Activation of Serine One-Carbon Metabolism by Calcineurin A beta 1 Reduces Myocardial Hypertrophy and Improves Ventricular Function

Background In response to pressure overload, the heart develops ventricular hypertrophy that progressively decompensates and leads to heart failure. This pathological hypertrophy is mediated, among others, by the phosphatase calcineurin and is characterized by metabolic changes that impair energy production by mitochondria. Objectives The authors aimed to determine the role of the calcineurin splicing variant CnAβ1 in the context of cardiac hypertrophy and its mechanism of action. Methods Transgenic mice overexpressing CnAβ1 specifically in cardiomyocytes and mice lacking the unique C-terminal domain in CnAβ1 (CnAβ1Δi12 mice) were used. Pressure overload hypertrophy was induced by transaortic constriction. Cardiac function was measured by echocardiography. Mice were characterized using various molecular analyses. Results In contrast to other calcineurin isoforms, the authors show here that cardiac-specific overexpression of CnAβ1 in transgenic mice reduces cardiac hypertrophy and improves cardiac function. This effect is mediated by activation of serine and one-carbon metabolism, and the production of antioxidant mediators that prevent mitochondrial protein oxidation and preserve ATP production. The induction of enzymes involved in this metabolic pathway by CnAβ1 is dependent on mTOR activity. Inhibition of serine and one-carbon metabolism blocks the beneficial effects of CnAβ1. CnAβ1Δi12 mice show increased cardiac hypertrophy and declined contractility. Conclusions The metabolic reprogramming induced by CnAβ1 redefines the role of calcineurin in the heart and shows for the first time that activation of the serine and one-carbon pathway has beneficial effects on cardiac hypertrophy and function, paving the way for new therapeutic approaches

Potential role of Calcineurin isoform A-β1 in neurovascular niche stem cell dynamics as a therapeutic target

Calcineurin A-β1 (CnAβ1) is a noncanonical isoform of calcium- based protein phosphatase Calcineurin with a unique C-terminal domain that sets it apart from the canonical forms and results in completely different functions and interactions, sometimes directly opposing the effect of standard Cn. The actual roles of CnAβ1 in different tissues have been barely studied so far, however, and any processes it could be part of in the brain in particular are currently unknown. Our preliminary data suggests CnAβ1 could play a role in neural stem cell (NSC) regulation and dynamics; as the natural capabilities for adult neurogenesis and post-injury repair of the brain and its NSCs are limited, any insight on these processes and the potential involvement of CnAβ1 in them could provide new venues for therapeutic and neuroengineering approaches, as they concern neurodegenerative pathologies and cerebrovascular lesions. Further research will be carried out with advanced 3D imaging and tissue clearing techniques in order to verify and expand these findings.This work has been funded by Instituto de Salud Carlos III (ISCIII) through the projects DTS22/00030 co-funded by the European Union, and PT20/00044 co‐funded by European Regional Development Fund "A way to make Europe”. It has also been supported by Ministerio de Ciencia e Innovación through the grant PLEC2022‐009235 funded by MCIN/AEI /10.13039/501100011033 and by the “European Union NextGenerationEU/ PRTR”, and through the grant PID2021-127033OB C21/MCIN/AEI/10.13039/501100011033

Potential role of Calcineurin isoform A-β1 in neurovascular niche stem cell dynamics as a therapeutic target

Calcineurin A-β1 (CnAβ1) is a noncanonical isoform of calcium- based protein phosphatase Calcineurin with a unique C-terminal domain that sets it apart from the canonical forms and results in completely different functions and interactions, sometimes directly opposing the effect of standard Cn. The actual roles of CnAβ1 in different tissues have been barely studied so far, however, and any processes it could be part of in the brain in particular are currently unknown. Our preliminary data suggests CnAβ1 could play a role in neural stem cell (NSC) regulation and dynamics; as the natural capabilities for adult neurogenesis and post-injury repair of the brain and its NSCs are limited, any insight on these processes and the potential involvement of CnAβ1 in them could provide new venues for therapeutic and neuroengineering approaches, as they concern neurodegenerative pathologies and cerebrovascular lesions. Further research will be carried out with advanced 3D imaging and tissue clearing techniques in order to verify and expand these findings.This work has been funded by Instituto de Salud Carlos III (ISCIII) through the projects DTS22/00030 co-funded by the European Union, and PT20/00044 co‐funded by European Regional Development Fund "A way to make Europe”. It has also been supported by Ministerio de Ciencia e Innovación through the grant PLEC2022‐009235 funded by MCIN/AEI /10.13039/501100011033 and by the “European Union NextGenerationEU/ PRTR”, and through the grant PID2021-127033OB C21/MCIN/AEI/10.13039/501100011033

Calcineurin splicing variant calcineurin Aβ1 improves cardiac function after myocardial infarction without inducing hypertrophy

BACKGROUND: Calcineurin is a calcium-regulated phosphatase that plays a major role in cardiac hypertrophy. We previously described that alternative splicing of the calcineurin Aβ (CnAβ) gene generates the CnAβ1 isoform, with a unique C-terminal region that is different from the autoinhibitory domain present in all other CnA isoforms. In skeletal muscle, CnAβ1 is necessary for myoblast proliferation and stimulates regeneration, reducing fibrosis and accelerating the resolution of inflammation. Its role in the heart is currently unknown. METHODS AND RESULTS: We generated transgenic mice overexpressing CnAβ1 in postnatal cardiomyocytes under the control of the α-myosin heavy chain promoter. In contrast to previous studies using an artificially truncated calcineurin, CnAβ1 overexpression did not induce cardiac hypertrophy. Moreover, transgenic mice showed improved cardiac function and reduced scar formation after myocardial infarction, with reduced neutrophil and macrophage infiltration and decreased expression of proinflammatory cytokines. Immunoprecipitation and Western blot analysis showed interaction of CnAβ1 with the mTOR complex 2 and activation of the Akt/SGK cardioprotective pathway in a PI3K-independent manner. In addition, gene expression profiling revealed that CnAβ1 activated the transcription factor ATF4 downstream of the Akt/mTOR pathway to promote the amino acid biosynthesis program, to reduce protein catabolism, and to induce the antifibrotic and antiinflammatory factor growth differentiation factor 15, which protects the heart through Akt activation. CONCLUSIONS: Calcineurin Aβ1 shows a unique mode of action that improves cardiac function after myocardial infarction, activating different cardioprotective pathways without inducing maladaptive hypertrophy. These features make CnAβ1 an attractive candidate for the development of future therapeutic approaches.British Heart Foundation [PG/07/020/22503]; Spanish Ministry of Science and Innovation [BFU2009-10016]; National Institutes of Health Research, Cardiovascular Biomedical Research Unit at the Royal Brompton; Hare-field NHS Foundation Trust; Imperial College; Spanish Fondo Nacional de Investigaciones Sanitarias [EIF-040545, ERG-239158, CP08/00144

Follistatin-like 3 mediates paracrine fibroblast activation by cardiomyocytes

Follistatins are extracellular inhibitors of the TGF-β family ligands including activin A, myostatin and bone morphogenetic proteins. Follistatin-like 3 (FSTL3) is a potent inhibitor of activin signalling and antagonises the cardioprotective role of activin A in the heart. FSTL3 expression is elevated in patients with heart failure and is upregulated in cardiomyocytes by hypertrophic stimuli, but its role in cardiac remodelling is largely unknown. Here, we show that the production of FSTL3 by cardiomyocytes contributes to the paracrine activation of cardiac fibroblasts, inducing changes in cell adhesion, promoting proliferation and increasing collagen production. We found that FSTL3 is necessary for this response and for the induction of cardiac fibrosis. However, full activation requires additional factors, and we identify connective tissue growth factor as a FSTL3 binding partner in this process. Together, our data unveil a novel mechanism of paracrine communication between cardiomyocytes and fibroblasts that may provide potential as a therapeutic target in heart remodelling.British Heart Foundation [PG/08/084/25827]; Heart Research UK; National Institute for Health Research Cardiovascular Biomedical Research Unit at the Royal Brompton; Harefield NHS Foundation Trust; Imperial College; European Union [ERG-239158, ITN-289600]; Spanish Ministry of Science and Innovation [BFU2009-10016, CP08/00144]; Regional Government of Madrid [S2010/BMD-2321 'Fibroteam']S

Alternative Splicing of NOX4 in the Failing Human Heart

Increased oxidative stress is a major contributor to the development and progression of heart failure, however, our knowledge on the role of the distinct NADPH oxidase (NOX) isoenzymes, especially on NOX4 is controversial. Therefore, we aimed to characterize NOX4 expression in human samples from healthy and failing hearts. Explanted human heart samples (left and right ventricular, and septal regions) were obtained from patients suffering from heart failure of ischemic or dilated origin. Control samples were obtained from donor hearts that were not used for transplantation. Deep RNA sequencing of the cardiac transcriptome indicated extensive alternative splicing of the NOX4 gene in heart failure as compared to samples from healthy donor hearts. Long distance PCR analysis with a universal 5'-3' end primer pair, allowing amplification of different splice variants, confirmed the presence of the splice variants. To assess translation of the alternatively spliced transcripts we determined protein expression of NOX4 by using a specific antibody recognizing a conserved region in all variants. Western blot analysis showed up-regulation of the full-length NOX4 in ischemic cardiomyopathy samples and confirmed presence of shorter isoforms both in control and failing samples with disease-associated expression pattern. We describe here for the first time that NOX4 undergoes extensive alternative splicing in human hearts which gives rise to the expression of different enzyme isoforms. The full length NOX4 is significantly upregulated in ischemic cardiomyopathy suggesting a role for NOX4 in ROS production during heart failure

Hepatitis B Virus X Protein Drives Multiple Cross-Talk Cascade Loops Involving NF-κB, 5-LOX, OPN and Capn4 to Promote Cell Migration

Hepatitis B virus X protein (HBx) plays an important role in the development of hepatocellular carcinoma (HCC). However, the mechanism remains unclear. Recently, we have reported that HBx promotes hepatoma cell migration through the upregulation of calpain small subunit 1 (Capn4). In addition, several reports have revealed that osteopontin (OPN) plays important roles in tumor cell migration. In this study, we investigated the signaling pathways involving the promotion of cell migration mediated by HBx. We report that HBx stimulates several factors in a network manner to promote hepatoma cell migration. We showed that HBx was able to upregulate the expression of osteopontin (OPN) through 5-lipoxygenase (5-LOX) in HepG2-X/H7402-X (stable HBx-transfected cells) cells. Furthermore, we identified that HBx could increase the expression of 5-LOX through nuclear factor-κB (NF-κB). We also found that OPN could upregulate Capn4 through NF-κB. Interestingly, we showed that Capn4 was able to upregulate OPN through NF-κB in a positive feedback manner, suggesting that the OPN and Capn4 proteins involving cell migration affect each other in a network through NF-κB. Importantly, NF-κB plays a crucial role in the regulation of 5-LOX, OPN and Capn4. Thus, we conclude that HBx drives multiple cross-talk cascade loops involving NF-κB, 5-LOX, OPN and Capn4 to promote cell migration. This finding provides new insight into the mechanism involving the promotion of cell migration by HBx

Author Correction: WWP2 regulates pathological cardiac fibrosis by modulating SMAD2 signaling.

An amendment to this paper has been published and can be accessed via a link at the top of the paper