent activation energy for water filtration was 10.4 +/- 0.4 (S.E.) kcal . mol-1. This value is significantly greater than the activation energy for the self diffusion of water. The product of the hydraulic permeability coefficient and the viscosity coefficient for water was temperature-dependent. However, the product of the hydraulic permeability coefficient and the viscosity coefficient for membrane lipid did not vary with temperature. These data are interpreted as evidence for water movement across a lipid membrane barrier rather than through aqueous channels.