Osmotic gradient-induced water permeation across the sarcolemma of rabbit ventricular myocytes.

The mechanism of water permeation across the sarcolemma was characterized by examining the kinetics and temperature dependence of osmotic swelling and shrinkage of rabbit ventricular myocytes. The magnitude of swelling and the kinetics of swelling and shrinkage were temperature dependent, but the magnitude of shrinkage was very similar at 6 degrees, 22 degrees, and 37 degrees C. Membrane hydraulic conductivity, Lp, was approximately 1.2 x 10(-10) liter.N-1.s-1 at 22 degrees C, corresponding to an osmotic permeability coefficient, Pf, of 16 microns.s-1, and was independent of the direction of water flux, the magnitude of the imposed osmotic gradient (35-165 mosm/liter), and the initial cell volume. This value of Lp represents an upper limit because the membrane was assumed to be a smooth surface. Based on capacitive membrane area, Lp was 0.7 to 0.9 x 10(-10) liter.N-1.s-1. Nevertheless, estimates of Lp in ventricle are 15 to 25 times lower than those in human erythrocytes and are in the range of values reported for protein-free lipid bilayers and biological membranes without functioning water channels (aquaporin). Evaluation of the effect of unstirred layers showed that in the worst case they decrease Lp by < or = 2.3%. Analysis of the temperature dependence of Lp indicated that its apparent Arrhenius activation energy, Ea', was 11.7 +/- 0.9 kcal/mol between 6 degrees and 22 degrees C and 9.2 +/- 0.9 kcal/mol between 22 degrees and 37 degrees C. These values are significantly greater than that typically found for water flow through water-filled pores, approximately 4 kcal/mol, and are in the range reported for artificial and natural membranes without functioning water channels. Taken together, these data strongly argue that the vast majority of osmotic water flux in ventricular myocytes penetrates the lipid bilayer itself rather than passing through water-filled pores.

Stretch-activated channel blockers modulate cell volume in cardiac ventricular myocytes.

Stretch-activated channels (SAC) are postulated to regulate cell volume. While this hypothesis is appealing, direct evidence is lacking. Using digital video microscopy, we found that pharmacological blockade of SACs alters the cell volume of isolated rabbit ventricular myocytes during hypoosmotic stress. Under control conditions, relative cell volume increased from 1.0 to 1.311 +/- 0.019 after 10 min in 195 mosmol/l solution. The cation SAC blocker gadolinium (Gd3+; 10 microM) reduced the amount of swelling in hypoosmotic solution by 24% and induced a regulatory volume decrease otherwise not observed. In contrast, the anion SAC blocker 9-anthracene carboxylic acid (9-AC; 1 mM) increased swelling by 44% under the same conditions. Based on the direction of SAC currents, Gd3+ and 9-AC are expected to have opposite effects on cell volume. Furthermore, Gd3+ and 9-AC changed cell volume by only approximately 2% in isosmotic solutions when SACs are expected to be closed. This supports the idea that Gd3+ and 9-AC affect stretch-activated transport processes. In contrast, omitting bath Ca2+ did not alter cell volume under iso- or hypoosmotic conditions suggesting stretch-activated Ca2+ influx is not important in setting cell volume. Not all channels can affect cell volume. Opening ATP-sensitive K+ channels with aprikalim (100 microM) or blocking them with glibenclamide (1 microM) did not alter cell volume under isosmotic or hypoosmotic conditions. These data support the idea that SACs are involved in cardiac cell volume regulation.

The effect of osmotic gradients on the outward potassium current in dialyzed neurons of Helix pomatia.

1. The effect of outward and inward water flows through the membrane on outward potassium currents of dialyzed Helix pomatia neurons was studied. 2. An outward water flow increased the peak and sustained outward potassium currents and accelerated the kinetics of their activation. An inward water flow had quite opposite effects--it decreased the peak and sustained potassium currents and delayed the kinetics of their activation. 3. The analysis of the effect of water flow on the conductance of potassium channels showed that an outward water flow increased both the potassium conductance at a given potential (gk) and the maximum potassium conductance (gkmax). An inward water flow again had the opposite effect--it decreased the potassium conductance at given potential and the maximum potassium conductance. 4. Neither an outward nor an inward water flow significantly affected the fraction of open potassium channels at a given potential [n infinity(V)]. 5. These data suggest that in dialyzed neurons the changes of outward potassium current during water flow through the membrane are due mainly to the changes in single-channel conductance and the time constant of current activation.

The changes in CiNa of sheep cardiac Purkinje fibres in hyperosmotic solutions.

1. The changes in intracellular sodium ion concentration (CiNa) of sheep cardiac Purkinje fibres in hyperosmotic solutions were studied using Na-sensitive liquid ion-exchanger microelectrodes. 2. CiNa was increased in hyperosmotic solutions containing different concentrations of sucrose from 0 to 300 mM. 3. The changes in resting membrane potential (RMP) in hyperosmotic solutions had no regularity. In most of the experiments there was hyperpolarization of the membrane but in a few cases a depolarization or no change of RMP were also observed. 4. The N-shape of I-V relations of the fibres became more pronounced in hyperosomotic solutions.

The effects of short-chain fatty acids on the neuronal membrane functions of Helix pomatia. III. 22Na efflux from the cells.

The effect of short-chain fatty acids on both ouabain-sensitive and ouabain-insensitive fractions of 22Na efflux from the neurons of Helix pomatia was studied. Fatty acids, having fewer than 10 carbon atoms in the hydrocarbon chain, increased the ouabain-sensitive 22Na efflux from the neurons, while fatty acids, having more than 9 carbon atoms, inhibited the 22Na efflux in comparison with that in normal physiological solution. All the fatty acids used had an inhibiting effect on the ouabain-insensitive 22Na efflux from the cells independent on the number of carbon atoms in the hydrocarbon chain. These studies indicate that these short-chain fatty acids can be effective modulators of both ouabain-sensitive and ouabain-insensitive fractions of Na efflux from the cells.

The effects of short-chain fatty acids on the neuronal membrane functions of Helix pomatia. I. Electrical properties.

The effects of short-chain fatty acids on the membrane excitability, current-voltage (I-V) characteristics, and cell volume of Helix pomatia neurons were studied. 2-Decenoic acid (DA), having 10 carbon atoms in the hydrocarbon chain, suppressed the excitability of bursting neurons RPa1 (Sakharov and Salanki, 1969) for 30-60 min, while valeric acid (VA), having 5 carbon atoms, had no significant effect on excitability. DA had three different effects on the excitability of beating neurons: in some neurons DA suppressed excitability as in bursting neurons; in a second type of neuron DA had a negligible effect on excitability; and in the neuron located near RPa1 DA had a pentylentetrazol (PTZ)-like effect, i.e., it converted the discharge of the neuron from beating to bursting. DA decreased the peak value of the current, inducing a negative-resistance region in the I-V curve of the bursting neuron without any change in the level of the voltage at which the current reaches its maximal value. DA inhibited the hyperpolarization induced by activation of the Na+ pump, tested after preliminary enrichment of neurons with Na+ ions by incubation in a potassium-free solution for 20 min. DA caused a swelling of the neuron by about 10% which was independent of the Na+ pump. In all the above-mentioned cases VA had no significant effect.