scholarly journals Metformin accelerates zebrafish heart regeneration by inducing autophagy

2021 ◽  
Vol 6 (1) ◽  
Author(s):  
Fangjing Xie ◽  
Shisan Xu ◽  
Yingying Lu ◽  
Kin Fung Wong ◽  
Lei Sun ◽  
...  
Keyword(s):  
Myocardial Infarction ◽  
Systolic Function ◽  
Cell Types ◽  
Underlying Mechanism ◽  
Systematic Evaluation ◽  
Autophagic Flux ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Clinical Value ◽  
Zebrafish Model

AbstractMetformin is one of the most widely used drugs for type 2 diabetes and it also exhibits cardiovascular protective activity. However, the underlying mechanism of its action is not well understood. Here, we used an adult zebrafish model of heart cryoinjury, which mimics myocardial infarction in humans, and demonstrated that autophagy was significantly induced in the injured area. Through a systematic evaluation of the multiple cell types related to cardiac regeneration, we found that metformin enhanced the autophagic flux and improved epicardial, endocardial and vascular endothelial regeneration, accelerated transient collagen deposition and resolution, and induced cardiomyocyte proliferation. Whereas, when the autophagic flux was blocked, then all these processes were delayed. We also showed that metformin transiently enhanced the systolic function of the heart. Taken together, our results indicate that autophagy is positively involved in the metformin-induced acceleration of heart regeneration in zebrafish and suggest that this well-known diabetic drug has clinical value for the prevention and amelioration of myocardial infarction.

Abstract 527: Role of IGFBP3 in Neonatal Heart Regeneration

2020 ◽  
Vol 127 (Suppl_1) ◽  
Author(s):  
Shah R Ali ◽  
Waleed El-Helaly ◽  
Ivan Menendez-Montes ◽  
Ngoc Uyen Nhi Nguyen ◽  
Suwannee Thet ◽  
...  
Keyword(s):  
Heart Disease ◽  
Knockout Mice ◽  
Systolic Function ◽  
Ectopic Expression ◽  
Secreted Protein ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Newborn Mice ◽  
Adult Heart ◽  
Neonatal Heart

Background: The adult mammalian heart is unable to regenerate after an injury. However, newborn mice are able to fully regenerate the heart after myocardial infarction (MI). The neonatal MI model therefore is a potential blueprint for regenerating the adult heart that could offer novel therapies for patients suffering from heart disease. To investigate the mechanism by which neonatal heart regeneration occurs, we screened for secreted proteins that are upregulated after neonatal MI but not after adult MI. We hypothesized that such a protein could be a cardiomyocyte mitogen that underlies the cardiomyocyte proliferation that occurs after neonatal MI. Methods: We performed microarrays on neonatal and adult MI (and sham) heart tissue samples: we identified IGFBP3 (Insulin Growth Factor Binding Protein 3), which canonically transports IGF ligands in circulation, as a secreted protein that is uniquely upregulated after neonatal MI. We used in situ hybridization, reporter mice, and immunostaining to validate the findings from the microarray. Single cell RNA-seq data revealed that IGFBP3 is expressed in vascular cells. Results: We first tested whether IGFBP3 is necessary during neonatal heart regeneration: we performed neonatal (P1) MI in global Igfbp3 knockout mice and wild-type mice, and found that knockout mice have more fibrosis and worse ejection fraction (EF) one month after P1 MI. To determine if IGFBP3 is sufficient to promote cardiomyocyte proliferation, we injected recombinant IGFBP3 protein into the heart of one week-old mice (P7) and saw more cycling myocytes. We generated novel transgenic vascular-Igfbp3-overexpression mice, which exhibit less fibrosis as well as improved EF after P7 MI compared to controls. Conclusions: IGFBP3 is a secreted protein that is necessary for complete regeneration after a neonatal MI. Its ectopic expression can cause cardiomyocyte proliferation and can improve systolic function, and it prolongs the window of neonatal heart regeneration. Therefore, IGFBP3 may represent a cardiomyocyte mitogen with potential therapeutic value for adult heart disease.

scholarly journals Hydrogen Sulfide Promotes Cardiomyocyte Proliferation and Heart Regeneration via ROS Scavenging

2020 ◽  
Vol 2020 ◽  
pp. 1-11
Author(s):  
Jianqiu Pei ◽  
Fang Wang ◽  
Shengqiang Pei ◽  
Ruifeng Bai ◽  
Xiangfeng Cong ◽  
...  
Keyword(s):  
Myocardial Infarction ◽  
Hydrogen Sulfide ◽  
Oxidative Dna Damage ◽  
Cardiac Injury ◽  
Protective Role ◽  
Neonatal Mouse ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Ros Scavenging ◽  
Old Mice

Neonatal mouse hearts can regenerate completely in 21 days after cardiac injury, providing an ideal model to exploring heart regenerative therapeutic targets. The oxidative damage by Reactive Oxygen Species (ROS) is one of the critical reasons for the cell cycle arrest of cardiomyocytes (CMs), which cause mouse hearts losing the capacity to regenerate in 7 days or shorter after birth. As an antioxidant, hydrogen sulfide (H2S) plays a protective role in a variety of diseases by scavenging ROS produced during the pathological processes. In this study, we found that blocking H2S synthesis by PAG (H2S synthase inhibitor) suspended heart regeneration and CM proliferation with ROS deposition increase after cardiac injury (myocardial infarction or apex resection) in 2-day-old mice. NaHS (a H2S donor) administration improved heart regeneration with CM proliferation and ROS elimination after myocardial infarction in 7-day-old mice. NaHS protected primary neonatal mouse CMs from H2O2-induced apoptosis and promoted CM proliferation via SOD2-dependent ROS scavenging. The oxidative DNA damage in CMs was reduced with the elimination of ROS by H2S. Our results demonstrated for the first time that H2S promotes heart regeneration and identified NaHS as a potent modulator for cardiac repair.

scholarly journals Polyploidy in Cardiomyocytes

2020 ◽  
Vol 126 (4) ◽  
pp. 552-565 ◽  
Author(s):  
Wouter Derks ◽  
Olaf Bergmann
Keyword(s):  
Cardiac Injury ◽  
Physiological Role ◽  
Cell Types ◽  
Cell Number ◽  
The Body ◽  
Cardiomyocyte Hypertrophy ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Hypertrophic Growth

The hallmark of most cardiac diseases is the progressive loss of cardiomyocytes. In the perinatal period, cardiomyocytes still proliferate, and the heart shows the capacity to regenerate upon injury. In the adult heart, however, the actual rate of cardiomyocyte renewal is too low to efficiently counteract substantial cell loss caused by cardiac injury. In mammals, cardiac growth by cell number expansion changes to growth by cardiomyocyte enlargement soon after birth, coinciding with a period in which most cardiomyocytes increase their DNA content by multinucleation and nuclear polyploidization. Although cardiomyocyte hypertrophy is often associated with these processes, whether polyploidy is a prerequisite or a consequence of hypertrophic growth is unclear. Both the benefits of cardiomyocyte enlargement over proliferative growth of the heart and the physiological role of polyploidy in cardiomyocytes are enigmatic. Interestingly, hearts in animal species with substantial cardiac regenerative capacity dominantly comprise diploid cardiomyocytes, raising the hypothesis that cardiomyocyte polyploidy poses a barrier for cardiomyocyte proliferation and subsequent heart regeneration. On the contrary, there is also evidence for self-duplication of multinucleated myocytes, suggesting a more complex picture of polyploidy in heart regeneration. Polyploidy is not restricted to the heart but also occurs in other cell types in the body. In this review, we explore the biological relevance of polyploidy in different species and tissues to acquire insight into its specific role in cardiomyocytes. Furthermore, we speculate about the physiological role of polyploidy in cardiomyocytes and how this might relate to renewal and regeneration.

scholarly journals Heart regeneration: beyond new muscle and vessels

2021 ◽  
Author(s):  
Judy R Sayers ◽  
Paul R Riley
Keyword(s):  
Heart Development ◽  
Cell Function ◽  
Cell Types ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Cardiovascular Tissue ◽  
Function Calls ◽  
Heart Muscle Cells ◽  
System Cell ◽  
Heart Injury

Abstract The most striking consequence of a heart attack is the loss of billions of heart muscle cells, alongside damage to the associated vasculature. The lost cardiovascular tissue is replaced by scar formation, which is non-functional and results in pathological remodelling of the heart and ultimately heart failure. It is, therefore, unsurprising that the heart regeneration field has centred efforts to generate new muscle and blood vessels through targeting cardiomyocyte proliferation and angiogenesis following injury. However, combined insights from embryological studies and regenerative models, alongside the adoption of -omics technology, highlight the extensive heterogeneity of cell types within the forming or re-forming heart and the significant crosstalk arising from non-muscle and non-vessel cells. In this review, we focus on the roles of fibroblasts, immune, conduction system, and nervous system cell populations during heart development and we consider the latest evidence supporting a function for these diverse lineages in contributing to regeneration following heart injury. We suggest that the emerging picture of neurologically, immunologically, and electrically coupled cell function calls for a wider-ranging combinatorial approach to heart regeneration.

scholarly journals Association of Circulating, Inflammatory-Response Exosomal mRNAs With Acute Myocardial Infarction

2021 ◽  
Vol 8 ◽  
Author(s):  
Guo-dong He ◽  
Yu-qing Huang ◽  
Lin Liu ◽  
Jia-yi Huang ◽  
Kenneth Lo ◽  
...  
Keyword(s):  
Myocardial Infarction ◽  
Acute Myocardial Infarction ◽  
Inflammatory Response ◽  
Immune Cell ◽  
Stable Coronary Artery Disease ◽  
Enrichment Analysis ◽  
Cell Types ◽  
Diagnostic Value ◽  
Acute Inflammatory Response ◽  
Clinical Value

Background: Although many cardiovascular disease studies have focused on the microRNAs of circulating exosomes, the profile and the potential clinical diagnostic value of plasma exosomal long RNAs (exoLRs) are unknown for acute myocardial infarction (AMI).Methods: In this study, the exoLR profile of 10 AMI patients, eight stable coronary artery disease (CAD) patients, and 10 healthy individuals was assessed by RNA sequencing. Bioinformatic approaches were used to investigate the characteristics and potential clinical value of exoLRs.Results: Exosomal mRNAs comprised the majority of total exoLRs. Immune cell types analyzed by CIBERSORT showed that neutrophils and monocytes were significantly enriched in AMI patients, consistent with clinical baseline values. Biological process enrichment analysis and co-expression network analysis demonstrated neutrophil activation processes to be enriched in AMI patients. Furthermore, two exosomal mRNAs, ALPL and CXCR2, were identified as AMI biomarkers that may be useful for evaluation of the acute inflammatory response mediated by neutrophils.Conclusions: ExoLRs were assessed in AMI patients and found to be associated with the acute inflammatory response mediated by neutrophils. Exosomal mRNAs, ALPL and CXCR2, were identified as potentially useful biomarkers for the study of AMI.

scholarly journals gp130 Controls Cardiomyocyte Proliferation and Heart Regeneration

Circulation ◽  
2020 ◽  
Vol 142 (10) ◽  
pp. 967-982
Author(s):  
Yandong Li ◽  
Jie Feng ◽  
Shen Song ◽  
Haotong Li ◽  
Huijun Yang ◽  
...  
Keyword(s):  
Myocardial Infarction ◽  
Gene Therapy ◽  
Rna Sequencing ◽  
Cardiac Injury ◽  
Oncostatin M ◽  
Functional Screening ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Adult Mice ◽  
Neonatal Heart

Background: A key cause of the high mortality of cardiovascular diseases is the cardiomyocyte inability to renew after cardiac injury. As a promising strategy to supplement functional myocytes for cardiac repair, there is a pressing need to understand the cellular and molecular mechanisms of heart regeneration. Methods: Seven genetic mouse lines were used: global OSM (oncostatin M) knockout, monocyte-/macrophage-specific OSM deletion, cardiomyocyte-specific lines, including OSM receptor deletion, gp130 (glycoprotein 130) deletion, gp130 activation, and Yap (yes-associated protein) ablation with gp130 activation mice. A series of molecular signaling experiments, including RNA sequencing, immunostaining, coimmunoprecipitation, and imaging flow cytometry, were conducted. Two models of cardiac injury, apical resection and myocardial infarction operation, were performed in neonatal, juvenile, and adult mice. Heart regeneration and cardiac function were evaluated by Masson staining and echocardiography, respectively. Gene recombinant adenovirus-associated virus was constructed and infected myocardial-infarcted mice as a gene therapy. Results: OSM was identified by RNA sequencing as a key upstream regulator of cardiomyocyte proliferation during neonatal heart regeneration in mice. Cardiomyocyte proliferation and heart regeneration were suspended in neonatal mice after cardiac injury when OSM was conditionally knockout in macrophages. The cardiomyocyte-specific deficiency of the OSM receptor heterodimers, OSM receptor and gp130, individually in cardiomyocytes reduced myocyte proliferation and neonatal heart regeneration. Conditional activation of gp130 in cardiomyocytes promoted cardiomyocyte proliferation and heart regeneration in juvenile and adult mice. Using RNA sequencing and functional screening, we found that Src mediated gp130-triggered cardiomyocyte proliferation by activating Yap (yes-associated protein) with Y357 phosphorylation independently of the Hippo pathway. Cardiomyocyte-specific deletion of Yap in Myh6-gp130 ACT mice blocked the effect of gp130 activation–induced heart regeneration in juvenile mice. Gene therapy with adenovirus-associated virus encoding constitutively activated gp130 promoted cardiomyocyte proliferation and heart regeneration in adult mice after myocardial infarction. Conclusions: Macrophage recruitment is essential for heart regeneration through the secretion of OSM, which promotes cardiomyocyte proliferation. As the coreceptor of OSM, gp130 activation is sufficient to promote cardiomyocyte proliferation by activating Yap through Src during heart regeneration. gp130 is a potential therapeutic target to improve heart regeneration after cardiac injury.

Abstract 225: Coordinated Transcriptome and Cell State Dynamics of Non-myocytes in Heart Regeneration

2020 ◽  
Vol 127 (Suppl_1) ◽  
Author(s):  
Hong Ma ◽  
Ziqing Liu ◽  
Yuchen Yang ◽  
Dong Feng ◽  
Yanhan Dong ◽  
...  
Keyword(s):  
Cardiac Regeneration ◽  
Cell Types ◽  
Multiple Time ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Cellular Functions ◽  
Molecular Features ◽  
Functional Dynamics ◽  
Cell Diversity ◽  
Multiple Time Points

Cardiac regeneration occurs primarily through proliferation of existing cardiomyocytes, yet the regenerative response also involves complex interactions between distinct cardiac cell types including not only cardiomyocytes, but also non-cardiomyocytes (nonCMs). However, the subpopulations, distinguishing molecular features, cellular functions, and intercellular interactions of nonCMs in heart regeneration remain largely unexplored. Using the LIGER algorithm, we assembled an atlas of cell states from 61,977 individual nonCM scRNA-seq profiles isolated at multiple time points during heart regeneration in both wildtype and mutant fish. This analysis revealed extensive nonCM cell diversity, including multiple macrophage, fibroblast and endothelial subpopulations with unique spatiotemporal distributions and cooperative interactions during the process of cardiac regeneration. Genetic and pharmacological perturbation of macrophage functional dynamics compromised interactions among nonCM subpopulations, reduced cardiomyocyte proliferation, and caused defective cardiac regeneration. Furthermore, we developed a computational algorithm called Topologizer to map the topological relationships and dynamics of nonCMs during heart regeneration. We uncovered dynamic transitions between macrophage functional states and identified factors involved in mRNA processing and transcriptional regulation associated with the transition. Together, our single-cell transcriptomic analysis of nonCMs during cardiac regeneration provides a blueprint for interrogating the molecular and cellular basis of cardiac regeneration.

Abstract 15756: Vascular Guidance of Cardiomyocyte Proliferation During Growth and Regeneration

Circulation ◽  
2020 ◽  
Vol 142 (Suppl_3) ◽  
Author(s):  
Paige DeBeneditts ◽  
Anish Karpurapu ◽  
Kyla Brezitski ◽  
Michael C Thomas ◽  
Ravi - Karra
Keyword(s):  
Large Scale ◽  
Nearest Neighbor ◽  
Critical Role ◽  
Cell Types ◽  
Neonatal Mouse ◽  
Angiogenic Factor ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Cardiac Growth ◽  
Multiple Cell

Introduction: Stimulating cardiomyocyte (CM) proliferation is a major strategy for achieving therapeutic heart regeneration. However, heart regeneration requires coordinated interactions of multiple cell types. Because a hallmark of advanced heart failure is vascular rarefaction, the requirement of cardiac endothelial cells (CECs) for cardiac growth and regeneration is of particular importance. Hypothesis: We hypothesized that CECs are required for CM proliferation during growth and regeneration. Methods and Results: We performed a large-scale histologic assessment of neonatal mouse hearts and found the rate of CEC proliferation to shadow CM proliferation over the first 10 days of life. Using a nearest neighbor analysis, we found the fraction of proliferating CECs to be significantly enriched around cycling CMs compared to non-cycling CMs, suggesting that CEC and CM expansion are coupled within a myovascular niche. Single cell sequencing of neonatal mouse hearts after cryoinjury revealed that a majority of these proliferating CECs also express Vegfr2 . To functionally link CEC and CM proliferation, we generated Cdh5-CreER T2 ; Vefgr2 flox/flox mice to genetically delete Vegfr2 from CECs. Compared to mice with intact Vegfr2 , loss of Vegfr2 from CECs in neonatal mice leads to loss of CECs and severely dampens CM proliferation by 4 days (7.01±0.88% vs 0.39±0.35%, p = 7.4x10-4, n = 9),. Interestingly, CM proliferation is attenuated when Vegfr2 is deleted from CECs despite an increase of hypoxia indicators in CMs, signifying that hypoxia-induced CM proliferation is dependent on CECs. In contrast to CEC depletion, treatment of cryoinjured neonatal hearts with AAV encoding the master angiogenic factor, Vegfa can enhance heart regeneration with increased CM cycling in the borderzone (12.6±2.2% vs 5.4±0.4%, p = 0.02, n = 8), reduced scarring of the left ventricle (3.4±1.4% vs 7.6±1.2%, p = 03, n = 16), and improved fractional shortening (51.7±2.5% vs 36.7±4.3%, p = 0.007, n = 14). Conclusions: CEC and CM expansion are spatiotemporally coupled in a myovascular niche during cardiac growth. CECs play a critical role to support CM proliferation and are likely to provide instructive cues that may be leveraged for therapeutic heart regeneration.

scholarly journals METTL3 improves cardiomyocyte proliferation upon myocardial infarction via upregulating miR-17-3p in a DGCR8-dependent manner

2021 ◽  
Vol 7 (1) ◽  
Author(s):  
Kun Zhao ◽  
Chuanxi Yang ◽  
Jing Zhang ◽  
Wei Sun ◽  
Bin Zhou ◽  
...  
Keyword(s):  
Myocardial Infarction ◽  
Rna Binding ◽  
Underlying Mechanism ◽  
Neonatal Rat ◽  
Dependent Manner ◽  
Cardiomyocyte Proliferation ◽  
Rat Cardiomyocytes

AbstractMyocardial infarction (MI), one of the most severe types of heart attack, exerts a strong negative effect on heart muscle by causing a massive and rapid loss of cardiomyocytes. However, the existing therapies do little to improve cardiac regeneration. Due to the role of methyltransferase-like 3 (METTL3) in the physiological proliferation of cardiomyocytes, we aimed to determine whether METTL3 could also promote cardiomyocyte proliferation under pathological conditions and to elucidate the underlying mechanism. The effects of METTL3 on cardiomyocyte proliferation and apoptosis were investigated in an in vivo rat model of MI and in an in vitro model of neonatal rat cardiomyocytes (NRCMs) exposed to hypoxia. We found that METTL3 expression was downregulated in hypoxia-exposed NRCMs and MI-induced rats. Furthermore, METTL3 pretreatment enhanced cardiomyocyte proliferation and inhibited cardiomyocyte apoptosis under hypoxic or MI conditions, and silencing METTL3 had the opposite effects. Additionally, METTL3 overexpression upregulated miR-17-3p expression. The miR-17-3p agomir mimicked the pro-proliferative and antiapoptotic effects of METTL3 in hypoxia-exposed cells or rats with MI, while the miR-17-3p antagomir blocked these effects. Additionally, pretreatment with the RNA-binding protein DGCR8 also hampered the protective role of METTL3 in hypoxia-exposed cells. Overall, the current study indicated that METTL3 could improve cardiomyocyte proliferation and subsequently ameliorate MI in rats by upregulating proliferation-related miR-17-3p in a DGCR8-dependent pri-miRNA-processing manner.

scholarly journals Polyploid cardiomyocytes: implications for heart regeneration

Development ◽  
2021 ◽  
Vol 148 (14) ◽  
Author(s):  
Anna Kirillova ◽  
Lu Han ◽  
Honghai Liu ◽  
Bernhard Kühn
Keyword(s):  
Cellular Proliferation ◽  
Cardiac Regeneration ◽  
Cell Types ◽  
Heart Regeneration ◽  
Cardiomyocyte Proliferation ◽  
Form And Function ◽  
Differentiated Cells ◽  
New Findings ◽  
Polyploid Cells ◽  
And Function

ABSTRACT Terminally differentiated cells are generally thought to have arrived at their final form and function. Many terminally differentiated cell types are polyploid, i.e. they have multiple copies of the normally diploid genome. Mammalian heart muscle cells, termed cardiomyocytes, are one such example of polyploid cells. Terminally differentiated cardiomyocytes are bi- or multi-nucleated, or have polyploid nuclei. Recent mechanistic studies of polyploid cardiomyocytes indicate that they can limit cellular proliferation and, hence, heart regeneration. In this short Spotlight, we present the mechanisms generating bi- and multi-nucleated cardiomyocytes, and the mechanisms generating polyploid nuclei. Our aim is to develop hypotheses about how these mechanisms might relate to cardiomyocyte proliferation and cardiac regeneration. We also discuss how these new findings could be applied to advance cardiac regeneration research, and how they relate to studies of other polyploid cells, such as cancer cells.

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