Multiple structural elements contribute to voltage-dependent facilitation of neuronal alpha 1C (CaV1.2) L-type calcium channels.

Voltage- and frequency-dependent facilitation of calcium channel activity has been implicated in a number of key physiological processes. Various mechanisms have been proposed to mediate these regulations, including a switch between channel gating modes, voltage-dependent phosphorylation, and a voltage-dependent deinhibition of G-protein block. Studying such modulation on recombinant Ca channels expressed in oocytes, we previously reported that alpha(1C) L-type calcium channel contrast with non-L type Ca channels by its ability to exhibit facilitation by pre-depolarization (Voltage-dependent facilitation of a neuronal alpha(IC) L-type calcium channel, E. Bourinet et al., EMBO Journal, 1994; 13, 5032-5039). To further analyze this effect, we have investigated the molecular determinants which mediate the differences in voltage-dependent facilitation between "facilitable" alpha(1C) and "non facilitable" alpha(1E) calcium channels. We used a series of chimeras which combine the four transmembrane domains of the two channels. Results show that the four domains of alpha(1C) contribute to facilitation, with domain I being most critical. This domain is required but not sufficient alone to generate facilitation. The minimal requirement to observe the effect is the presence of domain I plus one of the three others. We conclude that similarly to activation gating, voltage-dependent facilitation of alpha(1C) is a complex process which involves multiple structural elements were domains I and III play the major role.

Interaction of SNX482 with domains III and IV inhibits activation gating of alpha(1E) (Ca(V)2.3) calcium channels.

We have investigated the action of SNX482, a toxin isolated from the venom of the tarantula Hysterocrates gigas, on voltage-dependent calcium channels expressed in tsa-201 cells. Upon application of 200 nM SNX482, R-type alpha(1E) calcium channels underwent rapid and complete inhibition, which was only poorly reversible upon washout. However, upon application of strong membrane depolarizations, rapid and complete recovery from inhibition was obtained. Tail current analysis revealed that SNX482 mediated an approximately 70 mV depolarizing shift in half-activation potential, suggesting that the toxin inhibits alpha(1E) calcium channels by preventing their activation. Experiments involving chimeric channels combining structural features of alpha(1E) and alpha(1C) subunits indicated that the presence of the domain III and IV of alpha(1E) is a prerequisite for a strong gating inhibition. In contrast, L-type alpha(1C) channels underwent incomplete inhibition at saturating concentrations of SNX482 that was paralleled by a small shift in half-activation potential and which could be rapidly reversed, suggesting a less pronounced effect of the toxin on L-type calcium channel gating. We conclude that SNX482 does not exhibit unequivocal specificity for R-type channels, but highly effectively antagonizes their activation.

Fast inactivation of voltage-dependent calcium channels. A hinged-lid mechanism?

We recently described domains II and III as important determinants of fast, voltage-dependent inactivation of R-type calcium channels (Spaetgens, R. L., and Zamponi, G. W. (1999) J. Biol. Chem. 274, 22428-22438). Here we examine in greater detail the structural determinants of inactivation using a series of chimeras comprising various regions of wild type alpha(1C) and alpha(1E) calcium channels. Substitution of the II S6 and/or III S6 segments of alpha(1E) into the alpha(1C) backbone resulted in rapid inactivation rates that closely approximated those of wild type alpha(1E) channels. However, neither individual or combined substitution of the II S6 and III S6 segments could account for the 60 mV more negative half-inactivation potential seen with wild type alpha(1E) channels, indicating that the S6 regions contribute only partially to the voltage dependence of inactivation. Interestingly, the converse replacement of alpha(1E) S6 segments of domains II, III, or II+III with those of alpha(1C) was insufficient to significantly slow inactivation rates. Only when the I-II linker region and the domain II and III S6 regions of alpha(1E) were concomitantly replaced with alpha(1C) sequence could inactivation be abolished. Conversely, introduction of the alpha(1E) domain I-II linker sequence into alpha(1C) conferred alpha(1E)-like inactivation rates, indicating that the domain I-II linker is a key contributor to calcium channel inactivation. Overall, our data are consistent with a mechanism in which inactivation of voltage-dependent calcium channels may occur via docking of the I-II linker region to a site comprising, at least in part, the domain II and III S6 segments.

Block of voltage-dependent calcium channel by the green mamba toxin calcicludine.

A number of peptide toxins derived from marine snails and various spiders have been shown to potently inhibit voltage-dependent calcium channels. Here, we describe the effect of calcicludine, a 60 amino-acid peptide isolated from the venom of the green mamba (Dendroaspis angusticeps), on transiently expressed high voltage-activated calcium channels. Upon application of calcicludine, L-type (alpha(1)(C)) calcium channels underwent a rapid, irreversible decrease in peak current amplitude with no change in current kinetics, or any apparent voltage-dependence. However, even at saturating toxin concentrations, block was always incomplete with a maximum inhibition of 58%, indicating either partial pore block, or an effect on channel gating. Block nonetheless was of high affinity with an IC(50) value of 88 nm. Three other types of high voltage activated channels tested (alpha(1)(A), alpha(1)(B), and alpha(1)(E)) exhibited a diametrically different response to calcicludine. First, the maximal inhibition observed was around 10%, furthermore, the voltage-dependence of channel activation was shifted slightly towards more negative potentials. Thus, at relatively hyperpolarized test potentials, calcicludine actually upregulated current activity of (N-type) alpha(1)(B) channels by as much as 50%. Finally, the use of several chimeric channels combining the major transmembrane domains of alpha(1)(C) and alpha(1)(E) revealed that calcicludine block of L-type calcium channels involves interactions with multiple structural domains. Overall, calcicludine is a potent and selective inhibitor of neuronal L-type channels with a unique mode of action.

Modulation of neuronal voltage-gated calcium channels by farnesol.

The modulation of presynaptic voltage-dependent calcium channels by classical second messenger molecules such as protein kinase C and G protein betagamma subunits is well established and considered a key factor for the regulation of neurotransmitter release. However, little is known of other endogenous mechanisms that control the activity of these channels. Here, we demonstrate a unique modulation of N-type calcium channels by farnesol, a dephosphorylated intermediate of the mammalian mevalonate pathway. At micromolar concentrations, farnesol acts as a relatively non-discriminatory rapid open channel blocker of all types of high voltage-activated calcium channels, with a mild specificity for L-type channels. However, at 250 nM, farnesol induces an N-type channel-specific hyperpolarizing shift in channel availability that results in approximately 50% inhibition at a typical neuronal resting potential. Additional experiments demonstrated the presence of farnesol in the brain (rodents and humans) at physiologically relevant concentrations (100-800 pmol/g (wet weight)). Altogether, our results indicate that farnesol is a selective, high affinity inhibitor of N-type Ca(2+) channels and raise the possibility that endogenous farnesol and the mevalonate pathway are implicated in neurotransmitter release through regulation of presynaptic voltage-gated Ca(2+) channels.

Multiple structural domains contribute to voltage-dependent inactivation of rat brain alpha(1E) calcium channels.

We have investigated the molecular determinants that mediate the differences in voltage-dependent inactivation properties between rapidly inactivating (R-type) alpha(1E) and noninactivating (L-type) alpha(1C) calcium channels. When coexpressed in human embryonic kidney cells with ancillary beta(1b) and alpha(2)-delta subunits, the wild type channels exhibit dramatically different inactivation properties; the half-inactivation potential of alpha(1E) is 45 mV more negative than that observed with alpha(1C), and during a 150-ms test depolarization, alpha(1E) undergoes 65% inactivation compared with only about 15% for alpha(1C). To define the structural determinants that govern these intrinsic differences, we have created a series of chimeric calcium channel alpha(1) subunits that combine the major structural domains of the two wild type channels, and we investigated their voltage-dependent inactivation properties. Each of the four transmembrane domains significantly affected the half-inactivation potential, with domains II and III being most critical. In particular, substitution of alpha(1C) sequence in domains II or III with that of alpha(1E) resulted in 25-mV negative shifts in half-inactivation potential. Similarly, the differences in inactivation rate were predominantly governed by transmembrane domains II and III and to some extent by domain IV. Thus, voltage-dependent inactivation of alpha(1E) channels is a complex process that involves multiple structural domains and possibly a global conformational change in the channel protein.