The structure and functioning of the couplon in the mammalian cardiomyocyte

The couplons of the cardiomyocyte form nanospaces within the cell that place the L-type calcium channel (Ca_v1.2), situated on the plasmalemma, in opposition to the type 2 ryanodine receptor (RyR2), situated on the sarcoplasmic reticulum. These two molecules, which form the basis of excitation–contraction coupling, are separated by a very limited space, which allows a few Ca²⁺ ions passing through Ca_v1.2 to activate the RyR2 at concentration levels that would be deleterious to the whole cell. The limited space also allows Ca²⁺ inactivation of Ca_v1.2. We have found that not all couplons are the same and that their properties are likely determined by their molecular partners which, in turn, determine their excitability. In particular, there are a class of couplons that lie outside the RyR2-Ca_v1.2 dyad; in this case, the RyR2 is close to caveolin-3 rather than Ca_v1.2. These extra-dyadic couplons are probably controlled by the multitude of molecules associated with caveolin-3 and may modulate contractile force under situations such as stress. It has long been assumed that like the skeletal muscle, the RyR2 in the couplon are arranged in a structured array with the RyR2 interacting with each other via domain 6 of the RyR2 molecule. This arrangement was thought to provide local control of RyR2 excitability. Using 3D electron tomography of the couplon, we show that the RyR2 in the couplon do not form an ordered pattern, but are scattered throughout it. Relatively few are in a checkerboard pattern—many RyR2 sit edge-to-edge, a configuration which might preclude their controlling each other's excitability. The discovery of this structure makes many models of cardiac couplon function moot and is a current avenue of further research     

The couplonopathies: A comparative approach to a class of diseases of skeletal and cardiac muscle

ConclusionsWe define a novel category of diseases of striated muscle, the couplonopathies, as those that have in common a substantial disruption of the functional unit of Ca²⁺ release for EC coupling, the couplon. Consideration of similarities and differences between the couplons of skeletal and cardiac muscle affords insights into the pathogenesis of several couplonopathies, including MH and CPVT. Specifically, we argue that the allosteric connection among couplon proteins Ca_V1.1 and RyR1 is required for the MH phenotype usually linked to mutations in the RyR channel to also associate with mutations in Ca_V1.1. As an extension of this idea, we propose that the same allosteric interaction underpins the beneficial effects of dantrolene. The absence of a corresponding mechanical connection in cardiac muscle explains the absence of CPVT diseases caused by mutations in Ca_V1.2. Based on mechanistic considerations applicable to both couplons, we identify the plasmalemma as a site of alterations in transport properties, typically consisting of an increase in store-operated calcium entry, secondary to couplon mutations that promote Ca²⁺ release. These secondary changes constitute significant factors in the pathogenesis of MH. Mutations in triadin and calsequestrin have tissue-specific consequences: in the heart they cause couplonopathies associated with either loss of the allosteric control putatively exerted by these proteins on the Ca²⁺ release channel or loss of Ca²⁺ buffer capacity in the SR. In skeletal muscle, the phenotypes are milder or nonexistent because of the narrower range of physiological [Ca²⁺]_SR visited during function, as well as the much greater functional reserve of Ca storage that is present in this tissue. Finally, the effects of variants or ablation of JP-45 demonstrate a control of the DHPR that is unique to skeletal muscle and may be prescribed by the separate channel and sensor functions of the skeletal muscle DHPR.     

The structure and functioning of the couplon in the mammalian cardiomyocyte

The couplons of the cardiomyocyte form nanospaces within the cell that place the L-type calcium channel (Ca(v)1.2), situated on the plasmalemma, in opposition to the type 2 ryanodine receptor (RyR2), situated on the sarcoplasmic reticulum. These two molecules, which form the basis of excitation-contraction coupling, are separated by a very limited space, which allows a few Ca(2+) ions passing through Ca(v)1.2 to activate the RyR2 at concentration levels that would be deleterious to the whole cell. The limited space also allows Ca(2+) inactivation of Ca(v)1.2. We have found that not all couplons are the same and that their properties are likely determined by their molecular partners which, in turn, determine their excitability. In particular, there are a class of couplons that lie outside the RyR2-Ca(v)1.2 dyad; in this case, the RyR2 is close to caveolin-3 rather than Ca(v)1.2. These extra-dyadic couplons are probably controlled by the multitude of molecules associated with caveolin-3 and may modulate contractile force under situations such as stress. It has long been assumed that like the skeletal muscle, the RyR2 in the couplon are arranged in a structured array with the RyR2 interacting with each other via domain 6 of the RyR2 molecule. This arrangement was thought to provide local control of RyR2 excitability. Using 3D electron tomography of the couplon, we show that the RyR2 in the couplon do not form an ordered pattern, but are scattered throughout it. Relatively few are in a checkerboard pattern--many RyR2 sit edge-to-edge, a configuration which might preclude their controlling each other's excitability. The discovery of this structure makes many models of cardiac couplon function moot and is a current avenue of further research.     

Age attenuates the T‐type CaV3.2‐RyR axis in vascular smooth muscle

Caveolae position Ca_V3.2 (T‐type Ca²⁺ channel encoded by the α‐3.2 subunit) sufficiently close to RyR (ryanodine receptors) for extracellular Ca²⁺ influx to trigger Ca²⁺ sparks and large‐conductance Ca²⁺‐activated K⁺ channel feedback in vascular smooth muscle. We hypothesize that this mechanism of Ca²⁺ spark generation is affected by age. Using smooth muscle cells (VSMCs) from mouse mesenteric arteries, we found that both Ca_v3.2 channel inhibition by Ni²⁺ (50 µM) and caveolae disruption by methyl‐ß‐cyclodextrin or genetic abolition of Eps15 homology domain‐containing protein (EHD2) inhibited Ca²⁺ sparks in cells from young (4 months) but not old (12 months) mice. In accordance, expression of Ca_v3.2 channel was higher in mesenteric arteries from young than old mice. Similar effects were observed for caveolae density. Using SMAKO Ca_v1.2^?/? mice, caffeine (RyR activator) and thapsigargin (Ca²⁺ transport ATPase inhibitor), we found that sufficient SR Ca²⁺ load is a prerequisite for the Ca_V3.2‐RyR axis to generate Ca²⁺ sparks. We identified a fraction of Ca²⁺ sparks in aged VSMCs, which is sensitive to the TRP channel blocker Gd³⁺ (100 µM), but insensitive to Ca_V1.2 and Ca_V3.2 channel blockade. Our data demonstrate that the VSMC Ca_V3.2‐RyR axis is down‐regulated by aging. This defective Ca_V3.2‐RyR coupling is counterbalanced by a Gd³⁺ sensitive Ca²⁺ pathway providing compensatory Ca²⁺ influx for triggering Ca²⁺ sparks in aged VSMCs.     

Single Ryanodine Receptor Channel Basis of Caffeine's Action on Ca Sparks

Caffeine (1, 3, 7-trimethylxanthine) is a widely used pharmacological agonist of the cardiac ryanodine receptor (RyR2) Ca²⁺ release channel. It is also a well-known stimulant that can produce adverse side effects, including arrhythmias. Here, the action of caffeine on single RyR2 channels in bilayers and Ca²⁺ sparks in permeabilized ventricular cardiomyocytes is defined. Single RyR2 caffeine activation depended on the free Ca²⁺ level on both sides of the channel. Cytosolic Ca²⁺ enhanced RyR2 caffeine affinity, whereas luminal Ca²⁺ essentially scaled maximal caffeine activation. Caffeine activated single RyR2 channels in diastolic quasi-cell-like solutions (cytosolic MgATP, pCa 7) with an EC₅₀ of 9.0 ± 0.4 mM. Low-dose caffeine (0.15 mM) increased Ca²⁺ spark frequency ∼75% and single RyR2 opening frequency ∼150%. This implies that not all spontaneous RyR2 openings during diastole are associated with Ca²⁺ sparks. Assuming that only the longest openings evoke sparks, our data suggest that a spark may result only when a spontaneous single RyR2 opening lasts >6 ms.     

Chronic fluoxetine administration increases expression of the L-channel gene Cav1.2 in astrocytes from the brain of treated mice and in culture and augments K-induced increase in [Ca]i

We have recently shown that freshly isolated astrocytes from the mouse brain express mRNA for the L-channel gene Ca_v1.3 to at least the same degree (per mg mRNA) as corresponding neurons. The amount of extracellular Ca²⁺ actually entering cultured astrocytes by its opening is modest, but due to secondary Ca²⁺-mediated stimulation of the ryanodine receptor (RyR) the increase in free cytosolic Ca²⁺ [Ca²⁺]_i is substantial. The other Ca_v1 subtype expressed in brain is Ca_v1.2, which is even expressed in higher density. Although the different primers used for the two genes preclude exact quantitative comparison, the present study suggests that this is also the case in the freshly isolated astrocytes and neurons, which express equal Ca_v1.2 densities. Again, most of the increase in [Ca²⁺]_i occurred by RyR activity. In contrast to Ca_v1.3 the expression of Ca_v1.2 was greatly increased (doubled) after two weeks of treatment with fluoxetine hydrochloride (10 mg/kg). Accordingly [Ca²⁺]_i in cultured astrocytes exposed to the addition of 10–60 mM KCl increased substantially in cultured astrocytes treated chronically with fluoxetine with the lag time until the effect was observed depending upon the fluoxetine concentration. This effect was inhibited by nifedipine or siRNA against Ca_v1.2. The increase in K⁺-induced rise in [Ca²⁺]_i after fluoxetine treatment is directly opposite to a decrease in [Ca²⁺]_i after treatment with any of the anti-bipolar drugs lithium, carbamazepine or valproic acid, due to reduced capacitative Ca²⁺ influx. We have previously shown a similar effect after fluoxetine treatment, but it becomes overridden by the Ca_v1.2 up-regulation.     

Effect of Cavβ Subunits on Structural Organization of Cav1.2 Calcium Channels

Background

Voltage-gated Ca_v1.2 calcium channels play a crucial role in Ca²⁺ signaling. The pore-forming α_1C subunit is regulated by accessory Ca_vβ subunits, cytoplasmic proteins of various size encoded by four different genes (Ca_vβ₁ - β₄) and expressed in a tissue-specific manner.

Methods and Results

Here we investigated the effect of three major Ca_vβ types, β_1b, β_2d and β₃, on the structure of Ca_v1.2 in the plasma membrane of live cells. Total internal reflection fluorescence microscopy showed that the tendency of Ca_v1.2 to form clusters depends on the type of the Ca_vβ subunit present. The highest density of Ca_v1.2 clusters in the plasma membrane and the smallest cluster size were observed with neuronal/cardiac β_1b present. Ca_v1.2 channels containing β₃, the predominant Ca_vβ subunit of vascular smooth muscle cells, were organized in a significantly smaller number of larger clusters. The inter- and intramolecular distances between α_1C and Ca_vβ in the plasma membrane of live cells were measured by three-color FRET microscopy. The results confirm that the proximity of Ca_v1.2 channels in the plasma membrane depends on the Ca_vβ type. The presence of different Ca_vβ subunits does not result in significant differences in the intramolecular distance between the termini of α_1C, but significantly affects the distance between the termini of neighbor α_1C subunits, which varies from 67 Å with β_1b to 79 Å with β₃.

Conclusions

Thus, our results show that the structural organization of Ca_v1.2 channels in the plasma membrane depends on the type of Ca_vβ subunits present.     

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.     

Surface L‐type Ca2+ channel expression levels are increased in aged hippocampus

Age‐related increase in L‐type Ca²⁺ channel (LTCC) expression in hippocampal pyramidal neurons has been hypothesized to underlie the increased Ca²⁺ influx and subsequent reduced intrinsic neuronal excitability of these neurons that lead to age‐related cognitive deficits. Here, using specific antibodies against Ca_v1.2 and Ca_v1.3 subunits of LTCCs, we systematically re‐examined the expression of these proteins in the hippocampus from young (3 to 4 month old) and aged (30 to 32 month old) F344xBN rats. Western blot analysis of the total expression levels revealed significant reductions in both Ca_v1.2 and Ca_v1.3 subunits from all three major hippocampal regions of aged rats. Despite the decreases in total expression levels, surface biotinylation experiments revealed significantly higher proportion of expression on the plasma membrane of Ca_v1.2 in the CA1 and CA3 regions and of Ca_v1.3 in the CA3 region from aged rats. Furthermore, the surface biotinylation results were supported by immunohistochemical analysis that revealed significant increases in Ca_v1.2 immunoreactivity in the CA1 and CA3 regions of aged hippocampal pyramidal neurons. In addition, we found a significant increase in the level of phosphorylated Ca_v1.2 on the plasma membrane in the dentate gyrus of aged rats. Taken together, our present findings strongly suggest that age‐related cognitive deficits cannot be attributed to a global change in L‐type channel expression nor to the level of phosphorylation of Ca_v1.2 on the plasma membrane of hippocampal neurons. Rather, increased expression and density of LTCCs on the plasma membrane may underlie the age‐related increase in L‐type Ca²⁺ channel activity in CA1 pyramidal neurons.     

Examination of the Effects of Heterogeneous Organization of RyR Clusters,Myofibrils and Mitochondria on Ca2+ Release Patterns in Cardiomyocytes

Spatio-temporal dynamics of intracellular calcium, [Ca²⁺]_i, regulate the contractile function of cardiac muscle cells. Measuring [Ca²⁺]_i flux is central to the study of mechanisms that underlie both normal cardiac function and calcium-dependent etiologies in heart disease. However, current imaging techniques are limited in the spatial resolution to which changes in [Ca²⁺]_i can be detected. Using spatial point process statistics techniques we developed a novel method to simulate the spatial distribution of RyR clusters, which act as the major mediators of contractile Ca²⁺ release, upon a physiologically-realistic cellular landscape composed of tightly-packed mitochondria and myofibrils. We applied this method to computationally combine confocal-scale (~ 200 nm) data of RyR clusters with 3D electron microscopy data (~ 30 nm) of myofibrils and mitochondria, both collected from adult rat left ventricular myocytes. Using this hybrid-scale spatial model, we simulated reaction-diffusion of [Ca²⁺]_i during the rising phase of the transient (first 30 ms after initiation). At 30 ms, the average peak of the simulated [Ca²⁺]_i transient and of the simulated fluorescence intensity signal, F/F₀, reached values similar to that found in the literature ([Ca²⁺]_i ≈1 μM; F/F₀≈5.5). However, our model predicted the variation in [Ca²⁺]_i to be between 0.3 and 12.7 μM (~3 to 100 fold from resting value of 0.1 μM) and the corresponding F/F₀ signal ranging from 3 to 9.5. We demonstrate in this study that: (i) heterogeneities in the [Ca²⁺]_i transient are due not only to heterogeneous distribution and clustering of mitochondria; (ii) but also to heterogeneous local densities of RyR clusters. Further, we show that: (iii) these structure-induced heterogeneities in [Ca²⁺]_i can appear in line scan data. Finally, using our unique method for generating RyR cluster distributions, we demonstrate the robustness in the [Ca²⁺]_i transient to differences in RyR cluster distributions measured between rat and human cardiomyocytes.     

Hypoxia-inducible factor-1α regulates the expression of L-type voltage-dependent Ca2+ channels in PC12 cells under hypoxia

Hypoxia is an important factor in regulation of cell behavior both under physiological and pathological conditions. The mechanisms of hypoxia-induced cell death have not been completely elucidated yet. It is well known that Ca²⁺ is critically related to cell survival. Hypoxia-inducible factor-1α (HIF-1α) is a core regulatory factor during hypoxia, and L-type voltage-dependent Ca²⁺ channels (L-VDCCs) have been reported to play a critical role in cell survival. This study was conducted to explore the relationship between L-VDCC expression and HIF-1α regulation in PC12 cells under hypoxia. PC12 cells were treated at 20 or 3 % O₂ to observe its proliferation and the intracellular calcium concentration. Then, we detected the protein expression of HIF-1α and L-VDCCs subtypes, Ca_v1.2 and Ca_v1.3. At last, to verify the relationship between HIF-1α and Ca_v1.2 and Ca_v1.3, we got the expression of Ca_v1.2 and Ca_v1.3 with Western blot and luciferase report gene assays after PC12 cells were treated by echinomycin, which is an HIF-1α inhibitor. Compared with 20 % O₂ (normoxia), 3 % O₂ (hypoxia) inhibited cell proliferation, increased the intracellular calcium concentration, and induced protein expression of HIF-1α. The protein expression of two L-VDCCs subtypes expressed in the nervous system, Ca_v1.2 and Ca_v1.3, was upregulated by hypoxia and reduced dose dependently by treatment with echinomycin, a HIF-1α inhibitor. Luciferase report gene assays showed that the expression of Ca_v1.2 and Ca_v1.3 genes was augmented under 3 % O₂. However, echinomycin only slightly and dose dependently decreased expression of the Ca_v1.2 gene, but not that of the Ca_v1.3 gene. These data indicated that Ca_v1.2 might be regulated by HIF-1α as one of its downstream target genes and involved in regulation of PC12 cells death under hypoxia.     

On the Adjacency Matrix of RyR2 Cluster Structures

In the heart, electrical stimulation of cardiac myocytes increases the open probability of sarcolemmal voltage-sensitive Ca²⁺ channels and flux of Ca²⁺ into the cells. This increases Ca²⁺ binding to ligand-gated channels known as ryanodine receptors (RyR2). Their openings cause cell-wide release of Ca²⁺, which in turn causes muscle contraction and the generation of the mechanical force required to pump blood. In resting myocytes, RyR2s can also open spontaneously giving rise to spatially-confined Ca²⁺ release events known as “sparks.” RyR2s are organized in a lattice to form clusters in the junctional sarcoplasmic reticulum membrane. Our recent work has shown that the spatial arrangement of RyR2s within clusters strongly influences the frequency of Ca²⁺ sparks. We showed that the probability of a Ca²⁺ spark occurring when a single RyR2 in the cluster opens spontaneously can be predicted from the precise spatial arrangements of the RyR2s. Thus, “function” follows from “structure.” This probability is related to the maximum eigenvalue (λ ₁) of the adjacency matrix of the RyR2 cluster lattice. In this work, we develop a theoretical framework for understanding this relationship. We present a stochastic contact network model of the Ca²⁺ spark initiation process. We show that λ ₁ determines a stability threshold for the formation of Ca²⁺ sparks in terms of the RyR2 gating transition rates. We recapitulate these results by applying the model to realistic RyR2 cluster structures informed by super-resolution stimulated emission depletion (STED) microscopy. Eigendecomposition of the linearized mean-field contact network model reveals functional subdomains within RyR2 clusters with distinct sensitivities to Ca²⁺. This work provides novel perspectives on the cardiac Ca²⁺ release process and a general method for inferring the functional properties of transmembrane receptor clusters from their structure.     

Total internal reflectance fluorescence imaging of genetically engineered ryanodine receptor-targeted Ca2+ probes in rat ventricular myocytes

The details of cardiac Ca²⁺ signaling within the dyadic junction remain unclear because of limitations in rapid spatial imaging techniques, and availability of Ca²⁺ probes localized to dyadic junctions. To critically monitor ryanodine receptors’ (RyR2) Ca²⁺ nano-domains, we combined the use of genetically engineered RyR2-targeted pericam probes, (FKBP-YCaMP, K_d = 150 nM, or FKBP-GCaMP6, K_d = 240 nM) with rapid total internal reflectance fluorescence (TIRF) microscopy (resolution, ∼80 nm). The punctate z-line patterns of FKBP,²-targeted probes overlapped those of RyR2 antibodies and sharply contrasted to the images of probes targeted to sarcoplasmic reticulum (SERCA2a/PLB), or cytosolic Fluo-4 images. FKBP-YCaMP signals were too small (∼20%) and too slow (2–3 s) to detect Ca²⁺ sparks, but the probe was effective in marking where Fluo-4 Ca²⁺ sparks developed. FKBP-GCaMP6, on the other hand, produced rapidly decaying Ca²⁺ signals that: a) had faster kinetics and activated synchronous with I_Ca³ but were of variable size at different z-lines and b) were accompanied by spatially confined spontaneous Ca²⁺ sparks, originating from a subset of eager sites. The frequency of spontaneously occurring sparks was lower in FKBP-GCaMP6 infected myocytes as compared to Fluo-4 dialyzed myocytes, but isoproterenol enhanced their frequency more effectively than in Fluo-4 dialyzed cells. Nevertheless, isoproterenol failed to dissociate FKBP-GCaMP6 from the z-lines. The data suggests that FKBP-GCaMP6 binds predominantly to junctional RyR2s and has sufficient on-rate efficiency as to monitor the released Ca²⁺ in individual dyadic clefts, and supports the idea that β-adrenergic agonists may modulate the stabilizing effects of native FKBP on RyR2.     

Life and death of a cardiac calcium spark

Calcium sparks in cardiac myocytes are brief, localized calcium releases from the sarcoplasmic reticulum (SR) believed to be caused by locally regenerative calcium-induced calcium release (CICR) via couplons, clusters of ryanodine receptors (RyRs). How such regeneration is terminated is uncertain. We performed numerical simulations of an idealized stochastic model of spark production, assuming a RyR gating scheme with only two states (open and closed). Local depletion of calcium in the SR was inevitable during a spark, and this could terminate sparks by interrupting CICR, with or without assumed modulation of RyR gating by SR lumenal calcium. Spark termination by local SR depletion was not robust: under some conditions, sparks could be greatly and variably prolonged, terminating by stochastic attrition–a phenomenon we dub “spark metastability.” Spark fluorescence rise time was not a good surrogate for the duration of calcium release. Using a highly simplified, deterministic model of the dynamics of a couplon, we show that spark metastability depends on the kinetic relationship of RyR gating and junctional SR refilling rates. The conditions for spark metastability resemble those produced by known mutations of RyR2 and CASQ2 that cause life-threatening triggered arrhythmias, and spark metastability may be mitigated by altering the kinetics of the RyR in a manner similar to the effects of drugs known to prevent those arrhythmias. The model was unable to explain the distributions of spark amplitudes and rise times seen in chemically skinned cat atrial myocytes, suggesting that such sparks may be more complex events involving heterogeneity of couplons or local propagation among sub-clusters of RyRs.     

Effect of metabolic inhibition on couplon behavior in rabbit ventricular myocytes

We investigated the effect of combined inhibition of oxidative and glycolytic metabolism on L-type Ca²⁺ channels (LCCs) and Ca²⁺ spikes in isolated patch-clamped rabbit ventricular myocytes. Metabolic inhibition (MI) reduced LCC open probability, increased null probability, increased first latency, and decreased open time but left conductance unchanged. These results explain the reduction in macroscopic Ca²⁺ current observed during MI. MI also produced a gradual reduction in action potential duration at 90% repolarization (APD₉₀), a clear decline in spike probability, and an increase in spike latency and variance. These effects are consistent with the changes we observed in LCC activity. MI had no effect on the amplitude or time to peak of Ca²⁺ spikes until APD₉₀ reached 10% of control, suggesting preserved sarcoplasmic reticulum Ca²⁺ stores and ryanodine receptor (RyR) conductance in those couplons that remained functioning. Ca²⁺ spikes disappeared completely when APD₉₀ reached <2% of control, although in two cells, spikes were reactivated in a highly synchronized fashion by very short action potentials. This reactivation is probably due to the increased driving force for Ca²⁺ entry through a reduced number of LCCs that remain open during early repolarization. The enlarged single channel flux produced by rapid repolarization is apparently sufficient to trigger RyRs whose Ca²⁺ sensitivity is likely reduced by MI. We suggest that loss of coupling fidelity during MI is explained by loss of LCC activity (possibly mediated by Ca²⁺-calmodulin kinase II activity). In addition, the results are consistent with loss of RyR activity, which can be mitigated under conditions likely to enlarge the trigger.     

Alternative Splicing Generates a Novel Truncated Cav1.2 Channel in Neonatal Rat Heart

L-type Ca_v1.2 Ca²⁺ channel undergoes extensive alternative splicing, generating functionally different channels. Alternatively spliced Ca_v1.2 Ca²⁺ channels have been found to be expressed in a tissue-specific manner or under pathological conditions. To provide a more comprehensive understanding of alternative splicing in Ca_v1.2 channel, we systematically investigated the splicing patterns in the neonatal and adult rat hearts. The neonatal heart expresses a novel 104-bp exon 33L at the IVS3-4 linker that is generated by the use of an alternative acceptor site. Inclusion of exon 33L causes frameshift and C-terminal truncation. Whole-cell electrophysiological recordings of Ca_v1.2_33L channels expressed in HEK 293 cells did not detect any current. However, when co-expressed with wild type Ca_v1.2 channels, Ca_v1.2_33L channels reduced the current density and altered the electrophysiological properties of the wild type Ca_v1.2 channels. Interestingly, the truncated 3.5-domain Ca_v1.2_33L channels also yielded a dominant negative effect on Ca_v1.3 channels, but not on Ca_v3.2 channels, suggesting that Ca_vβ subunits is required for Ca_v1.2_33L regulation. A biochemical study provided evidence that Ca_v1.2_33L channels enhanced protein degradation of wild type channels via the ubiquitin-proteasome system. Although the physiological significance of the Ca_v1.2_33L channels in neonatal heart is still unknown, our report demonstrates the ability of this novel truncated channel to modulate the activity of the functional Ca_v1.2 channels. Moreover, the human Ca_v1.2 channel also contains exon 33L that is developmentally regulated in heart. Unexpectedly, human exon 33L has a one-nucleotide insertion that allowed in-frame translation of a full Ca_v1.2 channel. An electrophysiological study showed that human Ca_v1.2_33L channel is a functional channel but conducts Ca²⁺ ions at a much lower level.     

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 calcium release channels mediate their own countercurrent: the ryanodine receptor case study

Intracellular calcium release channels like ryanodine receptors (RyRs) and inositol trisphosphate receptors (IP₃Rs) mediate large Ca²⁺ release events from Ca²⁺ storage organelles lasting >5 ms. To have such long-lasting Ca²⁺ efflux, a countercurrent of other ions is necessary to prevent the membrane potential from becoming the Ca²⁺ Nernst potential in <1 ms. A recent model of ion permeation through a single, open RyR channel is used here to show that the vast majority of this countercurrent is conducted by the RyR itself. Consequently, changes in membrane potential are minimized locally and instantly, assuring maintenance of a Ca²⁺-driving force. This RyR autocountercurrent is possible because of the poor Ca²⁺ selectivity and high conductance for both monovalent and divalent cations of these channels. The model shows that, under physiological conditions, the autocountercurrent clamps the membrane potential near 0 mV within ∼150 μs. Consistent with experiments, the model shows how RyR unit Ca²⁺ current is defined by luminal [Ca²⁺], permeable ion composition and concentration, and pore selectivity and conductance. This very likely is true of the highly homologous pore of the IP₃R channel.     

Two EF-hand motifs in ryanodine receptor calcium release channels contribute to isoform-specific regulation by calmodulin

The mammalian ryanodine receptor Ca²⁺ release channel (RyR) has a single conserved high affinity calmodulin (CaM) binding domain. However, the skeletal muscle RyR1 is activated and cardiac muscle RyR2 is inhibited by CaM at submicromolar Ca²⁺. This suggests isoform-specific domains are involved in RyR regulation by CaM. To gain insight into the differential regulation of cardiac and skeletal muscle RyRs by CaM, RyR1/RyR2 chimeras and mutants were expressed in HEK293 cells, and their single channel activities were measured using a lipid bilayer method. All RyR1/RyR2 chimeras and mutants were inhibited by CaM at 2 μM Ca²⁺, consistent with CaM inhibition of RyR1 and RyR2 at micromolar Ca²⁺ concentrations. An RyR1/RyR2 chimera with RyR1 N-terminal amino acid residues (aa) 1–3725 and RyR2 C-terminal aa 3692–4968 were inhibited by CaM at <1 μM Ca²⁺ similar to RyR2. In contrast, RyR1/RyR2 chimera with RyR1 aa 1–4301 and RyR2 4254–4968 was activated at <1 μM Ca²⁺ similar to RyR1. Replacement of RyR1 aa 3726–4298 with corresponding residues from RyR2 conferred CaM inhibition at <1 μM Ca²⁺, which suggests RyR1 aa 3726–4298 are required for activation by CaM. Characterization of additional RyR1/RyR2 chimeras and mutants in two predicted Ca²⁺ binding motifs in RyR1 aa 4081–4092 (EF1) and aa 4116–4127 (EF2) suggests that both EF-hand motifs and additional sequences in the large N-terminal regions are required for isoform-specific RyR1 and RyR2 regulation by CaM at submicromolar Ca²⁺ concentrations.