NEDD4L intramolecular interactions regulate its auto and substrate NaV1.5 ubiquitination

NEDD4L is a HECT-type E3 ligase that catalyzes the addition of ubiquitin to intracellular substrates such as the cardiac voltage-gated sodium channel, NaV1.5. The intramolecular interactions of NEDD4L regulate its enzymatic activity which is essential for proteostasis. For NaV1.5, this process is critical as alterations in Na+ current is involved in cardiac diseases including arrhythmias and heart failure. In this study, we perform extensive biochemical and functional analyses that implicate the C2 domain and the first WW-linker (1,2-linker) in the autoregulatory mechanism of NEDD4L. Through in vitro and electrophysiological experiments, the NEDD4L 1,2-linker was determined to be important in substrate ubiquitination of NaV1.5. We establish the preferred sites of ubiquitination of NEDD4L to be in the second WW-linker (2,3-linker). Interestingly, NEDD4L ubiquitinates the cytoplasmic linker between the first and second transmembrane domains of the channel (DI-DII) of NaV1.5. Moreover, we design a genetically encoded modulator of Nav1.5 that achieves Na+ current reduction using the NEDD4L HECT domain as cargo of a NaV1.5-binding nanobody. These investigations elucidate the mechanisms regulating the NEDD4 family and furnish a new molecular framework for understanding NaV1.5 ubiquitination.

Functional remodeling of the mitochondrial Ca2+ uniporter complex in metabolic cardiomyopathy

Funding Acknowledgements

Type of funding sources: Foundation. Main funding source(s): Fondation pour la Recherche Médicale

ANR

Background

Calcium (Ca2+) uptake through the mitochondrial Ca2+ uniporter complex (MCUC) controls keys steps of the oxidative metabolism. In metabolic cardiomyopathy, myocardial mitochondrial Ca2+ uptake is impaired, but whether it is an early feature of the pathology remain unsolved.

Purpose

To establish whether mitochondrial Ca2+ dynamics and MCUC structure and function are affected at the early stage of the metabolic cardiomyopathy.

Methods and Results

Mice fed two weeks with a high fat sucrose diet display early features of metabolic disorders and diastolic dysfunction. Concomitantly, mitochondrial Ca2+-dependent pyruvate dehydrogenase activity and the beat-to-beat mitochondrial Ca2+ uptake are reduced. The impaired mitochondrial Ca2+ uptake was further confirmed by single channel recordings of the native MCUC incorporated in planar lipid bilayer demonstrating a reduction of the ion conductance and the open probability. The MCUC biochemical analysis showed an elevation of the EMRE subunit expression and an increase interaction of EMRE with the MICU1 subunits. Co-immunoprecipitation also revealed a deceased interaction of the pore forming subunits MCU with EMRE-MICU1 subcomplex. The displacement of the MCUC assembly was confirmed by the decrease in m-AAA protease-interacting protein 1 expression as well as its loss of binding with EMRE.

Conclusions

The remodeling of the MCUC integrity impacts mitochondrial Ca2+ homeostasis at the early stage of the metabolic cardiomyopathy and provides a novel post-translational paradigm of the MCUC regulation in pathophysiological context.

The increase of extracellular Ca2+ from physiological concentrations to hypercalcemia impairs sino-atrial automaticity

Funding Acknowledgements

Type of funding sources: Foundation. Main funding source(s): ESC FRM Lefoulon Delalande

Aims

To investigate whether extracellular hypercalcemia alters the conduction through L-type Ca2+ channels (LTCCs), impairing the pacemaker activity of the heart.

Introduction

In the sino-atrial node (SAN), membrane currents and the dynamics of intracellular Ca2+ ([Ca2+]i) generate the pacemaker activity of the heart. SAN dysfunctions (SNDs) harm heart automaticity and have been associated with abnormal dynamics of [Ca2+]i. The LTCCs, Cav1.2 and Cav1.3 carry the main Ca2+ influx of SAN cells, which is necessary to sustain [Ca2+]i dynamics. Modified extracellular Ca2+ ([Ca2+]o) could alter Ca2+ influx through these channels. For example, cancer and hyperparathyroidism can raise [Ca2+]o, causing an extracellular hypercalcemia that could alter [Ca2+]i dynamics and impair SAN activity and heart automaticity.

Methods and results

To test this hypothesis, we measured contractions, [Ca2+]i release and L-type Ca2+ current (ICa,L) in spontaneous cells of the murine SAN. Then, we recorded rate and propagation of the spontaneous action potentials (APs) generated by the SAN tissue ex-vivo.

In spontaneously beating SAN cells, we observed that the modification of [Ca2+]o affected [Ca2+]i and cell contractility through changes of ICa,L. In particular, the increase of [Ca2+]o dysregulated pacemaker activity, likely through excessive Ca2+ influx mediated by Cav1.2.

[Ca2+]o increase to hypercalcemia induced arrhythmia also in the intact SAN tissues, activating ectopic leading regions of pacemaking and impairing conduction towards the atria.

Conclusions

Hypercalcemia causes excessive Cav1.2-mediated Ca2+ influx, which alters [Ca2+]I leading to pacemaker impairment. Modulation of LTCC may reduce pacemaker dysfunctions, preventing SND progression.

Concomitant genetic ablation of L-type Cav1.3 (α1D) and T-type Cav3.1 (α1G) Ca2+ channels disrupts heart automaticity

Cardiac automaticity is set by pacemaker activity of the sinus node (SAN). In addition to the ubiquitously expressed cardiac voltage-gated L-type Ca_v1.2 Ca²⁺ channel isoform, pacemaker cells within the SAN and the atrioventricular node co-express voltage-gated L-type Ca_v1.3 and T-type Ca_v3.1 Ca²⁺ channels (SAN-VGCCs). The role of SAN-VGCCs in automaticity is incompletely understood. We used knockout mice carrying individual genetic ablation of Ca_v1.3 (Ca_v1.3^−/−) or Ca_v3.1 (Ca_v3.1^−/−) channels and double mutant Ca_v1.3^−/−/Ca_v3.1^−/− mice expressing only Ca_v1.2 channels. We show that concomitant loss of SAN-VGCCs prevents physiological SAN automaticity, blocks impulse conduction and compromises ventricular rhythmicity. Coexpression of SAN-VGCCs is necessary for impulse formation in the central SAN. In mice lacking SAN-VGCCs, residual pacemaker activity is predominantly generated in peripheral nodal and extranodal sites by f-channels and TTX-sensitive Na⁺ channels. In beating SAN cells, ablation of SAN-VGCCs disrupted late diastolic local intracellular Ca²⁺ release, which demonstrates an important role for these channels in supporting the sarcoplasmic reticulum based “Ca²⁺clock” mechanism during normal pacemaking. These data implicate an underappreciated role for co-expression of SAN-VGCCs in heart automaticity and define an integral role for these channels in mechanisms that control the heartbeat.