A novel role of the L-type calcium channel α1D subunit as a gatekeeper for intracellular zinc signaling: zinc wave

Recent studies have shown that zinc ion (Zn) can behave as an intracellular signaling molecule. We previously demonstrated that mast cells stimulated through the high-affinity IgE receptor (FcεRI) rapidly release intracellular Zn from the endoplasmic reticulum (ER), and we named this phenomenon the "Zn wave". However, the molecules responsible for releasing Zn and the roles of the Zn wave were elusive. Here we identified the pore-forming α(1) subunit of the Cav1.3 (α(1D)) L-type calcium channel (LTCC) as the gatekeeper for the Zn wave. LTCC antagonists inhibited the Zn wave, and an agonist was sufficient to induce it. Notably, α(1D) was mainly localized to the ER rather than the plasma membrane in mast cells, and the Zn wave was impaired by α(1D) knockdown. We further found that the LTCC-mediated Zn wave positively controlled cytokine gene induction by enhancing the DNA-binding activity of NF-κB. Consistent with this finding, LTCC antagonists inhibited the cytokine-mediated delayed-type allergic reaction in mice without affecting the immediate-type allergic reaction. These findings indicated that the LTCC α(1D) subunit located on the ER membrane has a novel function as a gatekeeper for the Zn wave, which is involved in regulating NF-κB signaling and the delayed-type allergic reaction.     

L-type calcium channel β subunit modulates angiotensin II responses in cardiomyocytes

Angiotensin II regulation of L-type calcium currents in cardiac muscle is controversial and the underlying signaling events are not completely understood. Moreover, the possible role of auxiliary subunit composition of the channels in Angiotensin II modulation of L-type calcium channels has not yet been explored. In this work we study the role of Ca_vβ subunits and the intracellular signaling responsible for L-type calcium current modulation by Angiotensin II. In cardiomyocytes, Angiotensin II exposure induces rapid inhibition of L-type current with a magnitude that is correlated with the rate of current inactivation. Semi-quantitative PCR of cardiomyocytes at different days of culture reveals changes in the Ca_vβ subunits expression pattern that are correlated with the rate of current inactivation and with Angiotensin II effect. Over-expression of individual b subunits in heterologous systems reveals that the magnitude of Angiotensin II inhibition is dependent on the Ca_vβ subunit isoform, with _Cavβ1bcontaining channels being more strongly regulated. _Cavβ2acontaining channels were insensitive to modulation and this effect was partially due to the N-terminal palmitoylation sites of this subunit. Moreover, PLC or diacylglycerol lipase inhibition prevents the Angiotensin II effect on L-type calcium channels, while PKC inhibition with chelerythrine does not, suggesting a role of arachidonic acid in this process. Finally, we show that in intact cardiomyocytes the magnitude of calcium transients on spontaneous beating cells is modulated by Angiotensin II in a Ca_vβ subunit-dependent manner. These data demonstrate that Ca_vβ subunits alter the magnitude of inhibition of L-type current by Angiotensin II.     

L-type calcium channel β subunit modulates angiotensin II responses in cardiomyocytes

Angiotensin II regulation of L-type calcium currents in cardiac muscle is controversial and the underlying signaling events are not completely understood. Moreover, the possible role of auxiliary subunit composition of the channels in Angiotensin II modulation of L-type calcium channels has not yet been explored. In this work we study the role of Ca(v)β subunits and the intracellular signaling responsible for L-type calcium current modulation by Angiotensin II. In cardiomyocytes, Angiotensin II exposure induces rapid inhibition of L-type current with a magnitude that is correlated with the rate of current inactivation. Semi-quantitative PCR of cardiomyocytes at different days of culture reveals changes in the Ca(v)β subunits expression pattern that are correlated with the rate of current inactivation and with Angiotensin II effect. Over-expression of individual b subunits in heterologous systems reveals that the magnitude of Angiotensin II inhibition is dependent on the Ca(v)β subunit isoform, with Ca(v)β(1b) containing channels being more strongly regulated. Ca(v)β(2a) containing channels were insensitive to modulation and this effect was partially due to the N-terminal palmitoylation sites of this subunit. Moreover, PLC or diacylglycerol lipase inhibition prevents the Angiotensin II effect on L-type calcium channels, while PKC inhibition with chelerythrine does not, suggesting a role of arachidonic acid in this process. Finally, we show that in intact cardiomyocytes the magnitude of calcium transients on spontaneous beating cells is modulated by Angiotensin II in a Ca(v)β subunit-dependent manner. These data demonstrate that Ca(v)β subunits alter the magnitude of inhibition of L-type current by Angiotensin II.     

Drugging the undruggable: gabapentin,pregabalin and the calcium channel α2δ subunit

In the post-genomic era, the idea of using the sequence of a protein to determine its potential role as a drug target has gained currency. The goal of this approach to drug discovery is to use the sequence of a protein that is known to bind a specific ligand or drug, along with the known structure of the ligand binding site, to predict other similar proteins that are also “druggable”. Gabapentin (Neurontin) and pregabalin (Lyrica) are drugs currently in the clinic that were developed based on the hypothesis that generating non-hydrolyzable analogs of GABA would lead to the development of antiepileptic agents. While these compounds are indeed good anticonvulsants, their activity is surprisingly not due to activity in the GABAergic system. By purifying the protein to which gabapentin bound, and determining its identity as the α₂δ₁ subunit of voltage gated calcium channels, it was possible to make progress in developing new compounds with similar activities to gabapentin, including pregabalin. The recognition of the α₂δ₁ subunit as the receptor for these drugs also meant that related proteins, such as α₂δ₃, may be interesting targets for novel pain therapeutics.     

cAMP-dependent phosphorylation of the cardiac L-type Ca channel: A missing link?

Cardiac inotropic effects of β adrenergic agonists occur mainly through an increase in L-type (class C) calcium channel activity. This response has been attributed to phosphorylation of the L-type Ca channel, or a closely associated protein, by the cAMP-dependent protein kinase A (PKA). Among the three subunits forming the cardiac L-type Ca channel (α1, β and α2-δ), biochemical studies have revealed that two subunits, α1 and β, are phosphorylated in vitro by protein kinase A, the α1 subunit being the primary target. However, attempts to reconstitute the cAMP-dependent regulation of the expressed class C Ca channel, either in Xenopus oocytes or in cell lines, have provided contradictory results. We were unable to detect cAMP-dependent modulation of class C α1 subunit Ca channels expressed in Xenopus oocytes, even when coinjected with auxiliary subunits β and α2-δ. Nevertheless, activity of Ca channels recorded from cardiac-mRNA injected oocytes was potentiated by injection of cAMP or PKA, even when expression of the β subunit was suppressed using antisense oligonucleotide. Taken together, these results indicate that cAMP-dependent regulation does not exclusively involve the α1 and the β subunits of the Ca channel and suggest that unidentified protein(s), expressed in cardiac tissue, are most likely necessary.     

L-type calcium channel: Clarifying the “oxygen sensing hypothesis”

The heart is able to respond acutely to changes in oxygen tension. Since ion channels can respond rapidly to stimuli, the “ion channel oxygen sensing hypothesis” has been proposed to explain acute adaptation of cells to changes in oxygen demand. However the exact mechanism for oxygen sensing continues to be debated. Mitochondria consume the lion’s share of oxygen in the heart, fuelling the production of ATP that drives excitation and contraction. Mitochondria also produce reactive oxygen species that are capable of altering the redox state of proteins. The cardiac L-type calcium channel is responsible for maintaining excitation and contraction. Recently, the reactive cysteine on the cardiac L-type calcium channel was identified. These data clarified that the channel does not respond directly to changes in oxygen tension, but rather responds to cellular redox state. This leads to acute alterations in cell signalling responsible for the development of arrhythmias and pathology.     

Skeletal muscle cells express different isoforms of the calcium channel α2/δ subunit

We examined developmental changes in calcium channel alpha2/delta subunit mRNA in skeletal muscle and their possible influence on L-type calcium currents (ICa-L). Several isoforms of alpha2/delta-1 mRNA were found in myotubes and muscle fibers, and their relative levels changed with time in culture or age of the animal. Levels of alpha2/delta-1a were largest in older myotubes and was the only alpha2/delta-1 isoform present in adult muscle. Both myotubes and muscle fibers also expressed low levels of alpha2/delta-2 and alpha2/delta-3 mRNA at all ages. alpha2/delta-4 mRNA could not be detected in either myotubes or muscle fibers. Changes in amplitude and voltage-dependent inactivation of the ICa-L concurred with the shift in alpha2/delta-1 isoform message, suggesting that alternative splicing of this subunit might be important for modulation of ICa-L.     

Expression pattern of voltage-dependent calcium channel α1 and β subunits in adrenal gland of N-type Ca2+ channel α1B subunit gene-deficient mice

The Ca²⁺ channel _1B subunit is a pore-forming component capable of generating N-type Ca²⁺ channel activity. Although N-type Ca²⁺ channel plays a role in a variety of neuronal functions, _1B-deficient mice exhibit normal life span without apparent abnormalities of behavior, histology or plasma norepinephrine level, presumably owing to compensation by some other Ca²⁺ channel ₁ or subunit. In this study, we studied the levels of _1A, _1C, _1D, _1E, ₁, ₂, ₃ and ₄ mRNAs in adrenal gland of _1B-deficient mice. The _1A mRNA in homozygous mice was expressed at higher level than in wild or heterozygous mice, but no difference in the expression levels of _1C, _1D, _1E, ₁, ₂, ₃ and ₄ was found among wild, heterozygous and homozygous mice. The protein level of _1A in homozygous mice was also expressed at higher level than in wild or heterozygous mice. To examine whether increased expression is induced by cis-regulatory element within 5-upstream region of _1A gene, we examined lacZ expression in _1B-deficient × _1A6.3-lacZ mice (carrying a 6.3-kb 5-upstream fragment of _1A gene fused to E. coli lacZ reporter gene), which express lacZ in medullar chromaffin cells, but not in cortex. The levels of lacZ expression in homozygous _1B-deficient × _1A6.3-lacZ mice were higher than in wild or heterozygous mice. Therefore, a possible explanation of the normal behavior and plasma norepinephrine level of _1B-deficient mice is that compensation by _1A subunit occurs and that 6.3-kb 5-upstream region of _1A gene contains enhancer cis-element(s) for compensation in adrenal medulla chromaffin cells. (Mol Cell Biochem 271: 91–99, 2005)     

Calcium currents recorded from a neuronal α1C L-type calcium channel in Xenopus oocytes

Xenopus oocytes expressing neuronal α_1C, α₂ and β_1b calcium channel subunit cDNAs were used in this study. During two-electric voltage clamp recording the oocyte was injected with 10–20 nl of a 100 mM BAPTA solution. Under these conditions, the endogenous Ca-activated Cl current was completely suppressed resulting in an α_1C Ba current free from Cl current contamination. BAPTA injection also allowed α_1C currents with different permeating ions, including Ca, to be examined. Compared to Ba and Sr, α_1C whole cell Ca currents were smaller in magnitude and showed kinetic and voltage-dependent properties more similar to those for L-type Ca currents recorded in native cells. That Ca-dependent inactivation occurs in BAPTA-buffered cells suggests that the Ca-binding site involved in this type of inactivation is very close to the pore of the channel.     

Immunolocalization of voltage-gated calcium channel α1 subunits in the chinchilla cochlea

The immunohistochemical localization of 1A, 1B, 1C, 1D, and 1E voltage-gated calcium channel subunits was investigated in the chinchilla organ of Corti and spiral ganglia with the use of specific antipeptide antibodies. The inner and outer hair cells were immunoreactive for 1A and 1D subunit antibodies. 1C immunoreactivity localized to the nerve terminals innervating inner hair cells and the basal pole of the outer hair cell. There was only non-specific staining to 1B and 1E. Supporting cells were non-immunoreactive. Spiral ganglia neurons were 1B, 1C, and 1D immunoreactive. A few spiral ganglia neurons were 1E immunoreactive. The importance of 1D, the pore-forming subunit of the L-type channel, in outer and inner hair cell function has been clearly demonstrated in electrophysiological, molecular biological, and knockout models. The presence of 1A, the pore-forming subunit of the P/Q type channels, has not previously been demonstrated in inner and outer hair cells, and its function in the cochlear hair cell is unknown.The National Institutes of Health grants AG09693-10, DC005224, 00140-02, and DC05187-01 supported this work.     

The role of the C-terminus of human α-synuclein: intra-disulfide bonds between the C-terminus and other regions stabilize non-fibrillar monomeric isomers

Substantial evidence implicates that the aggregation of α-synuclein (αSyn) is a critical factor in the pathogenesis of Parkinson’s disease. This study focuses on the role of αSyn C-terminus. We introduced two additional cysteine residues at positions 107 and 124 (A107C and A124C) to our previous construct. Five X-isomers of oxidative-folded mutation of α-synuclein with three disulfides were isolated and their secondary structures and aggregating features were analyzed. All isomers showed similar random coil structures as wild-type α-synuclein. However, these isomers did not form aggregates or fibrils, even with prolonged incubation, suggesting that the interactions between the C-terminal and N-terminal or central NAC region are important in maintaining the natively unfolded structure of αSyn and thus prevent αSyn from changing conformation, which is a critical step for fibrillation.     

Interactions between N and C termini of α1C subunit regulate inactivation of CaV1.2 L-type Ca2+ channel

The modulation and regulation of voltage-gated Ca²⁺ channels is affected by the pore-forming segments, the cytosolic parts of the channel, and interacting intracellular proteins. In this study we demonstrate a direct physical interaction between the N terminus (NT) and C terminus (CT) of the main subunit of the L-type Ca²⁺ channel Ca_V1.2, α_1C, and explore the importance of this interaction for the regulation of the channel. We used biochemistry to measure the strength of the interaction and to map the location of the interaction sites, and electrophysiology to investigate the functional impact of the interaction. We show that the full-length NT (amino acids 1-154) and the proximal (close to the plasma membrane) part of the CT, pCT (amino acids 1508-1669) interact with sub-micromolar to low-micromolar affinity. Calmodulin (CaM) is not essential for the binding. The results further suggest that the NT-CT interaction regulates the channel's inactivation, and that Ca²⁺, presumably through binding to calmodulin (CaM), reduces the strength of NT-CT interaction. We propose a molecular mechanism in which NT and CT of the channel serve as levers whose movements regulate inactivation by promoting changes in the transmembrane core of the channel via S1 (NT) or S6 (pCT) segments of domains I and IV, accordingly, and not as a kind of pore blocker. We hypothesize that Ca²⁺-CaM-induced changes in NT-CT interaction may, in part, underlie the acceleration of Ca_V1.2 inactivation induced by Ca²⁺ entry into the cell.     

Genetic characterization of a new splice variant of the β2 subunit of the voltage-dependent calcium channel

This study reports a novel splice variant form of the voltage-dependent calcium channel ₂ subunit (_2g). This variant is composed of the conserved amino-terminal sequences of the _2a subunit, but lacks the -subunit interaction domain (BID), which is thought essential for interactions with the ₁ subunit. Gene structure analysis revealed that this gene was composed of 13 translated exons spread over 107 kb of the genome. The gene structure of the ₂ subunit was similar in exon-intron organization to the murine ₃ and human ₄ subunits. Electrophysiological evaluation revealed that _2a and _2g affected channel properties in different ways. The _2a subunit increased the peak amplitude, but failed to increase channel inactivation, while _2g had no significant effects on either the peak current amplitude or channel inactivation. Other subunits, such as ₃ and ₄, significantly increased the peak current and accelerated current inactivation.     

Spatial association of the Cav1.2 calcium channel with α5β1-integrin

Engagement of α(5)β(1)-integrin by fibronectin (FN) acutely enhances Cav1.2 channel (Ca(L)) current in rat arteriolar smooth muscle and human embryonic kidney cells (HEK293-T) expressing Ca(L). Using coimmunoprecipitation strategies, we show that coassociation of Ca(L) with α(5)- or β(1)-integrin in HEK293-T cells is specific and depends on cell adhesion to FN. In rat arteriolar smooth muscle, coassociations between Ca(L) and α(5)β(1)-integrin and between Ca(L) and phosphorylated c-Src are also revealed and enhanced by FN treatment. Using site-directed mutagenesis of Ca(L) heterologously expressed in HEK293-T cells, we identified two regions of Ca(L) required for these interactions: 1) COOH-terminal residues Ser(1901) and Tyr(2122), known to be phosphorylated by protein kinase A (PKA) and c-Src, respectively; and 2) two proline-rich domains (PRDs) near the middle of the COOH terminus. Immunofluorescence confocal imaging revealed a moderate degree of wild-type Ca(L) colocalization with β(1)-integrin on the plasma membrane. Collectively, our results strongly suggest that 1) upon ligation by FN, Ca(L) associates with α(5)β(1)-integrin in a macromolecular complex including PKA, c-Src, and potentially other protein kinases; 2) phosphorylation of Ca(L) at Y(2122) and/or S(1901) is required for association of Ca(L) with α(5)β(1)-integrin; and 3) c-Src, via binding to PRDs that reside in the II-III linker region and/or the COOH terminus of Ca(L), mediates current potentiation following α(5)β(1)-integrin engagement. These findings provide new evidence for how interactions between α(5)β(1)-integrin and FN can modulate Ca(L) entry and consequently alter the physiological function of multiple types of excitable cells.     

Atypical properties of a conventional calcium channel β subunit from the platyhelminth Schistosoma mansoni

Background

Serotonin induces fluid secretion from Calliphora salivary glands by the parallel activation of the InsP₃/Ca²⁺ and cAMP signaling pathways. We investigated whether cAMP affects 5-HT-induced Ca²⁺ signaling and InsP₃-induced Ca²⁺ release from the endoplasmic reticulum (ER).

Results

Increasing intracellular cAMP level by bath application of forskolin, IBMX or cAMP in the continuous presence of threshold 5-HT concentrations converted oscillatory [Ca²⁺]_i changes into a sustained increase. Intraluminal Ca²⁺ measurements in the ER of β-escin-permeabilized glands with mag-fura-2 revealed that cAMP augmented InsP₃-induced Ca²⁺ release in a concentration-dependent manner. This indicated that cAMP sensitized the InsP₃ receptor Ca²⁺ channel for InsP₃. By using cAMP analogs that activated either protein kinase A (PKA) or Epac and the application of PKA-inhibitors, we found that cAMP-induced augmentation of InsP₃-induced Ca²⁺ release was mediated by PKA not by Epac. Recordings of the transepithelial potential of the glands suggested that cAMP sensitized the InsP₃/Ca²⁺ signaling pathway for 5-HT, because IBMX potentiated Ca²⁺-dependent Cl^- transport activated by a threshold 5-HT concentration.

Conclusion

This report shows, for the first time for an insect system, that cAMP can potentiate InsP₃-induced Ca²⁺ release from the ER in a PKA-dependent manner, and that this crosstalk between cAMP and InsP₃/Ca²⁺ signaling pathways enhances transepithelial electrolyte transport.     

The calcium channel α2/δ1 subunit interacts with ATP5b in the plasma membrane of developing muscle cells

The α2/δ1 and α(1)1.1 subunits are present at a 1:1 ratio in the dihydropyridine receptor (DHPR) from adult skeletal muscle. In contrast, during early myotube development α2/δ1 is present at higher levels than α(1)1.1 and localizes at the ends of the cells, suggesting that α2/δ1 may have a role independent from DHPRs. We sought to identify binding partners of α2/δ1 at a period when levels of α(1)1.1 are low. Analysis of protein complexes in their native configuration established that α2/δ1 may be associating with ATP5b, a subunit of a mitochondrial ATP synthase complex. This interaction was confirmed with fluorescence resonance energy transfer and coimmunoprecipitation. The association of α2/δ1 and ATP5b occurs in intracellular membranes and at the plasma membrane, where they form a functional signaling complex capable of accelerating the rate of decline of calcium transients. The acceleration of decay was more evident when myotubes were stimulated with a train of pulses. Our data indicate that the α2/δ1 subunit is not only part of the DHPR but that it may interact with other cellular components in developing myotubes, such as the ATP5b in its atypical localization in the plasma membrane.