Phosphorylation states greatly regulate the activity and gating properties of Cav3.1 T-type Ca2+ channels

Ca_v3.1 T-type Ca²⁺ channels play pivotal roles in neuronal low-threshold spikes, visceral pain, and pacemaker activity. Phosphorylation has been reported to potently regulate the activity and gating properties of Ca_v3.1 channels. However, systematic identification of phosphorylation sites (phosphosites) in Ca_v3.1 channel has been poorly investigated. In this work, we analyzed rat Ca_v3.1 protein expressed in HEK-293 cells by mass spectrometry, identified 30 phosphosites located at the cytoplasmic regions, and illustrated them as a Ca_v3.1 phosphorylation map which includes the reported mouse Ca_v3.1 phosphosites. Site-directed mutagenesis of the phosphosites to Ala residues and functional analysis of the phospho-silent Ca_v3.1 mutants expressed in Xenopus oocytes showed that the phospho-silent mutation of the N-terminal Ser18 reduced its current amplitude with accelerated current kinetics and negatively shifted channel availability. Remarkably, the phospho-silent mutations of the C-terminal Ser residues (Ser1924, Ser2001, Ser2163, Ser2166, or Ser2189) greatly reduced their current amplitude without altering the voltage-dependent gating properties. In contrast, the phosphomimetic Asp mutations of Ca_v3.1 on the N- and C-terminal Ser residues reversed the effects of the phospho-silent mutations. Collectively, these findings demonstrate that the multiple phosphosites of Ca_v3.1 at the N- and C-terminal regions play crucial roles in the regulation of the channel activity and voltage-dependent gating properties.     

Mechanism underlying the block of human Cav3.2 T-type Ca2+ channels by benidipine, a dihydropyridine Ca2+ channel blocker

AimsBenidipine, a dihydropyridine Ca²⁺ channel blocker, has been reported to block T-type Ca²⁺ channels; however, the mechanism underlying this effect was unclear. In this study, we characterized the mechanism responsible for this blocking activity. Furthermore, the blocking activity was compared between two enantiomers of benidipine, (S, S)- and (R, R)-benidipine.Main methodsHuman Ca_v3.2 (hCa_v3.2) T-type Ca²⁺ channels stably expressed in the human embryonic kidney cell line, HEK-293, were studied in whole-cell patch-clamp recordings and Ca²⁺ mobilization assay.Key findingsIn whole-cell patch-clamp recordings, benidipine blocked hCa_v3.2 T-type Ca²⁺ currents elicited by depolarization to a comparable extent as efonidipine. The block was dependent on stimulation frequency and holding potential, but not test potential. Benidipine significantly shifted the steady-state inactivation curve to the hyperpolarizing direction, but had no effect on the activation curve. Benidipine prolonged the recovery from inactivation of hCa_v3.2 T-type Ca²⁺ channels without any effect on the kinetics of activation, inactivation, or deactivation. In the Ca²⁺ mobilization assay, benidipine was more potent than efonidipine in blocking Ca²⁺ influx through hCa_v3.2 T-type Ca²⁺ channels. (S, S)-Benidipine was more potent than (R, R)-benidipine in blocking hCa_v3.2 T-type Ca²⁺ currents, but there was no difference in blocking the Ca²⁺ influx.SignificanceWe have characterized the blocking activity of benidipine against hCa_v3.2 Ca²⁺ channels and revealed the difference between the two enantiomers of benidipine. The blocking action of benidipine could be mediated by stabilizing hCa_v3.2 Ca²⁺ channels in an inactivated state.     

T-type calcium channel expression and function in the diseased heart

The regulation of intracellular Ca²⁺ is essential for cardiomyocyte function, and alterations in proteins that regulate Ca²⁺ influx have dire consequences in the diseased heart. Low voltage-activated, T-type Ca²⁺ channels are one pathway of Ca²⁺ entry that is regulated according to developmental stage and in pathological conditions in the adult heart. Cardiac T-type channels consist of two main types, Ca_v3.1 (α1G) and Ca_v3.2 (α1H), and both can be induced in the myocardium in disease and injury but still, relatively little is known about mechanisms for their regulation and their respective functions. This article integrates previous data establishing regulation of T-type Ca²⁺ channels in animal models of cardiac disease, with recent data that begin to address the functional consequences of cardiac Ca_v3.1 and Ca_v3.2 Ca²⁺ channel expression in the pathological setting. The putative association of T-type Ca²⁺ channels with Ca²⁺ dependent signaling pathways in the context of cardiac hypertrophy is also discussed.     

Contrasting Effects of Cd<Superscript>2+</Superscript> and Co<Superscript>2+</Superscript> on the Blocking/Unblocking of Human Ca<Subscript>v</Subscript>3 Channels

Inorganic ions have been used widely to investigate biophysical properties of high voltage-activated calcium channels (HVA: Ca_v1 and Ca_v2 families). In contrast, such information regarding low voltage-activated calcium channels (LVA: Ca_v3 family) is less documented. We have studied the blocking effect of Cd²⁺, Co²⁺ and Ni²⁺ on T-currents expressed by human Ca_v3 channels: Ca_v3.1, Ca_v3.2, and Ca_v3.3. With the use of the whole-cell configuration of the patch-clamp technique, we have recorded Ca²⁺ (2 mM) currents from HEK−293 cells stably expressing recombinant T-type channels. Cd²⁺ and Co²⁺ block was 2- to 3-fold more potent for Ca_v3.2 channels (EC₅₀ = 65 and 122 μM, respectively) than for the other two LVA channel family members. Current-voltage relationships indicate that Co²⁺ and Ni²⁺ shift the voltage dependence of Ca_v3.1 and Ca_v3.3 channels activation to more positive potentials. Interestingly, block of those two Ca_v3 channels by Co²⁺ and Ni²⁺ was drastically increased at extreme negative voltages; in contrast, block due to Cd²⁺ was significantly decreased. This unblocking effect was slightly voltage-dependent. Tail-current analysis reveals a differential effect of Cd²⁺ on Ca_v3.3 channels, which can not close while the pore is occupied with this metal cation. The results suggest that metal cations affect differentially T-type channel activity by a mechanism involving the ionic radii of inorganic ions and structural characteristics of the channels pore.     

Epigallocatechin-3-gallate elicits Ca spike in MCF-7 breast cancer cells: Essential role of Cav3.2 channels

We used MCF-7 human breast cancer cells that endogenously express Cav3.1 and Cav3.2 T-type Ca²⁺ channels toward a mechanistic study on the effect of EGCG on [Ca²⁺]_i. Confocal Ca²⁺ imaging showed that EGCG induces a [Ca²⁺]_i spike which is due to extracellular Ca²⁺ entry and is sensitive to catalase and to low-specificity (mibefradil) and high-specificity (Z944) T-type Ca²⁺channel blockers. siRNA knockdown of T-type Ca²⁺ channels indicated the involvement of Cav3.2 but not Cav3.1. Application of EGCG to HEK cells expressing either Cav3.2 or Cav3.1 induced enhancement of Cav3.2 and inhibition of Cav3.1 channel activity. Measurements of K⁺ currents in MCF-7 cells showed a reversible, catalase-sensitive inhibitory effect of EGCG, while siRNA for the Kv1.1 K⁺ channel induced a reduction of the EGCG [Ca²⁺]_i spike. siRNA for Cav3.2 reduced EGCG cytotoxicity to MCF-7 cells, as measured by calcein viability assay. Together, data suggest that EGCG promotes the activation of Cav3.2 channels through K⁺ current inhibition leading to membrane depolarization, and in addition increases Cav3.2 currents. Cav3.2 channels are in part responsible for EGCG inhibition of MCF-7 viability, suggesting that deregulation of [Ca²⁺]_i by EGCG may be relevant in breast cancer treatment.     

Selectivity signatures of three isoforms of recombinant T-type Ca channels

Voltage-gated Ca²⁺ channels (VGCCs) are recognized for their superb ability for the preferred passage of Ca²⁺ over any other more abundant cation present in the physiological saline. Most of our knowledge about the mechanisms of selective Ca²⁺ permeation through VGCCs was derived from the studies on native and recombinant L-type representatives. However, the specifics of the selectivity and permeation of known recombinant T-type Ca²⁺-channel α1 subunits, Ca_v3.1, Ca_v3.2 and Ca_v3.3, are still poorly defined. In the present study we provide comparative analysis of the selectivity and permeation Ca_v3.1, Ca_v3.2, and Ca_v3.3 functionally expressed in Xenopus oocytes. Our data show that all Ca_v3 channels select Ca²⁺ over Na⁺ by affinity. Ca_v3.1 and Ca_v3.2 discriminate Ca²⁺, Sr²⁺ and Ba²⁺ based on the ion's effects on the open channel probability, whilst Ca_v3.3 discriminates based on the ion's intrapore binding affinity. All Ca_v3s were characterized by much smaller difference in the K_D values for Na⁺ current blockade by Ca²⁺ (K_D1 ∼ 6 μM) and for Ca²⁺ current saturation (K_D2 ∼ 2 mM) as compared to L-type channels. This enabled them to carry notable mixed Na⁺/Ca²⁺ current at close to physiological Ca²⁺ concentrations, which was the strongest for Ca_v3.3, smaller for Ca_v3.2 and the smallest for Ca_v3.1. In addition to intrapore Ca²⁺ binding site(s) Ca_v3.2, but not Ca_v3.1 and Ca_v3.3, is likely to possess an extracellular Ca²⁺ binding site that controls channel permeation. Our results provide novel functional tests for identifying subunits responsible for T-type Ca²⁺ current in native cells.     

Pituitary adenylate cyclase-activating peptide (PACAP) recruits low voltage-activated T-type calcium influx under acute sympathetic stimulation in mouse adrenal chromaffin cells

Low voltage-activated T-type Ca_v3.2 calcium channels are expressed in neurosecretory chromaffin cells of the adrenal medulla. Previous studies have shown that naïve adrenal chromaffin cells express a nominal Ca_v3.2-dependent conductance. However, Ca_v3.2 conductance is up-regulated following chronic hypoxia or long term exposure to cAMP analogs. Thus, although a link between chronic stressors and up-regulation of Ca_v3.2 exists, there are no reports testing the specific role of Ca_v3.2 channels in the acute sympathoadrenal stress response. In this study, we examined the effects of acute sympathetic stress on T-type Ca_v3.2 calcium influx in mouse chromaffin cells in situ. Pituitary adenylate cyclase-activating peptide (PACAP) is an excitatory neuroactive peptide transmitter released by the splanchnic nerve under elevated sympathetic activity to stimulate the adrenal medulla. PACAP stimulation did not evoke action potential firing in chromaffin cells but did cause a persistent subthreshold membrane depolarization that resulted in an immediate and robust Ca²⁺-dependent catecholamine secretion. Moreover, PACAP-evoked secretion was sensitive to block by nickel chloride and was acutely inhibited by protein kinase C blockers. We utilized perforated patch electrophysiological recordings conducted in adrenal tissue slices to investigate the mechanism of PACAP-evoked calcium entry. We provide evidence that stimulation with exogenous PACAP and native neuronal stress stimulation both lead to a protein kinase C-mediated phosphodependent recruitment of a T-type Ca_v3.2 Ca²⁺ influx. This in turn evokes catecholamine release during the acute sympathetic stress response.     

Sodium/calcium selectivity of cloned calcium T-type channels

We studied the peculiarities of permeability with respect to the main extracellular cations, Na⁺ and Ca²⁺, of cloned low-threshold calcium channels (LTCCs) of three subtypes, Ca_v3.1 (α1G), Ca_v3.2 (α 1H), and Ca_v3.3 (α1I), functionally expressed in Xenopus oocytes. In a calcium-free solution containing 100 mM Na⁺ and 5 mM calcium-chelating EGTA buffer (to eliminate residual concentrations of Ca²⁺) we observed considerable integral currents possessing the kinetics of inactivation typical of LTCCs and characterized by reversion potentials of −10 ± 1, −12 ± 1, and −18 ± 2 mV, respectively, for Ca_v3.1, Ca_v3.2, and Ca_v3.3 channels. The presence of Ca²⁺ in the extracellular solution exerted an ambiguous effect on the examined currents. On the one hand, Ca²⁺ effectively blocked the current of monovalent cations through cloned LTCCs (K _d = 2, 10, and 18 μM for currents through channels Ca_v3.1, Ca_v3.2, and Ca_v3.3, respectively). On the other hand, at the concentration of 1 to 100 mM, Ca²⁺ itself functioned as a carrier of the inward current. Despite the fact that the calcium current reached the level of saturation in the presence of 5 mM Ca²⁺ in the external solution, extracellular Na⁺ influenced the permeability of these channels even in the presence of 10 mM Ca²⁺. The Ca_v3.3 channels were more permeable with respect to Na⁺ (P _Ca/P _Na ∼ 21) than Ca_v3.1 and Ca_v3.2 (P _Ca/P _Na ∼ 66). As a whole, our data indicate that cloned LTCCs form multi-ion Ca²⁺-selective pores, as these ions possess a high affinity for certain binding sites. Monovalent cations present together with Ca²⁺ in the external solution modulate the calcium permeability of these channels. Among the above-mentioned subtypes, Ca_v3.3 channels show the minimum selectivity with respect to Ca²⁺ and are most permeable for monovalent cations. Neirofiziologiya/Neurophysiology, Vol. 38, No. 3, pp. 183–192, May–June, 2006.     

Endogenous and exogenous hydrogen sulfide facilitates T-type calcium channel currents in Cav3.2-expressing HEK293 cells

Hydrogen sulfide (H₂S), a gasotransmitter, is formed from l-cysteine by multiple enzymes including cystathionine-γ-lyase (CSE). We have shown that an H₂S donor, NaHS, causes hyperalgesia in rodents, an effect inhibited by knockdown of Ca_v3.2 T-type Ca²⁺ channels (T-channels), and that NaHS facilitates T-channel-dependent currents (T-currents) in NG108-15 cells that naturally express Ca_v3.2. In the present study, we asked if endogenous and exogenous H₂S participates in regulation of the channel functions in Ca_v3.2-transfected HEK293 (Ca_v3.2-HEK293) cells. dl-Propargylglycine (PPG), a CSE inhibitor, significantly decreased T-currents in Ca_v3.2-HEK293 cells, but not in NG108-15 cells. NaHS at 1.5 mM did not affect T-currents in Ca_v3.2-HEK293 cells, but enhanced T-currents in NG108-15 cells. In the presence of PPG, NaHS at 1.5 mM, but not 0.1–0.3 mM, increased T-currents in Ca_v3.2-HEK293 cells. Similarly, Na₂S, another H₂S donor, at 0.1–0.3 mM significantly increased T-currents in the presence, but not absence, of PPG in Ca_v3.2-HEK293 cells. Expression of CSE was detected at protein and mRNA levels in HEK293 cells. Intraplantar administration of Na₂S, like NaHS, caused mechanical hyperalgesia, an effect blocked by NNC 55-0396, a T-channel inhibitor. The in vivo potency of Na₂S was higher than NaHS. These results suggest that the function of Ca_v3.2 T-channels is tonically enhanced by endogenous H₂S synthesized by CSE in Ca_v3.2-HEK293 cells, and that exogenous H₂S is capable of enhancing Ca_v3.2 function when endogenous H₂S production by CSE is inhibited. In addition, Na₂S is considered a more potent H₂S donor than NaHS in vitro as well as in vivo.     

In vitro and in vivo phosphorylation of the Cav2.3 voltage-gated R-type calcium channel

During the recording of whole cell currents from stably transfected HEK-293 cells, the decline of currents carried by the recombinant human Cav2.3+β3 channel subunits is related to adenosine triphosphate (ATP) depletion after rupture of the cells. It reduces the number of functional channels and leads to a progressive shift of voltage-dependent gating to more negative potentials (Neumaier F., et al., 2018). Both effects can be counteracted by hydrolysable ATP, whose protective action is almost completely prevented by inhibition of serine/threonine but not tyrosine or lipid kinases. These findings indicate that ATP promotes phosphorylation of either the channel or an associated protein, whereas dephosphorylation during cell dialysis results in run-down. Protein phosphorylation is required for Ca_v2.3 channel function and could directly influence the normal features of current carried by these channels. Therefore, results from in vitro and in vivo phosphorylation of Ca_v2.3 are summarized to come closer to a functional analysis of structural variations in Ca_v2.3 splice variants.     

Regulation of L-type CaV1.3 channel activity and insulin secretion by the cGMP-PKG signaling pathway

cGMP is a second messenger widely used in the nervous system and other tissues. One of the major effectors for cGMP is the serine/threonine protein kinase, cGMP-dependent protein kinase (PKG), which catalyzes the phosphorylation of a variety of proteins including ion channels. Previously, it has been shown that the cGMP-PKG signaling pathway inhibits Ca²⁺ currents in rat vestibular hair cells and chromaffin cells. This current allegedly flow through voltage-gated Ca_V1.3L-type Ca²⁺ channels, and is important for controlling vestibular hair cell sensory function and catecholamine secretion, respectively. Here, we show that native L-type channels in the insulin-secreting RIN-m5F cell line, and recombinant Ca_V1.3 channels heterologously expressed in HEK-293 cells, are regulatory targets of the cGMP-PKG signaling cascade. Our results indicate that the Ca_Vα₁ ion-conducting subunit of the Ca_V1.3 channels is highly expressed in RIN-m5F cells and that the application of 8-Br-cGMP, a membrane-permeable analogue of cGMP, significantly inhibits Ca²⁺ macroscopic currents and impair insulin release stimulated with high K⁺. In addition, KT-5823, a specific inhibitor of PKG, prevents the current inhibition generated by 8-Br-cGMP in the heterologous expression system. Interestingly, mutating the putative phosphorylation sites to residues resistant to phosphorylation showed that the relevant PKG sites for Ca_V1.3 L-type channel regulation centers on two amino acid residues, Ser793 and Ser860, located in the intracellular loop connecting the II and III repeats of the Ca_Vα₁ pore-forming subunit of the channel. These findings unveil a novel mechanism for how the cGMP-PKG signaling pathway may regulate Ca_V1.3 channels and contribute to regulate insulin secretion.     

The role of STIM1 in the receptor- and store-operated calcium influx in HEK293 cells

The possible role of STIM1 protein in the regulation of activity of receptor- and store-operated Ca²⁺ channels in non-excitable cells has been studied. Receptor- and store-operated Ca²⁺ influxes have been measured using the fluorescent method of detection of cytosolic Ca²⁺ concentration and the electrophysiological methods of whole-cell and single-channel current recordings in the control HEK293 cells and in HEK293 cells with suppressed expression of STIM1. The experiments have shown that STIM1 suppression results in a reduction of the amplitudes of both receptor- and store-operated inward calcium currents. The decrease of total Ca²⁺ influx of in response to an agonist or to passive depletion of calcium stores upon STIM1 suppression was due to the decrease or total absence of the activity of high-conductance channels I_max and non-selective channels I_ns in HEK293 cells. A decrease in the STIM1 amount also altered the activity regulation of low-conductance I_min channels that changed from exclusively agonist-operated into store-dependent channels in HEK293 cells.     

Ca<Subscript>v</Subscript>1.3 and BK Channels for Timing and Regulating Cell Firing

L-type Ca²⁺ channels (LTCCs, Ca_v1) open readily during membrane depolarization and allow Ca²⁺ to enter the cell. In this way, LTCCs regulate cell excitability and trigger a variety of Ca²⁺-dependent physiological processes such as: excitation–contraction coupling in muscle cells, gene expression, synaptic plasticity, neuronal differentiation, hormone secretion, and pacemaker activity in heart, neurons, and endocrine cells. Among the two major isoforms of LTCCs expressed in excitable tissues (Ca_v1.2 and Ca_v1.3), Ca_v1.3 appears suitable for supporting a pacemaker current in spontaneously firing cells. It has steep voltage dependence and low threshold of activation and inactivates slowly. Using Ca_v1.3^−/− KO mice and membrane current recording techniques such as the dynamic and the action potential clamp, it has been possible to resolve the time course of Ca_v1.3 pacemaker currents that regulate the spontaneous firing of dopaminergic neurons and adrenal chromaffin cells. In several cell types, Ca_v1.3 is selectively coupled to BK channels within membrane nanodomains and controls both the firing frequency and the action potential repolarization phase. Here we review the most critical aspects of Ca_v1.3 channel gating and its coupling to large conductance BK channels recently discovered in spontaneously firing neurons and neuroendocrine cells with the aim of furnishing a converging view of the role that these two channel types play in the regulation of cell excitability.     

T-type Channels Become Highly Permeable to Sodium Ions Using an Alternative Extracellular Turret Region (S5-P) Outside the Selectivity Filter

T-type (Ca_v3) channels are categorized as calcium channels, but invertebrate ones can be highly sodium-selective channels. We illustrate that the snail LCa_v3 T-type channel becomes highly sodium-permeable through exon splicing of an extracellular turret and descending helix in domain II of the four-domain Ca_v3 channel. Highly sodium-permeable T-type channels are generated without altering the invariant ring of charged residues in the selectivity filter that governs calcium selectivity in calcium channels. The highly sodium-permeant T-type channel expresses in the brain and is the only splice isoform expressed in the snail heart. This unique splicing of turret residues offers T-type channels a capacity to serve as a pacemaking sodium current in the primitive heart and brain in lieu of Na_v1-type sodium channels and to substitute for voltage-gated sodium channels lacking in many invertebrates. T-type channels would also contribute substantially to sodium leak conductances at rest in invertebrates because of their large window currents.     

Cyclic GMP–gated Channels in a Sympathetic Neuron Cell Line

The stimulation of IP₃ production by muscarinic agonists causes both intracellular Ca²⁺ release and activation of a voltage-independent cation current in differentiated N1E-115 cells, a neuroblastoma cell line derived from mouse sympathetic ganglia. Earlier work showed that the membrane current requires an increase in 3′,5′-cyclic guanosine monophosphate (cGMP) produced through the NO-synthase/guanylyl cyclase cascade and suggested that the cells may express cyclic nucleotide–gated ion channels. This was tested using patch clamp methods. The membrane permeable cGMP analogue, 8-br-cGMP, activates Na⁺ permeable channels in cell attached patches. Single channel currents were recorded in excised patches bathed in symmetrical Na⁺ solutions. cGMP-dependent single channel activity consists of prolonged bursts of rapid openings and closings that continue without desensitization. The rate of occurrence of bursts as well as the burst length increase with cGMP concentration. The unitary conductance in symmetrical 160 mM Na⁺ is 47 pS and is independent of voltage in the range −50 to +50 mV. There is no apparent effect of voltage on opening probability. The dose response curve relating cGMP concentration to channel opening probability is fit by the Hill equation assuming an apparent K _D of 10 μm and a Hill coefficient of 2. In contrast, cAMP failed to activate the channel at concentrations as high as 100 μm. Cyclic nucleotide gated (CNG) channels in N1E-115 cells share a number of properties with CNG channels in sensory receptors. Their presence in neuronal cells provides a mechanism by which activation of the NO/cGMP pathway by G-protein–coupled neurotransmitter receptors can directly modify Ca²⁺ influx and electrical excitability. In N1E-115 cells, Ca²⁺ entry by this pathway is necessary to refill the IP₃-sensitive intracellular Ca²⁺ pool during repeated stimulation and CNG channels may play a similar role in other neurons.     

Eps15 Homology Domain-containing Protein 3 Regulates Cardiac T-type Ca2+ Channel Targeting and Function in the Atria

Proper trafficking of membrane-bound ion channels and transporters is requisite for normal cardiac function. Endosome-based protein trafficking of membrane-bound ion channels and transporters in the heart is poorly understood, particularly in vivo. In fact, for select cardiac cell types such as atrial myocytes, virtually nothing is known regarding endosomal transport. We previously linked the C-terminal Eps15 homology domain-containing protein 3 (EHD3) with endosome-based protein trafficking in ventricular cardiomyocytes. Here we sought to define the roles and membrane protein targets for EHD3 in atria. We identify the voltage-gated T-type Ca²⁺ channels (Ca_V3.1, Ca_V3.2) as substrates for EHD3-dependent trafficking in atria. Mice selectively lacking EHD3 in heart display reduced expression and targeting of both Ca_v3.1 and Ca_V3.2 in the atria. Furthermore, functional experiments identify a significant loss of T-type-mediated Ca²⁺ current in EHD3-deficient atrial myocytes. Moreover, EHD3 associates with both Ca_V3.1 and Ca_V3.2 in co-immunoprecipitation experiments. T-type Ca²⁺ channel function is critical for proper electrical conduction through the atria. Consistent with these roles, EHD3-deficient mice demonstrate heart rate variability, sinus pause, and atrioventricular conduction block. In summary, our findings identify Ca_V3.1 and Ca_V3.2 as substrates for EHD3-dependent protein trafficking in heart, provide in vivo data on endosome-based trafficking pathways in atria, and implicate EHD3 as a key player in the regulation of atrial myocyte excitability and cardiac conduction.     

Cooperative regulation of Cav1.2 channels by intracellular Mg2+, the proximal C-terminal EF-hand,and the distal C-terminal domain

L-type Ca²⁺ currents conducted by Ca_v1.2 channels initiate excitation–contraction coupling in cardiac myocytes. Intracellular Mg²⁺ (Mg_i) inhibits the ionic current of Ca_v1.2 channels. Because Mg_i is altered in ischemia and heart failure, its regulation of Ca_v1.2 channels is important in understanding cardiac pathophysiology. Here, we studied the effects of Mg_i on voltage-dependent inactivation (VDI) of Ca_v1.2 channels using Na⁺ as permeant ion to eliminate the effects of permeant divalent cations that engage the Ca²⁺-dependent inactivation process. We confirmed that increased Mg_i reduces peak ionic currents and increases VDI of Ca_v1.2 channels in ventricular myocytes and in transfected cells when measured with Na⁺ as permeant ion. The increased rate and extent of VDI caused by increased Mg_i were substantially reduced by mutations of a cation-binding residue in the proximal C-terminal EF-hand, consistent with the conclusion that both reduction of peak currents and enhancement of VDI result from the binding of Mg_i to the EF-hand (K_D ≈ 0.9 mM) near the resting level of Mg_i in ventricular myocytes. VDI was more rapid for L-type Ca²⁺ currents in ventricular myocytes than for Ca_v1.2 channels in transfected cells. Coexpression of Ca_vβ_2b subunits and formation of an autoinhibitory complex of truncated Ca_v1.2 channels with noncovalently bound distal C-terminal domain (DCT) both increased VDI in transfected cells, indicating that the subunit structure of the Ca_v1.2 channel greatly influences its VDI. The effects of noncovalently bound DCT on peak current amplitude and VDI required Mg_i binding to the proximal C-terminal EF-hand and were prevented by mutations of a key divalent cation-binding amino acid residue. Our results demonstrate cooperative regulation of peak current amplitude and VDI of Ca_v1.2 channels by Mg_i, the proximal C-terminal EF-hand, and the DCT, and suggest that conformational changes that regulate VDI are propagated from the DCT through the proximal C-terminal EF-hand to the channel-gating mechanism.     

Intracellular Ca(2+) oscillations induced by over-expressed Ca(V)3.1 T-type Ca(2+) channels in NG108-15 cells

T-type Ca²⁺ channel family includes three subunits Ca_V3.1, Ca_V3.2 and Ca_V3.3 and have been shown to control burst firing and intracellular Ca²⁺ concentration ([Ca²⁺]_i) in neurons. Here, we investigated whether Ca_V3.1 channels could generate a pacemaker current and contribute to cell excitability. Ca_V3.1 clones were over-expressed in the neuronal cell line NG108-15. Ca_V3.1 channel expression induced repetitive action potentials, generating spontaneous membrane potential oscillations (MPOs) and concomitant [Ca²⁺]_i oscillations. These oscillations were inhibited by T-type channels antagonists and were present only if the membrane potential was around −61 mV. [Ca²⁺]_i oscillations were critically dependent on Ca²⁺ influx through Ca_V3.1 channels and did not involve Ca²⁺ release from the endoplasmic reticulum. The waveform and frequency of the MPOs are constrained by electrophysiological properties of the Ca_V3.1 channels. The trigger of the oscillations was the Ca_V3.1 window current. This current induced continuous [Ca²⁺]_i increase at −60 mV that depolarized the cells and triggered MPOs. Shifting the Ca_V3.1 window current potential range by increasing the external Ca²⁺ concentration resulted in a corresponding shift of the MPOs threshold. The hyperpolarization-activated cation current (I_h) was not required to induce MPOs, but when expressed together with Ca_V3.1 channels, it broadened the membrane potential range over which MPOs were observed. Overall, the data demonstrate that the Ca_V3.1 window current is critical in triggering intrinsic electrical and [Ca²⁺]_i oscillations.