Your search keyword '"heart regeneration"' showing total 987 results

1. Advancing Human iPSC-Derived Cardiomyocyte Hypoxia Resistance for Cardiac Regenerative Therapies through a Systematic Assessment of In Vitro Conditioning.

Author

Snyder, Caroline A., Dwyer, Kiera D., and Coulombe, Kareen L. K.

Subjects

*HEART metabolism, *WNT signal transduction, *MYOCARDIAL ischemia, *TISSUE engineering, *GENETIC translation, *PLURIPOTENT stem cells, *MYOCARDIAL infarction

Abstract

Acute myocardial infarction (MI) is a sudden, severe cardiac ischemic event that results in the death of up to one billion cardiomyocytes (CMs) and subsequent decrease in cardiac function. Engineered cardiac tissues (ECTs) are a promising approach to deliver the necessary mass of CMs to remuscularize the heart. However, the hypoxic environment of the heart post-MI presents a critical challenge for CM engraftment. Here, we present a high-throughput, systematic study targeting several physiological features of human induced pluripotent stem cell-derived CMs (hiPSC-CMs), including metabolism, Wnt signaling, substrate, heat shock, apoptosis, and mitochondrial stabilization, to assess their efficacy in promoting ischemia resistance in hiPSC-CMs. The results of 2D experiments identify hypoxia preconditioning (HPC) and metabolic conditioning as having a significant influence on hiPSC-CM function in normoxia and hypoxia. Within 3D engineered cardiac tissues (ECTs), metabolic conditioning with maturation media (MM), featuring high fatty acid and calcium concentration, results in a 1.5-fold increase in active stress generation as compared to RPMI/B27 control ECTs in normoxic conditions. Yet, this functional improvement is lost after hypoxia treatment. Interestingly, HPC can partially rescue the function of MM-treated ECTs after hypoxia. Our systematic and iterative approach provides a strong foundation for assessing and leveraging in vitro culture conditions to enhance the hypoxia resistance, and thus the successful clinical translation, of hiPSC-CMs in cardiac regenerative therapies. [ABSTRACT FROM AUTHOR]

Published

2024

2. Hypoxic extracellular vesicles from hiPSCs protect cardiomyocytes from oxidative damage by transferring antioxidant proteins and enhancing Akt/Erk/NRF2 signaling.

Author

Bobis-Wozowicz, Sylwia, Paw, Milena, Sarna, Michał, Kędracka-Krok, Sylwia, Nit, Kinga, Błażowska, Natalia, Dobosz, Anna, Hammad, Ruba, Cathomen, Toni, Zuba-Surma, Ewa, Tyszka-Czochara, Małgorzata, and Madeja, Zbigniew

Subjects

*EXTRACELLULAR vesicles, *LIQUID chromatography-mass spectrometry, *MOLECULAR biology, *INDUCED pluripotent stem cells, *PROTEOMICS, *GEL permeation chromatography, *ULTRAFILTRATION

Abstract

Background: Stem cell-derived extracellular vesicles (EVs) are an emerging class of therapeutics with excellent biocompatibility, bioactivity and pro-regenerative capacity. One of the potential targets for EV-based medicines are cardiovascular diseases (CVD). In this work we used EVs derived from human induced pluripotent stem cells (hiPSCs; hiPS-EVs) cultured under different oxygen concentrations (21, 5 and 3% O2) to dissect the molecular mechanisms responsible for cardioprotection. Methods: EVs were isolated by ultrafiltration combined with size exclusion chromatography (UF + SEC), followed by characterization by nanoparticle tracking analysis, atomic force microscopy (AFM) and Western blot methods. Liquid chromatography and tandem mass spectrometry coupled with bioinformatic analyses were used to identify differentially enriched proteins in various oxygen conditions. We directly compared the cardioprotective effects of these EVs in an oxygen-glucose deprivation/reoxygenation (OGD/R) model of cardiomyocyte (CM) injury. Using advanced molecular biology, fluorescence microscopy, atomic force spectroscopy and bioinformatics techniques, we investigated intracellular signaling pathways involved in the regulation of cell survival, apoptosis and antioxidant response. The direct effect of EVs on NRF2-regulated signaling was evaluated in CMs following NRF2 inhibition with ML385. Results: We demonstrate that hiPS-EVs derived from physiological hypoxia at 5% O2 (EV-H5) exert enhanced cytoprotective function towards damaged CMs compared to EVs derived from other tested oxygen conditions (normoxia; EV-N and hypoxia 3% O2; EV-H3). This resulted from higher phosphorylation rates of Akt kinase in the recipient cells after transfer, modulation of AMPK activity and reduced apoptosis. Furthermore, we provide direct evidence for improved calcium signaling and sustained contractility in CMs treated with EV-H5 using AFM measurements. Mechanistically, our mass spectrometry and bioinformatics analyses revealed differentially enriched proteins in EV-H5 associated with the antioxidant pathway regulated by NRF2. In this regard, EV-H5 increased the nuclear translocation of NRF2 protein and enhanced its transcription in CMs upon OGD/R. In contrast, inhibition of NRF2 with ML385 abolished the protective effect of EVs on CMs. Conclusions: In this work, we demonstrate a superior cardioprotective function of EV-H5 compared to EV-N and EV-H3. Such EVs were most effective in restoring redox balance in stressed CMs, preserving their contractile function and preventing cell death. Our data support the potential use of hiPS-EVs derived from physiological hypoxia, as cell-free therapeutics with regenerative properties for the treatment of cardiac diseases. [ABSTRACT FROM AUTHOR]

Published

2024

3. Anti-Ferroptotic Treatment Deteriorates Myocardial Infarction by Inhibiting Angiogenesis and Altering Immune Response.

Author

Stairley, Rebecca A., Trouten, Allison M., Li, Shuang, Roddy, Patrick L., DeLeon-Pennell, Kristine Y., Lee, Kyu-Ho, Sucov, Henry M., Liu, Chun, and Tao, Ge

Subjects

CONGENITAL heart disease, MYOCARDIAL infarction, WOUND healing, HEART diseases, CARDIOMYOPATHIES, HEART

Abstract

Mammalian cardiomyocytes have limited regenerative ability. Cardiac disease, such as congenital heart disease and myocardial infarction, causes an initial loss of cardiomyocytes through regulated cell death (RCD). Understanding the mechanisms that govern RCD in the injured myocardium is crucial for developing therapeutics to promote heart regeneration. We previously reported that ferroptosis, a non-apoptotic and iron-dependent form of RCD, is the main contributor to cardiomyocyte death in the injured heart. To investigate the mechanisms underlying the preference for ferroptosis in cardiomyocytes, we examined the effects of anti-ferroptotic reagents in infarcted mouse hearts. The results revealed that the anti-ferroptotic reagent did not improve neonatal heart regeneration, and further compromised the cardiac function of juvenile hearts. On the other hand, ferroptotic cardiomyocytes played a supportive role during wound healing by releasing pro-angiogenic factors. The inhibition of ferroptosis in the regenerating mouse heart altered the immune and angiogenic responses. Our study provides insights into the preference for ferroptosis over other types of RCD in stressed cardiomyocytes, and guidance for designing anti-cell-death therapies for treating heart disease. [ABSTRACT FROM AUTHOR]

Published

2024

4. Hypoxic extracellular vesicles from hiPSCs protect cardiomyocytes from oxidative damage by transferring antioxidant proteins and enhancing Akt/Erk/NRF2 signaling

Author

Sylwia Bobis-Wozowicz, Milena Paw, Michał Sarna, Sylwia Kędracka-Krok, Kinga Nit, Natalia Błażowska, Anna Dobosz, Ruba Hammad, Toni Cathomen, Ewa Zuba-Surma, Małgorzata Tyszka-Czochara, and Zbigniew Madeja

Subjects

Cardiovascular disease, Heart regeneration, Extracellular vesicles, Induced pluripotent stem cells, Hypoxia, Cardiomyocyte, Medicine, Cytology, QH573-671

Abstract

Abstract Background Stem cell-derived extracellular vesicles (EVs) are an emerging class of therapeutics with excellent biocompatibility, bioactivity and pro-regenerative capacity. One of the potential targets for EV-based medicines are cardiovascular diseases (CVD). In this work we used EVs derived from human induced pluripotent stem cells (hiPSCs; hiPS-EVs) cultured under different oxygen concentrations (21, 5 and 3% O2) to dissect the molecular mechanisms responsible for cardioprotection. Methods EVs were isolated by ultrafiltration combined with size exclusion chromatography (UF + SEC), followed by characterization by nanoparticle tracking analysis, atomic force microscopy (AFM) and Western blot methods. Liquid chromatography and tandem mass spectrometry coupled with bioinformatic analyses were used to identify differentially enriched proteins in various oxygen conditions. We directly compared the cardioprotective effects of these EVs in an oxygen-glucose deprivation/reoxygenation (OGD/R) model of cardiomyocyte (CM) injury. Using advanced molecular biology, fluorescence microscopy, atomic force spectroscopy and bioinformatics techniques, we investigated intracellular signaling pathways involved in the regulation of cell survival, apoptosis and antioxidant response. The direct effect of EVs on NRF2-regulated signaling was evaluated in CMs following NRF2 inhibition with ML385. Results We demonstrate that hiPS-EVs derived from physiological hypoxia at 5% O2 (EV-H5) exert enhanced cytoprotective function towards damaged CMs compared to EVs derived from other tested oxygen conditions (normoxia; EV-N and hypoxia 3% O2; EV-H3). This resulted from higher phosphorylation rates of Akt kinase in the recipient cells after transfer, modulation of AMPK activity and reduced apoptosis. Furthermore, we provide direct evidence for improved calcium signaling and sustained contractility in CMs treated with EV-H5 using AFM measurements. Mechanistically, our mass spectrometry and bioinformatics analyses revealed differentially enriched proteins in EV-H5 associated with the antioxidant pathway regulated by NRF2. In this regard, EV-H5 increased the nuclear translocation of NRF2 protein and enhanced its transcription in CMs upon OGD/R. In contrast, inhibition of NRF2 with ML385 abolished the protective effect of EVs on CMs. Conclusions In this work, we demonstrate a superior cardioprotective function of EV-H5 compared to EV-N and EV-H3. Such EVs were most effective in restoring redox balance in stressed CMs, preserving their contractile function and preventing cell death. Our data support the potential use of hiPS-EVs derived from physiological hypoxia, as cell-free therapeutics with regenerative properties for the treatment of cardiac diseases.

Published

2024

5. A bibliometric study related to the treatment of myocardial ischemia-reperfusion Injury

Author

Jie Feng, Leilei Han, Yunman Liu, Kai Li, and Yanqing Wu

Subjects

Bibliometrics, MIRI, Treatment, Visual analysis, Heart regeneration, Surgery, RD1-811, Anesthesiology, RD78.3-87.3

Abstract

Abstract Background Myocardial ischemia-reperfusion injury (MIRI) is defined as the restoration of blood flow to the myocardium after a brief interruption of blood supply, causing more severe damage to the ischemic myocardium. However, currently, reperfusion therapy is the preferred therapy for ischemic cardiomyopathy, which undoubtedly causes MIRI, and thus it has become a challenging issue affecting the prognosis of coronary artery disease. Methods A search was conducted in the Web of Science Core Collection database for papers relevant to MIRI therapy published between 1 January 2000 and 1 October 2023. Bibliometric analyses were performed using VOSviewer and CiteSpace to elucidate the progress and hotspots. Results 3304 papers from 64 countries, 2134 research institutions and 13,228 authors were enrolled in the study. Of these, China contributed the most papers and had the biggest impact, while the United States had the most extensive partnership. The Fourth Military Medical University was the primary research institution. The most valuable authors include Chattipakorn, Nipon, Chattipakorn, Siriporn c, Yang, Jian and Yang, Yang. Conclusion Over the past 20 years, research on MIRI therapies has made significant strides. Further studies are necessary to explore the interactions between various therapeutic options. Future investigations will emphasize nanocarriers, cardiac regeneration, and stem cell therapies. Our study identifies MIRI research hotspots from a bibliometric perspective, forecasts future trends, and offers fresh insights into MIRI therapy research.

Published

2024

6. MBNL1 Regulates Programmed Postnatal Switching Between Regenerative and Differentiated Cardiac States.

Author

Bailey, Logan R. J., Bugg, Darrian, Reichardt, Isabella M., Ortaç, C. Dessirée, Nagle, Abigail, Gunaje, Jagadambika, Martinson, Amy, Johnson, Richard, MacCoss, Michael J., Tomoya Sakamoto, Kelly, Daniel P., Regnier, Michael, and Davis, Jennifer

Subjects

*CARDIAC regeneration, *CELL cycle, *HEART cells, *HEART diseases, *MULTIOMICS, *SKIN regeneration, *CARDIAC contraction

Abstract

BACKGROUND: Discovering determinants of cardiomyocyte maturity is critical for deeply understanding the maintenance of differentiated states and potentially reawakening endogenous regenerative programs in adult mammalian hearts as a therapeutic strategy. Forced dedifferentiation paired with oncogene expression is sufficient to drive cardiac regeneration, but elucidation of endogenous developmental regulators of the switch between regenerative and mature cardiomyocyte cell states is necessary for optimal design of regenerative approaches for heart disease. MBNL1 (muscleblind-like 1) regulates fibroblast, thymocyte, and erythroid differentiation and proliferation. Hence, we examined whether MBNL1 promotes and maintains mature cardiomyocyte states while antagonizing cardiomyocyte proliferation. METHODS: MBNL1 gain- and loss-of-function mouse models were studied at several developmental time points and in surgical models of heart regeneration. Multi-omics approaches were combined with biochemical, histological, and in vitro assays to determine the mechanisms through which MBNL1 exerts its effects. RESULTS: MBNL1 is coexpressed with a maturation-association genetic program in the heart and is regulated by the MEIS1/ calcineurin signaling axis. Targeted MBNL1 overexpression early in development prematurely transitioned cardiomyocytes to hypertrophic growth, hypoplasia, and dysfunction, whereas loss of MBNL1 function increased cardiomyocyte cell cycle entry and proliferation through altered cell cycle inhibitor transcript stability. Moreover, MBNL1-dependent stabilization of estrogen-related receptor signaling was essential for maintaining cardiomyocyte maturity in adult myocytes. In accordance with these data, modulating MBNL1 dose tuned the temporal window of neonatal cardiac regeneration, where increased MBNL1 expression arrested myocyte proliferation and regeneration and MBNL1 deletion promoted regenerative states with prolonged myocyte proliferation. However, MBNL1 deficiency was insufficient to promote regeneration in the adult heart because of cell cycle checkpoint activation. CONCLUSIONS: Here, MBNL1 was identified as an essential regulator of cardiomyocyte differentiated states, their developmental switch from hyperplastic to hypertrophic growth, and their regenerative potential through controlling an entire maturation program by stabilizing adult myocyte mRNAs during postnatal development and throughout adulthood. Targeting loss of cardiomyocyte maturity and downregulation of cell cycle inhibitors through MBNL1 deletion was not sufficient to promote adult regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

7. Exploring Cellular Dynamics in the Goldfish Bulbus Arteriosus: A Multifaceted Perspective.

Author

Mokhtar, Doaa M., Abd-Elhafez, Enas A., Albano, Marco, Zaccone, Giacomo, and Hussein, Manal T.

Subjects

*SECRETORY granules, *GOLDFISH, *CELL morphology, *EXTRACELLULAR matrix, *ENDOCARDIUM, *GLYCOCALYX

Abstract

The bulbus arteriosus of goldfish, Carassius auratus, possesses unique structural features. The wall of the bulbus arteriosus is exceptionally thick, with an inner surface characterized by longitudinally arranged finger-like ridges, resulting in an uneven luminal appearance. These ridges are covered by endocardium and encased in an amorphous extracellular matrix. The inner surface of the bulbus arteriosus also contains rodlet cells at different developmental stages, often clustered beneath the endothelium lining the bulbar lumen. Ruptured rodlet cells release their contents via a holocrine secretion process. The high abundance of rodlet cells in the bulbus arteriosus suggests that this is the site of origin for these cells. Within the middle layer of the bulbus arteriosus, smooth muscle cells, branched telocytes (TCs), and collagen bundles coexist. TCs and their telopodes form complex connections within a dense collagen matrix, extending to rodlet cells and macrophages. Moreover, the endothelium makes direct contact with telopodes. The endocardial cells within the bulbus arteriosus display irregular, stellate shapes and numerous cell processes that establish direct contact with TCs. TEM reveals that they contain moderately dense bodies and membrane-bound vacuoles, suggesting a secretory activity. TCs exhibit robust secretory activity, evident from their telopodes containing numerous secretory vesicles. Furthermore, TCs release excretory vesicles containing bioactive molecules into the extracellular matrix, which strengthens evidence for telocytes as promising candidates for cellular therapies and regeneration in various heart pathologies. [ABSTRACT FROM AUTHOR]

Published

2024

8. Triiodothyronine induces a proinflammatory monocyte/macrophage profile and impedes cardiac regeneration.

Author

Chen, Ziwei, Cai, Dongcheng, Xie, Yifan, Zhong, Jiajun, Wu, Mengge, Yang, Huijun, Feng, Jie, Lian, Hong, Dou, Kefei, and Nie, Yu

Subjects

*CARDIAC regeneration, *TRIIODOTHYRONINE, *MACROPHAGES, *PHENOTYPIC plasticity, *THYROID hormone regulation, *THYROID hormones, *LIVER regeneration

Abstract

Neonatal mouse hearts can regenerate post-injury, unlike adult hearts that form fibrotic scars. The mechanism of thyroid hormone signaling in cardiac regeneration warrants further study. We found that triiodothyronine impairs cardiomyocyte proliferation and heart regeneration in neonatal mice after apical resection. Single-cell RNA-Sequencing on cardiac CD45-positive leukocytes revealed a pro-inflammatory phenotype in monocytes/macrophages after triiodothyronine treatment. Furthermore, we observed that cardiomyocyte proliferation was inhibited by medium from triiodothyronine-treated macrophages, while triiodothyronine itself had no direct effect on the cardiomyocytes in vitro. Our study unveils a novel role of triiodothyronine in mediating the inflammatory response that hinders heart regeneration. [Display omitted] • T3 impedes cardiac regeneration in neonatal mouse after cardiac injury. • T3 induces pro-inflammatory macrophages in injured neonatal hearts. • T3 regulates cardiomyocyte proliferation by inducing macrophage phenotype transition. [ABSTRACT FROM AUTHOR]

Published

2024

9. Mesenchymal Stem Cell-Derived Exosomes and Their MicroRNAs in Heart Repair and Regeneration.

Author

Akbar, Nukhba, Razzaq, Syeda Saima, Salim, Asmat, and Haneef, Kanwal

Abstract

Mesenchymal stem cells (MSCs) can be differentiated into cardiac, endothelial, and smooth muscle cells. Therefore, MSC-based therapeutic approaches have the potential to deal with the aftermaths of cardiac diseases. However, transplanted stem cells rarely survive in damaged myocardium, proposing that paracrine factors other than trans-differentiation may involve in heart regeneration. Apart from cytokines/growth factors, MSCs secret small, single-membrane organelles named exosomes. The MSC-secreted exosomes are enriched in lipids, proteins, nucleic acids, and microRNA (miRNA). There has been an increasing amount of data that confirmed that MSC-derived exosomes and their active molecule microRNA (miRNAs) regulate signaling pathways involved in heart repair/regeneration. In this review, we systematically present an overview of MSCs, their cardiac differentiation, and the role of MSC-derived exosomes and exosomal miRNAs in heart regeneration. In addition, biological functions regulated by MSC-derived exosomes and exosomal-derived miRNAs in the process of heart regeneration are reviewed. [ABSTRACT FROM AUTHOR]

Published

2024

10. ZebraReg--a novel platform for discovering regulators of cardiac regeneration using zebrafish.

Author

Apolínová, Kateřina, Pérez, Ferran Arqué, Dyballa, Sylvia, Coppe, Benedetta, Huber, Nadia Mercader, Terriente, Javier, and Di Donato, Vincenzo

Subjects

CARDIAC regeneration, BRACHYDANIO, MYOCARDIUM, MYOCARDIAL infarction, CARDIAC imaging

Abstract

Cardiovascular disease is the leading cause of death worldwide with myocardial infarction being the most prevalent. Currently, no cure is available to either prevent or revert the massive death of cardiomyocytes that occurs after a myocardial infarction. Adult mammalian hearts display a limited regeneration capacity, but it is insufficient to allow complete myocardial recovery. In contrast, the injured zebrafish heart muscle regenerates efficiently through robust proliferation of pre-existing myocardial cells. Thus, zebrafish allows its exploitation for studying the genetic programs behind cardiac regeneration, which may be present, albeit dormant, in the adult human heart. To this end, we have established ZebraReg, a novel and versatile automated platform for studying heart regeneration kinetics after the specific ablation of cardiomyocytes in zebrafish larvae. In combination with automated heart imaging, the platform can be integrated with genetic or pharmacological approaches and used for medium-throughput screening of presumed modulators of heart regeneration. We demonstrate the versatility of the platform by identifying both anti- and proregenerative effects of genes and drugs. In conclusion, we present a tool which may be utilised to streamline the process of target validation of novel gene regulators of regeneration, and the discovery of new drug therapies to regenerate the heart after myocardial infarction. [ABSTRACT FROM AUTHOR]

Published

2024

11. Syndecan-4 is required for early-stage repair responses during zebrafish heart regeneration.

Author

Lai, Zih-Yin, Yang, Chung-Chi, Chen, Po-Hsun, Chen, Wei-Chen, Lai, Ting-Yu, Lu, Guan-Yun, Yang, Chiao-Yu, Wang, Ko-Ying, Liu, Wei-Cen, Chen, Yu-Chieh, Liu, Lawrence Yu-Min, and Chuang, Yung-Jen

Abstract

Background: The healing process after a myocardial infarction (MI) in humans involves complex events that replace damaged tissue with a fibrotic scar. The affected cardiac tissue may lose its function permanently. In contrast, zebrafish display a remarkable capacity for scar-free heart regeneration. Previous studies have revealed that syndecan-4 (SDC4) regulates inflammatory response and fibroblast activity following cardiac injury in higher vertebrates. However, whether and how Sdc4 regulates heart regeneration in highly regenerative zebrafish remains unknown. Methods and Results: This study showed that sdc4 expression was differentially regulated during zebrafish heart regeneration by transcriptional analysis. Specifically, sdc4 expression increased rapidly and transiently in the early regeneration phase upon ventricular cryoinjury. Moreover, the knockdown of sdc4 led to a significant reduction in extracellular matrix protein deposition, immune cell accumulation, and cell proliferation at the lesion site. The expression of tgfb1a and col1a1a, as well as the protein expression of Fibronectin, were all down-regulated under sdc4 knockdown. In addition, we verified that sdc4 expression was required for cardiac repair in zebrafish via in vivo electrocardiogram analysis. Loss of sdc4 expression caused an apparent pathological Q wave and ST elevation, which are signs of human MI patients. Conclusions: Our findings support that Sdc4 is required to mediate pleiotropic repair responses in the early stage of zebrafish heart regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

12. Cell-Cycle–Specific Autoencoding Improves Cluster Analysis of Cycling Cardiomyocytes.

Author

Nguyen, Thanh, Nakada, Yuji, Wu, Yalin, Zhao, Jianli, Garry, Daniel J, Sadek, Hesham, and Zhang, Jianyi

Subjects

CLUSTER analysis (Statistics), FETAL heart, PHASE transitions, FETUS, MYOCARDIAL infarction, CELL cycle, CYCLING competitions

Abstract

Background Our previous analyses of cardiomyocyte single-nucleus RNA sequencing (snRNAseq) data from the hearts of fetal pigs and pigs that underwent apical resection surgery on postnatal day (P) 1 (ARP1), myocardial infarction (MI) surgery on P28 (MIP28), both ARP1 and MIP28 (ARP1MIP28), or controls (no surgical procedure or CTL) identified 10 cardiomyocyte subpopulations (clusters), one of which appeared to be primed to proliferate in response to MI. However, the clusters composed of primarily proliferating cardiomyocytes still contained noncycling cells, and we were unable to distinguish between cardiomyocytes in different phases of the cell cycle. Here, we improved the precision of our assessments by conducting similar analyses with snRNAseq data for only the 1646 genes included under the Gene Ontology term "cell cycle." Methods Two cardiac snRNAseq datasets, one from mice (GEO dataset number GSE130699) and one from pigs (GEO dataset number GSE185289), were evaluated via our cell-cycle–specific analytical pipeline. Cycling cells were identified via the co-expression of 5 proliferation markers (AURKB, MKI67, INCENP, CDCA8, and BIRC5). Results The cell-cycle–specific autoencoder (CSA) algorithm identified 7 cardiomyocyte clusters in mouse hearts (mCM1 and mCM3-mCM8), including one prominent cluster of cycling cardiomyocytes in animals that underwent MI or Sham surgery on P1. Five cardiomyocyte clusters (pCM1, pCM3-pCM6) were identified in pig hearts, 2 of which (pCM1 and pCM4) displayed evidence of cell cycle activity; pCM4 was found primarily in hearts from fetal pigs, while pCM1 comprised a small proportion of cardiomyocytes in both fetal hearts and hearts from ARP1MIP28 pigs during the 2 weeks after MI induction, but was nearly undetectable in all other experimental groups and at all other time points. Furthermore, pseudotime trajectory analysis of snRNAseq data from fetal pig cardiomyocytes identified a pathway that began at pCM3, passed through pCM2, and ended at pCM1, whereas pCM3 was enriched for the expression of a cell cycle activator that regulates the G1/S phase transition (cyclin D2), pCM2 was enriched for an S-phase regulator (CCNE2), and pCM1 was enriched for the expression of a gene that regulates the G2M phase transition and mitosis (cyclin B2). We also identified 4 transcription factors (E2F8, FOXM1, GLI3, and RAD51) that were more abundantly expressed in cardiomyocytes from regenerative mouse hearts than from nonregenerative mouse hearts, from the hearts of fetal pigs than from CTL pig hearts, and from ARP1MIP28 pig hearts than from MIP28 pig hearts during the 2 weeks after MI induction. Conclusions The CSA algorithm improved the precision of our assessments of cell cycle activity in cardiomyocyte subpopulations and enabled us to identify a trajectory across 3 clusters that appeared to track the onset and progression of cell cycle activity in cardiomyocytes from fetal pigs. [ABSTRACT FROM AUTHOR]

Published

2024

13. Unlocking cardiomyocyte renewal potential for myocardial regeneration therapy

Author

Mehdipour, Melod, Park, Sangsoon, and Huang, Guo N

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Heart Disease - Coronary Heart Disease, Cardiovascular, Regenerative Medicine, Heart Disease, 2.1 Biological and endogenous factors, Good Health and Well Being, Animals, Myocytes, Cardiac, Zebrafish, Cell Proliferation, Heart, Cell Cycle Checkpoints, Heart Failure, Mammals, Heart regeneration, Cardiomyocyte proliferation, Polyploidization, Ontogeny, Phylogeny, Oxygen -rich environment, Acquistion of endothermy, Complex immune system, Cancer risk tradeoff, endocrine, sympathetic and parasympatheric nervous, system, non -coding RNAs, Acquistion of endothermy, Oxygen-rich environment, non-coding RNAs, sympathetic and parasympatheric nervous system, Cardiorespiratory Medicine and Haematology, Cardiovascular System & Hematology, Biochemistry and cell biology, Cardiovascular medicine and haematology, Medical physiology

Abstract

Cardiovascular disease remains the leading cause of mortality worldwide. Cardiomyocytes are irreversibly lost due to cardiac ischemia secondary to disease. This leads to increased cardiac fibrosis, poor contractility, cardiac hypertrophy, and subsequent life-threatening heart failure. Adult mammalian hearts exhibit notoriously low regenerative potential, further compounding the calamities described above. Neonatal mammalian hearts, on the other hand, display robust regenerative capacities. Lower vertebrates such as zebrafish and salamanders retain the ability to replenish lost cardiomyocytes throughout life. It is critical to understand the varying mechanisms that are responsible for these differences in cardiac regeneration across phylogeny and ontogeny. Adult mammalian cardiomyocyte cell cycle arrest and polyploidization have been proposed as major barriers to heart regeneration. Here we review current models about why adult mammalian cardiac regenerative potential is lost including changes in environmental oxygen levels, acquisition of endothermy, complex immune system development, and possible cancer risk tradeoffs. We also discuss recent progress and highlight conflicting reports pertaining to extrinsic and intrinsic signaling pathways that control cardiomyocyte proliferation and polyploidization in growth and regeneration. Uncovering the physiological brakes of cardiac regeneration could illuminate novel molecular targets and offer promising therapeutic strategies to treat heart failure.

Published

2023

14. mTORC1 regulates the metabolic switch of postnatal cardiomyocytes during regeneration.

Author

Paltzer, Wyatt G., Aballo, Timothy J., Bae, Jiyoung, Flynn, Corey G.K., Wanless, Kayla N., Hubert, Katharine A., Nuttall, Dakota J., Perry, Cassidy, Nahlawi, Raya, Ge, Ying, and Mahmoud, Ahmed I.

Subjects

*CARDIAC regeneration, *HEART metabolism, *HEART development, *FATTY acid oxidation, *PROTEIN synthesis, *PROTEIN metabolism

Abstract

The metabolic switch from glycolysis to fatty acid oxidation in postnatal cardiomyocytes contributes to the loss of the cardiac regenerative potential of the mammalian heart. However, the mechanisms that regulate this metabolic switch remain unclear. The protein kinase complex mechanistic target of rapamycin complex 1 (mTORC1) is a central signaling hub that regulates cellular metabolism and protein synthesis, yet its role during mammalian heart regeneration and postnatal metabolic maturation is undefined. Here, we use immunoblotting, rapamycin treatment, myocardial infarction, and global proteomics to define the role of mTORC1 in postnatal heart development and regeneration. Our results demonstrate that the activity of mTORC1 is dynamically regulated between the regenerating and the non-regenerating hearts. Acute inhibition of mTORC1 by rapamycin or everolimus reduces cardiomyocyte proliferation and inhibits neonatal heart regeneration following injury. Our quantitative proteomic analysis demonstrates that transient inhibition of mTORC1 during neonatal heart injury did not reduce protein synthesis, but rather shifts the cardiac proteome of the neonatal injured heart from glycolysis towards fatty acid oxidation. This indicates that mTORC1 inhibition following injury accelerates the postnatal metabolic switch, which promotes metabolic maturation and impedes cardiomyocyte proliferation and heart regeneration. Taken together, our results define an important role for mTORC1 in regulating postnatal cardiac metabolism and may represent a novel target to modulate cardiac metabolism and promote heart regeneration. [Display omitted] • mTORC1 activity is distinct between regenerating and non-regenerating hearts. • mTORC1 inhibition reduces cardiomyocyte proliferation and heart regeneration. • mTORC1 inhibition shifts the cardiac proteome towards metabolic maturation. • mTORC1 inhibition inhibits heart regeneration via metabolic remodeling. [ABSTRACT FROM AUTHOR]

Published

2024

15. A novel gene-trap line reveals the dynamic patterns and essential roles of cysteine and glycine-rich protein 3 in zebrafish heart development and regeneration.

Author

Liang, Shuzhang, Zhou, Yating, Chang, Yue, Li, Jiayi, Zhang, Min, Gao, Peng, Li, Qi, Yu, Hong, Kawakami, Koichi, Ma, Jinmin, and Zhang, Ruilin

Abstract

Mutations in cysteine and glycine-rich protein 3 (CSRP3)/muscle LIM protein (MLP), a key regulator of striated muscle function, have been linked to hypertrophic cardiomyopathy (HCM) and dilated cardiomyopathy (DCM) in patients. However, the roles of CSRP3 in heart development and regeneration are not completely understood. In this study, we characterized a novel zebrafish gene-trap line, gSAIzGFFM218A, which harbors an insertion in the csrp3 genomic locus, heterozygous fish served as a csrp3 expression reporter line and homozygous fish served as a csrp3 mutant line. We discovered that csrp3 is specifically expressed in larval ventricular cardiomyocytes (CMs) and that csrp3 deficiency leads to excessive trabeculation, a common feature of CSRP3-related HCM and DCM. We further revealed that csrp3 expression increased in response to different cardiac injuries and was regulated by several signaling pathways vital for heart regeneration. Csrp3 deficiency impeded zebrafish heart regeneration by impairing CM dedifferentiation, hindering sarcomere reassembly, and reducing CM proliferation while aggravating apoptosis. Csrp3 overexpression promoted CM proliferation after injury and ameliorated the impairment of ventricle regeneration caused by pharmacological inhibition of multiple signaling pathways. Our study highlights the critical role of Csrp3 in both zebrafish heart development and regeneration, and provides a valuable animal model for further functional exploration that will shed light on the molecular pathogenesis of CSRP3-related human cardiac diseases. [ABSTRACT FROM AUTHOR]

Published

2024

16. Spatiotemporal modulation of nitric oxide and Notch signaling by hemodynamic-responsive Trpv4 is essential for ventricle regeneration.

Author

Yu, Chunxiao, Li, Xueyu, Ma, Jinmin, Liang, Shuzhang, Zhao, Yan, Li, Qi, and Zhang, Ruilin

Abstract

Zebrafish have a remarkable ability to regenerate injured hearts. Altered hemodynamic forces after larval ventricle ablation activate the endocardial Klf2a-Notch signaling cascade to direct zebrafish cardiac regeneration. However, how the heart perceives blood flow changes and initiates signaling pathways promoting regeneration is not fully understood. The present study demonstrated that the mechanosensitive channel Trpv4 sensed the altered hemodynamic forces in injured hearts and its expression was regulated by blood flow. In addition to mediating the endocardial Klf2a-Notch signal cascade around the atrioventricular canal (AVC), we discovered that Trpv4 regulated nitric oxide (NO) signaling in the bulbus arteriosus (BA). Further experiments indicated that Notch signaling primarily acted at the early stage of regeneration, and the major role of NO signaling was at the late stage and through TGF-β pathway. Overall, our findings revealed that mechanosensitive channels perceived the changes in hemodynamics after ventricle injury, and provide novel insights into the temporal and spatial coordination of multiple signaling pathways regulating heart regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

17. ZebraReg—a novel platform for discovering regulators of cardiac regeneration using zebrafish

Author

Kateřina Apolínová, Ferran Arqué Pérez, Sylvia Dyballa, Benedetta Coppe, Nadia Mercader Huber, Javier Terriente, and Vincenzo Di Donato

Subjects

heart regeneration, zebrafish, genetic ablation, cardiomyocyte, proliferation, drug discovery, Biology (General), QH301-705.5

Abstract

Cardiovascular disease is the leading cause of death worldwide with myocardial infarction being the most prevalent. Currently, no cure is available to either prevent or revert the massive death of cardiomyocytes that occurs after a myocardial infarction. Adult mammalian hearts display a limited regeneration capacity, but it is insufficient to allow complete myocardial recovery. In contrast, the injured zebrafish heart muscle regenerates efficiently through robust proliferation of pre-existing myocardial cells. Thus, zebrafish allows its exploitation for studying the genetic programs behind cardiac regeneration, which may be present, albeit dormant, in the adult human heart. To this end, we have established ZebraReg, a novel and versatile automated platform for studying heart regeneration kinetics after the specific ablation of cardiomyocytes in zebrafish larvae. In combination with automated heart imaging, the platform can be integrated with genetic or pharmacological approaches and used for medium-throughput screening of presumed modulators of heart regeneration. We demonstrate the versatility of the platform by identifying both anti- and pro-regenerative effects of genes and drugs. In conclusion, we present a tool which may be utilised to streamline the process of target validation of novel gene regulators of regeneration, and the discovery of new drug therapies to regenerate the heart after myocardial infarction.

Published

2024

18. Interdependent changes of nuclear lamins, nuclear pore complexes, and ploidy regulate cellular regeneration and stress response in the heart.

Author

Li, Yao, Bertozzi, Alberto, Mann, Mellissa RW, and Kühn, Bernhard

Subjects

*NUCLEAR pore complex, *NUCLEAR transport, *MYOCARDIUM, *CARDIAC regeneration, *PLOIDY, *LAMINS

Abstract

In adult mammals, many heart muscle cells (cardiomyocytes) are polyploid, do not proliferate (post-mitotic), and, consequently, cannot contribute to heart regeneration. In contrast, fetal and neonatal heart muscle cells are diploid, proliferate, and contribute to heart regeneration. We have identified interdependent changes of the nuclear lamina, nuclear pore complexes, and DNA-content (ploidy) in heart muscle cell maturation. These results offer new perspectives on how cells alter their nuclear transport and, with that, their gene regulation in response to extracellular signals. We present how changes of the nuclear lamina alter nuclear pore complexes in heart muscle cells. The consequences of these changes for cellular regeneration and stress response in the heart are discussed. [ABSTRACT FROM AUTHOR]

Published

2023

19. The translation initiation factor homolog eif4e1c regulates cardiomyocyte metabolism and proliferation during heart regeneration.

Author

Rao, Anupama, Baken Lyu, Jahan, Ishrat, Lubertozzi, Anna, Gao Zhou, Tedeschi, Frank, Jankowsky, Eckhard, Junsu Kang, Carstens, Bryan, Poss, Kenneth D., Baskin, Kedryn, and Goldman, Joseph Aaron

Subjects

*CARDIAC regeneration, *RIBOSOMES, *GENETIC translation, *HEART development, *METABOLISM, *AMINO group, *HEART, *HEART injuries

Abstract

The eIF4E family of translation initiation factors bind 5' methylated caps and act as the limiting step for mRNA translation. The canonical eIF4E1A is required for cell viability, yet other related eIF4E families exist and are utilized in specific contexts or tissues. Here, we describe a family called Eif4e1c, for which we find roles during heart development and regeneration in zebrafish. The Eif4e1c family is present in all aquatic vertebrates but is lost in all terrestrial species. A core group of amino acids shared over 500 million years of evolution forms an interface along the protein surface, suggesting that Eif4e1c functions in a novel pathway. Deletion of eif4e1c in zebrafish caused growth deficits and impaired survival in juveniles. Mutants surviving to adulthood had fewer cardiomyocytes and reduced proliferative responses to cardiac injury. Ribosome profiling of mutant hearts demonstrated changes in translation efficiency of mRNA for genes known to regulate cardiomyocyte proliferation. Although eif4e1c is broadly expressed, its disruption had most notable impact on the heart and at juvenile stages. Our findings reveal context-dependent requirements for translation initiation regulators during heart regeneration. [ABSTRACT FROM AUTHOR]

Published

2023

20. Tnni3k influences cardiomyocyte S-phase activity and proliferation.

Author

Purdy, Alexandra L., Swift, Samantha K., Sucov, Henry M., and Patterson, Michaela

Subjects

*CELL cycle, *CELL suspensions, *PLOIDY, *CELL division, *CELL analysis, *MYOCARDIUM, *HEART cells

Abstract

Cardiomyocyte proliferation is a difficult phenomenon to capture and prove. Here we employ a retrospective analysis of single cell ventricular suspensions to definitively identify cardiomyocytes that have completed cell division. Through this analysis we determined that the capacity of cardiomyocytes to re-enter the cell cycle and complete cell division after injury are separate and variable traits. Further, we provide evidence that Tnni3k definitively influences both early and final stages of the cell cycle. [Display omitted] • CM ploidy in the naïve adult myocardium and cell cycle activity in response to injury are highly variable traits. • Some of the genetic drivers that regulate CM ploidy also in turn influence cell cycle activation and completion after injury. • Tnni3k influences both S-phase activity and completion of the cell cycle. [ABSTRACT FROM AUTHOR]

Published

2023

21. The ion channel Trpc6a regulates the cardiomyocyte regenerative response to mechanical stretch

Author

Laura Rolland, Jourdano Mancilla Abaroa, Adèle Faucherre, Aurélien Drouard, and Chris Jopling

Subjects

TRPC6 channel, heart regeneration, AP1 complex, mechanosensation, calcineurin/NFAT pathway, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Myocardial damage caused, for example, by cardiac ischemia leads to ventricular volume overload resulting in increased stretch of the remaining myocardium. In adult mammals, these changes trigger an adaptive cardiomyocyte hypertrophic response which, if the damage is extensive, will ultimately lead to pathological hypertrophy and heart failure. Conversely, in response to extensive myocardial damage, cardiomyocytes in the adult zebrafish heart and neonatal mice proliferate and completely regenerate the damaged myocardium. We therefore hypothesized that in adult zebrafish, changes in mechanical loading due to myocardial damage may act as a trigger to induce cardiac regeneration. Based on this notion we sought to identify mechanosensors which could be involved in detecting changes in mechanical loading and triggering regeneration. Here we show using a combination of knockout animals, RNAseq and in vitro assays that the mechanosensitive ion channel Trpc6a is required by cardiomyocytes for successful cardiac regeneration in adult zebrafish. Furthermore, using a cyclic cell stretch assay, we have determined that Trpc6a induces the expression of components of the AP1 transcription complex in response to mechanical stretch. Our data highlights how changes in mechanical forces due to myocardial damage can be detected by mechanosensors which in turn can trigger cardiac regeneration.

Published

2024

22. Anti-Ferroptotic Treatment Deteriorates Myocardial Infarction by Inhibiting Angiogenesis and Altering Immune Response

Author

Rebecca A. Stairley, Allison M. Trouten, Shuang Li, Patrick L. Roddy, Kristine Y. DeLeon-Pennell, Kyu-Ho Lee, Henry M. Sucov, Chun Liu, and Ge Tao

Subjects

heart regeneration, myocardial infarction, ferroptosis, angiogenesis, macrophage, Therapeutics. Pharmacology, RM1-950

Abstract

Mammalian cardiomyocytes have limited regenerative ability. Cardiac disease, such as congenital heart disease and myocardial infarction, causes an initial loss of cardiomyocytes through regulated cell death (RCD). Understanding the mechanisms that govern RCD in the injured myocardium is crucial for developing therapeutics to promote heart regeneration. We previously reported that ferroptosis, a non-apoptotic and iron-dependent form of RCD, is the main contributor to cardiomyocyte death in the injured heart. To investigate the mechanisms underlying the preference for ferroptosis in cardiomyocytes, we examined the effects of anti-ferroptotic reagents in infarcted mouse hearts. The results revealed that the anti-ferroptotic reagent did not improve neonatal heart regeneration, and further compromised the cardiac function of juvenile hearts. On the other hand, ferroptotic cardiomyocytes played a supportive role during wound healing by releasing pro-angiogenic factors. The inhibition of ferroptosis in the regenerating mouse heart altered the immune and angiogenic responses. Our study provides insights into the preference for ferroptosis over other types of RCD in stressed cardiomyocytes, and guidance for designing anti-cell-death therapies for treating heart disease.

Published

2024

23. Exploring Cellular Dynamics in the Goldfish Bulbus Arteriosus: A Multifaceted Perspective

Author

Doaa M. Mokhtar, Enas A. Abd-Elhafez, Marco Albano, Giacomo Zaccone, and Manal T. Hussein

Subjects

endocardium, rodlet cells, telocytes, secretory activity, heart regeneration, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

The bulbus arteriosus of goldfish, Carassius auratus, possesses unique structural features. The wall of the bulbus arteriosus is exceptionally thick, with an inner surface characterized by longitudinally arranged finger-like ridges, resulting in an uneven luminal appearance. These ridges are covered by endocardium and encased in an amorphous extracellular matrix. The inner surface of the bulbus arteriosus also contains rodlet cells at different developmental stages, often clustered beneath the endothelium lining the bulbar lumen. Ruptured rodlet cells release their contents via a holocrine secretion process. The high abundance of rodlet cells in the bulbus arteriosus suggests that this is the site of origin for these cells. Within the middle layer of the bulbus arteriosus, smooth muscle cells, branched telocytes (TCs), and collagen bundles coexist. TCs and their telopodes form complex connections within a dense collagen matrix, extending to rodlet cells and macrophages. Moreover, the endothelium makes direct contact with telopodes. The endocardial cells within the bulbus arteriosus display irregular, stellate shapes and numerous cell processes that establish direct contact with TCs. TEM reveals that they contain moderately dense bodies and membrane-bound vacuoles, suggesting a secretory activity. TCs exhibit robust secretory activity, evident from their telopodes containing numerous secretory vesicles. Furthermore, TCs release excretory vesicles containing bioactive molecules into the extracellular matrix, which strengthens evidence for telocytes as promising candidates for cellular therapies and regeneration in various heart pathologies.

Published

2024

24. Regeneration of the heart: from molecular mechanisms to clinical therapeutics

Author

Qian-Yun Guo, Jia-Qi Yang, Xun-Xun Feng, and Yu-Jie Zhou

Subjects

Heart regeneration, Cardiac disease, Therapeutics, Signaling mechanisms, Medicine (General), R5-920, Military Science

Abstract

Abstract Heart injury such as myocardial infarction leads to cardiomyocyte loss, fibrotic tissue deposition, and scar formation. These changes reduce cardiac contractility, resulting in heart failure, which causes a huge public health burden. Military personnel, compared with civilians, is exposed to more stress, a risk factor for heart diseases, making cardiovascular health management and treatment innovation an important topic for military medicine. So far, medical intervention can slow down cardiovascular disease progression, but not yet induce heart regeneration. In the past decades, studies have focused on mechanisms underlying the regenerative capability of the heart and applicable approaches to reverse heart injury. Insights have emerged from studies in animal models and early clinical trials. Clinical interventions show the potential to reduce scar formation and enhance cardiomyocyte proliferation that counteracts the pathogenesis of heart disease. In this review, we discuss the signaling events controlling the regeneration of heart tissue and summarize current therapeutic approaches to promote heart regeneration after injury.

Published

2023

25. A bibliometric study related to the treatment of myocardial ischemia-reperfusion Injury

Author

Feng, Jie, Han, Leilei, Liu, Yunman, Li, Kai, and Wu, Yanqing

Published

2024

26. Investigating CDK9 inhibitor treatment during the innate inflammatory and regenerative response in a zebrafish model of cardiac injury

Author

Kaveh, Aryan, Denvir, Martin, and Rossi, Adriano

Subjects

neutrophils, CDK9 inhibitors, zebrafish, heart regeneration, macrophage responses, AT7519

Abstract

Neutrophils and macrophages are crucial effectors and modulators of cardiac repair following myocardial infarction (MI). Sustained neutrophilic inflammation is detrimental for cardiac repair and associated with adverse MI outcomes. An attractive therapeutic strategy to treat acute inflammatory disorders, such as MI, is to resolve infiltrating neutrophils to positively influence downstream reparative mechanisms. CDK9 inhibitor compounds enhance the resolution of neutrophilic inflammation, however, their effects on cardiac repair/regeneration are unknown. Unlike adult mammalian hearts, zebrafish hearts regenerate following injury via cardiomyocyte proliferation. Prolonged neutrophil retention has been shown to impair cardiomyocyte proliferation and myocardial wound regression following cardiac injury in zebrafish. I therefore hypothesised that CDK9 inhibitor treatment enhances the resolution of neutrophilic inflammation following injury and promotes cardiac regeneration in zebrafish. I first refined a larval zebrafish cardiac laser injury model and developed bespoke epifluorescence and 4D heartbeat-synchronised light sheet fluorescence microscopy techniques. I characterised the innate inflammatory response to cardiac injury, specifically examining neutrophil and macrophage migration to the injured heart using high resolution imaging of transgenic reporter fish. Additionally, neutrophil and macrophage migratory responses were compared to the archetypal tail fin injury model. Live in vivo imaging permitted mapping of neutrophil and macrophage migration throughout the zebrafish larvae, from primary hematopoietic sites to the myocardial lesion. I found a conserved sequence of events marked by an early and acute phase of neutrophil recruitment followed by sustained macrophage recruitment. In each injury model I found the innate inflammatory response resolves by reverse migration. I used the characterised zebrafish cardiac injury model to test whether CDK9 inhibitors, AT7519 and Flavopiridol (FVP), resolve neutrophil infiltration and whether this regulates downstream macrophage involvement and cardiac repair/regeneration. AT7519 and FVP were found to enhance the resolution of neutrophilic inflammation by inducing neutrophil reverse migration from the injured heart. While continuous exposure to AT7519 or FVP caused adverse cardiac phenotypes, transient (pulsed) treatment accelerated neutrophil resolution and avoided these effects. Transient treatment with AT7519, but not FVP, augmented TNF polarisation of wound-associated macrophages, in turn enhancing cardiomyocyte number expansion and the rate of myocardial wound closure. Furthermore, I developed a selectivity assay using cdk9-/- knockout mutants that demonstrated AT7519 is a more selective CDK9 inhibitor than FVP. These findings highlight the potential of AT7519 as a promising treatment that resolves neutrophilic inflammation following cardiac injury and promotes cardiomyocyte regeneration. In collaboration with BioAscent Discovery Ltd, I performed an in silico ligand-based screen of a 125k compound library. The chemical structure of AT7519 and five other potent and selective CDK9 inhibitor compounds (AZD4573, LDC000067, iCDK9, NVP-2 and MC180295) were used to perform a 3D similarity search against BioAscent's 125k diversity library, with the aim of identifying novel and efficacious CDK9 inhibitors. For each of the six query compounds, the top 1000 BioAscent compounds were ranked based on 3D similarity score. Common (duplicated) compounds between the six ranked query lists were shortlisted and any compounds that displayed pan-assay interference properties were removed. This yielded a final focussed library of 598 BioAscent compounds. Further work is needed to develop a high throughput in vitro CDK9 inhibition assay to screen the custom library and identify promising candidate compounds for downstream validation and optimisation.

Published

2021

27. Interdependent changes of nuclear lamins, nuclear pore complexes, and ploidy regulate cellular regeneration and stress response in the heart

Author

Yao Li, Alberto Bertozzi, Mellissa RW Mann, and Bernhard Kühn

Subjects

Cardiac hypertrophy, cardiac remodeling, cardiomyocyte, heart regeneration, nuclear lamina, nuclear pore, Genetics, QH426-470, Cytology, QH573-671

Abstract

ABSTRACTIn adult mammals, many heart muscle cells (cardiomyocytes) are polyploid, do not proliferate (post-mitotic), and, consequently, cannot contribute to heart regeneration. In contrast, fetal and neonatal heart muscle cells are diploid, proliferate, and contribute to heart regeneration. We have identified interdependent changes of the nuclear lamina, nuclear pore complexes, and DNA-content (ploidy) in heart muscle cell maturation. These results offer new perspectives on how cells alter their nuclear transport and, with that, their gene regulation in response to extracellular signals. We present how changes of the nuclear lamina alter nuclear pore complexes in heart muscle cells. The consequences of these changes for cellular regeneration and stress response in the heart are discussed.

Published

2023

28. Harnessing developmental cues for cardiomyocyte production.

Author

Maas, Renee G. C., van den Dolder, Floor W., Qianliang Yuan, van der Velden, Jolanda, Wu, Sean M., Sluijter, Joost P. G., and Buikema, Jan W.

Subjects

*HEART, *HIPPO signaling pathway, *FETAL heart, *HEART size, *WNT signal transduction, *HEART development, *CELLULAR signal transduction, *CARDIAC regeneration

Abstract

Developmental research has attempted to untangle the exact signals that control heart growth and size, with knockout studies in mice identifying pivotal roles for Wnt and Hippo signaling during embryonic and fetal heart growth. Despite this improved understanding, no clinically relevant therapies are yet available to compensate for the loss of functional adult myocardium and the absence of mature cardiomyocyte renewal that underlies cardiomyopathies of multiple origins. It remains of great interest to understand which mechanisms are responsible for the decline in proliferation in adult hearts and to elucidate new strategies for the stimulation of cardiac regeneration. Multiple signaling pathways have been identified that regulate the proliferation of cardiomyocytes in the embryonic heart and appear to be upregulated in postnatal injured hearts. In this Review, we highlight the interaction of signaling pathways in heart development and discuss how this knowledge has been translated into current technologies for cardiomyocyte production. [ABSTRACT FROM AUTHOR]

Published

2023

29. MATHEMATICAL MODELING OF STEM CELL THERAPY FOR LEFT VENTRICULAR REMODELING AFTER MYOCARDIAL INFARCTION.

Author

BÜYÜKKAHRAMAN, MEHTAP LAFCI, CHEN-CHARPENTIER, BENITO M., LIAO, JUN, and KOJOUHAROV, HRISTO V.

Subjects

*VENTRICULAR remodeling, *STEM cell treatment, *MYOCARDIAL infarction, *ORDINARY differential equations, *NONLINEAR differential equations, *MATHEMATICAL models, *CARDIAC regeneration

Abstract

The heart is an organ with a limited capacity for regeneration and repair. In this paper, a new mathematical model is presented to study the left ventricular remodeling after myocardial infarction (MI) and followed stem cell therapeutic effort. The model represents the post-MI regeneration process of cardiomyocytes under stem cell therapy with oxygen restoration. The resulting system of nonlinear ordinary differential equations (ODE) is studied numerically in order to demonstrate the functionality and performance of the new model. The optimal time of stem cell injection for various oxygen restorations is determined. Moreover, the regeneration of cardiomyocytes is successfully correlated with improved left ventricle function observed in experiments. The proposed nonlinear ODE model is able to capture the complicated biological interactions in post-MI remodeling and can serve as a platform for in silico simulation and perturbation to optimize MI stem cell therapy. [ABSTRACT FROM AUTHOR]

Published

2023

30. Cellular reprogramming of fibroblasts in heart regeneration.

Author

Chi, Congwu and Song, Kunhua

Subjects

*REGENERATION (Biology), *INDUCED pluripotent stem cells, *FIBROBLASTS, *HEART cells, *CARDIAC regeneration, *PROGENITOR cells

Abstract

Myocardial infarction causes the loss of cardiomyocytes and the formation of cardiac fibrosis due to the activation of cardiac fibroblasts, leading to cardiac dysfunction and heart failure. Unfortunately, current therapeutic interventions can only slow the disease progression. Furthermore, they cannot fully restore cardiac function, likely because the adult human heart lacks sufficient capacity to regenerate cardiomyocytes. Therefore, intensive efforts have focused on developing therapeutics to regenerate the damaged heart. Several strategies have been intensively investigated, including stimulation of cardiomyocyte proliferation, transplantation of stem cell-derived cardiomyocytes, and conversion of fibroblasts into cardiac cells. Resident cardiac fibroblasts are critical in the maintenance of the structure and contractility of the heart. Fibroblast plasticity makes this type of cells be reprogrammed into many cell types, including but not limited to induced pluripotent stem cells, induced cardiac progenitor cells, and induced cardiomyocytes. Fibroblasts have become a therapeutic target due to their critical roles in cardiac pathogenesis. This review summarizes the reprogramming of fibroblasts into induced pluripotent stem cell-derived cardiomyocytes, induced cardiac progenitor cells, and induced cardiomyocytes to repair a damaged heart, outlines recent findings in utilizing fibroblast-derived cells for heart regeneration, and discusses the limitations and challenges. [Display omitted] • Cellular reprogramming of fibroblasts to generate cardiac cells. • Fibroblast-derived cardiac cells have the potential to regenerate a heart. • Limitations and challenges in the reprogramming approach for heart repair. [ABSTRACT FROM AUTHOR]

Published

2023

31. Patterned Arteriole-Scale Vessels Enhance Engraftment, Perfusion, and Vessel Branching Hierarchy of Engineered Human Myocardium for Heart Regeneration.

Author

Kant, Rajeev J., Dwyer, Kiera D., Lee, Jang-Hoon, Polucha, Collin, Kobayashi, Momoka, Pyon, Stephen, Soepriatna, Arvin H., Lee, Jonghwan, and Coulombe, Kareen L. K.

Subjects

*HEART, *MYOCARDIUM, *PERFUSION, *CARDIAC regeneration, *IMMUNOSTAINING, *RNA sequencing, *REGENERATION (Biology), *TISSUE engineering

Abstract

Heart regeneration after myocardial infarction (MI) using human stem cell-derived cardiomyocytes (CMs) is rapidly accelerating with large animal and human clinical trials. However, vascularization methods to support the engraftment, survival, and development of implanted CMs in the ischemic environment of the infarcted heart remain a key and timely challenge. To this end, we developed a dual remuscularization-revascularization therapy that is evaluated in a rat model of ischemia-reperfusion MI. This study details the differentiation of human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) for engineering cardiac tissue containing patterned engineered vessels 400 μm in diameter. Vascularized engineered human myocardial tissues (vEHMs) are cultured in static conditions or perfused in vitro prior to implantation and evaluated after two weeks. Immunohistochemical staining indicates improved engraftment of hiPSC-CMs in in vitro-perfused vEHMs with greater expression of SMA+ vessels and evidence of inosculation. Three-dimensional vascular reconstructions reveal less tortuous and larger intra-implant vessels, as well as an improved branching hierarchy in in vitro-perfused vEHMs relative to non-perfused controls. Exploratory RNA sequencing of explanted vEHMs supports the hypothesis that co-revascularization impacts hiPSC-CM development in vivo. Our approach provides a strong foundation to enhance vEHM integration, develop hierarchical vascular perfusion, and maximize hiPSC-CM engraftment for future regenerative therapy. [ABSTRACT FROM AUTHOR]

Published

2023

32. Comparative single-cell profiling reveals distinct cardiac resident macrophages essential for zebrafish heart regeneration

Author

Ke-Hsuan Wei, I-Ting Lin, Kaushik Chowdhury, Khai Lone Lim, Kuan-Ting Liu, Tai-Ming Ko, Yao-Ming Chang, Kai-Chien Yang, and Shih-Lei (Ben) Lai

Subjects

macrophages, heart regeneration, scRNAseq, immune response, comparative analysis, myocardial infarction, Medicine, Science, Biology (General), QH301-705.5

Abstract

Zebrafish exhibit a robust ability to regenerate their hearts following injury, and the immune system plays a key role in this process. We previously showed that delaying macrophage recruitment by clodronate liposome (–1d_CL, macrophage-delayed model) impairs neutrophil resolution and heart regeneration, even when the infiltrating macrophage number was restored within the first week post injury (Lai et al., 2017). It is thus intriguing to learn the regenerative macrophage property by comparing these late macrophages vs. control macrophages during cardiac repair. Here, we further investigate the mechanistic insights of heart regeneration by comparing the non-regenerative macrophage-delayed model with regenerative controls. Temporal RNAseq analyses revealed that –1d_CL treatment led to disrupted inflammatory resolution, reactive oxygen species homeostasis, and energy metabolism during cardiac repair. Comparative single-cell RNAseq profiling of inflammatory cells from regenerative vs. non-regenerative hearts further identified heterogeneous macrophages and neutrophils, showing alternative activation and cellular crosstalk leading to neutrophil retention and chronic inflammation. Among macrophages, two residential subpopulations (hbaa+ Mac and timp4.3+ Mac 3) were enriched only in regenerative hearts and barely recovered after +1d_CL treatment. To deplete the resident macrophage without delaying the circulating macrophage recruitment, we established the resident macrophage-deficient model by administrating CL earlier at 8 d (–8d_CL) before cryoinjury. Strikingly, resident macrophage-deficient zebrafish still exhibited defects in revascularization, cardiomyocyte survival, debris clearance, and extracellular matrix remodeling/scar resolution without functional compensation from the circulating/monocyte-derived macrophages. Our results characterized the diverse function and interaction between inflammatory cells and identified unique resident macrophages prerequisite for zebrafish heart regeneration.

Published

2023

33. Unravelling the Interplay between Cardiac Metabolism and Heart Regeneration.

Author

Yu, Fan, Cong, Shuo, Yap, En Ping, Hausenloy, Derek J., and Ramachandra, Chrishan J.

Subjects

*HEART metabolism, *CARDIAC regeneration, *CORONARY disease, *MYOCARDIAL ischemia, *HEART failure, *CELL cycle

Abstract

Ischemic heart disease (IHD) is the leading cause of heart failure (HF) and is a significant cause of morbidity and mortality globally. An ischemic event induces cardiomyocyte death, and the ability for the adult heart to repair itself is challenged by the limited proliferative capacity of resident cardiomyocytes. Intriguingly, changes in metabolic substrate utilisation at birth coincide with the terminal differentiation and reduced proliferation of cardiomyocytes, which argues for a role of cardiac metabolism in heart regeneration. As such, strategies aimed at modulating this metabolism-proliferation axis could, in theory, promote heart regeneration in the setting of IHD. However, the lack of mechanistic understanding of these cellular processes has made it challenging to develop therapeutic modalities that can effectively promote regeneration. Here, we review the role of metabolic substrates and mitochondria in heart regeneration, and discuss potential targets aimed at promoting cardiomyocyte cell cycle re-entry. While advances in cardiovascular therapies have reduced IHD-related deaths, this has resulted in a substantial increase in HF cases. A comprehensive understanding of the interplay between cardiac metabolism and heart regeneration could facilitate the discovery of novel therapeutic targets to repair the damaged heart and reduce risk of HF in patients with IHD. [ABSTRACT FROM AUTHOR]

Published

2023

34. Development of direct cardiac reprogramming for clinical applications.

Author

Yamada, Yu, Sadahiro, Taketaro, and Ieda, Masaki

Subjects

*CORONARY disease, *MYOCARDIAL infarction, *CLINICAL medicine, *MYOCARDIAL ischemia, *CARDIOVASCULAR diseases

Abstract

The incidence of cardiovascular diseases is increasing worldwide, and cardiac regenerative therapy has great potential as a new treatment strategy, especially for ischemic heart disease. Direct cardiac reprogramming is a promising new cardiac regenerative therapy that uses defined factors to induce transdifferentiation of endogenous cardiac fibroblasts (CFs) into induced cardiomyocyte-like cells (iCMs). In vivo reprogramming is expected to restore lost cardiac function without necessitating cardiac transplantation by converting endogenous CFs that exist abundantly in cardiac tissues directly into iCMs. Indeed, we and other groups have demonstrated that in vivo cardiac reprogramming improves cardiac contractile function and reduces scar area after acute myocardial infarction (MI). Recently, we demonstrated that in vivo cardiac reprogramming is an innovative cardiac regenerative therapy that not only regenerates the myocardium, but also reverses fibrosis by inducing the quiescence of pro-fibrotic fibroblasts, thereby improving heart failure in chronic MI. In this review, we summarize the recent progresses in in vivo cardiac reprogramming, and discuss its prospects for future clinical applications and the challenges of direct human reprogramming, which has been a longstanding issue. • Direct cardiac reprogramming can convert CFs into iCMs in vitro and in vivo. • In vivo cardiac reprogramming can regenerate myocardium and reverse fibrosis. • The reprogramming cocktail for human cardiac reprogramming requires further study. [ABSTRACT FROM AUTHOR]

Published

2023

35. One Billion hiPSC-Cardiomyocytes: Upscaling Engineered Cardiac Tissues to Create High Cell Density Therapies for Clinical Translation in Heart Regeneration.

Author

Dwyer, Kiera D., Kant, Rajeev J., Soepriatna, Arvin H., Roser, Stephanie M., Daley, Mark C., Sabe, Sharif A., Xu, Cynthia M., Choi, Bum-Rak, Sellke, Frank W., and Coulombe, Kareen L. K.

Subjects

*CELLULAR therapy, *CARDIAC regeneration, *MYOCARDIAL ischemia, *HEART, *ELASTIC modulus, *REGENERATION (Biology), *TISSUE engineering

Abstract

Despite the overwhelming use of cellularized therapeutics in cardiac regenerative engineering, approaches to biomanufacture engineered cardiac tissues (ECTs) at clinical scale remain limited. This study aims to evaluate the impact of critical biomanufacturing decisions—namely cell dose, hydrogel composition, and size-on ECT formation and function—through the lens of clinical translation. ECTs were fabricated by mixing human induced pluripotent stem-cell-derived cardiomyocytes (hiPSC-CMs) and human cardiac fibroblasts into a collagen hydrogel to engineer meso-(3 × 9 mm), macro- (8 × 12 mm), and mega-ECTs (65 × 75 mm). Meso-ECTs exhibited a hiPSC-CM dose-dependent response in structure and mechanics, with high-density ECTs displaying reduced elastic modulus, collagen organization, prestrain development, and active stress generation. Scaling up, cell-dense macro-ECTs were able to follow point stimulation pacing without arrhythmogenesis. Finally, we successfully fabricated a mega-ECT at clinical scale containing 1 billion hiPSC-CMs for implantation in a swine model of chronic myocardial ischemia to demonstrate the technical feasibility of biomanufacturing, surgical implantation, and engraftment. Through this iterative process, we define the impact of manufacturing variables on ECT formation and function as well as identify challenges that must still be overcome to successfully accelerate ECT clinical translation. [ABSTRACT FROM AUTHOR]

Published

2023

36. Single-cell analysis reveals an Angpt4-initiated EPDC-EC-CM cellular coordination cascade during heart regeneration.

Author

Wu, Zekai, Shi, Yuan, Cui, Yueli, Xing, Xin, Zhang, Liya, Liu, Da, Zhang, Yutian, Dong, Ji, Jin, Li, Pang, Meijun, Xiao, Rui-Ping, Zhu, Zuoyan, Xiong, Jing-Wei, Tong, Xiangjun, Zhang, Yan, Wang, Shiqiang, Tang, Fuchou, and Zhang, Bo

Abstract

Mammals exhibit limited heart regeneration ability, which can lead to heart failure after myocardial infarction. In contrast, zebrafish exhibit remarkable cardiac regeneration capacity. Several cell types and signaling pathways have been reported to participate in this process. However, a comprehensive analysis of how different cells and signals interact and coordinate to regulate cardiac regeneration is unavailable. We collected major cardiac cell types from zebrafish and performed high-precision single-cell transcriptome analyses during both development and post-injury regeneration. We revealed the cellular heterogeneity as well as the molecular progress of cardiomyocytes during these processes, and identified a subtype of atrial cardiomyocyte exhibiting a stem-like state which may transdifferentiate into ventricular cardiomyocytes during regeneration. Furthermore, we identified a regeneration-induced cell (RIC) population in the epicardium-derived cells (EPDC), and demonstrated Angiopoietin 4 (Angpt4) as a specific regulator of heart regeneration. angpt4 expression is specifically and transiently activated in RIC, which initiates a signaling cascade from EPDC to endocardium through the Tie2-MAPK pathway, and further induces activation of cathepsin K in cardiomyocytes through RA signaling. Loss of angpt4 leads to defects in scar tissue resolution and cardiomyocyte proliferation, while overexpression of angpt4 accelerates regeneration. Furthermore, we found that ANGPT4 could enhance proliferation of neonatal rat cardiomyocytes, and promote cardiac repair in mice after myocardial infarction, indicating that the function of Angpt4 is conserved in mammals. Our study provides a mechanistic understanding of heart regeneration at single-cell precision, identifies Angpt4 as a key regulator of cardiomyocyte proliferation and regeneration, and offers a novel therapeutic target for improved recovery after human heart injuries. [ABSTRACT FROM AUTHOR]

Published

2023

37. Regeneration of the heart: from molecular mechanisms to clinical therapeutics.

Author

Guo, Qian-Yun, Yang, Jia-Qi, Feng, Xun-Xun, and Zhou, Yu-Jie

Subjects

REGENERATION (Biology), CARDIAC regeneration, HEART failure, DISEASE risk factors, HEART, HEART diseases

Abstract

Heart injury such as myocardial infarction leads to cardiomyocyte loss, fibrotic tissue deposition, and scar formation. These changes reduce cardiac contractility, resulting in heart failure, which causes a huge public health burden. Military personnel, compared with civilians, is exposed to more stress, a risk factor for heart diseases, making cardiovascular health management and treatment innovation an important topic for military medicine. So far, medical intervention can slow down cardiovascular disease progression, but not yet induce heart regeneration. In the past decades, studies have focused on mechanisms underlying the regenerative capability of the heart and applicable approaches to reverse heart injury. Insights have emerged from studies in animal models and early clinical trials. Clinical interventions show the potential to reduce scar formation and enhance cardiomyocyte proliferation that counteracts the pathogenesis of heart disease. In this review, we discuss the signaling events controlling the regeneration of heart tissue and summarize current therapeutic approaches to promote heart regeneration after injury. [ABSTRACT FROM AUTHOR]

Published

2023

38. Targeting immunoregulation for cardiac regeneration.

Author

Li, Ruopu, Xiang, Chenying, Li, Yixun, and Nie, Yu

Subjects

*CARDIAC regeneration, *IMMUNOREGULATION, *IMMUNE response, *MYOCARDIAL infarction, *HEART failure, *MYOCARDIUM

Abstract

Inducing endogenous cardiomyocyte proliferation and heart regeneration is a promising strategy to treat ischemic heart failure. The immune response has recently been considered critical in cardiac regeneration. Thus, targeting the immune response is a potent strategy to improve cardiac regeneration and repair after myocardial infarction. Here we reviewed the characteristics of the relationship between the postinjury immune response and heart regenerative capacity and summarized the latest studies focusing on inflammation and heart regeneration to identify potent targets of the immune response and strategies in the immune response to promote cardiac regeneration. • Acute immune response is mandatory for the initiation of cardiac regeneration in neonates. • Transplantation of pro-regenerative immune cells improves the outcome of cardiac repair. • IL-6 family cytokines actively regulate myocardium repair and are potent targets for cardiac regeneration. [ABSTRACT FROM AUTHOR]

Published

2023

39. The longevity protein p66Shc is required for neonatal heart regeneration.

Author

Huang, Chengzhen, Ding, Tong, Zhang, Yuan, Li, Xunkai, Sun, Xin, Lv, Shuangjie, Hao, Yanyan, Bai, Lina, Liu, Ning, Xie, Yifan, Chen, Houzao, and Nie, Yu

Subjects

*CARDIAC regeneration, *WNT signal transduction, *LONGEVITY, *HEART, *NON-coding RNA, *RNA sequencing, *CATENINS, *PROTEINS

Abstract

The longevity protein p66Shc is essential for the senescence signaling that is involved in heart regeneration and remodeling. However, the exact role of p66Shc in heart regeneration is unknown. In this study, we found that p66Shc deficiency decreased neonatal mouse cardiomyocyte (CM) proliferation and impeded neonatal heart regeneration after apical resection injury. RNA sequencing and functional verification demonstrated that p66Shc regulated CM proliferation by activating β-catenin signaling. These findings reveal the critical role of p66Shc in neonatal heart regeneration and provide new insights into senescence signaling in heart regeneration. [Display omitted] • P66Shc deficiency suspends neonatal heart regeneration. • P66Shc is required for primary cardiomyocyte proliferation. • Activation of β-catenin mediates the effect of p66Shc on cardiomyocyte proliferation. [ABSTRACT FROM AUTHOR]

Published

2023

40. IDENTIFICATION OF MIRROR REPEATS WITHIN THE Pdgf-Aa GENE OF DANIO RERIO.

Author

Dangi, Namrata, Saini, Kavita, Madhuri, bhargava, Anu, and Bhardwaj, Vikash

Subjects

*MIRRORS, *BRACHYDANIO, *GENES, *CARDIAC regeneration, *BIOLOGY, *REGENERATION (Biology), *ZEBRA danio

Abstract

Compared to other organs, the adult human heart lacks the capacity to regenerate after injury. In contrast, a zebrafish's (Danio rerio) heart renews after amputation. It is one of the most relevant model organisms which is used to study regenerative biology. Various types of repetitive elements have been identified within the genome of different organisms. The repetitive elements can be direct, inverted, tandem, mirror repeats, etc. One such repeat which is not widely explored in Danio rerio is mirror repeats. The present study aims to determine the mirror repeats within the pdgf-aa gene of Danio rerio. The pdgf signalling plays a crucial role in initiating cardiomyocyte proliferation during Danio rerio (zebrafish) heart regeneration. Using a simple approach, we have identified mirror repeats within the pdgf-aa gene. We concluded that these mirror repeats are limited to the pdgf-aa gene and well distributed within the Danio rerio genome and other organism genomes. [ABSTRACT FROM AUTHOR]

Published

2023

41. Electrophysiological Properties of Tetraploid Cardiomyocytes Derived from Murine Pluripotent Stem Cells Generated by Fusion of Adult Somatic Cells with Embryonic Stem Cells.

Author

Xu, Guoxing, Fatima, Azra, Breitbach, Martin, Kuzmenkin, Alexey, Fügemann, Christopher J., Ivanyuk, Dina, Kim, Kee Pyo, Cantz, Tobias, Pfannkuche, Kurt, Schöler, Hans R., Fleischmann, Bernd K., Hescheler, Jürgen, and Šarić, Tomo

Subjects

*PLURIPOTENT stem cells, *SOMATIC cells, *CELL fusion, *EMBRYONIC stem cells, *POLYPLOIDY, *ELECTROPHYSIOLOGY, *ACTION potentials, *ION channels

Abstract

Most cardiomyocytes (CMs) in the adult mammalian heart are either binucleated or contain a single polyploid nucleus. Recent studies have shown that polyploidy in CMs plays an important role as an adaptive response to physiological demands and environmental stress and correlates with poor cardiac regenerative ability after injury. However, knowledge about the functional properties of polyploid CMs is limited. In this study, we generated tetraploid pluripotent stem cells (PSCs) by fusion of murine embryonic stem cells (ESCs) and somatic cells isolated from bone marrow or spleen and performed a comparative analysis of the electrophysiological properties of tetraploid fusion-derived PSCs and diploid ESC-derived CMs. Fusion-derived PSCs exhibited characteristics of genuine ESCs and contained a near-tetraploid genome. Ploidy features and marker expression were also retained during the differentiation of fusion-derived cells. Fusion-derived PSCs gave rise to CMs, which were similar to their diploid ESC counterparts in terms of their expression of typical cardiospecific markers, sarcomeric organization, action potential parameters, response to pharmacologic stimulation with various drugs, and expression of functional ion channels. These results suggest that the state of ploidy does not significantly affect the structural and electrophysiological properties of murine PSC-derived CMs. These results extend our knowledge of the functional properties of polyploid CMs and contribute to a better understanding of their biological role in the adult heart. [ABSTRACT FROM AUTHOR]

Published

2023

42. Irisin Regulates Cardiac Responses to Exercise in Health and Diseases: a Narrative Review.

Author

Zhu, Baishu, Wang, Bin, Zhao, Chen, Wang, Yuanxin, Zhou, Yalan, Lin, Junjie, and Zhao, Renqing

Abstract

Exercise has been recognized as an important non-pharmacological approach for the prevention, treatment, and rehabilitation of cardiovascular diseases, but the mechanisms of exercise in promoting cardiovascular health remain unclear. Exercise generates cardiac benefits via stimulating muscle to secret hundreds of myokines that directly enter circulation and target heart tissue. Therefore, inter-organ communication between skeletal muscle and heart may be one important regulating pattern, and such communication can occur through secretion of molecules, frequently known as myokines. Irisin, a newly identified myokine, is cleaved from fibronectin type III domain-containing protein 5 (FNDC5) and secreted by the stimulation of exercise. Recently, accumulating evidence focusing on the interaction between irisin and cardiac function has been reported. This review highlights the molecular signaling by which irisin regulates the benefits of exercise on cardiac function both in physiological and pathological process, and discusses the clinical potential of irisin in treating heart diseases. Exercise generates various cardiovascular benefits through stimulating skeletal muscle to secrete irisin. The exercise "hormone" irisin, both produced by exercise or recombinant form, exerts therapeutic effects in a group of cardiovascular disorders including heart failure, myocardial infarction, atherosclerosis and hypertension. However, the molecular mechanisms involved remain ambiguous.This review highlights the most up-to-date findings to bridge the gap between exercise, irisin and cardiovascular diseases, and discusses the potential clinical prospect of irisin [ABSTRACT FROM AUTHOR]

Published

2023

43. Cell Therapy with Human ESC-Derived Cardiac Cells: Clinical Perspectives

Author

Menasché, Philippe, Zhang, Jianyi, editor, and Serpooshan, Vahid, editor

Published

2022

44. Foxm1 regulates cardiomyocyte proliferation in adult zebrafish after cardiac injury.

Author

Zuppo, Daniel A., Missinato, Maria A., Santana-Santos, Lucas, Guang Li, Benos, Panayiotis V., and Tsang, Michael

Subjects

*FORKHEAD transcription factors, *CELL cycle regulation, *HEART injuries, *CARDIAC regeneration, *BRACHYDANIO, *CELL cycle

Abstract

The regenerative capacity of the mammalian heart is poor, with one potential reason being that adult cardiomyocytes cannot proliferate at sufficient levels to replace lost tissue. During development and neonatal stages, cardiomyocytes can successfully divide under injury conditions; however, as these cells mature their ability to proliferate is lost. Therefore, understanding the regulatory programs that can induce post-mitotic cardiomyocytes into a proliferative state is essential to enhance cardiac regeneration. Here, we report that the forkhead transcription factor Foxm1 is required for cardiomyocyte proliferation after injury through transcriptional regulation of cell cycle genes. Transcriptomic analysis of injured zebrafish hearts revealed that foxm1 expression is increased in border zone cardiomyocytes. Decreased cardiomyocyte proliferation and expression of cell cycle genes in foxm1 mutant hearts was observed, suggesting it is required for cell cycle checkpoints. Subsequent analysis of a candidate Foxm1 target gene, cenpf, revealed that this microtubule and kinetochore binding protein is also required for cardiac regeneration. Moreover, cenpf mutants show increased cardiomyocyte binucleation. Thus, foxm1 and cenpf are required for cardiomyocytes to complete mitosis during zebrafish cardiac regeneration. [ABSTRACT FROM AUTHOR]

Published

2023

45. Increasing Mononuclear Diploid Cardiomyocytes by Loss of E2F Transcription Factor 7/8 Fails to Improve Cardiac Regeneration After Infarct.

Author

Yu, Zhe, Zhang, Lunfeng, Cattaneo, Paola, Guimarães-Camboa, Nuno, Fang, Xi, Gu, Yusu, Peterson, Kirk L., Bogomolovas, Julius, Cuitino, Cecilia, Leone, Gustavo W., Chen, Ju, and Evans, Sylvia M.

Subjects

*CARDIAC regeneration, *TRANSCRIPTION factors, *DNA synthesis, *DNA replication

Abstract

Cardiac regeneration and functional recovery after myocardial infarction (MI) have been correlated with an increased baseline frequency of mononuclear diploid (MND) CMs.[1] However, the capacity of MND adult CMs to undergo proliferation is still controversial. Although at baseline, mononuclear CMs represented only 5% to 14% of total CMs ([]), mononuclear CMs represented 50% to 92% of EdU-labeled CMs in controls and I XMLC2-78dKOs i ([]), suggesting preferential uptake of EdU by mononuclear CMs. Keywords: E2f7; E2f8; heart regeneration; mononuclear diploid cardiomyocytes; polyploidization; proliferation EN E2f7 E2f8 heart regeneration mononuclear diploid cardiomyocytes polyploidization proliferation 183 186 4 01/06/23 20230110 NES 230110 The heart is among the least regenerative of organs. [Extracted from the article]

Published

2023

46. A Tedious Journey: Cardiomyocyte Proliferation Requires More Than S-Phase Entry and Loss of Polyploidization.

Author

Ding, Dong and Braun, Thomas

Subjects

*HEART failure, *CARDIAC regeneration, *GUANINE nucleotide exchange factors, *MYOCARDIAL infarction

Abstract

Keywords: Editorials; cardiomyocyte proliferation; cytokinesis; heart regeneration; polyploid; S phase EN Editorials cardiomyocyte proliferation cytokinesis heart regeneration polyploid S phase 154 157 4 01/06/23 20230110 NES 230110 The adult myocardium of mammals is marked by limited renewal capability. Inhibition of epithelial cell transforming 2, a guanine nucleotide exchange factor required for contractile ring assembly and cytokinesis initiation, prevents cardiomyocyte proliferation and induces polyploidization in zebrafish.[4] However, this does not prove that alleviation of polyploidization promotes cardiomyocyte proliferation. [Extracted from the article]

Published

2023

47. Brain Natriuretic Peptide Protects Cardiomyocytes from Apoptosis and Stimulates Their Cell Cycle Re-Entry in Mouse Infarcted Hearts.

Author

Bon-Mathier, Anne-Charlotte, Déglise, Tamara, Rignault-Clerc, Stéphanie, Bielmann, Christelle, Mazzolai, Lucia, and Rosenblatt-Velin, Nathalie

Subjects

*BRAIN natriuretic factor, *CELL cycle, *BIOAVAILABILITY, *DNA synthesis, *MYOCARDIAL infarction, *APOPTOSIS, *MITOGEN-activated protein kinases

Abstract

Brain Natriuretic Peptide (BNP) supplementation after infarction increases heart function and decreases heart remodeling. BNP receptors, NPR-A and NPR-B are expressed on adult cardiomyocytes (CMs). We investigated whether a part of the BNP cardioprotective effect in infarcted and unmanipulated hearts is due to modulation of the CM fate. For this purpose, infarcted adult male mice were intraperitoneally injected every two days during 2 weeks with BNP or saline. Mice were sacrificed 1 and 14 days after surgery. BNP or saline was also injected intraperitoneally every two days into neonatal pups (3 days after birth) for 10 days and in unmanipulated 8-week-old male mice for 2 weeks. At sacrifice, CMs were isolated, counted, measured, and characterized by qRT-PCR. The proportion of mononucleated CMs was determined. Immunostainings aimed to detect CM re-entry in the cell cycle were performed on the different hearts. Finally, the signaling pathway activated by BNP treatment was identified in in vitro BNP-treated adult CMs and in CMs isolated from BNP-treated hearts. An increased number of CMs was detected in the hypoxic area of infarcted hearts, and in unmanipulated neonatal and adult hearts after BNP treatment. Accordingly, Troponin T plasma concentration was significantly reduced 1 and 3 days after infarction in BNP-treated mice, demonstrating less CM death. Furthermore, higher number of small, dedifferentiated and mononucleated CMs were identified in adult BNP-treated hearts when compared to saline-treated hearts. BNP-treated CMs express higher levels of mRNAs coding for hif1 alpha and for the different cyclins than CMs isolated from saline-treated hearts. Higher percentages of CMs undergoing DNA synthesis, expressing Ki67, phospho histone3 and Aurora B were detected in all BNP-treated hearts, demonstrating that CMs re-enter into the cell cycle. BNP effect on adult CMs in vivo is mediated by NPR-A binding and activation of the ERK MAP kinase pathway. Interestingly, an increased number of CMs was also detected in adult infarcted hearts treated with LCZ696, an inhibitor of the natriuretic peptide degradation. Altogether, our results identified BNP and all therapies aimed to increase BNP's bioavailability as new cardioprotective targets as BNP treatment leads to an increased number of CMs in neonatal, adult unmanipulated and infarcted hearts. [ABSTRACT FROM AUTHOR]

Published

2023

48. How can the adult zebrafish and neonatal mice teach us about stimulating cardiac regeneration in the human heart?

Author

Sorbini, Michela, Arab, Sammy, Soni, Tara, Frisiras, Angelos, and Mehta, Samay

Abstract

The proliferative capacity of mammalian cardiomyocytes diminishes shortly after birth. In contrast, adult zebrafish and neonatal mice can regenerate cardiac tissues, highlighting new potential therapeutic avenues. Different factors have been found to promote cardiomyocyte proliferation in zebrafish and neonatal mice; these include maintenance of mononuclear and diploid cardiomyocytes and upregulation of the proto-oncogene c-Myc. The growth factor NRG-1 controls cell proliferation and interacts with the Hippo–Yap pathway to modulate regeneration. Key components of the extracellular matrix such as Agrin are also crucial for cardiac regeneration. Novel therapies explored in this review, include intramyocardial injection of Agrin or zebrafish-ECM and NRG-1 administration. These therapies may induce regeneration in patients and should be further explored. The heart pumps blood across the body carrying nutrients and oxygen where they are needed. If the heart is damaged (e.g., after a heart attack), it may lose its ability to pump blood, and this can lead to heart failure, where the heart cannot meet the body's needs, leaving the affected person tired and breathless. This occurs because the human heart unfortunately has a limited ability to heal and regain function. Current therapies for heart injuries focus on minimizing the problems resulting from the injury but cannot recover damaged heart tissue. Scientists have found that in contrast to adult human hearts, the hearts of baby mice and zebrafish can repair themselves after injuries and recover normal function. This review highlights some important mechanisms that occur in the hearts of baby mice and zebrafish, which may help contribute to their regenerative abilities. These mechanisms involve small messenger chemicals that stimulate heart cells to replicate and reform normal heart tissues. Further research into these pathways may help develop new therapies for damaged human hearts and help them regain function. Unlike humans, adult zebrafish and neonatal mice can regenerate cardiac tissues. Key regenerative processes that occur in zebrafish and neonatal mice may help the development of future therapeutic avenues for many cardiovascular diseases. [ABSTRACT FROM AUTHOR]

Published

2023

49. Cardiomyocyte-fibroblast crosstalk in the postnatal heart

Author

Maria Uscategui Calderon, Brittany A. Gonzalez, and Katherine E. Yutzey

Subjects

cardiomyocyte, cardiac fibroblast, postnatal heart, extracellular matrix, cell signaling, heart regeneration, Biology (General), QH301-705.5

Abstract

During the postnatal period in mammals, the heart undergoes significant remodeling in response to increased circulatory demands. In the days after birth, cardiac cells, including cardiomyocytes and fibroblasts, progressively lose embryonic characteristics concomitant with the loss of the heart’s ability to regenerate. Moreover, postnatal cardiomyocytes undergo binucleation and cell cycle arrest with induction of hypertrophic growth, while cardiac fibroblasts proliferate and produce extracellular matrix (ECM) that transitions from components that support cellular maturation to production of the mature fibrous skeleton of the heart. Recent studies have implicated interactions of cardiac fibroblasts and cardiomyocytes within the maturing ECM environment to promote heart maturation in the postnatal period. Here, we review the relationships of different cardiac cell types and the ECM as the heart undergoes both structural and functional changes during development. Recent advances in the field, particularly in several recently published transcriptomic datasets, have highlighted specific signaling mechanisms that underlie cellular maturation and demonstrated the biomechanical interdependence of cardiac fibroblast and cardiomyocyte maturation. There is increasing evidence that postnatal heart development in mammals is dependent on particular ECM components and that resulting changes in biomechanics influence cell maturation. These advances, in definition of cardiac fibroblast heterogeneity and function in relation to cardiomyocyte maturation and the extracellular environment provide, support for complex cell crosstalk in the postnatal heart with implications for heart regeneration and disease mechanisms.

Published

2023

50. Cardiac Reprogramming Factors Synergistically Activate Genome-wide Cardiogenic Stage-Specific Enhancers

Author

Hashimoto, Hisayuki, Wang, Zhaoning, Garry, Glynnis A, Malladi, Venkat S, Botten, Giovanni A, Ye, Wenduo, Zhou, Huanyu, Osterwalder, Marco, Dickel, Diane E, Visel, Axel, Liu, Ning, Bassel-Duby, Rhonda, and Olson, Eric N

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Genetics, Human Genome, Cardiovascular, Heart Disease, Animals, Basic Helix-Loop-Helix Transcription Factors, Cells, Cultured, Cellular Reprogramming, ErbB Receptors, Fibroblasts, GATA4 Transcription Factor, Gene Regulatory Networks, Genome-Wide Association Study, MEF2 Transcription Factors, Mice, Mice, Inbred C57BL, Myocytes, Cardiac, Signal Transduction, T-Box Domain Proteins, Akt1, Gata4, Hand2, Mef2c, Tbx5, cardiomyocytes, direct reprogramming, heart regeneration, induced cardiac-like myocytes, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

The cardiogenic transcription factors (TFs) Mef2c, Gata4, and Tbx5 can directly reprogram fibroblasts to induced cardiac-like myocytes (iCLMs), presenting a potential source of cells for cardiac repair. While activity of these TFs is enhanced by Hand2 and Akt1, their genomic targets and interactions during reprogramming are not well studied. We performed genome-wide analyses of cardiogenic TF binding and enhancer profiling during cardiac reprogramming. We found that these TFs synergistically activate enhancers highlighted by Mef2c binding sites and that Hand2 and Akt1 coordinately recruit other TFs to enhancer elements. Intriguingly, these enhancer landscapes collectively resemble patterns of enhancer activation during embryonic cardiogenesis. We further constructed a cardiac reprogramming gene regulatory network and found repression of EGFR signaling pathway genes. Consistently, chemical inhibition of EGFR signaling augmented reprogramming. Thus, by defining epigenetic landscapes these findings reveal synergistic transcriptional activation across a broad landscape of cardiac enhancers and key signaling pathways that govern iCLM reprogramming.

Published

2019