Voltage-gated T-type Ca 2ϩ (Ca V 3) channels regulate diverse physiological events, including neuronal excitability, and have been linked to several pathological conditions such as absence epilepsy, cardiovascular diseases, and neuropathic pain. It is also acknowledged that calcium/calmodulin-dependent protein kinase II and protein kinases A and C regulate the activity of T-type channels. Interestingly, peripheral nerve injury induces tactile allodynia and upregulates Ca V 3.2 channels and cyclin-dependent kinase 5 (Cdk5) in dorsal root ganglia (DRG) and spinal dorsal horn. Here, we report that recombinant Ca V 3.2 channels expressed in HEK293 cells are regulatory targets of Cdk5. Site-directed mutagenesis showed that the relevant sites for this regulation are residues S561 and S1987. We also found that Cdk5 may regulate Ca V 3.2 channel functional expression in rats with mechanical allodynia induced by spinal nerve ligation (SNL). Consequently, the Cdk5 inhibitor olomoucine affected the compound action potential recorded in the spinal nerves, as well as the paw withdrawal threshold. Likewise, Cdk5 expression was upregulated after SNL in the DRG. These findings unveil a novel mechanism for how phosphorylation may regulate Ca V 3.2 channels and suggest that increased channel activity by Cdk5-mediated phosphorylation after SNL contributes nerve injury-induced tactile allodynia.
Voltage-gated Ca2+ (CaV) channels mediate Ca2+ ions influx into cells in response to depolarization of the plasma membrane. They are responsible for initiation of excitation-contraction and excitation-secretion coupling, and the Ca2+ that enters cells through this pathway is also important in the regulation of protein phosphorylation, gene transcription, and many other intracellular events. Initial electrophysiological studies divided CaV channels into low-voltage-activated (LVA) and high-voltage-activated (HVA) channels. The HVA CaV channels were further subdivided into L, N, P/Q, and R-types which are oligomeric protein complexes composed of an ion-conducting CaVα1 subunit and auxiliary CaVα2δ, CaVβ, and CaVγ subunits. The functional consequences of the auxiliary subunits include altered functional and pharmacological properties of the channels as well as increased current densities. The latter observation suggests an important role of the auxiliary subunits in membrane trafficking of the CaVα1 subunit. This includes the mechanisms by which CaV channels are targeted to the plasma membrane and to appropriate regions within a given cell. Likewise, the auxiliary subunits seem to participate in the mechanisms that remove CaV channels from the plasma membrane for recycling and/or degradation. Diverse studies have provided important clues to the molecular mechanisms involved in the regulation of CaV channels by the auxiliary subunits, and the roles that these proteins could possibly play in channel targeting and membrane Stabilization.
Voltage-gated calcium (CaV) channels are transmembrane proteins that form Ca2+-selective pores gated by depolarization and are essential regulators of the intracellular Ca2+ concentration. By providing a pathway for rapid Ca2+ influx, CaV channels couple membrane depolarization to a wide array of cellular responses including neurotransmission, muscle contraction and gene expression. CaV channels fall into two major classes, low voltage-activated (LVA) and high voltage-activated (HVA). The ion-conducting pathway of HVA channels is the α1 subunit, which typically contains associated β and α2δ ancillary subunits that regulate the properties of the channel. Although it is widely acknowledged that α2δ-1 is post-translationally cleaved into an extracellular α2 polypeptide and a membrane-anchored δ protein that remain covalently linked by disulfide bonds, to date the contribution of different cysteine (Cys) residues to the formation of disulfide bridges between these proteins has not been investigated. In the present report, by predicting disulfide connectivity with bioinformatics, molecular modeling and protein biochemistry experiments we have identified two Cys residues involved in the formation of an intermolecular disulfide bond of critical importance for the structure and function of the α2δ-1 subunit. Site directed-mutagenesis of Cys404 (located in the von Willebrand factor-A region of α2) and Cys1047 (in the extracellular domain of δ) prevented the association of the α2 and δ peptides upon proteolysis, suggesting that the mature protein is linked by a single intermolecular disulfide bridge. Furthermore, co-expression of mutant forms of α2δ-1 Cys404Ser and Cys1047Ser with recombinant neuronal N-type (CaV2.2α1/β3) channels, showed decreased whole-cell patch-clamp currents indicating that the disulfide bond between these residues is required for α2δ-1 function.
Background and Purpose Postoperative pain occurs in as many as 70% of surgeries performed worldwide. Postoperative pain management still relies on opioids despite their negative consequences, resulting in a public health crisis. Therefore, it is important to develop alternative therapies to treat chronic pain. Natural products derived from medicinal plants are potential sources of novel biologically active compounds for development of safe analgesics. In this study, we screened a library of natural products to identify small molecules that target the activity of voltage‐gated sodium and calcium channels that have important roles in nociceptive sensory processing. Experimental Approach Fractions derived from the Native American medicinal plant, Parthenium incanum, were assessed using depolarization‐evoked calcium influx in rat dorsal root ganglion (DRG) neurons. Further separation of these fractions yielded a cycloartane‐type triterpene identified as argentatin C, which was additionally evaluated using whole‐cell voltage and current‐clamp electrophysiology, and behavioural analysis in a mouse model of postsurgical pain. Key Results Argentatin C blocked the activity of both voltage‐gated sodium and low‐voltage‐activated (LVA) calcium channels in calcium imaging assays. Docking analysis predicted that argentatin C may bind to NaV1.7–1.9 and CaV3.1–3.3 channels. Furthermore, argentatin C decreased Na+ and T‐type Ca2+ currents as well as excitability in rat and macaque DRG neurons, and reversed mechanical allodynia in a mouse model of postsurgical pain. Conclusion and Implications These results suggest that the dual effect of argentatin C on voltage‐gated sodium and calcium channels supports its potential as a novel treatment for painful conditions.
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