The MAP1B-LC1/UBE2L3 complex catalyzes degradation of cell surface CaV2.2 channels

We reported recently a new mechanism by which the neuronal N-type Ca²⁺ (Ca_V2.2) channel expression may be regulated by ubiquitination. This mechanism involves the interaction between the channel and the light chain (LC1) of the microtubule associated protein B (MAP1B). We also showed that MAP1B-LC1 could interact with the ubiquitin-conjugating E2 enzyme UBE2L3 and that the ubiquitination/degradation mechanism triggered by MAP1B-LC1 could be prevented by inhibiting the ubiquitin-proteasome proteolytic pathway. We now report that MAP1B-LC1 can interact with the 2 main variants of the Ca_V2.2 channels (Ca_V2.2e37a and Ca_V2.2e37b) and that the MAP1B-LC1-mediated regulation most likely involves an internalization of the channels via a dynamin and clathrin-dependent pathway. In addition, here we propose that this novel mechanism of Ca_V channel regulation might be conserved among N-type and P/Q-type channels.     

Single channel measurements demonstrate the voltage dependence of permeation through N-type and L-type CaV channels

The delivery of Ca²⁺ into cells by Ca_V channels provides the trigger for many cellular actions, such as cardiac muscle contraction and neurotransmitter release. Thus, a full understanding of Ca²⁺ permeation through these channels is critical. Using whole-cell voltage-clamp recordings, we recently demonstrated that voltage modulates the apparent affinity of N-type (Ca_V2.2) channels for permeating Ca²⁺ and Ba²⁺ ions. While we took many steps to ensure the high fidelity of our recordings, problems can occur when Ca_V currents become large and fast, or when currents run down. Thus, we use here single channel recordings to further test the hypothesis that permeating ions interact with N-type channels in a voltage-dependent manner. We also examined L-type (Ca_V1.2) channels to determine if these channels also exhibit voltage-dependent permeation. Like our whole-cell data, we find that voltage modulates N-channel affinity for Ba²⁺ at voltages > 0 mV, but has little or no effect at voltages < 0 mV. Furthermore, we demonstrate that permeation through L-channel is also modulated by voltage. Thus, voltage-dependence may be a common feature of divalent cation permeation through Ca_V1 and Ca_V2 channels (i.e. high-voltage activated Ca_V channels). The voltage dependence of Ca_V1 channel permeation is likely a mechanism mediating sustained Ca²⁺ influx during the plateau phase of the cardiac action potential.     

Single channel measurements demonstrate the voltage dependence of permeation through N-type and L-type CaV channels

The delivery of Ca²⁺ into cells by Ca_V channels provides the trigger for many cellular actions, such as cardiac muscle contraction and neurotransmitter release. Thus, a full understanding of Ca²⁺ permeation through these channels is critical. Using whole-cell voltage-clamp recordings, we recently demonstrated that voltage modulates the apparent affinity of N-type (Ca_V2.2) channels for permeating Ca²⁺ and Ba²⁺ ions. While we took many steps to ensure the high fidelity of our recordings, problems can occur when Ca_V currents become large and fast, or when currents run down. Thus, we use here single channel recordings to further test the hypothesis that permeating ions interact with N-type channels in a voltage-dependent manner. We also examined L-type (Ca_V1.2) channels to determine if these channels also exhibit voltage-dependent permeation. Like our whole-cell data, we find that voltage modulates N-channel affinity for Ba²⁺ at voltages > 0 mV, but has little or no effect at voltages < 0 mV. Furthermore, we demonstrate that permeation through L-channel is also modulated by voltage. Thus, voltage-dependence may be a common feature of divalent cation permeation through Ca_V1 and Ca_V2 channels (i.e. high-voltage activated Ca_V channels). The voltage dependence of Ca_V1 channel permeation is likely a mechanism mediating sustained Ca²⁺ influx during the plateau phase of the cardiac action potential.     

Bipartite syntaxin 1A interactions mediate CaV2.2 calcium channel regulation

Functional interactions between syntaxin 1A and Ca_V2 calcium channels are critical for fast neurotransmitter release in the mammalian brain, and coexpression of syntaxin 1A with these channels not only regulates channel availability, but also promotes G-protein inhibition. Both the syntaxin 1A C-terminal H3 domain, and N-terminal Ha domain have been shown to interact with the Ca_V2.2 channel synprint region, suggesting a bipartite model of functional interaction, however the molecular determinants of this interaction have not been closely investigated. We used in vitro binding assays to assess interactions of syntaxin 1A truncation mutants with Ca_V2.2 synprint and Ca_V2.3 II–III linker regions. We identified two distinct interactions between the Ca_V2.2 synprint region and syntaxin 1A: the first between C-terminal H3c domain of syntaxin 1A and residues 822–872 of Ca_V2.2; and the second between the N-terminal 10 residues of the syntaxin 1A Ha region and residues 718–771 of Ca_V2.2. The N-terminal syntaxin 1A fragment also interacted with the Ca_V2.3 II–III linker. We then performed whole cell patch clamp recordings to test the effects of a putative interacting syntaxin 1A N-terminus peptide with Ca_V2.2 and Ca_V2.3 channels in a recombinant expression system. A YFP-tagged peptide corresponding to the N-terminal 10 residues of the syntaxin 1A Ha domain was sufficient to allosterically inhibit both Ca_V2.2 and Ca_V2.3 channel function but had no effect on G-protein mediated inhibition. Our results support a model of bipartite functional interactions between syntaxin 1A and Ca_V2.2 channels and add accuracy to the two putative interacting domains, consistent with previous studies. Furthermore, we highlight the syntaxin 1A N-terminus as the minimal determinant for functional regulation of Ca_V2.2 and Ca_V2.3 channels.     

Voltage-dependent regulation of CaV2.2 channels by Gq-coupled receptor is facilitated by membrane-localized β subunit

G protein–coupled receptors (GPCRs) signal through molecular messengers, such as Gβγ, Ca²⁺, and phosphatidylinositol 4,5-bisphosphate (PIP₂), to modulate N-type voltage-gated Ca²⁺ (Ca_V2.2) channels, playing a crucial role in regulating synaptic transmission. However, the cellular pathways through which G_qPCRs inhibit Ca_V2.2 channel current are not completely understood. Here, we report that the location of Ca_V β subunits is key to determining the voltage dependence of Ca_V2.2 channel modulation by G_qPCRs. Application of the muscarinic agonist oxotremorine-M to tsA-201 cells expressing M₁ receptors, together with Ca_V N-type α1B, α2δ1, and membrane-localized β2a subunits, shifted the current-voltage relationship for Ca_V2.2 activation 5 mV to the right and slowed current activation. Muscarinic suppression of Ca_V2.2 activity was relieved by strong depolarizing prepulses. Moreover, when the C terminus of β-adrenergic receptor kinase (which binds Gβγ) was coexpressed with N-type channels, inhibition of Ca_V2.2 current after M₁ receptor activation was markedly reduced and delayed, whereas the delay between PIP₂ hydrolysis and inhibition of Ca_V2.2 current was decreased. When the Gβγ-insensitive Ca_V2.2 α1C-1B chimera was expressed, voltage-dependent inhibition of calcium current was virtually abolished, suggesting that M₁ receptors act through Gβγ to inhibit Ca_V2.2 channels bearing membrane-localized Ca_V β2a subunits. Expression of cytosolic β subunits such as β2b and β3, as well as the palmitoylation-negative mutant β2a(C3,4S), reduced the voltage dependence of M₁ muscarinic inhibition of Ca_V2.2 channels, whereas it increased inhibition mediated by PIP₂ depletion. Together, our results indicate that, with membrane-localized Ca_V β subunits, Ca_V2.2 channels are subject to Gβγ-mediated voltage-dependent inhibition, whereas cytosol-localized β subunits confer more effective PIP₂-mediated voltage-independent regulation. Thus, the voltage dependence of G_qPCR regulation of calcium channels can be determined by the location of isotype-specific Ca_V β subunits.     

G protein inhibition of CaV2 calcium channels

Voltage-gated Ca²⁺ channels translate the electrical inputs of excitable cells into biochemical outputs by controlling influx of the ubiquitous second messenger Ca²⁺. As such the channels play pivotal roles in many cellular functions including the triggering of neurotransmitter and hormone release by Ca_V2.1 (P/Q-type) and Ca_V2.2 (N-type) channels. It is well established that G protein coupled receptors (GPCRs) orchestrate precise regulation neurotransmitter and hormone release through inhibition of Ca_V2 channels. Although the GPCRs recruit a number of different pathways, perhaps the most prominent, and certainly most studied among these is the so-called voltage-dependent inhibition mediated by direct binding of Gβγ to the α₁ subunit of Ca_V2 channels. This article will review the basics of Ca²⁺-channels and G protein signaling, and the functional impact of this now classical inhibitory mechanism on channel function. It will also provide an update on more recent developments in the field, both related to functional effects and crosstalk with other signaling pathways, and advances made toward understanding the molecular interactions that underlie binding of Gβγ to the channel and the voltage-dependence that is a signature characteristic of this mechanism.     

Synthesis and evaluation of aminobenzothiazoles as blockers of N- and T-type calcium channels

Both N- and T-type calcium ion channels have been implicated in pain transmission and the N-type channel is a well-validated target for the treatment of neuropathic pain. An SAR investigation of a series of substituted aminobenzothiazoles identified a subset of five compounds with comparable activity to the positive control Z160 in a FLIPR-based intracellular calcium response assay measuring potency at both Ca_V2.2 and Ca_V3.2 channels. These compounds may form the basis for the development of drug leads and tool compounds for assessing in vivo effects of variable modulation of Ca_V2.2 and Ca_V3.2 channels.     

Stargazin Modulates Neuronal Voltage-dependent Ca2+ Channel Cav2.2 by a Gβγ-dependent Mechanism

Loss of neuronal protein stargazin (γ₂) is associated with recurrent epileptic seizures and ataxia in mice. Initially, due to homology to the skeletal muscle calcium channel γ₁ subunit, stargazin and other family members (γ_3–8) were classified as γ subunits of neuronal voltage-gated calcium channels (such as Ca_V2.1-Ca_V2.3). Here, we report that stargazin interferes with G protein modulation of Ca_V2.2 (N-type) channels expressed in Xenopus oocytes. Stargazin counteracted the Gβγ-induced inhibition of Ca_V2.2 channel currents, caused either by coexpression of the Gβγ dimer or by activation of a G protein-coupled receptor. Expression of high doses of Gβγ overcame the effects of stargazin. High affinity Gβγ scavenger proteins m-cβARK and m-phosducin produced effects similar to stargazin. The effects of stargazin and m-cβARK were not additive, suggesting a common mechanism of action, and generally independent of the presence of the Ca_Vβ₃ subunit. However, in some cases, coexpression of Ca_Vβ₃ blunted the modulation by stargazin. Finally, the Gβγ-opposing action of stargazin was not unique to Ca_V2.2, as stargazin also inhibited the Gβγ-mediated activation of the G protein-activated K⁺ channel. Purified cytosolic C-terminal part of stargazin bound Gβγ in vitro. Our results suggest that the regulation by stargazin of biophysical properties of Ca_V2.2 are not exerted by direct modulation of the channel but via a Gβγ-dependent mechanism.     

Divergent Ca2+/calmodulin feedback regulation of CaV1 and CaV2 voltage-gated calcium channels evolved in the common ancestor of Placozoa and Bilateria

Ca_V1 and Ca_V2 voltage-gated calcium channels evolved from an ancestral Ca_V1/2 channel via gene duplication somewhere near the stem animal lineage. The divergence of these channel types led to distinguishing functional properties that are conserved among vertebrates and bilaterian invertebrates and contribute to their unique cellular roles. One key difference pertains to their regulation by calmodulin (CaM), wherein bilaterian Ca_V1 channels are uniquely subject to pronounced, buffer-resistant Ca²⁺/CaM-dependent inactivation, permitting negative feedback regulation of calcium influx in response to local cytoplasmic Ca²⁺ rises. Early diverging, nonbilaterian invertebrates also possess Ca_V1 and Ca_V2 channels, but it is unclear whether they share these conserved functional features. The most divergent animals to possess both Ca_V1 and Ca_V2 channels are placozoans such as Trichoplax adhaerens, which separated from other animals over 600 million years ago shortly after their emergence. Hence, placozoans can provide important insights into the early evolution of Ca_V1 and Ca_V2 channels. Here, we build upon previous characterization of Trichoplax Ca_V channels by determining the cellular expression and ion-conducting properties of the Ca_V1 channel orthologue, TCa_V1. We show that TCa_V1 is expressed in neuroendocrine-like gland cells and contractile dorsal epithelial cells. In vitro, this channel conducts dihydropyridine-insensitive, high-voltage–activated Ca²⁺ currents with kinetics resembling those of rat Ca_V1.2 but with left-shifted voltage sensitivity for activation and inactivation. Interestingly, TCa_V1, but not TCa_V2, exhibits buffer-resistant Ca²⁺/CaM-dependent inactivation, indicating that this functional divergence evolved prior to the emergence of bilaterian animals and may have contributed to their unique adaptation for cytoplasmic Ca²⁺ signaling within various cellular contexts.     

Voltage control of Ca2+ permeation through N-type calcium (CaV2.2) channels

Voltage-gated calcium (Ca_V) channels deliver Ca²⁺ to trigger cellular functions ranging from cardiac muscle contraction to neurotransmitter release. The mechanism by which these channels select for Ca²⁺ over other cations is thought to involve multiple Ca²⁺-binding sites within the pore. Although the Ca²⁺ affinity and cation preference of these sites have been extensively investigated, the effect of voltage on these sites has not received the same attention. We used a neuronal preparation enriched for N-type calcium (Ca_V2.2) channels to investigate the effect of voltage on Ca²⁺ flux. We found that the EC₅₀ for Ca²⁺ permeation increases from 13 mM at 0 mV to 240 mM at 60 mV, indicating that, during permeation, Ca²⁺ ions sense the electric field. These data were nicely reproduced using a three-binding-site step model. Using roscovitine to slow Ca_V2.2 channel deactivation, we extended these measurements to voltages <0 mV. Permeation was minimally affected at these hyperpolarized voltages, as was predicted by the model. As an independent test of voltage effects on permeation, we examined the Ca²⁺-Ba²⁺ anomalous mole fraction (MF) effect, which was both concentration and voltage dependent. However, the Ca²⁺-Ba²⁺ anomalous MF data could not be reproduced unless we added a fourth site to our model. Thus, Ca²⁺ permeation through Ca_V2.2 channels may require at least four Ca²⁺-binding sites. Finally, our results suggest that the high affinity of Ca²⁺ for the channel helps to enhance Ca²⁺ influx at depolarized voltages relative to other ions (e.g., Ba²⁺ or Na⁺), whereas the absence of voltage effects at negative potentials prevents Ca²⁺ from becoming a channel blocker. Both effects are needed to maximize Ca²⁺ influx over the voltages spanned by action potentials.     

The CaVβ Subunit Protects the I-II Loop of the Voltage-gated Calcium Channel CaV2.2 from Proteasomal Degradation but Not Oligoubiquitination

Ca_Vβ subunits interact with the voltage-gated calcium channel Ca_V2.2 on a site in the intracellular loop between domains I and II (the I-II loop). This interaction influences the biophysical properties of the channel and leads to an increase in its trafficking to the plasma membrane. We have shown previously that a mutant Ca_V2.2 channel that is unable to bind Ca_Vβ subunits (Ca_V2.2 W391A) was rapidly degraded (Waithe, D., Ferron, L., Page, K. M., Chaggar, K., and Dolphin, A. C. (2011) J. Biol. Chem. 286, 9598–9611). Here we show that, in the absence of Ca_Vβ subunits, a construct consisting of the I-II loop of Ca_V2.2 was directly ubiquitinated and degraded by the proteasome system. Ubiquitination could be prevented by mutation of all 12 lysine residues in the I-II loop to arginines. Including a palmitoylation motif at the N terminus of Ca_V2.2 I-II loop was insufficient to target it to the plasma membrane in the absence of Ca_Vβ subunits even when proteasomal degradation was inhibited with MG132 or ubiquitination was prevented by the lysine-to-arginine mutations. In the presence of Ca_Vβ subunit, the palmitoylated Ca_V2.2 I-II loop was protected from degradation, although oligoubiquitination could still occur, and was efficiently trafficked to the plasma membrane. We propose that targeting to the plasma membrane requires a conformational change in the I-II loop that is induced by binding of the Ca_Vβ subunit.     

Orientation of palmitoylated CaVβ2a relative to CaV2.2 is critical for slow pathway modulation of N-type Ca2+ current by tachykinin receptor activation

The G_q-coupled tachykinin receptor (neurokinin-1 receptor [NK-1R]) modulates N-type Ca²⁺ channel (Ca_V2.2 or N channel) activity at two distinct sites by a pathway involving a lipid metabolite, most likely arachidonic acid (AA). In another study published in this issue (Heneghan et al. 2009. J. Gen Physiol. doi:10.1085/jgp.200910203), we found that the form of modulation observed depends on which Ca_Vβ is coexpressed with Ca_V2.2. When palmitoylated Ca_Vβ2a is coexpressed, activation of NK-1Rs by substance P (SP) enhances N current. In contrast, when Ca_Vβ3 is coexpressed, SP inhibits N current. However, exogenously applied palmitic acid minimizes this inhibition. These findings suggested that the palmitoyl groups of Ca_Vβ2a may occupy an inhibitory site on Ca_V2.2 or prevent AA from interacting with that site, thereby minimizing inhibition. If so, changing the orientation of Ca_Vβ2a relative to Ca_V2.2 may displace the palmitoyl groups and prevent them from antagonizing AA''s actions, thereby allowing inhibition even in the presence of Ca_Vβ2a. In this study, we tested this hypothesis by deleting one (Bdel1) or two (Bdel2) amino acids proximal to the α interacting domain (AID) of Ca_V2.2''s I–II linker. Ca_Vβs bind tightly to the AID, whereas the rigid region proximal to the AID is thought to couple Ca_Vβ''s movements to Ca_V2.2 gating. Although Bdel1/β2a currents exhibited more variable enhancement by SP, Bdel2/β2a current enhancement was lost at all voltages. Instead, inhibition was observed that matched the profile of N-current inhibition from Ca_V2.2 coexpressed with Ca_Vβ3. Moreover, adding back exogenous palmitic acid minimized inhibition of Bdel2/β2a currents, suggesting that when palmitoylated Ca_Vβ2a is sufficiently displaced, endogenously released AA can bind to the inhibitory site. These findings support our previous hypothesis that Ca_Vβ2a''s palmitoyl groups directly interact with an inhibitory site on Ca_V2.2 to block N-current inhibition by SP.     

Gating charges per channel of CaV2.2 channels are modified by G protein activation in rat sympathetic neurons

It has been suggested that voltage-dependent G protein modulation of Ca_V2.2 channels is carried out at closed states of the channel. Our purpose was to estimate the number of gating charges of Ca_V2.2 channel in control and G protein-modulated conditions. By using a Cole-Moore protocol we observed a significant delay in Ca_V2.2 channel activation according to a transit of the channel through a series of closed states before channel opening. If G protein voltage-dependent modulation were carried out at these closed states, then we would have expected a greater Cole-Moore lag in the presence of a neurotransmitter. This prediction was confirmed for noradrenaline, while no change was observed in the presence of angiotensin II, a voltage-insensitive G protein modulator. We used the limiting slope method for calculation of the gating charge per channel. Effective charge z was 6.32 ± 0.65 for Ca_V2.2 channels in unregulated conditions, while GTPγS reduced elementary charge by ∼4 e₀. Accordingly, increased concentration of noradrenaline induced a gradual decrease on z, indicating that this decrement was due to a G protein voltage-sensitive modulation. This paper shows for the first time a significant and reversible decrease in charge transfer of Ca_V2.2 channels under G protein modulation, which might depend on the activated G protein inhibitory pathway.     

Molecular Basis of Regulating High Voltage-Activated Calcium Channels by S-Nitrosylation

Nitric oxide (NO) is involved in a variety of physiological processes, such as vasoregulation and neurotransmission, and has a complex role in the regulation of pain transduction and synaptic transmission. We have shown previously that NO inhibits high voltage-activated Ca²⁺ channels in primary sensory neurons and excitatory synaptic transmission in the spinal dorsal horn. However, the molecular mechanism involved in this inhibitory action remains unclear. In this study, we investigated the role of S-nitrosylation in the NO regulation of high voltage-activated Ca²⁺ channels. The NO donor S-nitroso-N-acetyl-dl-penicillamine (SNAP) rapidly reduced N-type currents when Cav2.2 was coexpressed with the Cavβ1 or Cavβ3 subunits in HEK293 cells. In contrast, SNAP only slightly inhibited P/Q-type and L-type currents reconstituted with various Cavβ subunits. SNAP caused a depolarizing shift in voltage-dependent N-type channel activation, but it had no effect on Cav2.2 protein levels on the membrane surface. The inhibitory effect of SNAP on N-type currents was blocked by the sulfhydryl-specific modifying reagent methanethiosulfonate ethylammonium. Furthermore, the consensus motifs of S-nitrosylation were much more abundant in Cav2.2 than in Cav1.2 and Cav2.1. Site-directed mutagenesis studies showed that Cys-805, Cys-930, and Cys-1045 in the II-III intracellular loop, Cys-1835 and Cys-2145 in the C terminus of Cav2.2, and Cys-346 in the Cavβ3 subunit were nitrosylation sites mediating NO sensitivity of N-type channels. Our findings demonstrate that the consensus motifs of S-nitrosylation in cytoplasmically accessible sites are critically involved in post-translational regulation of N-type Ca²⁺ channels by NO. S-Nitrosylation mediates the feedback regulation of N-type channels by NO.     

Dynamic phospholipid interaction of β2e subunit regulates the gating of voltage-gated Ca2+ channels

High voltage-activated Ca²⁺ (Ca_V) channels are protein complexes containing pore-forming α1 and auxiliary β and α2δ subunits. The subcellular localization and membrane interactions of the β subunits play a crucial role in regulating Ca_V channel inactivation and its lipid sensitivity. Here, we investigated the effects of membrane phosphoinositide (PI) turnover on Ca_V2.2 channel function. The β2 isoform β2e associates with the membrane through electrostatic and hydrophobic interactions. Using chimeric β subunits and liposome-binding assays, we determined that interaction between the N-terminal 23 amino acids of β2e and anionic phospholipids was sufficient for β2e membrane targeting. Binding of the β2e subunit N terminus to liposomes was significantly increased by inclusion of 1% phosphatidylinositol 4,5-bisphosphate (PIP₂) in the liposomes, suggesting that, in addition to phosphatidylserine, PIs are responsible for β2e targeting to the plasma membrane. Membrane binding of the β2e subunit slowed Ca_V2.2 current inactivation. When membrane phosphatidylinositol 4-phosphate and PIP₂ were depleted by rapamycin-induced translocation of pseudojanin to the membrane, however, channel opening was decreased and fast inactivation of Ca_V2.2(β2e) currents was enhanced. Activation of the M₁ muscarinic receptor elicited transient and reversible translocation of β2e subunits from membrane to cytosol, but not that of β2a or β3, resulting in fast inactivation of Ca_V2.2 channels with β2e. These results suggest that membrane targeting of the β2e subunit, which is mediated by nonspecific electrostatic insertion, is dynamically regulated by receptor stimulation, and that the reversible association of β2e with membrane PIs results in functional changes in Ca_V channel gating. The phospholipid–protein interaction observed here provides structural insight into mechanisms of membrane–protein association and the role of phospholipids in ion channel regulation.     

Zebrafish CaV2.1 Calcium Channels Are Tailored for Fast Synchronous Neuromuscular Transmission

The Ca_V2.2 (N-type) and Ca_V2.1 (P/Q-type) voltage-dependent calcium channels are prevalent throughout the nervous system where they mediate synaptic transmission, but the basis for the selective presence at individual synapses still remains an open question. The Ca_V2.1 channels have been proposed to respond more effectively to brief action potentials (APs), an idea supported by computational modeling. However, the side-by-side comparison of Ca_V2.1 and Ca_V2.2 kinetics in intact neurons failed to reveal differences. As an alternative means for direct functional comparison we expressed zebrafish Ca_V2.1 and Ca_V2.2 α-subunits, along with their accessory subunits, in HEK293 cells. HEK cells lack calcium currents, thereby circumventing the need for pharmacological inhibition of mixed calcium channel isoforms present in neurons. HEK cells also have a simplified morphology compared to neurons, which improves voltage control. Our measurements revealed faster kinetics and shallower voltage-dependence of activation and deactivation for Ca_V2.1. Additionally, recordings of calcium current in response to a command waveform based on the motorneuron AP show, directly, more effective activation of Ca_V2.1. Analysis of calcium currents associated with the AP waveform indicate an approximately fourfold greater open probability (P_O) for Ca_V2.1. The efficient activation of Ca_V2.1 channels during APs may contribute to the highly reliable transmission at zebrafish neuromuscular junctions.     

Further characterization of regulation of CaV2.2 by Stargazin

Stargazin, a transmembrane protein expressed in the nervous system, shares similarities with the &gamma;1 subunit of skeletal muscle calcium channels. It was thus termed &gamma;2 subunit of neuronal calcium channels. Stargazin downregulates the expression of Ca_V2 channels, however, its functional modulation of these channels remains debated. We have reported that Stargazin modulates Ca_V2.2 channel by a G&beta;&gamma;-dependent mechanism and suggested that Stargazin is not a true subunit of this channel, since all its effects on channel function are dependent on the presence of G&beta;&gamma;. Moreover, Stargazin also modulated the GIRK channel in a G&beta;&gamma;-dependent fashion. Here we report that G&beta;&gamma;-dependent modulation by Stargazin of the biophysical properties of Ca_V2.2 is unrelated to its negative effect on channel expression and current amplitude. Finally, we suggest that this G&beta;&gamma; dependent modulation of Stargazin may have physiological relevance, since it was still present when we used Ca²⁺ as charge carrier, instead of Ba²⁺     

γ<Subscript>1</Subscript>-Dependent Down-regulation of Recombinant Voltage-gated Ca<Superscript>2+</Superscript> Channels

(1) Voltage-gated Ca²⁺ (Ca_V) channels are multi-subunit membrane complexes that allow depolarization-induced Ca²⁺ influx into cells. The skeletal muscle L-type Ca_V channels consist of an ion-conducting Ca_V1.1 subunit and auxiliary α₂δ−1, β₁ and γ₁ subunits. This complex serves both as a Ca_V channel and as a voltage sensor for excitation–contraction coupling. (2) Though much is known about the mechanisms by which the α₂δ−1 and β₁ subunits regulate Ca_V channel function, there is far less information on the γ₁ subunit. Previously, we characterized the interaction of γ₁ with the other components of the skeletal Ca_V channel complex, and showed that heterologous expression of this auxiliary subunit decreases Ca²⁺ current density in myotubes from γ₁ null mice. (3) In the current report, using Western blotting we show that the expression of the Ca_V1.1 protein is significantly lower when it is heterologously co-expressed with γ₁. Consistent with this, patch-clamp recordings showed that transient transfection of γ₁ drastically inhibited macroscopic currents through recombinant N-type (Ca_V2.2/α₂δ−1/β₃) channels expressed in HEK-293 cells. (4) These findings provide evidence that co-expression of the auxiliary γ₁ subunit results in a decreased expression of the ion-conducting subunit, which may help to explain the reduction in Ca²⁺ current density following γ₁ transfection.     

The HOOK region of β subunits controls gating of voltage-gated Ca2+ channels by electrostatically interacting with plasma membrane

Recently, we showed that the HOOK region of the β2 subunit electrostatically interacts with the plasma membrane and regulates the current inactivation and phosphatidylinositol 4,5-bisphosphate (PIP₂) sensitivity of voltage-gated Ca²⁺ (Ca_V) 2.2 channels. Here, we report that voltage-dependent gating and current density of the Ca_V2.2 channels are also regulated by the HOOK region of the β2 subunit. The HOOK region can be divided into 3 domains: S (polyserine), A (polyacidic), and B (polybasic). We found that the A domain shifted the voltage-dependent inactivation and activation of Ca_V2.2 channels to more hyperpolarized and depolarized voltages, respectively, whereas the B domain evoked these responses in the opposite directions. In addition, the A domain decreased the current density of the Ca_V2.2 channels, while the B domain increased it. Together, our data demonstrate that the flexible HOOK region of the β2 subunit plays an important role in determining the overall Ca_V channel gating properties.