Cruz FM et al. (2023), Extracellular cysteine disulfide bond break at ...

XB-ART-59817

bioRxiv 2023 Jun 08; doi: 10.1101/2023.06.07.544151.

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Extracellular cysteine disulfide bond break at Cys122 disrupts PIP 2 -dependent Kir2.1 channel function and leads to arrhythmias in Andersen-Tawil Syndrome.

Cruz FM , Macías Á , Moreno-Manuel AI , Gutiérrez LK , Vera-Pedrosa ML , Martínez-Carrascoso I , Pérez PS , Ruiz Robles JM , Bermúdez-Jiménez FJ , Díaz-Agustín A , Martínez de Benito F , Santiago SA , Braza-Boils A , Martín-Martínez M , Gutierrez-Rodríguez M , Bernal JA , Zorio E , Jiménez-Jaimez J , Jalife J .

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BACKGROUND: Andersen-Tawil Syndrome Type 1 (ATS1) is a rare heritable disease caused by mutations in the strong inwardly rectifying K + channel Kir2.1. The extracellular Cys122-to-Cys154 disulfide bond in the Kir2.1 channel structure is crucial for proper folding, but has not been associated with correct channel function at the membrane. We tested whether a human mutation at the Cys122-to-Cys154 disulfide bridge leads to Kir2.1 channel dysfunction and arrhythmias by reorganizing the overall Kir2.1 channel structure and destabilizing the open state of the channel. METHODS AND RESULTS: We identified a Kir2.1 loss-of-function mutation in Cys122 (c.366 A>T; p.Cys122Tyr) in a family with ATS1. To study the consequences of this mutation on Kir2.1 function we generated a cardiac specific mouse model expressing the Kir2.1 C122Y mutation. Kir2.1 C122Y animals recapitulated the abnormal ECG features of ATS1, like QT prolongation, conduction defects, and increased arrhythmia susceptibility. Kir2.1 C122Y mouse cardiomyocytes showed significantly reduced inward rectifier K + (I K1 ) and inward Na + (I Na ) current densities independently of normal trafficking ability and localization at the sarcolemma and the sarcoplasmic reticulum. Kir2.1 C122Y formed heterotetramers with wildtype (WT) subunits. However, molecular dynamic modeling predicted that the Cys122-to-Cys154 disulfide-bond break induced by the C122Y mutation provoked a conformational change over the 2000 ns simulation, characterized by larger loss of the hydrogen bonds between Kir2.1 and phosphatidylinositol-4,5-bisphosphate (PIP 2 ) than WT. Therefore, consistent with the inability of Kir2.1 C 122 Y channels to bind directly to PIP 2 in bioluminescence resonance energy transfer experiments, the PIP 2 binding pocket was destabilized, resulting in a lower conductance state compared with WT. Accordingly, on inside-out patch-clamping the C122Y mutation significantly blunted Kir2.1 sensitivity to increasing PIP 2 concentrations. CONCLUSION: The extracellular Cys122-to-Cys154 disulfide bond in the tridimensional Kir2.1 channel structure is essential to channel function. We demonstrated that ATS1 mutations that break disulfide bonds in the extracellular domain disrupt PIP 2 -dependent regulation, leading to channel dysfunction and life-threatening arrhythmias. CLINICAL PERSPECTIVE: NOVELTY AND SIGNIFICANCE: What is known? Andersen-Tawil Syndrome Type 1 (ATS1) is a rare arrhythmogenic disease caused by loss-of-function mutations in KCNJ2 , the gene encoding the strong inward rectifier potassium channel Kir2.1 responsible for I K1 . Extracellular Cys 122 and Cys 154 form an intramolecular disulfide bond that is essential for proper Kir2.1 channel folding but not considered vital for channel function. Replacement of Cys 122 or Cys 154 residues in the Kir2.1 channel with either alanine or serine abolished ionic current in Xenopus laevis oocytes. What new information does this article contribute? We generated a mouse model that recapitulates the main cardiac electrical abnormalities of ATS1 patients carrying the C122Y mutation, including prolonged QT interval and life-threatening ventricular arrhythmias.We demonstrate for the first time that a single residue mutation causing a break in the extracellular Cys122-to-Cys154 disulfide-bond leads to Kir2.1 channel dysfunction and arrhythmias in part by reorganizing the overall Kir2.1 channel structure, disrupting PIP2-dependent Kir2.1 channel function and destabilizing the open state of the channel.Defects in Kir2.1 energetic stability alter the functional expression of the voltage-gated cardiac sodium channel Nav1.5, one of the main Kir2.1 interactors in the macromolecular channelosome complex, contributing to the arrhythmias.The data support the idea that susceptibility to arrhythmias and SCD in ATS1 are specific to the type and location of the mutation, so that clinical management should be different for each patient.Altogether, the results may lead to the identification of new molecular targets in the future design of drugs to treat a human disease that currently has no defined therapy.

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Genes referenced: kcnj2 nav1 scd

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	Figure 2. Kir2.1C122Y mice recapitulate the ATS1 patientś phenotype and increased susceptibility to arrhythmias.A: Representative lead-II ECG recordings from AAV-transduced Kir2.1WT (top) and Kir2.1C122Y (bottom) mice. The record shows normal sinus rhythm with prolonged PR interval in mutant animals (N= 7 animals per group). B: ECG in a Kir2.1C122Y animal showing frequent premature ventricular complexes (PVCs) manifested as duplets. C-D: Effects of isoprenaline (ISO, 5 mg/Kg) administration on electrical conduction and QT interval in Kir2.1C122Y animals compared to basal condition (N= 7 animals per group). E: Representative lead-II ECG traces (top) and corresponding intracardiac recordings (bottom) before (SR; sinus rhythm), during and after intracardiac application of stimulus trains at 10 and 25 Hz under basal conditions. E.1, atrial stimulation in a Kir2.1WT mouse failed to induce an arrhythmia. E.2, atrial stimulation in a Kir2.1C122Y mouse induced a period atrial fibrillation. E.3, ventricular stimulation in a Kir2.1C122Y mouse induced polymorphic ventricular tachycardia (PVT). F: Contingency plots of number of animals with arrhythmogenic response after intracardiac stimulation at baseline, and after treatment with ISO (5 mg/Kg). Each value is the mean ± SEM (N=7–9 animals per group). Statistical analysis by two-tailed ANOVA and Student-t test. * p<0.05; ** p<0.01.
	Figure 3. Kir2.1C122Y cardiomyocytes preserve Kir2.1 and NaV1.5 protein trafficking, but both proteins are reduced at the sarcolemma.A: Confocal images of Kir2.1 and Nav1.5 channels in Kir2.1WT and Kir2.1C122Y cardiomyocytes. Scale bar, 10μm. B: Fluorescence intensity profiles show distribution patterns for both Kir2.1 (left panel) and NaV1.5 (right panel) channels in WT and Kir2.1C122Y cardiomyocytes. Note double banding for Kir2.1 indicating SR expression.24 C: Representative immunofluorescence images show co-localization of Kir2.1 (green) and NaV1.5 (red) with Na+/K+ ATPase (white) at the sarcolemma. Graphs show percentage of co-localization with significantly reduced NaV1.5 (* p<0.05; t test). Scale bar, 10μm D: Western blots comparing cytosolic and sarcolemmal Kir2.1 and NaV1.5 in Kir2.1WT vs Kir2.1C122Y cardiomyocytes. Data were normalized using Na+/K+ ATPase. E: Graphs show western blot quantification of cytosolic and sarcolemmal Kir2.1 and NaV1.5 channels. Note reduced NaV1.5 at the sarcolemma (N=4–5 animals per group) (* p<0.05; two-tailed ANOVA). F: Confocal images of classical (AP-1) and unconventional (GRASP65) trafficking routes for Kir2.1 and NaV1.5. Scale bar, 10μm. G: Quantification of fluorescence intensity profiles for AP-1, F-function (% nearest neighbour distances) and percentage of GRASP co-localization in isolated Kir2.1WT and Kir2.1C122Y cardiomyocytes. (N=3 animals per group; n=7–9 cells). (* p<0.05; two-tailed ANOVA). Scale bar, 10μm. Each value is the mean ± SEM.
	Figure 4. Kir2.1C122Y alters electrophysiology in isolated mouse cardiomyocytes.A: Superimposed IK1 current-voltage (IV) relationships for Kir2.1WT (blue) and Kir2.1C122Y (red) cardiomyocytes. B: Superimposed INa IV relationships for Kir2.1WT (blue) and Kir2.1C122Y (red) cardiomyocytes. C: Representative action potential time series recorded during current-clamping in an isolated Kir2.1C122Y cardiomyocyte. Note spontaneous action potentials with excessively long APD generating early afterdepolarizations (EADs) and triggered activity. D: Membrane potential bi-stability in a Kir2.1C122Y mutant with EADs appearing above −20 mV. Graph shows quantification of bi-stability events in a Kir2.1C122Ycardiomyocyte. E: Representative confocal image and profile of calcium transient dynamics in another isolated Kir2.1C122Y cardiomyocyte. Note amplitude bi-stability and large numbers of spontaneous calcium release events spreading throughout the cell. F: Left, Immunolocalization of ryanodine receptor (RyR2) and Ca2+-ATPase (SERCA) in AAV-transduced ventricular cardiomyocytes from Kir2.1WT and Kir2.1C122Y mice. Scale bar, 10μm (N=3 animals per group; n=7–8 cells). Right, western blots showing similar amounts of total protein for both (N=4 animals per group). G: Representative fluorescence profiles of caffeine-induce calcium release in Kir2.1WT and Kir2.1C122Y cardiomyocytes. H: Graphs show amplitude, Tau (Decay kinetics) and Baseline of each Ca2+ transient, as well as the total area) (N=3 animals per group; n=10–17 cells). Each value is represented as the mean ± SEM. Statistical analyses were conducted using two-tailed ANOVA. * p<0.05; p<0.01; ** p<0.0001.
	Figure 5. The C122Y mutation alters Kir2.1 channel conformation and PIP2 binding.A: Topological scheme of Kir2.1 homotetramer channel indicating cysteine positions (yellow). B: Amino acid sequence in Kir family indicating highly conserved extracellular disulfide bond. Cys122 and Cys154 are indicated in Kir2.1 C: Pairwise alignment for full model (Grey, Kir2.1WT; pink, Kir2.1C122Y). D: Upper panel, TMscore matrix of the pairwise alignment for the full model. Values between 0–1, where 1 is the identity. RMSD matrix (middle panel) in angstroms (Å). Lower panel, Table of Gibbs free-energy values (dG) of WT and mutant homo- and heterotetramer. E: Docking modelling of Kir2.1-PiP2 interaction in Kir2.1WT, homo- and heterotetramers of Kir2.1C122Y(see text for detailed explanation of each panel).
	Figure 6. Extracellular disulfide bond break reduces PiP2-dependent Kir2.1 regulation.A: Schematic representation of Kir2.1 tetramer embedded in a bilipid layer. B: Structure of Kir tetramer. Monomers are represented in different colors. C: Illustrative C122 or Y122 sidechain orientation. Superposition of Kir2.1WT (grey) and two representative Kir2.1C122Y monomers (in green the most frequent Y122 orientation, in purple, the minor one). D: Representative illustration of hydrogen bond network between Kir2.2 and PIP2. Same hydrogen bondings as in the generated homology model were tested for Kir2.1. E: Evolution of the C-linker during the MD: from a helix (green) to a less structured linker, as shown by a representative 2000 ns snapshot (grey). F: Histogram representing the average number of PIP2-Kir2.1 hydrogen bonds per residue along the 2000 ns simulation, for Kir2.1WT (blue), Kir2.1WT/C122Y (grey) and Kir2.1WT/C122Y (red). These values are the average of the three replicas and the four chains for each tetramer. G: Histogram representing the percentage of frames in which the ψ dihedral angle of the Pro186 is within those expected for a 310 helix (ψ =−18±30°). For Kir2.1WT/C122Y, A and C represent the non-mutated monomers. H: I176 and M180 Cα-Cα distances between two opposite monomers along the 2000 ns MD. Color code on top. N=3 replicates.
	Figure 7. The C122Y mutation reduces Kir2.1-PIP2 binding capacity and interaction.A: Diagram of Kir2.1 monomer fused to the bioluminescent protein nanoluciferase (Nluc) (adapted from Cabanos et al.25). B: Specific BRET signal of binding Fl-PIP2 to Kir2.1 WT, C122Y and R218W and competition with non-fluorescent PIP2 version. Reduced binding was observed for C122Y and R218W (N=3 replicates per group; n=8–10 wells). C: Representative inside-out recording of IK1 in the absence (black current) and the presence of 25 (blue) and 50 (purple) μg/ml of PiP2. D: Normalized peak currents (I/I0) from −30 to +10 mV show that heterozygous condition abolishes the response to increasing PIP2 concentration. In contrast, in Kir2.1WT-transfected cells inward current increased progressively with PIP2. Both groups maintained an unaltered outward IK1. (n=7). Statistical analyses were conducted using two-tailed ANOVA. * p<0.05; p<0.01; ** p<0.0001

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