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Single channel patch-clamp recordings show that embryonic rat spinal motoneurons express anomalous L-type calcium channels, which reopen upon repolarization to resting potentials, displaying both short and long reopenings. The probability of reopening increases with increasing voltage of the preceding depolarization without any apparent correlation with inactivation during the depolarization. The probability of long with respect to short reopenings increases with increasing length of the depolarization, with little change in the total number of reopenings and in their delay. With less negative repolarization voltages, the delay increases, while the mean duration of both short and long reopenings decreases, remaining longer than that of the openings during the preceding depolarization. Open times decrease with increasing voltage in the range -60 to +40 mV. Closed times tend to increase at V > 20 mV. The open probability is low at all voltages and has an anomalous bell-shaped voltage dependence. We provide evidence that short and long reopenings of anomalous L-type channels correspond to two gating modes, whose relative probability depends on voltage. Positive voltages favor both the transition from a short-opening to a long-opening mode and the occupancy of a closed state outside the activation pathway within each mode from which the channel reopens upon repolarization. The voltage dependence of the probability of reopenings reflects the voltage dependence of the occupancy of these closed states, while the relative probability of long with respect to short reopenings reflects the voltage dependence of the equilibrium between modes. The anomalous gating persists after patch excision, and therefore our data rule out voltage-dependent block by diffusible ions as the basis for the anomalous gating and imply that a diffusible cytosolic factor is not necessary for voltage-dependent potentiation of anomalous L-type channels.

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The short isoform of the Na+/Ca2+ exchanger (67 kDa) that is produced by alternative splicing during the expression of the 6 kb canine exchanger cDNA in 293 cells was separately expressed in the same system. The protein consisted of the five N-terminal transmembrane segments and of a large portion of the main hydrophilic loop, but lacked the six C-terminal hydrophobic segments of the regular protein (108 kDa). Very high RNA levels were found after transient cell transfection with plasmid DNA encoding this truncated isoform. The RNA processing, the translation and targeting of the resulting protein to the plasma membrane appeared to be less efficient than those of the 108-kDa polypeptide produced in the same system. The Na(+)-dependent Ca(2+)-uptake activity of 293 cells expressing the short isoform was measured by an isotopic rapid filtration method, whereas the current associated with Ca2+ extrusion was measured in electrophysiological patch-clamp experiments. The results showed that the expressed isoform functioned in the typical reverse and forward Na+/Ca2+ exchange modes. In both the electrophysiological and the isotopic measurements the activity of the short isoform was 6-7-fold lower than that of the 108-kDa protein expressed in the same system. However, lower amounts of the short isoform reached the plasma membrane: its specific activity could thus be significantly higher. Possibly, the short isoform could form a dimer in which a second 67 kDa polypeptide replaces the C-terminal part of the 108-kDa protein.

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Transport of K+ by the photoreceptor Na(+)-Ca2+, K+ exchanger was investigated in isolated rod outer segments (OS) by recording membrane current under whole-cell voltage-clamp conditions. Known amounts of K+ were imported in the OS through the Ca(2+)-activated K+ channels while perfusing with high extracellular concentration of K+, [K+]o. These channels were detected in the recordings from the OS, which probably retained a small portion of the rest of the cell. The activation of forward exchange (Na+ imported per Ca2+ and K+ extruded) by intracellular K+, Ki+, was described by first-order kinetics with a Michaelis constant, Kapp(Ki+), of about 2 mM and a maximal current, Imax, of about -60 pA. [Na+]i larger than 100 mM had little effect on Kapp(Ki+) and Imax, indicating that Nai+ did not compete with Ki+ for exchange sites under physiological conditions, and that Na+ release at the exchanger intracellular side was not a rate-limiting step for the exchange process. Exchanger stoichiometry resulted in one K+ ion extruded per one positive charge imported. Exchange current was detected only if Ca2+ and K+ were present on the same membrane side, and Na+ was simultaneously present on the opposite side. Nonelectrogenic modes of ion exchange were tested taking advantage of the hindered diffusion found for Cai2+ and Ki+. Experiments were carried out so that the occurrence of a putative nonelectrogenic ion exchange, supposedly induced by the preapplication of certain extracellular ion(s), would have resulted in the transient presence of both Cai2+ and Ki+. The lack of electrogenic forward exchange in a subsequent switch to high Nao+, excluded the presence of previous nonelectrogenic transport.

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