Paracrine signalling by cardiac calcitonin controls atrial fibrogenesis and arrhythmia

Atrial fibrillation, the most common cardiac arrhythmia, is an important contributor to mortality and morbidity, and particularly to the risk of stroke in humans1. Atrial-tissue fibrosis is a central pathophysiological feature of atrial fibrillation that also hampers its treatment; the underlying molecular mechanisms are poorly understood and warrant investigation given the inadequacy of present therapies2. Here we show that calcitonin, a hormone product of the thyroid gland involved in bone metabolism3, is also produced by atrial cardiomyocytes in substantial quantities and acts as a paracrine signal that affects neighbouring collagen-producing fibroblasts to control their proliferation and secretion of extracellular matrix proteins. Global disruption of calcitonin receptor signalling in mice causes atrial fibrosis and increases susceptibility to atrial fibrillation. In mice in which liver kinase B1 is knocked down specifically in the atria, atrial-specific knockdown of calcitonin promotes atrial fibrosis and increases and prolongs spontaneous episodes of atrial fibrillation, whereas atrial-specific overexpression of calcitonin prevents both atrial fibrosis and fibrillation. Human patients with persistent atrial fibrillation show sixfold lower levels of myocardial calcitonin compared to control individuals with normal heart rhythm, with loss of calcitonin receptors in the fibroblast membrane. Although transcriptome analysis of human atrial fibroblasts reveals little change after exposure to calcitonin, proteomic analysis shows extensive alterations in extracellular matrix proteins and pathways related to fibrogenesis, infection and immune responses, and transcriptional regulation. Strategies to restore disrupted myocardial calcitonin signalling thus may offer therapeutic avenues for patients with atrial fibrillation

Loss of Protein Phosphatase 1 Regulatory Subunit PPP1R3A Promotes Atrial Fibrillation

BACKGROUND: Abnormal calcium (Ca2+) release from the sarcoplasmic reticulum (SR) contributes to the pathogenesis of atrial fibrillation (AF). Increased phosphorylation of 2 proteins essential for normal SR-Ca2+ cycling, the type-2 ryanodine receptor (RyR2) and phospholamban (PLN), enhances the susceptibility to AF, but the underlying mechanisms remain unclear. Protein phosphatase 1 (PP1) limits steady-state phosphorylation of both RyR2 and PLN. Proteomic analysis uncovered a novel PP1-regulatory subunit (PPP1R3A [PP1 regulatory subunit type 3A]) in the RyR2 macromolecular channel complex that has been previously shown to mediate PP1 targeting to PLN. We tested the hypothesis that reduced PPP1R3A levels contribute to AF pathogenesis by reducing PP1 binding to both RyR2 and PLN. METHODS: Immunoprecipitation, mass spectrometry, and complexome profiling were performed from the atrial tissue of patients with AF and from cardiac lysates of wild-type and Pln-knockout mice. Ppp1r3a-knockout mice were generated by CRISPR-mediated deletion of exons 2 to 3. Ppp1r3a-knockout mice and wild-type littermates were subjected to in vivo programmed electrical stimulation to determine AF susceptibility. Isolated atrial cardiomyocytes were used for Stimulated Emission Depletion superresolution microscopy and confocal Ca2+ imaging. RESULTS: Proteomics identified the PP1-regulatory subunit PPP1R3A as a novel RyR2-binding partner, and coimmunoprecipitation confirmed PPP1R3A binding to RyR2 and PLN. Complexome profiling and Stimulated Emission Depletion imaging revealed that PLN is present in the PPP1R3A-RyR2 interaction, suggesting the existence of a previously unknown SR nanodomain composed of both RyR2 and PLN/sarco/endoplasmic reticulum calcium ATPase-2a macromolecular complexes. This novel RyR2/PLN/sarco/endoplasmic reticulum calcium ATPase-2a complex was also identified in human atria. Genetic ablation of Ppp1r3a in mice impaired binding of PP1 to both RyR2 and PLN. Reduced PP1 targeting was associated with increased phosphorylation of RyR2 and PLN, aberrant SR-Ca2+ release in atrial cardiomyocytes, and enhanced susceptibility to pacing-induced AF. Finally, PPP1R3A was progressively downregulated in the atria of patients with paroxysmal and persistent (chronic) AF. CONCLUSIONS: PPP1R3A is a novel PP1-regulatory subunit within the RyR2 channel complex. Reduced PPP1R3A levels impair PP1 targeting and increase phosphorylation of both RyR2 and PLN. PPP1R3A deficiency promotes abnormal SR-Ca2+ release and increases AF susceptibility in mice. Given that PPP1R3A is downregulated in patients with AF, this regulatory subunit may represent a new target for AF therapeutic strategies

Loss of SPEG Inhibitory Phosphorylation of RyR2 Promotes Atrial Fibrillation

Background: Enhanced diastolic calcium (Ca2+) release via ryanodine receptor type-2 (RyR2) has been implicated in atrial fibrillation (AF) promotion. Diastolic sarcoplasmic reticulum (SR) Ca2+ leak is caused by increased RyR2 phosphorylation by protein kinase A (PKA) or Ca2+/calmodulin-dependent kinase-II (CaMKII) phosphorylation, or less dephosphorylation by protein phosphatases. However, considerable controversy remains regarding the molecular mechanisms underlying altered RyR2 function in AF. We thus sought to determine the role of 'striated muscle preferentially expressed protein kinase' (SPEG), a novel regulator of RyR2 phosphorylation, in AF pathogenesis. Methods: Western blotting was performed with right atrial biopsies from paroxysmal (p)AF patients. SPEG atrial knock-out (aKO) mice were generated using adeno-associated virus 9 (AAV9). In mice, AF inducibility was determined using intracardiac programmed electrical stimulation (PES), and diastolic Ca2+ leak in atrial cardiomyocytes was assessed using confocal Ca2+ imaging. Phospho-proteomics studies and western blotting were used to measure RyR2 phosphorylation. In order to test the effects of RyR2-S2367 phosphorylation, knock-in mice with an inactivated S2367 phosphorylation site (S2367A) and a constitutively activated S2367 residue (S2367D) were generated using CRISPR-Cas9. Results: Western blotting revealed decreased SPEG protein levels in atrial biopsies from pAF patients in comparison to patients in sinus rhythm. SPEG aKO mice exhibited increased susceptibility to pacing-induced AF by PES and enhanced Ca2+ spark frequency in atrial cardiomyocytes with Ca2+ imaging, establishing a causal role for decreased SPEG in AF pathogenesis. Phospho-proteomics in hearts from SPEG cardiomyocyte knock-out mice identified RyR2-S2367 as a novel kinase substrate of SPEG. Additionally, western blotting demonstrated that RyR2-S2367 phosphorylation was also decreased in pAF patients. RyR2-S2367A mice exhibited an increased susceptibility to pacing-induced AF as well as aberrant atrial SR Ca2+ leak. In contrast, RyR2-S2367D mice were resistant to pacing-induced AF. Conclusions: Unlike other kinases (PKA, CaMKII) that increase RyR2 activity, SPEG phosphorylation reduces RyR2-mediated SR Ca2+-release. Reduced SPEG levels and RyR2-S2367 phosphorylation typified patients with pAF. Studies in S2367 knock-in mouse models showed a causal relationship between reduced S2367 phosphorylation and AF susceptibility. Thus, modulating SPEG activity and phosphorylation levels of the novel S2367 site on RyR2 may represent a novel target for AF treatment

Loss of SPEG Inhibitory Phosphorylation of RyR2 Promotes Atrial Fibrillation

Background: Enhanced diastolic calcium (Ca2+) release via ryanodine receptor type-2 (RyR2) has been implicated in atrial fibrillation (AF) promotion. Diastolic sarcoplasmic reticulum (SR) Ca2+ leak is caused by increased RyR2 phosphorylation by protein kinase A (PKA) or Ca2+/calmodulin-dependent kinase-II (CaMKII) phosphorylation, or less dephosphorylation by protein phosphatases. However, considerable controversy remains regarding the molecular mechanisms underlying altered RyR2 function in AF. We thus sought to determine the role of 'striated muscle preferentially expressed protein kinase' (SPEG), a novel regulator of RyR2 phosphorylation, in AF pathogenesis. Methods: Western blotting was performed with right atrial biopsies from paroxysmal (p)AF patients. SPEG atrial knock-out (aKO) mice were generated using adeno-associated virus 9 (AAV9). In mice, AF inducibility was determined using intracardiac programmed electrical stimulation (PES), and diastolic Ca2+ leak in atrial cardiomyocytes was assessed using confocal Ca2+ imaging. Phospho-proteomics studies and western blotting were used to measure RyR2 phosphorylation. In order to test the effects of RyR2-S2367 phosphorylation, knock-in mice with an inactivated S2367 phosphorylation site (S2367A) and a constitutively activated S2367 residue (S2367D) were generated using CRISPR-Cas9. Results: Western blotting revealed decreased SPEG protein levels in atrial biopsies from pAF patients in comparison to patients in sinus rhythm. SPEG aKO mice exhibited increased susceptibility to pacing-induced AF by PES and enhanced Ca2+ spark frequency in atrial cardiomyocytes with Ca2+ imaging, establishing a causal role for decreased SPEG in AF pathogenesis. Phospho-proteomics in hearts from SPEG cardiomyocyte knock-out mice identified RyR2-S2367 as a novel kinase substrate of SPEG. Additionally, western blotting demonstrated that RyR2-S2367 phosphorylation was also decreased in pAF patients. RyR2-S2367A mice exhibited an increased susceptibility to pacing-induced AF as well as aberrant atrial SR Ca2+ leak. In contrast, RyR2-S2367D mice were resistant to pacing-induced AF. Conclusions: Unlike other kinases (PKA, CaMKII) that increase RyR2 activity, SPEG phosphorylation reduces RyR2-mediated SR Ca2+-release. Reduced SPEG levels and RyR2-S2367 phosphorylation typified patients with pAF. Studies in S2367 knock-in mouse models showed a causal relationship between reduced S2367 phosphorylation and AF susceptibility. Thus, modulating SPEG activity and phosphorylation levels of the novel S2367 site on RyR2 may represent a novel target for AF treatment