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. 1987 Mar;384:247–261. doi: 10.1113/jphysiol.1987.sp016453

Selectivity of calcium channels in rat uterine smooth muscle: interactions between sodium, calcium and barium ions.

K Jmari 1, C Mironneau 1, J Mironneau 1
PMCID: PMC1192261  PMID: 2443660

Abstract

1. Action potentials and membrane currents were recorded by means of a double sucrose-gap technique from Cs-loaded strips from pregnant rats superfused in Ca-free EGTA-containing solutions. 2. When external Ca was reduced below 1 microM in the presence of 1 mM-EGTA, step depolarizations from a holding potential close to the normal resting potential produced tetrodotoxin-resistant inward currents. These currents were suppressed after removal of external Na and blocked by a variety of Ca-channel blockers such as Mn, Co, Ni and nifedipine. 3. Inactivation of the inward Na current was studied using a double-pulse protocol. The degree of inactivation of the Na current was almost maximal for depolarizations of +50 mV. Application of stronger depolarizations did not significantly increase it and had no effect on recovery from inactivation. Similarly, increasing the duration of the conditioning pulse from 30 to 250 ms had no further effect on both amplitude and kinetics of the Na current. These results suggest that the Na current inactivation reflects a pure voltage-dependent mechanism. 4. The effects of external Ca were studied over a 10(9)-fold range in concentration. When external Ca was gradually increased from 1 nM to 1 microM, the inward Na current was reduced and finally abolished. As the external Ca was increased over 0.5 mM, inward current reappeared and increased as Ca became the charge carrier. 5. When Na was the charge carrier, external Ca was the most effective divalent cation in blocking the Ca channel with a half-blockage concentration of 0.1 microM. Addition of millimolar concentrations of Ca and Sr also reduced the Ba current while adding Ba to Ca-containing solution produced no increase in current. 6. Membrane currents in solutions containing both Ba and Ca ions were less than in solutions containing either Ca or Ba at the same concentration, suggesting that Ca channels are single-file multi-ion pores. 7. We conclude that the selectivity of uterine Ca channels depends on the presence of external Ca. In the absence of Ca, these channels become permeable to other divalent (Ba and Sr) and monovalent (Na) cations.

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Selected References

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