Nebivolol induces a hyperpolarizing effect on smooth muscle cells in the mouse renal artery by activation of beta-2-adrenoceptors.

Nebivolol is a highly selective beta(1)-adrenoceptor antagonist with vasodilator properties involving the vascular endothelium, but its effect on the smooth muscle cells (SMC) is still unclear. In this paper, we tested the effect of nebivolol on renal artery smooth muscle cells and investigated the cellular mechanism involved. To this purpose, the denuded renal arteries isolated from mice were studied in vitro using the myograph and the nitric oxide (NO) sensor techniques, while the SMC in culture were analyzed by the patch-clamp technique. The myograph technique was used to assay the vasodilator effect of nebivolol on the arterial muscular layer, and to establish the optimal dose of the drug to be tested on single SMC by the patch-clamp technique. Using both the myograph and the patch-clamp techniques, we examined the potential contribution of beta(2)-adrenoceptors and Ca(2+)-activated K(+) channels to the nebivolol-induced effects, by exposing the denuded arteries and SMC cultures to specific inhibitors such as butoxamine (100 micromol/l), tetraethylammonium (TEA, 1 mmol/l), and iberiotoxin (100 nmol/l). The direct measurement of NO using the NO sensor enabled us to evaluate if nebivolol induces/or not the release of NO in denuded renal arteries. The results of this study show that nebivolol exerts vasodilator effects on the SMC in the denuded renal arteries and the maximal response is achieved at a concentration of 50 micromol/l. Nebivolol effects involve binding to the beta(2)-adrenoceptors and the subsequent activation of Ca(2+)-activated K(+) channels in SMC, with no contribution of NO. Taken together, the study brings new insights into the mechanism underlying the nebivolol-induced arterial vasodilation.

Cu2+ reveals different binding sites of amiloride and CDPC on the apical Na channel of frog skin.

The effect of Cu2+ ions, present in the mucosal bathing solution, on the transepithelial short-circuit current (Isc) and conductance (Gt) and on the blocker-induced noise of apical Na channels, was studied on the isolated ventral skin of the frog Rana temporaria. Cu2+ effects were concentration-dependent, the full effect being reached at 50 micromol/l. Cu2+ increased Isc and Gt; this effect was eliminated by high concentrations of amiloride (30 micromol/l) and of CDPC (150 micromol/l). Cu2+ markedly reduced the corner frequency (fc) of the Na channel noise, while having virtually no effect on the fc of CDPC-induced noise. Cu2+ reduces the association rate constant of amiloride to the Na channel to one third; this effect is interpreted as indicating competition between Cu2+ and amiloride for the same (negatively charged) binding site on the channel, while CDPC appears to bind on a different site.

A system for applying rapid warming or cooling stimuli to cells during patch clamp recording or ion imaging.

We describe a system for superfusing small groups of cells at a precisely controlled and rapidly adjustable local temperature. Before being applied to the cell or cells under study, solutions are heated or cooled in a chamber of small volume ( approximately 150 microl) and large surface area, sandwiched between four small Peltier elements. The current through the Peltier elements is controlled by a microprocessor using a PID (proportional-integral-derivative) feedback algorithm. The chamber can be heated to at least 60 degrees C and cooled to 0 degrees C, changing its temperature at a maximum rate of about 7 degrees C per second; temperature ramps can be followed under feedback control at up to 4 degrees C per second. Temperature commands can be applied from the digital-to-analogue converter of any laboratory interface or generated digitally by the microprocessor. The peak-to-peak noise contributed by the system does not exceed that contributed by a patch pipette, holder and headstage, making it suitable for single channel as well as whole cell recordings.

Fourier analysis of potential oscillations of a liquid membrane for the discrimination of taste substances.

Electrical potential oscillations were obtained across a liquid membrane composed of nitrobenzene/picric acid placed between two aqueous phases in the presence of various taste (i.e. salty, sweet and bitter) substances. The influence of these compounds on electrical oscillations was studied using Fourier analysis to establish a "fingerprint" of the substance that can be correlated with its taste index. Various concentrations of each substance were tested to obtain a Fourier spectrum with discrete peaks which can be further processed. The electrical oscillations consisted of a number of weak damped oscillators, and the Fourier spectra of these signals were found to have a number of discrete peaks of decreasing amplitude at low frequencies (0-0.5 Hz). A correlation of the frequency of the first peak of the Fourier spectrum with the taste index was found for bitter substances, whereas for salty substances the amplitude of the first two peaks of the spectrum was correlated with the taste index.

Hydrodynamic effects on the solute transport across endothelial pores and hepatocyte membranes.

In this short note we propose a simple and rapid procedure to calculate the net quantity of metabolites absorbed by hepatocytes from blood plasma. The blood movement through sinusoids determines an opposed circulation of plasma through the space of Disse. Hydrodynamic considerations lead to the conclusion that hepatocytes absorb for their own synthesis processes a quantity of metabolites in a volume flow of the order of 10(-12) nl s(-1) through a sieve plate surface with an area of 1 microm2. At pathological temperature (40 degrees C), the excess of the net absorbed volume flow for the entire sinusoidal surface of the mammalian liver may be as high as 1.9 nl s(-1). Some observations on the effect of red and white blood cells on the chylomicron traffic through endothelial pores are made.

Immersion weighing method for recording the flows through macroscopic membranes.

The continuous record of the apparent weight of a membrane-bounded small vessel immersed in a solution of different density as compared to that inside it, offers a cheap and reliable possibility to measure osmotic flows at 10(-5) kg x m-2 x s-1 sensitivity. The method equally applies for diffusional (isotopic) water flows.

Interaction of the antioxidant flavonoid quercetin with planar lipid bilayers.

Our capacitance and conductance measurements on reconstituted planar lipid bilayers (BLM) suggest an insertion of the flavonoid quercetin (QCT) in the membranes, which is concentration- and pH-dependent. Interaction of the flavonoid with the membrane has no impact on either structure or integrity of the lipid bilayer. The QCT molecules penetrate the lipid bilayer by intercalating between the flexible acyl chains of the phospholipids, the deepest insertion occuring in acidic medium, when QCT is neutral and completely liposoluble. Results indicated that aggregation of QCT within the hydrophobic core is accompanied by an increase of the transmembrane conductance following an alteration of the hydrophobic barrier for small electrolytes. By contrast, within alkaline media where QCT is deprotonated, the reaction site of the flavonoid is restricted to the hydrophilic domain of the membrane. This significantly changes the double layer capacitance as the negatively charged QCT molecules become sandwiched between polar headgroups at the bilayer surface. At highest alkaline pH, the transmembrane conductance was not affected, since QCT did not perturb the molecular packing of the hydrocarbonic acyl chains of the phospholipids. Results also demonstrated that changes in physical properties of the lipid bilayers following interstitial QCT embedding within either the hydrophobic domain or the polar headgroup domain may be related to both its lipophilic nature and interactions with the electric dipole moments of the polar headgroups of phospholipids. Data also demonstrated that translocation of QCT in the polar part of the lipid bilayer, at physiological pH and salt conditions, may be correlated with its optimized radical scavenging activity. This paper discusses the significance of the free radical scavenging capacity and antioxidant efficiency of QCT.

Slowed inactivation at positive potentials in a rat axonal K+ channel is not due to preferential closed-state inactivation.

We have investigated slow inactivation in a rat axonal K+ channel, the I channel. Using voltage steps to potentials between -70 mV and +80 mV, from a holding potential of -100 mV, we observed a marked slowing of inactivation at positive potentials: the time constant was 4.5+/-0.4 s at -40 mV (mean +/- S.E.M.), increasing to 14.7+/-2.0 s at +40 mV. Slowed inactivation at positive potentials is not consistent with published descriptions of C-type inactivation, but can be explained by models in which inactivation is preferentially from closed states (which have been developed for Kv2.1 and some Ca2+ channels). We tested two predictions of preferential closed-state models: inactivation should be more rapid during a train of brief pulses than during a long pulse to the same potential, and the cumulative inactivation measured with paired pulses should be greater than the inactivation at the same time during a continuous pulse. The I channel does not behave according to these predictions, indicating that preferential closed-state inactivation does not explain the slowing of inactivation we observe at positive potentials. Inactivation of the I channel therefore differs both from C-type inactivation, as presently understood, and from the inactivation of Kv2.1.

Characteristics of ionic transport processes in fish intestinal epithelial cells.

A general mathematical version of the cell model of a leaky epithelium for the NaCl absorption is presented, analysed and integrated numerically. The model consists in the adequate differential equations that describe the rate of change of the intracellular ion concentrations and are expressed in strict accordance with the law of mass conservation. The model includes many state variables representing ion concentrations, the cell volume, and membrane potentials. Ion movements are described by the Michaelis-Menten kinetics or by the constant field flux equation (Goldman-Hodgkin-Katz). In this paper, we model the intracellular ion concentrations, change in the cell volume, the transmembrane flux and membrane potentials of intestinal epithelium of both fresh water and sea water fish, and generate several simulations (in both the steady state and the transient state analysis) that appear to accord with prior experimental data in this area. For the ion movements of the sea water fish intestine, there were included a Na+/K+ pump, a K(+)-Cl- symport system, the K+ and Cl- channels in the basolateral membrane, whereas a Na(+)-K(+)-2Cl- cotransporter for NaCl absorption and K+ channels are located in the apical membrane. In the fresh water fish intestinal cells, the NaCl absorption is performed by two coupled antiporters Na+/H+ and Cl-/HCO3- presumably responsible for the intracellular pH regulation. In this type of cells, Na+ and K+ channels are located within the apical membrane, whereas Cl- channels are located within the basolateral membrane. The osmotically induced water transport across the apical and basolateral membranes has been taken into account as well. The simulations plot the steady state values for membrane potential difference, short-circuit current and intracellular ionic concentrations using the magnitude of the transmembrane flux through the Na+/K+ pump and Na(+)-K(+)-2Cl- cotransporter, or the basolateral Cl- permeability as dependent variables. The model behaves appropriately with regard to several experimental studies regarding the hyperpolarization (sea water fish intestine) and depolarization (fresh water fish intestine) of the apical membrane potential and inhibition of the short-circuit flux with reduced NaCl absorption. The model is also used to make several analytical predictions regarding the response of the membrane potential and ionic concentrations to variations in the basolateral Cl- flux. Furthermore, maintaining conservation of both mass and electroneutrality and taking into account the osmolar forces is an important advantage, because it allows a rigorous analysis of the relationship between membrane potential difference, volume and flux. The model can be used in the analysis and planning of the experiments and is capable of predicting the instantaneous values of ionic fluxes and intracellular concentrations and of cell volume.

Physiology. Cold current in thermoreceptive neurons.

We sense the temperature of our skin and surroundings using specific thermoreceptors, which are sensitive to cold and warmth, but little is known about how these receptors transduce temperature into electrical activity. We have discovered an inward ionic current that is activated by moderate cooling in a small number of rat sensory neurons. This current has features that are found in intact cold receptors, including sensitization by menthol, adaptation upon sustained cooling, and modulation by calcium, and is likely to be important in cold sensing.

Evaluation of the stimulatory capacity of procaine on Na transport through frog skin.

Procaine has different effects on various ionic conductive pathways through the frog skin. We investigated the season and temperature dependence of the stimulation by mucosal procaine, of the Na-conductive pathway. For this stimulation, we found higher half-maximal saturation constants (KNa) in winter animals (6.38 +/- 0.8 mmol/l), than in summer ones (4.03 +/- 0.7 mmol/l). Summer frogs kept for 2 weeks at 4 degrees C, reacted like winter frogs (6.24 +/- 0.8 mmol/l). However, the maximal sodium currents (INa max) did not depend on temperature adaptation. Procaine-induced increased of KNa is associated with an increase of INa. The effects of procaine associated with BIG (benzoylimidazole-2-guanidine) were non-additive, while with vasopressin they were additive. A biphasic, dose-dependent response was recorded after procaine application to the inner surface. Vasopressin counteracted the serosal procaine-induced inhibition of the Na-transport.

The action of Cu2+ on the frog epithelium.

The mechanism of action of Cu2+ when applied to the external side of the frog skin preparation was investigated. Cu2+ acts most probably on the external barrier of this preparation, since it increases the transport pool of Na proportionally to the increase in the short-circuit current (I(sc)). Cu2+ does not open new routes for the Na+ entry since the stimulated I(sc) is still completely abolished by amiloride. The I(sc) dependence of Na concentration in the external medium is modified by cooper, since the Ksm value increases in addition to changes in I(sc).

Procaine effects on sodium and chloride transport in frog skin.

Procaine, a tertiary amine, has previously been shown to stimulate reversibly transepithelial Na transport across frog skin after application from the epithelial side. In the present study with intracellular recording from principal, i.e. amiloride-sensitive cells, we demonstrate that the stimulation results from increase in apical membrane Na permeability. A second effect of procaine (10-25 mmol/l) in the outside perfusion solution is a reversible increase of transepithelial conductance which drastically exceeds the predicted response of the transcellular Na pathway. It requires presence of chloride on the epithelial side and depends on the non-ionized molecule of procaine. Abolition of apical membrane Na uptake by amiloride or Na-free mucosal incubation decreases the magnitude but does not prevent the stimulatory effect of procaine. The origin of this gain in conductance from stimulation of a Cl-specific pathway is demonstrated by a highly significant correlation between the increases in electrically determined tissue conductance and partial Cl conductance, obtained from measurements of influx and efflux of Cl-36. Measurements with microelectrodes indicate that the stimulated Cl-specific pathway is distinct from the principal cells. Since procaine activates a conductive pathway with similar response pattern as spontaneously existing Cl conductance, it might be a valuable tool for investigating mode and way of Cl movement across epithelial tissues.

Procaine has opposite effects on passive Na and K permeabilities in frog skin.

Procaine has opposite effects on the active transport of Na+ when applied on the mucosal side of the frog skin [where it produces a stimulation of the short-circuit current (Isc)] or when added on the serosal side (where it produces an inhibition of Isc). In an attempt to reveal and localize the primary effect of procaine on either the apical or latero-basal membranes of the epithelial cells, we have tried to "chemically dissect" both membrane functions with inhibitors and ionophores. When applied on the apical side of the latero-basally depolarized epithelium, 25 mmol/l procaine increases Isc and Voc (transepithelial open-circuit potential), while decreasing the transepithelial resistance. The E1-E2 linearity domain of the I-V curves is narrowed. On the serosal side of the depolarized epithelium, the same concentration of procaine does not affect Isc and Voc (which are already inhibited) but it produces an increase in the transepithelial resistance (Rt). Procaine influence on the passive K+ permeability was studied by using the ionophore nystatin, which is assumed to form channels permeable to K+, when applied on the amiloride blocked apical membrane. In nystatin-treated epithelia, 25 mmol/l procaine on the apical side decreased Isc, Voc and Rt. In parallel experiments during Cl- substitution by SO2-(4), the procaine effects on Isc and Voc are no longer maintained, but transient.(ABSTRACT TRUNCATED AT 250 WORDS)

Glutaraldehyde inhibits the active transport of sodium and the oxygen consumption, while increasing the water diffusional permeability in frog skin.

A detailed investigation of the effects of mild glutaraldehyde (GA) treatments on both active and passive transport properties of isolated frog skin is presented. The active transport of sodium, as expressed by the short-circuit current, is gradually inhibited when GA is present in the Ringer solution on the serosal face of the skin, even at 0.01% (w/v) concentration. The inhibition is roughly exponential, with time constants ranging from 19 min (at 25 degrees C and 0.10% aldehyde), up to 63 min (at 10 degrees C and 0.01% aldehyde). It seems be partly due to (or, at least, is concomitant with) the inhibition by GA of the tissular oxygen consumption. This is reduced to half of the initial value by 0.10% GA. Higher GA concentrations (0.10 to 1.0%) increase with up to 50% the transepithelial diffusional permeability of water, and also produce even more pronounced increments in the diffusional permeabilities for sodium and potassium. All these data are consistent with the image of GA cross-linking between the free amino (and other reactive) groups on the proteins. This probably results in the severe modification of every functional protein aggregate, thus inactivating the transport ATPases, but also causes a stabilization of protein hydrophilic membrane domains making the water and the small ions to penetrate easier. In view of these opposite effects on active and passive transport of ions, the possibility of using GA at concentrations around 0.05% (w/v) to block the active transport through frog skin and other tight epithelia is suggested.

Procaine effects on the sodium transport in frog skin.

A study on the influence of procaine on the sodium transport properties in frog skin was carried out. The application of procaine hydrochloride on either the mucosal or the serosal sides of the isolated frog skin has opposite effects. When added to the mucosal compartment, the procaine (as well as two procaine based drugs: Gerovital H3 and Aslavital) biphasically increase the short-circuit current (Isc) with a noticeable "recline" phenomenon, and decrease the slope resistance, as given by the I-V curves. When applied in the serosal compartment, Isc is decreased and the slope resistance of the epithelium is increased. The procaine effect on the apical membranes shows a pronounced dependence on the external sodium concentration. The shift of the E2 inflection point (which indicates the critical intensity of the electric field at which the epithelial conductance changes), with respect to the transepithelial open-circuit potential, shows a rapid and quasi-exponential increase following the application of 25 mM procaine in addition to the different mucosal Na concentrations.