Abstract. Self-referencing ion -selective electrodes (ISEs), made with Chloride Ionophore I-Cocktail A (Fluka), were positioned 1-3 lm from human embryonic kidney cells (tsA201a) and used to record chloride flux during a sustained hyposmotic challenge. The ISE response was close to Nernstian when comparing potentials (V N ) measured in 100 and 10 mM NaCl (DV N = 57 ± 2 mV), but was slightly greater than ideal when comparing 1 and 10 mM NaCl (DV N = 70 ± 3 mV). The response was also linear in the presence of 1 mM glutamate, gluconate, or acetate, 10 lM tamoxifen, or 0.1, 1, or 10 mM HEPES at pH 7.0. The ISE was $3 orders of magnitude more selective for Cl ) over glutamate or gluconate but less than 2 orders of magnitude move selective for Cl ) over bicarbonate, acetate, citrate or thiosulfate. As a result this ISE is best described as an anion sensor. The ISE was 'poisoned' by 50 lM 5)nitro-2-(3phe-nylpropyl-amino)-benzoic acid (NPPB), but not by tamoxifen. An outward anion efflux was recorded from cells challenged with hypotonic (250 ± 5 mOsm) solution. The increase in efflux peaked 7-8 min before decreasing, consistent with regulatory volume decreases observed in separate experiments using a similar osmotic protocol. This anion efflux was blocked by 10 lM tamoxifen. These results establish the feasibility of using the modulation of electrochemical, anion-selective, electrodes to monitor anions and, in this case, chloride movement during volume regulatory events. The approach provides a real-time measure of anion movement during regulated volume decrease at the single-cell level.
Short (<1 sec) duration depolarization of Xenopus laevis oocytes to voltages greater than +40 mV activates a sodium-selective channel (Na(x)) with sodium permeability five to six times greater than the permeability of other monovalent cations examined, including K+, Rb+, Cs+, TMA+, and Choline+. The permeability to Li+ is about equal to that of Na+. This channel was present in all oocytes examined. The kinetics, voltage dependence and pharmacology of Na(x)distinguish it from TTX-sensitive or epithelial sodium channels. It is also different from the sodium channel of Xenopus oocytes activated by prolonged depolarization, which is more highly selective for Na+, requires prolonged depolarization to be activated, and is blocked by Li+. Intracellular Mg2+ reversibly inhibits Na(x), whereas extracellular Mg2+ does not have an inhibitory effect. Intracellular Mg2+ inhibition of Na(x), is voltage dependent, suggesting that Mg2+ binding occurs within the membrane field. Eosin is also a reversible voltage-dependent intracellular inhibitor of Na(x), suggesting that a P-type ATPase may mediate the current. An additional cytoplasmic factor is involved in maintaining Na(x) since the current runs down in internally perfused oocytes and excised membrane patches. The rundown is reversible by reintroduction of the membrane patch into oocyte cytoplasm. The cytoplasmic factor is not ATP, because ATP has no effect on Na(x) current magnitude in either cut-open or inside-out patch preparations. Extracellular Gd3+ is also an inhibitor of Na(x). Na(x) activation follows a sigmoid time course. Its half-maximal activation potential is +100 mV and the effective valence estimated from the steepness of conductance activation is 1.0. Na(x) deactivates monoexponentially upon return to the holding potential (-40 mV). The deactivation rate is voltage dependent, increasing at more negative membrane potentials.
Centrally administered rat/human corticotropin-releasing factor (rCRF) increases low levels of locomotor activity by rats tested in a familiar environment but suppresses the higher levels of activity associated with exposure of the animals to a novel environment. These opposing responses do not appear to be manifestations of a simple rate-dependent effect, since ICV-administered rCRF did not lower the higher levels of locomotor activity associated with the dark (active) phase of the animal's activity cycle. Caffeine, which has anxiogenic effects in man, produces effects in rats which are similar to those of rCRF. That is, both compounds elevate activity in a familiar environment but lower activity in a novel environment. Furthermore, caffeine appears to substitute for novelty in determining the direction of the locomotor effect of rCRF. Animals made hyperactive by caffeine show decreased activity when co-administered rCRF. These findings are consistent with the view that CRF acts through pathways which also subserve the responsiveness to novelty and to the anxiogenic compound caffeine.
The goal of this study was to assess the effect of extracellular glucose and K+ ((K)o) on the intracellular osmolyte content and cell volume maintenance and regulation in a human embryonic kidney cell line (tsA201a). Cell volume maintenance was studied by isotonic (313 +/- 5 mOsm) replacement of culture media by a glucose-free Ringer solution containing (in mM) 0, 3, 6, or 10 K+. Cell volume regulation was studied by exposing cells to hypotonic (250 +/- 5 mOsm) glucose-free Ringer solution containing the various (K)o. The results showed that: 1) intracellular osomlyte content (i.e. Na+, Cl-, Urea and free amino acids (FAA)) and cell volume increased when culture media was replaced with isotonic Ringer at all (K)o; 2) osmolyte content decreased with continuous exposure to isotonic Ringer at all (K)o but cell volume changes depended on (K)o. Volume recovery occurred at 6 and 10 mM K+; 3) exposure to hypotonic Ringer induced swelling at all (K)o followed by a reduction in measured intracellular osmolytes. Regulatory volume decrease occurred in 6 or 10 mM K+ but swelling continued in 0 or 3 mM K+; and 4) addition of ouabain produced swelling without recovery under iso- and hypotonic conditions. These results indicate that the removal of extracellular glucose produced a transient inhibition of the Na+/K+ ATPase resulting in a transient increase in the intracellular content of Urea, FAA and cell volume and (K)o regulated an as yet unidentified intracellular osmolyte.
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