External Ni2 + and ENaC in A6 cells: Na+ current stimulation by competition at a binding site for amiloride and Na+.

In cultured A6 monolayers from distal Xenopus kidney, external Ni2+ stimulated active Na+ uptake via the epithelial Na+ channel, ENaC. Transepithelial capacitance measurements ruled out exocytosis of ENaC-containing vesicles underlying the Ni2+ effect. Na+ current noise analysis was performed using the neutral Na(+) -channel blocker 6-chloro-3,5-diamino-pyrazine-2-carboxamide (CDPC) and amiloride. The analysis of CDPC-induced noise in terms of a three-state channel model revealed that Ni2+ elicits an increase in the number of open channels as well as in the spontaneous open probability. While Ni2+ had no influence on CDPC-blocker kinetics, the macroscopic and microscopic blocking kinetics of amiloride were affected. Ni2+ turned out to compete with amiloride for a putative binding site but not with CDPC. Moreover, external Na(+)--known to compete with amiloride and so producing the "self-inhibition" phenomenon--and Ni2+ exerted mutually exclusive analogous effects on amiloride kinetics. Na+ current kinetics revealed that Ni2+ prevents ENaC to be downregulated by self-inhibition. Co2+ behaved similarly to Ni2+, whereas Zn2+ did not. Attempts to disclose the chemical nature of the site reacting with Ni2+ suggested cysteine but not histidine as reaction partner.

Spontaneous electrical potential oscillation on a filter impregnated with soybean lecithin placed between identical solutions of alanine.

Filters impregnated with soybean lecithin, placed between two identical aqueous alanine solutions, display spontaneous electric potential oscillations. Alanine solutions used in a large concentration range from 1 mM to 1 M produce damped oscillatory behaviour with an exponential decay in time. The dependence of decay time on concentration shows saturation behaviour which is well fitted with a sigmoidal curve. Power spectra obtained by Fourier transform show peaks specific for each concentration. When fitted with a Lorentzian curve in the peak domain, the centre of the peak height and width at half height could be extracted. All these parameters depend on alanine concentration in a saturating pattern.

Effects of extracellular Mg2+ on transepithelial capacitance and Na+ transport in A6 cells under different osmotic conditions.

The electrophysiological characteristics of monolayers of cultured renal epithelial A6 cells were studied under short-circuit conditions. Replacing basolateral isosmotic (260 mOsm/kg H2O) media by hyposmotic (140 mOsm/kg H2O) solutions transiently increased the transepithelial capacitance (C(T)) by 57.3+/-2.3% after 16 min. The transepithelial Na+ current (I(Na)) increased concomitantly from 4.2+/-0.7 to 26.1+/-2.6 microA/cm2 with a time course that was noticeably slower, reaching its maximum after 60 min of hypotonicity. The transepithelial conductance (G(T)) increased synchronously with I(Na). Analysis of blocker-induced noise in I(Na), using the amiloride analogue 6-chloro-3,5-diaminopyrazine-2-carboxamide (CDPC), showed that the hypotonic shock increased Na+ channel density (N(T)) at the apical border. The presence of 10 mM Mg2+ on both sides of the epithelium suppressed the hypotonicity-induced C(T) increase to 14.3+/-0.5%, whereas the I(Na) increase was even larger than without Mg2+. Both effects of Mg2+ were located at an extracellular, basolateral site, because apical administration was without effect, whereas the acute basolateral addition of Mg2+ at the moment of the hypotonic shock was sufficient. Interaction between Mg2+ and Ca2+ influenced the behaviour of C(T). At constant osmolality (200 mOsm/kg H2O) 10 mM Mg2+ increased I(Na), leaving C(T) unaffected, whereas 10 mM Ca2+ stimulated both I(Na) and CT. In the presence of 1 mM Mg2+, however, the Ca(2+)-induced CT increase was abolished. The failure of CT to increase during stimulation of I(Na) by Mg2+ suggests that the divalent cation activates pre-existing channels in the apical membrane. Noise analysis showed that the natriferic effects of Mg2+ were also mediated by an increase in NT. The moderate initial increase in CT in the presence of Mg2+ under hypotonic conditions, occurring in parallel with increases in GT and I(Na), reflects most likely Na+ channel insertion induced by the hypotonic treatment. However, the large, transient, Mg(2+)-sensitive increase in CT, not correlated with increases in GT and I(Na), seems to be unrelated to Na+ channel recruitment.

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.

Changes in the iodine content of vegetables following the Chernobyl accident.

In the early phenophases and at maturity the vegetables grown in the goitrogenic area have a lower iodine concentration than in non-goitrogenic areas. Within the same area, the amount of iodine is higher in young than in old vegetables and, in some species, it is higher in the young vegetables of the goitrogenic area than in the nature vegetables of the non-goitrogenic ones. Following the accident at the Chernobyl Nuclear Power Plant in April 1986, the iodine metabolism in plants was disorganized.