Abstract
Voltage-gated calcium channels contain four highly conserved transmembrane helices known as S4 segments that exhibit a positively charged residue every third position, and play the role of voltage sensing. Nonetheless, the activation range between high-voltage (HVA) and low-voltage (LVA) activated calcium channels is around 30–40 mV apart, despite the high level of amino acid similarity within their S4 segments. To investigate the contribution of S4 voltage sensors for the low-voltage activation characteristics of CaV3.3 channels we constructed chimeras by swapping S4 segments between this LVA channel and the HVA CaV1.2 channel. The substitution of S4 segment of Domain II in CaV3.3 by that of CaV1.2 (chimera IIS4C) induced a ~35 mV shift in the voltage-dependence of activation towards positive potentials, showing an I-V curve that almost overlaps with that of CaV1.2 channel. This HVA behavior induced by IIS4C chimera was accompanied by a 2-fold decrease in the voltage-dependence of channel gating. The IVS4 segment had also a strong effect in the voltage sensing of activation, while substitution of segments IS4 and IIIS4 moved the activation curve of CaV3.3 to more negative potentials. Swapping of IIS4 voltage sensor influenced additional properties of this channel such as steady-state inactivation, current decay, and deactivation. Notably, Domain I voltage sensor played a major role in preventing CaV3.3 channels to inactivate from closed states at extreme hyperpolarized potentials. Finally, site-directed mutagenesis in the CaV3.3 channel revealed a partial contribution of the S4-S5 linker of Domain II to LVA behavior, with synergic effects observed in double and triple mutations. These findings indicate that IIS4 and, to a lesser degree IVS4, voltage sensors are crucial in determining the LVA properties of CaV3.3 channels, although the accomplishment of this function involves the participation of other structural elements like S4-S5 linkers.
Highlights
T-type calcium or CaV3 channels are low-voltage activated (LVA) calcium channels that, together with high-voltage activated (HVA) calcium channels, are key elements in regulating calcium influx in most cells [1]
The maximal inward current for CaV3.3 channels was observed at -30 mV and at 0 mV for CaV1.2 channels, and currents were significantly larger for the LVA channel (Fig 2B)
In this study we have demonstrated the relevance of IIS4 voltage sensor to the low-voltage activation behavior of CaV3.3 T-type calcium channel, IVS4 segment has significant effects on the low-voltage activation and the fast-deactivation of the CaV3.3 channel
Summary
T-type calcium or CaV3 channels are low-voltage activated (LVA) calcium channels that, together with high-voltage activated (HVA) calcium channels, are key elements in regulating calcium influx in most cells [1]. Two previous studies performed by the group of Wray and colleagues [29,30], using chimeras between the LVA (CaV3.1) and HVA (CaV1.2) calcium channels, have suggested that Domains I, III and IV are decisive for channel opening and each Domain, as a whole, strongly contributes to the difference in voltage dependence of activation between CaV3.1 and CaV1.2 channels. These studies were focused on the voltage dependence of activation characteristic, whereas other LVA properties of the CaV3.1 T-type calcium channel were not investigated
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