Inhibition of voltage-gated calcium channels by sequestration of β subunits

Dominant-negative suppression of Cav2.1 currents by alpha(1)2.1 truncations requires the conserved interaction domain for beta subunits

Episodic ataxia type 2 (EA2) is an autosomal dominant disorder arising from CACNA1A mutations, which commonly predict heterozygous expression of Ca(v)2.1 calcium channels with truncated alpha(1)2.1 pore subunits. We hypothesized that alpha(1)2.1 truncations in EA2 exert dominant-negative effects on the function of wild-type subunits. Wild-type and truncated alpha(1)2.1 subunits with fluorescent protein tags were transiently co-expressed in cells stably expressing Ca(v) auxiliary beta subunits, which facilitate alpha1 subunit functional expression through high-affinity interactions with the alpha interaction domain (AID). Co-expression of wild-type subunits with truncations often resulted in severely reduced whole-cell currents compared to expression of wild-type subunits alone. Cellular image analyses revealed that current suppression was not due to reduced wild-type expression levels. Instead, the current suppression depended on truncations terminating distal to the AID. Moreover, only AID-bearing alpha(1)2.1 proteins co-immunoprecipitated with Ca(v) beta subunits. These results indicate that Ca(v) beta subunits may play a prominent role in EA2 disease pathogenesis.

[Voltage-dependent calcium channels at the heart of pain perception]

Voltage-dependent calcium channels represent a major pathway of calcium entry into neurons, where they participate actively to cell excitability and to the molecular processes of synaptic transmission. For that reason, they have been the direct or indirect pharmacological targets of analgesics and this long before their implication in the physiology of nociception had been demonstrated. These last years, the still more refined molecular characterization of these channels and their associated regulatory subunits and the demonstration of their implication in nociceptive processes indicates that these structures are prime pharmacological targets for the management of pain. Herein, we detail the recent breakthroughs on calcium channel structure, function and pharmacology, review the implication of calcium channels in the transmission of nociception, and evaluate their importance as targets for the treatment of pain perception. The search for specific inhibitors of voltage-dependent calcium channels appears as a prelude to the development of new promising analgesic molecules.

Depolarization evokes different patterns of calcium signals and exocytosis in bovine and mouse chromaffin cells: the role of mitochondria

This study was planned on the assumptions that different high-voltage activated calcium channels and/or the ability of mitochondria to take up Ca(2+) could be responsible for different cytosolic Ca(2+) concentrations ([Ca(2+)](c)) and catecholamine release responses in adrenal chromaffin cells of bovine and mouse species. Short K(+) pulses (2-5 s, 70 mM K(+)) increased [Ca(2+)](c) to a peak of about 1 microM; however, in bovine cells the decline was slower than in mouse cells. Secretory responses were faster in mouse but were otherwise quantitatively similar. Upon longer K(+) applications (1 min), elevations of [Ca(2+)](c) and secretion were prolonged in bovine cells; in contrast [Ca(2+)](c) in mouse cells declined three-fold faster and failed to sustain a continued secretion. Confocal [Ca(2+)](c) imaging following a 50-ms depolarizing pulse showed a similar Ca(2+) entry, but a rate of [Ca(2+)](c) increase and a maximum peak significantly higher in bovine cells; the rate of dissipation of the Ca(2+) wave was faster in the mouse. The mitochondrial protonophore CCCP (2 microm) halved the K(+)-evoked [Ca(2+)](c) and secretory signals in mouse cells, but had little affect on bovine responses. We conclude that the relative densities of L (15% in bovine and 50% in mouse) and P/Q Ca(2+) channels (50% in bovine and 15% in mouse) do not contribute to the observed differences; rather, the different intracellular distribution of Ca(2+), which is strongly influenced by mitochondria, is responsible for a more sustained secretory response in bovine, and for a faster and more transient secretory response in mouse chromaffin cells. It seems that mitochondria near the plasmalemma sequester Ca(2+) more rapidly and efficiently in the mouse than in the bovine chromaffin cell.