Abstract
Voltage-gated calcium channels are in a closed conformation at rest and open temporarily when the membrane is depolarized. To gain insight into the molecular architecture of Ca(v)1.2, we probed the closed and open conformations with the charged phenylalkylamine (-)devapamil ((-)qD888). To elucidate the access pathway of (-)D888 to its binding pocket from the intracellular side, we used mutations replacing a highly conserved Ile-781 by threonine/proline in the pore-lining segment IIS6 of Ca(v)1.2 (1). The shifted channel gating of these mutants (by 30-40 mV in the hyperpolarizing direction) enabled us to evoke currents with identical kinetics at different potentials and thus investigate the effect of the membrane potentials on the drug access per se. We show here that under these conditions the development of channel block by (-)qD888 is not affected by the transmembrane voltage. Recovery from block at rest was, however, accelerated at more hyperpolarized voltages. These findings support the conclusion that Ca(v)1.2 must be opening widely to enable free access of the charged (-)D888 molecule to its binding site, whereas drug dissociation from the closed channel conformation is restricted by bulky channel gates. The functional data indicating a location of a trapped (-)D888 molecule close to the central pore region are supported by a homology model illustrating that the closed Ca(v)1.2 is able to accommodate a large cation such as (-)D888.
Highlights
Voltage-gated calcium channels are in a closed conformation at rest and open temporarily when the membrane is depolarized
We show here that under these conditions the development of channel block by (؊)qD888 is not affected by the transmembrane voltage
Recovery from block at rest was, accelerated at more hyperpolarized voltages. These findings support the conclusion that Cav1.2 must be opening widely to enable free access of the charged (؊)D888 molecule to its binding site, whereas drug dissociation from the closed channel conformation is restricted by bulky channel gates
Summary
Voltage-gated calcium channels are in a closed conformation at rest and open temporarily when the membrane is depolarized. Recovery from block at rest was, accelerated at more hyperpolarized voltages These findings support the conclusion that Cav1.2 must be opening widely to enable free access of the charged (؊)D888 molecule to its binding site, whereas drug dissociation from the closed channel conformation is restricted by bulky channel gates. The novel findings of this study are that the development of channel block by (Ϫ)qD888 is unaffected by the transmembrane voltage, but recovery from block at rest is affected, i.e. dissociation accelerates as the voltage becomes more negative These findings lead us to conclude that drug association occurs via a widely open channel mouth (free access of the charged molecule with no voltage drop from inside to the binding site), whereas drug dissociation from the closed channel conformation is restricted by the closed channel gate that has a substantial voltage drop across it. Analyzing the voltage-dependence of recovery using the Eyring rate constant theory predicts that the quaternary and tertiary (Ϫ)D888 bind near the central pore region
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