Abstract
Brugada syndrome (BrS) is an inherited arrhythmogenic disease that may lead to sudden cardiac death in young adults with structurally normal hearts. No pharmacological therapy is available for BrS patients. This situation highlights the urgent need to overcome current difficulties by developing novel groundbreaking curative strategies. BrS has been associated with mutations in 18 different genes of which loss-of-function (LoF) CACNA1C mutations constitute the second most common cause. Here we tested the hypothesis that BrS associated with mutations in the CACNA1C gene encoding the L-type calcium channel (LTCC) pore-forming unit (Cavα1.2) is functionally reverted by administration of a mimetic peptide (MP), which through binding to the LTCC chaperone beta subunit (Cavβ2) restores the physiological life cycle of aberrant LTCCs. Two novel Cavα1.2 mutations associated with BrS were identified in young individuals. Transient transfection in heterologous and cardiac cells showed LoF phenotypes with reduced Ca2+ current (ICa). In HEK293 cells overexpressing the two novel Cavα1.2 mutations, Western blot analysis and cell surface biotinylation assays revealed reduced Cavα1.2 protein levels at the plasma membrane for both mutants. Nano-BRET, Nano-Luciferase assays, and confocal microscopy analyses showed (i) reduced affinity of Cavα1.2 for its Cavβ2 chaperone, (ii) shortened Cavα1.2 half-life in the membrane, and (iii) impaired subcellular localization. Treatment of Cavα1.2 mutant-transfected cells with a cell permeant MP restored channel trafficking and physiologic channel half-life, thereby resulting in ICa similar to wild type. These results represent the first step towards the development of a gene-specific treatment for BrS due to defective trafficking of mutant LTCC.
Keywords: brugada syndrome, arrhythmia, L-type calcium channel, mimetic peptide, channel trafficking, corrective therapy, cardiac disease
Introduction
Brugada syndrome (BrS) is an inherited arrhythmogenic disorder causing sudden death in young individuals (Napolitano et al., 2012) and has been associated with mutations in 18 different genes. Loss-of-function (LoF) mutations in the CACNA1C and CACNB2 genes encoding the alpha- (Cavα1.2) and beta2- (Cavβ2) subunits of the L-type calcium channel (LTCC), respectively, account for up to 12% of genotyped BrS cases (Antzelevitch et al., 2007; Burashnikov et al., 2010; Napolitano and Antzelevitch, 2011).
The phenotypic consequences of mutations that are incompletely known and only in part experimentally reproduced in pharmacological models of LTCC LoF (Fish and Antzelevitch, 2004) are: (1) ST segment elevation due to a transmural voltage gradient, which is particularly accentuated in the right ventricular outflow tract epicardium that shows a prominent transient outward potassium current. In the precordial unipolar electrocardiographic leads V1 and V2 covering this region the typical Type I BrS pattern is detected; (2) QT shortening due to the reduction of the inward Ca2+ current (ICa) in the ventricular myocardium (Burashnikov et al., 2010; Napolitano and Antzelevitch, 2011); (3) ST elevation in inferior or lateral leads, also called early repolarization (ERP; Burashnikov et al., 2010). All these conditions predispose to an increased risk of sudden death. The coexistence of ST segment elevation and abbreviated repolarization (short QT interval) often coexist in association with CACNA1C mutations and lead to an overlapping syndrome combining phenotypes of BrS and Short QT syndromes.
However, direct experimental assessments of the cellular consequences of LTCC-BrS mutants have been scanty and incomplete. In fact, the few Cavα1.2 and Cavβ2 mutants that have been expressed in heterologous cellular systems mainly show a reduction in current density with absent or minor kinetic abnormalities (Antzelevitch et al., 2007; Bourdin et al., 2015). This effect is likely to be due to a reduced number of channels in the membrane that derives from either reduced forward trafficking or increased reverse trafficking/channel degradation, or both. However, detailed LTCC-mutant studies aimed at addressing the efficiency of both forward and reverse trafficking as well as their correction via novel molecular approaches have not yet been carried out.
In the clinical setting, risk stratification of BrS is relatively well defined (Priori et al., 2015), while the therapeutic options are limited to the use of an implantable cardioverter defibrillator (ICD), which may hamper the quality of life of young patients due to inappropriate shocks or lead-related complications that occur in up to 30% of patients (Napolitano et al., 2012). No pharmacological therapy has been demonstrated to be able to reduce life threatening arrhythmic events in controlled clinical trials. Thus, in this context, the identification of an innovative antiarrhythmic therapy would represent a major step forward with remarkable clinical impact.
Our group has developed an LTCC-specific peptide (MP), which can restore physiological LTCC levels when the channel density at the plasma membrane is reduced (Rusconi et al., 2016; Miragoli et al., 2018; Romanelli et al., 2018). The MP, designed from the C-terminal tail of the otherwise globular Cavβ2, binds to a region (Tail Interacting Domain, TID; Rusconi et al., 2016) within the globular Cavβ2 chaperone, facilitating the restoration of Cavα1.2 density at the plasma membrane. Therefore, the MP directly acts the regulation of LTCC intracellular protein trafficking, i.e., reducing Cavα1.2 reverse trafficking and protein degradation by preventing LTCC endocytosis as well as promoting Cavα1.2 forward trafficking by facilitating efficient Cavβ2-mediated chaperoning of Cavα1.2 to the plasma membrane. Importantly, this effect does not come at the cost of altered contractility or pro-arrhythmic effects as the gating kinetics of the LTCC remain unaltered following MP administration both in vitro and in vivo (Rusconi et al., 2016; Miragoli et al., 2018). The MP, designed with an arginine-rich cationic cell-penetrating peptide (R7W-MP; Rusconi et al., 2016) or loaded in inhalable nanoparticles (Miragoli et al., 2018), was shown by our group to be effective in an in vivo model of diabetic cardiomyopathy (Rusconi et al., 2016; Miragoli et al., 2018).
Based on these previous results, we hypothesized that the MP could correct electrophysiological and molecular defects associated with LoF LTCC mutations linked to BrS. Two novel Cavα1.2 mutations (T320M and Q428E) were identified in two young individuals with a diagnosis of BrS. Electrophysiological and molecular characterization showed a LoF ICa phenotype associated with reduced LTCC membrane localization. In this setting, we evaluated the pharmacological application of R7W-MP and demonstrated that treatment of heterologous and cardiac cells carrying the two mutations is sufficient to correct the LTTC channel density at the plasma membrane and restore physiological ICa.
Materials and Methods
Genetic Analysis
Gene mutations were identified in subjects with BrS enrolled in the TRIAD registry of inherited arrhythmias at the ICS Maugeri Institute.1 Genetic analysis was performed by conventional Sanger sequencing and included the entire open reading frame of CACNA1C (NM_000719), including 8 alternative exons (LRG_334). The coding region of SCN5A, the most common gene associated with BrS (Crotti et al., 2012) was also screened (NM_198056.29). The diagnosis of BrS was established in agreement with the current accepted criteria (Priori et al., 2015) after excluding the presence of structural cardiomyopathies. The TRIAD registry (registration number 911CEC, 22nd May 2013) is approved by the Ethical Committee of the ICS Maugeri, Pavia, Italy, and the study conforms to the principles outlined in the Declaration of Helsinki. All patients gave written informed consent agreeing to the use of their clinical and genetic data for research purposes.
DNA Constructs and Peptides
Site-directed mutagenesis was performed on full-length human alternative transcript variant 17 CACNA1C (NM_001129843) cloned into the pCMV6-XL4 vector (Origene Technologies) using the QuickChange II XL kit (Agilent Technologies). Human CACN2B (NM_201572) was cloned into the pCMV6-XL5 vector (Origene Technologies). For the Nano-Luciferase assay, WT and mutant Cavα1.2 cDNAs were cloned into the pNLF1-N vector (Promega), whereas for the BRET assay, Cavα1.2 and Cavβ2 cDNAs were cloned into the pNLF1-N and HaloTag-pFN21A vectors, respectively. All clonings were performed using the In-fusion HD Cloning Plus kit (Clontech). All constructs were verified by sequencing of the complete insert. Peptides were synthetized by GenScript (USA). R7W-MP: RRRRRRRW-DQRPDREAPRS; R7W-Scr: RRRRRRRW-DQPPSRRDERA.
Cell Culture Conditions and Transfection
Human embryonic kidney cells (HEK293) were cultured in DMEM (Sigma) supplemented with 10% HI-FBS (Life Technologies), 100 U/ml penicillin, and 0.1 mg/ml streptomycin (Euroclone). HL-1 cardiac cells were maintained in a special culture medium according to an optimized protocol provided by Dr. Claycomb’s laboratory. HEK293 and HL-1 cells were transiently transfected with Cavβ2 and Cavα1.2 (WT or mutant). Viafect (Promega) and Lipofectamine (ThermoFisher) transfection reagent were used for HL-1 and HEK293 cells, respectively.
Electrophysiology
L-type Ca2+ (ICa,L) currents were measured using the Patch-Clamp technique in the whole cell configuration and voltage-clamp mode. For the experiments performed in HEK293 cells the extracellular solution had the following composition (in mM): 140 NaCl, 2 CaCl2, 1 MgCl2, 10 HEPES, and 5 Glucose, pH 7.4 adjusted with NaOH. Patch pipettes were pulled from borosilicate glass (WPI, Inc) on a P-97 horizontal puller (Sutter Instruments) and had a resistance of 2 to 3 MΩ when filled with a solution containing (in mmol/L): 120 CsCl, 2 MgCl2, 10 HEPES, 5 CaCl2, 2 MgATP, and 10 EGTA, pH 7.2 adjusted with CsOH. Recording protocols were applied by 300 ms depolarizing pulses from a holding potential of −80 mV with 10 mV steps from −60 mV to +50 mV. Membrane currents were analyzed with pCLAMP 9.2 (Axon Instruments) and Origin 6.0 (Northampton, USA) software. All the experiments were performed at room temperature (24–26°C). For HL-1 cells all measurements were carried out at 36 ± 0.5°C and ICa,L was recorded in extracellular and patch pipette solutions where potassium currents were suppressed by substituting K+ with Cs+. The composition of the extracellular solution was (mmol/l): NaCl, 140; CsCl, 5.4; MgCl2, 1.25; CaCl2, 2; HEPES, 10; D-glucose, 10; adjusted to pH 7.4 with NaOH; while the patch pipette solution contained (mmol/l): CsCl, 120; EGTA, 10; MgCl2, 4; HEPES, 10; 4 Na2ATP, 4; adjusted to pH 7.4 with CsOH. Experimental protocols were controlled using Clampex software (version 10.3 of pClamp, Axon Instruments). Pipette resistances ranged from 2 to 3 MOhm and pipette potentials were zeroed before cell contact. Peak ICa,L was measured in response to 400 ms depolarization steps ranging from −50 to 70 mV at a rate of 0.33 Hz (holding potential of −90 mV). A 50-ms prepulse to −40 mV was used to inactivate sodium channels and T-type ICa (if present). In both cells models, steady state activation curves were derived from each I-V relation and described by fitting experimental points with the Boltzmann equation. For all the experimental settings, 1.3 μM R7W-MP or R7W-Scr was added to the medium 24 h before the analysis.
Western Blot Analyses
Protein expression was evaluated by Western blot analyses according to standard procedures and as previously described (Rusconi et al., 2016). 3–8% NuPAGE Tris-Acetate gels (Life Technologies) were used for electrophoresis followed by blotting to a PVDF membrane (Millipore). The following antibodies were used: Cavα1.2 and Transferrin Receptor (Abcam); GAPDH (14C10) (Cell Signaling Technology); Goat anti-mouse-HRP and Goat anti-rabbit-HRP (Thermo Fisher Scientific). ECL was used for protein detection using a Chemidoc MP Imaging System (Biorad).
Cell Surface Biotinylation
The assay was performed as previously described (Rusconi et al., 2016). Briefly, transfected HEK293 cells were washed in ice cold PBS, biotinylated for 20 min with 0.5 mg/ml EZ Link Sulfo-NHS-LC-Biotin (Thermo Scientific), and subsequently lysed in RIPA buffer. After incubation with 50 μl High Capacity NeutrAvidin agarose beads (Thermo Scientific), biotinylated membrane proteins trapped to NeutrAvidin beads were washed and assayed by Western blot analysis for Cavα1.2 (Abcam).
Protein level detection for Transferrin Receptor (plasma membrane fraction) and GAPDH (cytoplasm fraction) were used as positive and negative controls, respectively, for quality assessment of the assay.
Nano Luciferase Assay
The NanoLuc Luciferase assay was performed as previously described (Rusconi et al., 2016). Briefly, HEK293 cells pretreated for 30 min with 20 μM cycloheximide were transfected and time-course analysis (NanoLuc Luciferase activity from 0.5 to 8 h post treatment) was performed using a Synergy 4 instrument (BioTek) as described by the manufacturer (Promega).
Nano-BRET Assay
The NanoBRET Assay was performed as previously described (Rusconi et al., 2016). Briefly, transfected HEK293 cells were treated with 100 nM NanoBRET 618 Ligand (Promega), and signals were detected 6 h after treatment. Signals were detected using a Synergy 4 instrument (BioTek).
Confocal Microscopy
Transfected HEK293 cells were blocked and permeabilized with 3% normal goat serum, 0.1% Triton X-100, and 50 mM glycine in 1 × PBS for 1 h. After incubation with Cavα1.2 primary antibody and secondary antibodies, cells were scanned with an Olympus FluoView FV1000 confocal laser-scanning microscope. Images were analyzed using Fiji Image J software (National Institutes of Health). Measurements of the relative increase in plasma membrane localization were performed as described elsewhere (Viard et al., 2004). Internalization was detected by calculation of cytoplasm fluorescence (Fc)/membrane fluorescence (Fm).
Statistical Analysis
Data are presented as mean ± standard error of the mean (SEM) or as individual values. Assessment of the normality of the data was calculated using the Kolmogorov-Smirnov (K-S) test. Statistical comparison between two samples was performed in at least three independent experiments with the Mann-Whitney T test. For multiple confrontations, one-way ANOVA followed by Tukey’s post hoc test or the Kruskal-Wallis test in combination with Dunn’s test were applied.
Prism 6.0 software (GraphPad Software, CA) was used for result analyses and statistical calculation. p < 0.05 was considered statistically significant.
Results
Brugada Patients With Novel Cavα1.2 Mutations
Two Cavα1.2 mutations (n.C959T/p.T320M and n.C1282G/p.Q428E) were identified by genetic screening of subjects with clinical diagnosis of BrS and referred to our Center for genetic testing. Both mutants mapped in highly conserved regions between domains I and II of Cavα1.2 (Figure 1A).
The Cavα1.2 T320M mutation was identified in a 33-year-old asymptomatic male patient, who was admitted at the emergency room for abdominal pain. The electrocardiogram (ECG) showed diagnostic BrS features (Figure 1B, left panel). The patient has remained asymptomatic for the following 8 years of follow-up, showing spontaneous manifestation of a type 1 pattern during 24-h Holter recordings.
The Cavα1.2 Q428E mutation was identified in a 32-year-old male diagnosed after a cardiac arrest occurring at rest, showing a spontaneous type 1 BrS pattern at baseline ECG (Figure 1B, right panel). The patient received an ICD. After 13 years of follow-up, ICD memory interrogation revealed two episodes of self-terminating polymorphic ventricular tachycardia and runs of atrial fibrillation.
A Loss-of-Function Phenotype Is Associated With the T320M and Q428E Cavα1.2 Mutations
As a first step, cDNAs of WT, T320M, and Q428E Cavα1.2 as well as of the accessory Cavß2 subunit were cloned in expression vectors, which were cotransfected in heterologous HEK293 and cardiac HL-1 cells for assessment of the electrophysiological phenotype. In HEK293 cells, patch clamp measurements at test pulse +10 mV showed an about 50% reduction in ICa currents in cells transfected with Cavα1.2 T320M (−1.09 ± 0.05 pA/pF; n = 14; p < 0.01) and Q428E (−0.98 ± 0.10 pA/pF; n = 13; p < 0.001) compared to WT transfected cells (−1.92 ± 0.15 pA/pF; n = 14; Figures 2A,B).
Experiments were also performed in HL-1 cells where, due to the presence of an endogenous WT Cavα1.2 subunit, we were able to evaluate the effect of the mutant channel in conditions of heterozygosity similar to those present in BrS patients. Data showed a reduction of ICa in both Cavα1.2 T320M- (−6.73 ± 0.76 pA/pF; n = 7; p < 0.05) and Q428E- (−6.11 ± 0.73 pA/pF; n = 6; p < 0.01) transfected cells compared to Cavα1.2 WT-transfected cells (−9.12 ± 0.60 pA/pF; n = 11; Supplementary Figures 1A,B). Altogether, these data provide evidence of a LoF phenotype for both T320M and Q428E Cavα1.2 mutations.
R7W-MP Restores Ca2+ Current Reduction Due to Cavα1.2 Loss-of-Function Mutations
Based on our recent results showing the ability of nanoparticle-loaded MP (Miragoli et al., 2018) or cell permeant R7W-MP (Rusconi et al., 2016) to recover LTCC dysregulation in diabetic cardiomyopathy, we hypothesized that also in the case of T320M and Q428E LoF BrS, the MP therapeutic peptide can correct the LTCC abnormalities. To test this, a similar experiment was performed as above, and HEK293-transfected cells were evaluated for ICa 24 h after R7W-MP-treatment. As shown in Figures 2A,B, ICa currents in R7W-MP-treated HEK293 cells cotransfected with Cavα1.2 T320M (−1.85 ± 0.21 pA/pF; n = 14) or Q428E (−1.70 ± 0.15 pA/pF; n = 12) and the Cavß2 subunit were restored to levels similar to those of Cavα1.2 WT-transfected cells. Notably, no kinetic abnormalities were observed either before or after R7W-MP-treatment (Figure 2C), consistent with our previous study (Rusconi et al., 2016). Furthermore, no effects were obtained following treatment with R7W-scramble peptide (R7W-Scr) either in Cavα1.2 T320M- (−0.92 ± 0.15 pA/pF; n = 7) or Q428E- (−0.98 ± 0.03 pA/pF; n = 7) transfected cells (Figure 2B).
Notably, a similar R7W-MP-dependent corrective effect was also observed in HL-1 cardiac cells, where ICa currents in both Cavα1.2 T320M- (−9.12 ± 0.60 pA/pF; n = 12) and Q428E- (−9.31 ± 0.65 pA/pF; n = 8) transfected cells were restored to levels comparable to non-transfected cells without affecting channel kinetics (Supplementary Figure 1). On the other hand, no positive modulation of ICa currents was observed in HL-1 cells expressing Cavα1.2 T320M (−6.34 ± 0.80 pA/pF, n = 9) or Q428E (−5.97 ± 1.06 pA/pF, n = 6) when the R7W-Scr was used (Supplementary Figure 1B).
Altogether these results showed that, without affecting channel gating properties, R7W-MP can correct the T320M and Q428E LoF phenotype in both cardiac and heterologous cells. Based on this evidence and with the attempt to avoid any experimental bias due to the endogenous Cavα1.2, all further analyses dissecting the molecular mechanisms underlying the LoF mutant-dependent deregulation of LTCCs and the corrective effect of R7W-MP were subsequently performed only within the heterologous HEK293 cells.
R7W-MP Corrects the Reduced Interaction Between Mutant Cavα1.2 and Cavβ2
Point mutations in the I-II loop of the Cavα1.2 pore unit have previously been shown to disrupt its interaction with Cavβ2 and prevent its targeting to the plasma membrane (Simms and Zamponi, 2012). Based on the localization of the Cavα1.2 T320M and Q428E variants in proximity to and inside the α-interacting domain (AID), respectively (Figure 1A), we hypothesized that these mutations affect the Cavβ2 - Cavα1.2 interaction and possibly related intracellular trafficking features. To assess this hypothesis, we performed a bioluminescence resonance energy transfer (BRET) assay and found that both mutations strongly reduce the Cavβ2-Cavα1.2 interaction (Cavα1.2 T320M by 80% and Cavα1.2 Q428E by 70%) (Figure 3). Importantly, R7W-MP-administration corrected the defective interaction resulting in full recovery, while R7W-Scr-administration had no effect (Figure 3).
This result supports the hypothesis that R7W-MP-treatment facilitates ICa recovery via restoration of Cavα1.2 trafficking towards the plasma membrane.
R7W-MP Restores LTCC Protein Density at the Plasma Membrane in Cavα1.2 Mutant-Transfected Cells
Alterations in the interaction between Cavβ2 and Cavα1.2 have previously been shown to affect the relative distribution of Cavα1.2 between the plasma membrane and the cytosol (Viard et al., 2004). Thus, to determine the effect of the Cavα1.2 mutations on Cavβ2 trafficking, we measured fluorescence intensity profiles in Cavα1.2 WT- and mutant-transfected cells immunostained for Cavα1.2. Whereas intensity profiles with predominant fluorescence at the plasma membrane were observed in Cavα1.2 WT-transfected cells, as expected (Viard et al., 2004), cells transfected with the two Cavα1.2 mutants showed homogeneous staining throughout the cell, demonstrating a clear trafficking defect (Figure 4A and Supplementary Figure 2). This was further supported by a surface protein biotinylation assay, which showed a reduction in Cavα1.2 plasma membrane levels in cells transfected with Cavα1.2 T320M (66%) and Q428E (62%) compared to WT (Figure 4B). These results are consistent with the patch-clamp data, showing reduced ICa in Cavα1.2 mutant-transfected cells (Figure 2 and Supplementary Figure 1).
Notably, treatment with R7W-MP fully restored the proper plasma membrane localization of both Cavα1.2 T320M and Q428E mutants, resulting in fluorescence intensity profiles, comparable to those of Cavα1.2 WT-transfected cells (Figure 4A and Supplementary Figure 2A). Consistently, a trend of recovery of Cavα1.2 T320M (81%) and Q428E (84%) membrane densities was obtained in R7W-MP-treated cells compared to R7W-Scr-treated cells (Figure 4B and Supplementary Figure 2B). Taken together, these data demonstrate that the R7W-MP can efficiently correct the trafficking defect of Cavα1.2 mutants.
Finally, due to the overall reduction in LTCC density, a decreased half-life of the channel might be expected. To determine this, we performed a nano-luciferase protein stability assay, which consistent with our hypothesis, revealed a 61 and 55% reduction in Cavα1.2 half-life for the T320M and Q428E mutants compared to WT, respectively (Figure 4C). R7W-MP-treatment largely restored the reduced Cavα1.2 half-life, demonstrating that the R7W-MP also has a corrective effect on Cavα1.2 half-life.
Discussion
The prevalence of LoF CACNA1C mutations that cause ECG abnormalities and risk of sudden death is not yet fully established and its definition is hampered by the complexity of the associated clinical phenotypes. Indeed, they have not only been associated with ST elevation in the right precordial leads (i.e., Brugada ECG pattern) but also with ERP and unexplained sudden death in the normal heart (also called “idiopathic ventricular fibrillation”; Priori and Napolitano, 2018). In this context, the Cavα1.2 T320M mutation reported in this paper has a very low allelic frequency in the population (0.0007% GnomAD database) and it has been observed in one subject from a cohort of 174 cases with unexplained cardiac arrest from the CASPER registry (Mellor et al., 2017). The Cavα1.2 Q428E mutation has never been observed, nor it is present in the population genomic databases. Both patients presented with typical Brugada type 1 ECG and mild intraventricular conduction delay. The Q428E carrier also presented J point elevation (ERP) in the inferior leads.
The percentage of CACNA1C mutations that cause a trafficking defect and that can be rescued is clinically relevant since other reported mutations display impaired trafficking (Antzelevitch et al., 2007). Furthermore the fact that many mutations characterized in vitro (Fish and Antzelevitch, 2004; Antzelevitch et al., 2007; Bourdin et al., 2015; Sutphin et al., 2016) cause a loss of current density in the absence of kinetic abnormalities strongly suggest the idea that a trafficking defect is often implicated.
This proof of concept study demonstrates for the first time that it is possible to design therapeutic molecules able to correct the deficient trafficking of mutant LoF Cavα1.2, thereby restoring ICa to WT levels. Although only few LTCC mutations associated with BrS have been functionally characterized so far, it is well established that LoF pathogenic variants cause a reduction in current density (Antzelevitch et al., 2007; Burashnikov et al., 2010; Bourdin et al., 2015), often secondary to a trafficking defect (Antzelevitch et al., 2007; Burashnikov et al., 2010; Bourdin et al., 2015). This mechanism was also found to be responsible for the pathological effect of the two new mutations reported in this study, where impaired forward trafficking and increased protein turnover (reduced half-life) were observed. Notably, these molecular abnormalities were corrected by R7W-MP treatment.
The therapy of BrS is currently based mainly on the use of an ICD, which is associated with various complications, especially when used in young subjects (Miyazaki et al., 2013; Olde Nordkamp et al., 2016). Quinidine has been proposed for patients with contraindications to ICD or to treat electrical storms (Priori et al., 2015). However, its efficacy to prevent cardiac events has not been definitely established and the high incidence of side effects often leads to therapy withdrawal.
Therapeutic peptides are increasingly recognized for their high selectivity and efficiency for the treatment of various diseases (Fosgerau and Hoffmann, 2015). Several are currently under evaluation in clinical trials (~200 peptide drugs in clinical development) and >60 peptide medicines are already approved in the US market. Semaglutide, a peptide-based analog to the human glucagon-like peptide-1, is a recently approved drug for the treatment of type 2 diabetes (Bucheit et al., 2020). Here we tested the hypothesis that our Cavβ2-targeting R7W-MP, regulating the subcellular distribution and life cycle of Cavα1.2 (Rusconi et al., 2016) can be used to selectively modulate cardiac electrophysiology with a demonstrable therapeutic effect. In particular, treatment of Cavα1.2 mutant-transfected cells with R7W-MP restored the interaction between Cavα1.2 and Cavβ2, correcting Cavα1.2 targeting to the plasma membrane through normalization of deficient trafficking and increased Cavα1.2 half-life. These molecular effects lead to a reversal of the electrophysiological abnormalities associated with the Cavα1.2 LoF mutants in both heterologous and cardiac cells. It is particular encouraging that the R7W-MP was not found to alter channel gating properties in agreement with our previous studies, where we also showed that R7W-MP or nanoparticle-loaded MP do not affect cardiomyocyte contractility and Ca2+ handling, or have pro-arrhythmogenic effects in a structurally normal heart (Rusconi et al., 2016; Miragoli et al., 2018). In contrast, previously identified Ca2+ agonists (e.g., BAYK8644) have been associated with unwanted changes in LTCC gating kinetics and altered Ca2+ release from the sarcoplasmic reticulum (Katoh et al., 2000), causing deleterious effects. The future availability of in vivo models accurately replicating the typical transmural heterogeneity of action potential duration and conduction velocity of BrS (Zhang et al., 2015) will be critical for further exploration towards translation to the clinic.
Altogether, we here prove that R7W-MP-treatment is sufficient for correction of defective Cavα1.2 trafficking associated with BrS type 3, which may open a new perspective for the treatment of at least some of the genetic defects causing BrS. Whether or not the same effect can be achieved in the treatment of other LTCC LoF mutants (such as those found in the C-terminal region of Cavα1.2) should be the object of future studies.
In summary, our data provide the evidence that R7W-MP, by controlling the LTCC life cycle, can be used to treat the molecular dysfunctions and electrophysiological consequences of trafficking-defective CACNA1C mutations associated with BrS. To the best of our knowledge the MP mechanism of action represents the first example of an LTCC-targeting therapeutic molecule that can correct ICa defects through modulation of channel density at the plasma membrane. At a broader perspective, it is conceivable to think that MP in combination with safe and cardiac-specific carriers [e.g., inhalable nanoparticles (Di Mauro et al., 2016; Miragoli et al., 2018) or cell-specific targeting aptamers (Thiel et al., 2016; Romanelli et al., 2018)], could lead to the development of a new therapy for LTCC-related BrS, a severe arrhythmogenic disorder for which limited therapeutic options are currently available.
Data Availability Statement
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.
Author Contributions
VDM, PC, FL, JM, NS, and AM performed the experiment and analyzed data. VDM, FL, NS, MLB, SP, and DC wrote the manuscript. DC and SP designed the study. DC and SP acquired the funding for the study. All authors contributed to the article and approved the submitted version.
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Acknowledgments
We thank Diego Morone for assistance with immunofluorescence acquisition and data analysis.
Funding. This work was supported by the Cariplo Foundation (2013-1019) to DC and CN, the Italian Ministry of Health (GR-2011-02352546) to DC, and the Italian Ministry of Research and University (Dipartimenti di Eccellenza 2018–2022 grant) to the Molecular Medicine Department University of Pavia.
Supplementary Material
The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fphys.2020.616819/full#supplementary-material
References
- Antzelevitch C., Pollevick G. D., Cordeiro J. M., Casis O., Sanguinetti M. C., Aizawa Y., et al. (2007). Loss-of-function mutations in the cardiac calcium channel underlie a new clinical entity characterized by ST-segment elevation, short QT intervals, and sudden cardiac death. Circulation 115, 442–449. 10.1161/CIRCULATIONAHA.106.668392, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Bourdin B., Shakeri B., Tétreault M. -P., Sauvé R., Lesage S., Parent L. (2015). Functional characterization of CaV α2δ mutations associated with sudden cardiac death. J. Biol. Chem. 290, 2854–2869. 10.1074/jbc.M114.597930, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Bucheit J. D., Pamulapati L. G., Carter N., Malloy K., Dixon D. L., Sisson E. M. (2020). Oral semaglutide: a review of the first oral glucagon-like peptide 1 receptor agonist. Diabetes Technol. Ther. 22, 10–18. 10.1089/dia.2019.0185, PMID: [DOI] [PubMed] [Google Scholar]
- Burashnikov E., Pfeiffer R., Barajas-Martinez H., Delpón E., Hu D., Desai M., et al. (2010). Mutations in the cardiac L-type calcium channel associated with inherited J-wave syndromes and sudden cardiac death. Heart Rhythm. 7, 1872–1882. 10.1016/j.hrthm.2010.08.026, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Crotti L., Marcou C. A., Tester D. J., Castelletti S., Giudicessi J. R., Torchio M., et al. (2012). Spectrum and prevalence of mutations involving BrS1- through BrS12-susceptibility genes in a cohort of unrelated patients referred for Brugada syndrome genetic testing. J. Am. Coll. Cardiol. 60, 1410–1418. 10.1016/j.jacc.2012.04.037, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Di Mauro V., Iafisco M., Salvarani N., Vacchiano M., Carullo P., Ramírez-Rodríguez G. B., et al. (2016). Bioinspired negatively charged calcium phosphate nanocarriers for cardiac delivery of MicroRNAs. Nanomedicine 11, 891–906. 10.2217/nnm.16.26, PMID: [DOI] [PubMed] [Google Scholar]
- Fish J. M., Antzelevitch C. (2004). Role of sodium and calcium channel block in unmasking the Brugada syndrome. Heart Rhythm. 1, 210–217. 10.1016/j.hrthm.2004.03.061, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Fosgerau K., Hoffmann T. (2015). Peptide therapeutics: current status and future directions. Drug Discov. Today 20, 122–128. 10.1016/j.drudis.2014.10.003, PMID: [DOI] [PubMed] [Google Scholar]
- Katoh H., Schlotthauer K., Bers D. M. (2000). Transmission of information from cardiac dihydropyridine receptor to ryanodine receptor: evidence from BayK 8644 effects on resting Ca2+ Sparks. Circ. Res. 87, 106–111. 10.1161/01.RES.87.2.106 [DOI] [PubMed] [Google Scholar]
- Mellor G., Laksman Z. W. M., Tadros R., Roberts J. D., Gerull B., Simpson C. S., et al. (2017). Genetic testing in the evaluation of unexplained cardiac arrest: from the CASPER (cardiac arrest survivors with preserved ejection fraction registry). Circ. Cardiovasc. Genet. 10:e001686. 10.1161/CIRCGENETICS.116.001686, PMID: [DOI] [PubMed] [Google Scholar]
- Miragoli M., Ceriotti P., Iafisco M., Vacchiano M., Salvarani N., Alogna A., et al. (2018). Inhalation of peptide-loaded nanoparticles improves heart failure. Sci. Transl. Med. 10:eaan6205. 10.1126/scitranslmed.aan6205, PMID: [DOI] [PubMed] [Google Scholar]
- Miyazaki S., Uchiyama T., Komatsu Y., Taniguchi H., Kusa S., Nakamura H., et al. (2013). Long-term complications of implantable defibrillator therapy in Brugada syndrome. Am. J. Cardiol. 111, 1448–1451. 10.1016/j.amjcard.2013.01.295, PMID: [DOI] [PubMed] [Google Scholar]
- Napolitano C., Antzelevitch C. (2011). Phenotypical manifestations of mutations in the genes encoding subunits of the cardiac voltage–dependent L-type calcium channel. Circ. Res. 108, 607–618. 10.1161/CIRCRESAHA.110.224279, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Napolitano C., Bloise R., Monteforte N., Priori S. G. (2012). Sudden cardiac death and genetic ion channelopathies: Long QT, Brugada, short QT, catecholaminergic polymorphic ventricular tachycardia, and idiopathic ventricular fibrillation. Circulation 125, 2027–2034. 10.1161/CIRCULATIONAHA.111.055947, PMID: [DOI] [PubMed] [Google Scholar]
- Olde Nordkamp L. R. A., Postema P. G., Knops R. E., van Dijk N., Limpens J., Wilde A. A. M., et al. (2016). Implantable cardioverter-defibrillator harm in young patients with inherited arrhythmia syndromes: a systematic review and meta-analysis of inappropriate shocks and complications. Heart Rhythm. 13, 443–454. 10.1016/j.hrthm.2015.09.010, PMID: [DOI] [PubMed] [Google Scholar]
- Priori S. G., Blomström-Lundqvist C., Mazzanti A., Blom N., Borggrefe M., Camm J., et al. (2015). 2015 ESC guidelines for the management of patients with ventricular arrhythmias and the prevention of sudden cardiac death: the task force for the management of patients with ventricular arrhythmias and the prevention of sudden cardiac death of the European Society of Cardiology (ESC) endorsed by: Association for European Paediatric and Congenital Cardiology (AEPC). Eur. Heart J. 36, 2793–2867. 10.1093/eurheartj/ehv316, PMID: [DOI] [PubMed] [Google Scholar]
- Priori S. G., Napolitano C. (2018). J-Wave Syndromes. Card. Electrophysiol. Clin. 10, 355–369. 10.1016/j.ccep.2018.02.009 [DOI] [PubMed] [Google Scholar]
- Romanelli A., Affinito A., Avitabile C., Catuogno S., Ceriotti P., Iaboni M., et al. (2018). An anti-PDGFRβ aptamer for selective delivery of small therapeutic peptide to cardiac cells. PLoS One 13:e0193392. 10.1371/journal.pone.0193392, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Rusconi F., Ceriotti P., Miragoli M., Carullo P., Salvarani N., Rocchetti M., et al. (2016). Peptidomimetic targeting of Ca v β2 overcomes Dysregulation of the L-type Calcium Channel density and recovers cardiac function. Circulation 134, 534–546. 10.1161/CIRCULATIONAHA.116.021347, PMID: [DOI] [PubMed] [Google Scholar]
- Simms B. A., Zamponi G. W. (2012). Trafficking and stability of voltage-gated calcium channels. Cell. Mol. Life Sci. 69, 843–856. 10.1007/s00018-011-0843-y, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Sutphin B. S., Boczek N. J., Barajas-Martínez H., Hu D., Ye D., Tester D. J., et al. (2016). Molecular and functional characterization of rare CACNA1C variants in sudden unexplained death in the young. Congenit. Heart Dis. 11, 683–692. 10.1111/chd.12371, PMID: [DOI] [PubMed] [Google Scholar]
- Thiel W. H., Esposito C. L., Dickey D. D., Dassie J. P., Long M. E., Adam J., et al. (2016). Smooth muscle cell–targeted RNA aptamer inhibits neointimal formation. Mol. Ther. 24, 779–787. 10.1038/mt.2015.235, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
- Viard P., Butcher A. J., Halet G., Davies A., Nürnberg B., Heblich F., et al. (2004). PI3K promotes voltage-dependent calcium channel trafficking to the plasma membrane. Nat. Neurosci. 7, 939–946. 10.1038/nn1300, PMID: [DOI] [PubMed] [Google Scholar]
- Zhang J., Sacher F., Hoffmayer K., O’Hara T., Strom M., Cuculich P., et al. (2015). Cardiac electrophysiological substrate underlying the ECG phenotype and Electrogram abnormalities in Brugada syndrome patients. Circulation 131, 1950–1959. 10.1161/CIRCULATIONAHA.114.013698, PMID: [DOI] [PMC free article] [PubMed] [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.