Block of the L-type Ca2+ channel pore by external and internal Mg2+ in rat phaeochromocytoma cells.

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Block of the L-type Ca2+ channel pore by external and internal Mg2+ in rat phaeochromocytoma cells.

C C Kuo and P Hess

Program in Neuroscience, Physiology, Harvard Medical School, Boston, MA 02115.

1. Three to eight micromolar external Mg2+ produces discreteblock of the unitary inward currents through the L-type Ca2+channel carried by 300 mM external Li+. Like the Ca2+ block,increasing Li+ concentration decreases the Mg2+ on-rate andincreases the Mg2+ off-rate. 2. These kinetic changes are saturatingand the apparent dissociation constant (Kd) for the on-ratesin 75 mM Li+ (in activity), the same as that in the case ofCa2+ block. This suggests that Mg2+ and Ca2+ produce the discreteblock at the same site. The apparent Kd for the off-rates is300 mM, much smaller than that in the case of Ca2+ block. Thisindicates that Mg2+ exerts much less repulsion on the Li+ ionin the neighbouring (enhancement) site than Ca2+, although Mg2+and Ca2+ both have two charges. The theoretical fits to theoff-rates also suggest that Mg2+ can exit the blocking sitesat a rate of several hundred per second in the absence of anyenhancement effect. 3. Seventeen to forty-eight micromolar internalMg2+ produces discrete block of the outward unitary currentscarried by 300 mM internal Li+. The off-rates are in generalapproximately 20 times faster as compared to the Mg2+ off-ratesin the inward currents. This finding suggests that Mg2+ in thehigh-affinity sites can much more easily exit to the outsidethan to the inside, implying significantly higher energy barrierson the inner side of the high-affinity sites for Mg2+. 4. Atleast 5-10 mM internal Mg2+ is needed to produce discrete blockof the inward unitary currents carried by 215 mM external Na+.The off-rates in such experiments are generally the same asthose in the case of external Mg2+ block of inward currents.This suggests that internal and external Mg2+ both reach thesame site, namely the high-affinity Ca2+ binding sites in thepore, to produce the discrete block. 5. Other than discreteblock, 5-10 mM internal Mg2+ also decreases the size of theinward unitary current. This is most probably due to a fastblock at the more internally located low-affinity sites in thepore. The fractional decrease of the currents is voltage dependentand can be fitted by a rectangular hyperbola to calculate theapparent Kd, which increases e-fold per 45 mV hyperpolarization,indicating an electrical distance of 0.3 between the low-affinitysites and the internal pore mouth.(ABSTRACT TRUNCATED AT 400WORDS)

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