New Insights in CaVβ Subunits: Role in the Regulation of Gene Expression and Cellular Homeostasis

Vergnol, A; Traoré, Massiré; Piétri‐Rouxel, France; Falcone, Sestina

doi:10.3389/fcell.2022.880441

Cited by 6 publications

(3 citation statements)

References 48 publications

(95 reference statements)

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“…The pore-forming subunit α 1D was tagged at the N-terminus preserving channel voltage-gating, while the C-terminus is crucial for regulatory functions that may be perturbed by fusion-tagging. In addition, we considered that alternative tagging of the accessory β-subunit (Conrad et al, 2021; Del Villar et al, 2021; Liu et al, 2020) was unsuitable for our study since Ca V β can bind other Ca 2+ channel isoforms and performs intracellular functions (Vergnol et al, 2022). We developed independent and synergistic cluster analysis workflows on hiPSC-aCM expressing tagged Ca V 1.3 proteins.…”

Section: Discussionmentioning

confidence: 99%

Nanoscale architecture and dynamics of CaV1.3 channel clusters in cardiac myocytes revealed by single channel nanoscopy

Schwenzer,

Tsukanov,

Kohl

et al. 2024

Preprint

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The clustering of L-type calcium channels in cardiac myocytes presents an important mechanism for functional regulation of calcium signaling. Here we applied targeted super-resolution imaging techniques for the study of atrial-specific CaV1.3 channel clusters in human iPSC-derived atrial cardiomyocytes (hiPSC-aCM). We thereby clarified cluster localization, dimensions, architecture, and dynamics, which were largely unexplored previously. Live-cell STimulated Emission Depletion (STED) imaging identified that cell surface-localized clusters contained 9 channel molecules within 120 nm diameter on average. DNA Points Accumulation for Imaging in Nanoscale Topography (DNA-PAINT) optimized for molecular mapping revealed an irregular arrangement of channels with significant spacing. Single Particle Tracking (SPT) further evidenced that clustered channels do not associate into rigidly packed structures (oligomers or lattices), but rather co-diffuse in confined and stationary membrane nanodomains. Immunofluorescence showed consistent cell-surface colocalization with Ryanodine Receptor type 2 and Junctophilin-2 forming stable calcium release units, similar to dyadic junctions containing CaV1.2 in ventricular cardiomyocytes. Lastly, novel genetic constructs for live-cell imaging showed that the cytosolic C-terminal tail of CaV1.3 by itself is sufficient for cluster formation. In conclusion, a novel strategy for LTCC clustering studies in atrial cells was established, suitable for a wide range of super-resolution imaging techniques. Based on live-cell STED, DNA-PAINT and SPT data, we propose that CaV1.3 channel clusters consist of mobile individual channels inside defined membrane nanodomains.

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Section: Discussionmentioning

confidence: 99%

Nanoscale architecture and dynamics of CaV1.3 channel clusters in cardiac myocytes revealed by single channel nanoscopy

Schwenzer,

Tsukanov,

Kohl

et al. 2024

Preprint

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“…20,21 The Cavβ subunits Cavβ1, Cavβ3, and Cavβ4 translocate to the nucleus where they influence gene expression. [22][23][24][25][26] When the electrical activity of innervated adult mouse muscle cells is impaired, the expression of a splice variant of Cavβ1 (Cavβ1e) is upregulated to limit the loss of muscle mass via GDF5 (growth differentiation factor 5). Overexpression of Cavβ1e in aged mice activates the GDF5 signaling pathway and counteracts age-related muscle mass loss.…”

mentioning

confidence: 99%

“…Overexpression of Cavβ1e in aged mice activates the GDF5 signaling pathway and counteracts age-related muscle mass loss. 25,26 In cardiomyocytes, a fraction of Cavβ2 translocates to the nucleus and regulates calpain-dependent hypertrophic signaling pathways. 27 Cavβ1 has been identified in T cells in the absence of functional Cav currents and may play a role in the regulation of T-cell proliferation and apoptosis.…”

mentioning

confidence: 99%

Cavβ3 Contributes to the Maintenance of the Blood-Brain Barrier and Alleviates Symptoms of Experimental Autoimmune Encephalomyelitis

Martus,

Williams,

Pichi

et al. 2024

ATVB

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BACKGROUND: Tight control of cytoplasmic Ca 2+ in endothelial cells is essential for the regulation of endothelial barrier function. Here, we investigated the role of Cavβ3, a subunit of voltage-gated Ca 2+ (Cav) channels, in modulating Ca 2+ signaling in brain microvascular endothelial cells (BMECs) and how this contributes to the integrity of the blood-brain barrier. METHODS: We investigated the function of Cavβ3 in BMECs by Ca 2+ imaging and Western blot, examined the endothelial barrier function in vitro and the integrity of the blood-brain barrier in vivo, and evaluated disease course after induction of experimental autoimmune encephalomyelitis in mice using Cavβ3 −/ − (Cav β3-deficient) mice as controls. RESULTS: We identified Cavβ3 protein in BMECs, but electrophysiological recordings did not reveal significant Cav channel activity. In vivo, blood-brain barrier integrity was reduced in the absence of Cavβ3. After induction of experimental autoimmune encephalomyelitis, Cavβ3 −/− mice showed earlier disease onset with exacerbated clinical disability and increased T-cell infiltration. In vitro, the transendothelial resistance of Cavβ3 −/− BMEC monolayers was lower than that of wild-type BMEC monolayers, and the organization of the junctional protein ZO-1 (zona occludens-1) was impaired. Thrombin stimulates inositol 1,4,5-trisphosphate–dependent Ca 2+ release, which facilitates cell contraction and enhances endothelial barrier permeability via Ca 2+ -dependent phosphorylation of MLC (myosin light chain). These effects were more pronounced in Cavβ3 −/− than in wild-type BMECs, whereas the differences were abolished in the presence of the MLCK (MLC kinase) inhibitor ML-7. Expression of Cacnb3 cDNA in Cavβ3 −/− BMECs restored the wild-type phenotype. Coimmunoprecipitation and mass spectrometry demonstrated the association of Cavβ3 with inositol 1,4,5-trisphosphate receptor proteins. CONCLUSIONS: Independent of its function as a subunit of Cav channels, Cavβ3 interacts with the inositol 1,4,5-trisphosphate receptor and is involved in the tight control of cytoplasmic Ca 2+ and Ca 2+ -dependent MLC phosphorylation in BMECs, and this role of Cavβ3 in BMECs contributes to blood-brain barrier integrity and attenuates the severity of experimental autoimmune encephalomyelitis disease.

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Molecular Mechanisms of Nuclear Transport of the Neuronal Voltage-gated Ca2+ Channel β3 Auxiliary Subunit

et al. 2023

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New Insights in CaVβ Subunits: Role in the Regulation of Gene Expression and Cellular Homeostasis

Cited by 6 publications

References 48 publications

Nanoscale architecture and dynamics of CaV1.3 channel clusters in cardiac myocytes revealed by single channel nanoscopy

Nanoscale architecture and dynamics of CaV1.3 channel clusters in cardiac myocytes revealed by single channel nanoscopy

Cavβ3 Contributes to the Maintenance of the Blood-Brain Barrier and Alleviates Symptoms of Experimental Autoimmune Encephalomyelitis

Molecular Mechanisms of Nuclear Transport of the Neuronal Voltage-gated Ca2+ Channel β3 Auxiliary Subunit

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