Project description:Loss of cardiomyocytes (CMs) following injury can lead to myocardial dysfunction, heart failure (HF) and ultimately death. The limited regenerative ability of the adult human heart after injury, however, poses a significant obstacle to restore cardiac function effectively. While mammalian hearts, including those of mice and humans, do have the potential to regenerate, this capacity is restricted to a narrow window during early stages of life. The molecular mechanisms governing the regenerative capacity of mammalian hearts remain incompletely understood. Exploring a comparative transcriptome analysis in regenerative neonatal vs. non-regenerative adult mouse CMs, we identified N-Cadherin, a member of Ca2+-dependent cell adhesion protein cadherin superfamily, as a potential novel regulator of CM proliferation/renewal. The primary objectives of this study were to elucidate the molecular mechanisms through which N-Cadherin regulates cardiomyocyte proliferation and regeneration, and to determine the therapeutic potential to promote CM renewal and restore cardiac function following injury by targeting N-Cadherin. Cardiac N-Cadherin expression exhibits a strong positive correlation with that of cell cycle- and proliferation-related genes. Its expression levels show an age-dependent reduction, with a 75% decrease of N-Cadherin in adult, compared to P1 neonatal, CMs. N-Cadherin expression is upregulated in the neonatal mouse heart in response to apical resection, especially in the peri-injury region, coinciding with increased CM mitotic activities in the neonatal heart. Knocking down N-Cadherin reduced, whereas overexpression of N-Cadherin increased, the proliferation activity of neonatal mouse CMs and human induced pluripotent stem cell-derived CMs. Mechanistically, increased N-Cadherin potentiates CM renewal through direct binding with and stabilization of a pro-mitotic transcription regulator β-Catenin, leading to increased CMs proliferative activity. Deletion of β-Catenin-binding domain on N-Cadherin abrogated its pro-regenerative activity. Importantly, targeted depletion of N-Cadherin in CMs resulted in incomplete cardiac repair/regeneration and excessive fibrotic scar formation in neonatal mouse hearts following injury. Cardiac-specific overexpression of N-Cadherin in adult mouse heart using adeno-associated viral vectors, by contrast, resulted in increased CM proliferation and protected against myocardial infarction-induced adverse remodeling and contractile dysfunction. Adherent junction protein N-cadherin is demonstrated to play a crucial role in maintaining CM renewal potential by post-translational stabilization of β-Catenin. Enhancing N-cadherin expression levels and downstream signaling activities in the heart, therefore, could be a powerful new approach to promote cardiac regeneration and restore myocardial function in adult human heart following injury.

Project description:Adult cardiomyocytes (CM) are terminally differentiated cells with minimal regenerative capacity, making cardiac tissue particularly vulnerable to injury. Thus, defining the roadblocks responsible for adult CM cell cycle arrest lies at the core of developing therapies to regenerate myocyte loss following injurious events such as myocardial infarction. We have previously shown that inactivating the p53/Mdm2 tumor suppressor circuitry, specifically in the heart (using the Cre-loxP recombination system of bacteriophage P1), can allow differentiated CMs to regain proliferative capacity, through an upregulation of factors involved in cell cycle re-entry. These factors are repressed in quiescent CMs, in part through the action of microRNAs (miRNAs). Notably, knockout of either p53 or Mdm2 individually was insufficient to promote CM proliferation. Therefore, we hypothesized that inactivation of p53/Mdm2-regulated miRNAs could promote the expression of cell cycle activators and induce proliferation of adult murine CMs. To identify miRNAs regulated by both p53 and Mdm2, total miRNA expression profiles from cardiac specific p53/Mdm2 double knockout (DKO) mouse hearts were compared with those from cardiac-specific single knockouts (p53KO and Mdm2KO), and vehicle-injected controls using the Nanostring nCounter mouse miRNA expression assay. This revealed a profile of 11 significantly downregulated miRNAs in the proliferative DKO hearts (versus vehicle-injected control), that were enriched for mRNA targets involved in cell cycle regulation. In vitro studies have demonstrated that knockdown of these 11 miRNAs in neonatal rat cardiomyocytes can increase the occurrence of cytokinetic events. Ultimately, we aim to inject antagomirs targeting these miRNAs into animals post-myocardial infarction to determine the effect of p53/Mdm2-regulated miRNAs on heart function and CM proliferation in vivo.

Project description:After myocardial infarction (MI), the heart fails to renew, and the cardiac microenvironment is irreversibly disrupted. Inactivation of the Hippo signaling pathway can rebuild the post ischemic microenvironment and improve cardiac function. We investigated spatially resolved cellular relationships of neonatal and adult renewal-competent hearts to gain insight into inefficient mammalian heart renewal. Spatial transcriptomics (ST) and single-cell sequencing of adult control hearts and hearts expressing YAP5SA, an active version of the Hippo signaling pathway effector YAP, which models heart renewal, revealed a conserved, renewal-competent cardiomyocyte (CM) population in control hearts and amplified in YAP5SA hearts. This CM population was also found in the wildtype, renewal competent neonatal heart after myocardial infarction, as well as the adult human heart. Cardiac fibroblasts (CFs), expressing complement C3, colocalized with these CMs. In YAP5SA hearts and neonatal hearts post-MI, macrophages (MPs) expressing complement receptor C3ar1 also colocalized, creating a pro-renewal niche composed of the CM, CF and MP triad. Both C3 and C3ar1 loss-of-function in YAP5SA hearts similarly suppressed heart renewal, indicating that C3-expressing CFs, C3ar1-expressing MPs, and complement system signaling play a direct role in heart renewal

Project description:Cardiomyocyte (CM) loss after injury results in adverse remodelling and fibrosis, which inevitably lead to heart failure. Neuregulin-ErbB2 and Hippo-Yap signaling pathways are key mediators of CM proliferation and regeneration although the crosstalk between these pathways is unclear. Here, we demonstrate in mice that temporal over-expression (OE) of activated ErbB2 in CMs promotes cardiac regeneration in a heart failure model. Cellularly, OE CMs present an EMT-like regenerative response involving cytoskeletal reprograming, migration, ECM turnover, and displacement. Molecularly, we identified Yap as a critical mediator of ErbB2 signaling. In OE CMs, Yap interacts with nuclear envelope and cytoskeletal components, reflective of the altered mechanic state elicited by ErbB2. Hippo-independent activating phosphorylation on Yap at S352 and S274 were enriched in OE CMs, peaking during metaphase. Viral overexpression of Yap phospho-mutants dampened the proliferative competence of OE CMs. Taken together, we demonstrate a potent ErbB2-mediated Yap mechanosensory signaling involving EMT-like characteristics, resulting in heart regeneration.

Project description:Contrary to adult mammals, zebrafish are able to regenerate their heart after cardiac injury. This regenerative response relies, in part, on the endogenous ability of cardiomyocytes (CMs) to dedifferentiate and proliferate to replenish the lost muscle. However, CM heterogeneity and population dynamics during development and regeneration remain poorly understood. Through comparative transcriptomic analyses of the developing and adult zebrafish heart, we identified tnnc2 and tnni4b.3 expression as markers for CMs at early and late developmental stages, respectively. Using newly developed reporter lines for these genes, we investigated their expression dynamics during development and regeneration, and observed interesting expression patterns. tnnc2 reporter lines label most CMs at embryonic stages, and this labeling declines rapidly during larval stages; in adult hearts expression is only detectable in a subset of CMs. Conversely, expression of a tnni4b.3 reporter is initially visible in outer curvature CMs at larval stages, and it is subsequently present in a vast majority of the CMs in adult hearts. Interestingly, we find that the adult CMs labeled by the embryonic reporter display higher levels of Tg(tp1:EGFP) expression, which indicates active Notch signaling. To further characterize this CM population, we performed transcriptomic analysis and found that it expresses genes encoding components of the Notch signaling pathway as well as markers of immature CMs. Moreover, during heart regeneration, proliferating CMs in the injured area activate the embryonic CM reporter. Overall, our findings provide further evidence of cardiomyocyte heterogeneity in the adult zebrafish heart.

Project description:The inability of the adult mammalian heart to regenerate represents a fundamental barrier in heart failure management. In contrast, the neonatal heart retains a transient regenerative capacity, but the underlying mechanisms are not fully understood. Wnt/β-catenin signaling has been suggested as a key cardio-regenerative pathway. Here, we show that Wnt/β-catenin signaling potentiates neonatal mouse cardiomyocyte proliferation in vivo and immature human pluripotent stem cell-derived cardiomyocyte (hPSC-CM) proliferation in vitro. In contrast, Wnt/β-catenin signaling in adult mice is cardioprotective but fails to induce cardiomyocyte proliferation. Transcriptional profiling of neonatal mouse and hPSC-CM revealed a core Wnt/β-catenin-dependent transcriptional network governing cardiomyocyte proliferation. In contrast, β-catenin failed to re-engage this proliferative gene network in the adult heart, which instead reverted to a neonatal-like glycolytic program. These findings suggest that Wnt/β-catenin drives distinct transcriptional networks in regenerative and non-regenerative cardiomyocytes, which may contribute towards the inability of the adult heart to regenerate following injury.

Project description:The adult mammalian heart is incapable of regeneration following injury. In contrast, the neonatal mouse heart can efficiently regenerate during the first week of life. The molecular mechanisms that mediate the regenerative response and its blockade in later life are not understood. Here, by single-nucleus RNA sequencing, we map the dynamic transcriptional landscape of five distinct cardiomyocyte populations in healthy, injured and regenerating mouse hearts. We identify immature cardiomyocytes that enter the cell-cycle following injury and disappear as the heart loses the ability to regenerate. These proliferative neonatal cardiomyocytes display a unique transcriptional program dependent on NFYa and NFE2L1 transcription factors, which exert proliferative and protective functions, respectively. Cardiac overexpression of these two factors conferred protection against ischemic injury in mature mouse hearts that were otherwise non-regenerative. These findings advance our understanding of the cellular basis of neonatal heart regeneration and reveal a transcriptional landscape for heart repair following injury.

Project description:Background: The adult mammalian heart has limited ability to repair itself following injury. Zebrafish, newts and neonatal mice can regenerate cardiac tissue, largely by cardiac myocyte (CM) proliferation. It is unknown if hearts of young large mammals can regenerate. Methods: We examined the regenerative capacity of the pig heart in neonatal animals (ages: 2, 3 or 14 days postnatal) after myocardial infarction (MI) or sham procedure. Myocardial scar and left ventricular function were determined by cardiac magnetic resonance (CMR) imaging and echocardiography. Bromodeoxyuridine pulse-chase labeling, histology, immunohistochemistry and Western blotting were performed to study cell proliferation, sarcomere dynamics and cytokinesis and to quantify myocardial fibrosis. RNA-sequencing was also performed. Results: After MI, there was early and sustained recovery of cardiac function and wall thickness in the absence of fibrosis in 2-day old pigs. In contrast, older animals developed full-thickness myocardial scarring, thinned walls and did not recover function. Genome wide analyses of the infarct zone revealed a strong transcriptional signature of fibrosis in 14-day old animals that was absent in 2-day old pigs, which instead had enrichment for cytokinesis genes. In regenerating hearts of the younger animals, up to 10% of CMs in the border zone of the MI showed evidence of DNA replication that was associated with markers of myocyte division and sarcomere disassembly. Conclusions: Hearts of large mammals have regenerative capacity, likely driven by cardiac myocyte division, but this potential is lost immediately after birth.

Project description:The heart undergoes significant structural, metabolic, gene expression and functional alterations during the perinatal to postnatal transition. While recent studies have identified multiple epigenetic and transcriptional regulators of cardiac maturation, post-transcriptional mechanisms regulating this process remain poorly understood. Neddylation is a post-translational modification that conjugates a small ubiquitin-like protein, NEDD8, to protein substrates via an E1-E2-E3 enzymatic cascade. The goal of this study was to define the role of neddylation in perinatal cardiac development and cardiac maturation. Neddylation was inhibited in adult mouse hearts by cardiac-specific deletion of NAE1 gene, a regulatory subunit of NEDD8 E1 enzyme, or in neonatal cardiomyocytes (CMs) with a pharmacological neddylation inhibitor, MLN4924. The impact on cardiac transcriptome, metabolism, maturation and function was assessed. Mosaic deletion of NAE1 in ~40% neonatal CMs disrupted aspects of maturation, including transverse-tubule formation, cellular hypertrophy and fetal/adult isoform switching, whereas deletion of NAE1 in over 80% CMs led to rapid development of cardiomyopathy and heart failure. Transcriptome analysis demonstrated an association of metabolic derangement with immature cardiomyocyte signature. Biochemical, ultrastructural and metabolomics analyses confirmed downregulation of fatty acid and oxidative phosphorylation genes, deficits in fatty acid utilization, mitochondrial dysfunction, and significantly altered metabolic profiles in NAE1-deficient hearts or MLN4924-treated neonatal CMs. Mechanistically, we found that HIF1α, a transcription factor known to promote glycolysis and suppress oxidative metabolism, is a putative NEDD8 target. Inhibition of neddylation resulted in HIF1α accumulation and activation, which contributed to diminished fatty acid utilization. Taken together, we conclude that neddylation plays a crucial role in CM maturation and postnatal cardiac development through sustaining the glycolytic to oxidative metabolic switch in perinatal hearts.

Project description:In mammals, Wnt pathway is activated during both heart regeneration post-injury and disease. Our previous work described the role of nuclear Wnt effectors B-catenin and Transcription factor 7-like 2 (TCF7L2) in heart disease progression; revealing GATA4 as a Wnt-repressor in the healthy adult heart. However, there is an urgent need to dissect molecular players distinguishing regenerative vs. disease-specific responses. In this study, we report a GATA4-B-catenin interaction in the regenerative neonatal myocardium, despite high TCF7L2 expression. TCF7L2 displayed strikingly unique genomic occupancies: proximal in neonatal and distal in diseased hearts. Integrative genomic and transcriptomic analyses showed that TCF7L2 differentially occupied and regulated fatty acid metabolic genes in the neonatal; and cardiac developmental and vasculogenesis genes in the diseased hearts, clearly discerning these two cardiac states. De-novo motif search identified TEAD as a commonly enriched motif in both TCF7L2 and GATA4-bound regions in the neonatal hearts, suggesting its potential role in providing a regenerative context to this GATA4-B-catenin interaction. Altogether, our study mapped for the first time, novel genome-wide TCF7L2 and GATA4 targets in the neonatal hearts and identified stage-specific roles for the cardiac Wnt-GATA4 complex. These findings demonstrate strong context-specificity of the cardiac Wnt-nuclear complex, which can be further exploited for therapeutic avenues.