Loading of fura-2/AM with an aid of DFP on single smooth muscle cells prepared from guinea pig taenia coli

Redox properties of the calcium chelator Fura-2 in mimetic biomembranes

Fura-2 is one of the most commonly used fluorescent dyes to analyze the cytosolic Ca(2+) concentration ([Ca(2+)](i)) of living cells. Fura-2-dependent measurements of [Ca(2+)](i) are susceptible to changes of pH, reactive oxygen species concentration and membrane potential. Fura-2 is often loaded over the lipophilic cell membrane into the cytosol of a cell in its esterified form (Fura-2/AM) which is then cleaved by endogenous esterases. We have analyzed the electrochemical properties of Fura-2/AM and Fura-2 salt by cyclic voltammetry ("three-phase" and "thin-film" electrode methods). Using Fura-2/AM as a redox facilitator, we were able to mimic the transport of various ions across a lipophilic barrier. We show that Fura-2/AM in this biomimetic set-up can be reversibly oxidized in a single electrochemical step. Its redox reaction was highly proton sensitive in buffers with pH< or =6. At physiological pH of around 7.0, the oxidation of Fura-2/AM was coupled to an uptake of mono-anions across the liquid-liquid interface. The voltage-dependence of the redox cycle was sensitive to the free Ca(2+) concentration, either after de-esterification of Fura-2/AM, or when Fura-2 salt was used. The complex between Fura-2 and Ca(2+) ions is ionic (complexation occurs via the dissociated negative groups of Fura forms), while the redox transformations in Fura-2 occurs at the nitrogen atoms of the amino groups. Our results suggest that redox transformations of the Fura-2 forms do not affect the binding ability toward Ca(2+) ions and thus do not interfere with [Ca(2+)](i) measurements.

Relaxant actions of isoprenaline on guinea-pig isolated tracheal smooth muscle

1. The effects of isoprenaline on membrane potential and intracellular Ca2+ concentration ([Ca2+]i) in guinea-pig isolated tracheal muscle were studied by use of intracellular micro-electrodes and fura-2 signals respectively. Measurements of membrane potential were carried out in the presence of spontaneously-generated muscle tone, whereas fura-2 signals were measured during contraction produced by exogenous prostaglandin E2 (100 nM). The potency of isoprenaline in causing relaxation was the same in these two different situations. 2. Isoprenaline (0.01 microM) produced relaxation accompanied by 5 mV hyperpolarization. A combination of tetraethylammonium (TEA, 10 mM) and verapamil (3 microM) did not alter the effects of isoprenaline. Removal of external K+ did not increase the degree of hyperpolarization produced by isoprenaline. 3. In the presence of TEA (10 mM) and verapamil (3 microM), isoprenaline (0.03-1 microM) reduced [Ca2+]i concentration-dependently. A similar degree of inhibition was observed when isoprenaline was applied during the maintained contraction induced by prostaglandin E2 and against the contraction evoked by the addition of Ca2+ to tissues bathed in a Ca(2+)-free medium and pretreated with both isoprenaline and prostaglandin E2. 4. It is concluded that activation of TEA-sensitive Ca(2+)-dependent K+ channels does not play a significant role in isoprenaline-induced relaxation. We propose that, in the guinea-pig tracheal muscle, isoprenaline may produce relaxation mainly by inhibiting a receptor-operated pathway for Ca2+ influx across the plasma membrane which is normally activated by prostaglandins.