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1. BMP signaling promotes zebrafish heart regeneration via alleviation of replication stress.

Author

Vasudevarao, Mohankrishna Dalvoy, Posadas Pena, Denise, Ihle, Michaela, Bongiovanni, Chiara, Maity, Pallab, Geissler, Dominik, Mohammadi, Hossein Falah, Rall-Scharpf, Melanie, Niemann, Julian, Mommersteeg, Mathilda T. M., Redaelli, Simone, Happ, Kathrin, Wu, Chi-Chung, Beisaw, Arica, Scharffetter-Kochanek, Karin, D'Uva, Gabriele, Malek Mohammadi, Mona, Wiesmüller, Lisa, Geiger, Hartmut, and Weidinger, Gilbert

Subjects
CYTOLOGY, DNA repair, REPLICATION fork, LIFE sciences, BONE morphogenetic proteins, DNA replication
Abstract

In contrast to mammals, adult zebrafish achieve complete heart regeneration via proliferation of cardiomyocytes. Surprisingly, we found that regenerating cardiomyocytes experience DNA replication stress, which represents one reason for declining tissue regeneration during aging in mammals. Pharmacological inhibition of ATM and ATR kinases revealed that DNA damage response signaling is essential for zebrafish heart regeneration. Manipulation of Bone Morphogenetic Protein (BMP)-Smad signaling using transgenics and mutants showed that BMP signaling alleviates cardiomyocyte replication stress. BMP signaling also rescues neonatal mouse cardiomyocytes, human fibroblasts and human hematopoietic stem and progenitor cells (HSPCs) from replication stress. DNA fiber spreading assays indicate that BMP signaling facilitates re-start of replication forks after replication stress-induced stalling. Our results identify the ability to overcome replication stress as key factor for the elevated zebrafish heart regeneration capacity and reveal a conserved role for BMP signaling in promotion of stress-free DNA replication. Zebrafish show robust heart regeneration after injury. Here they show that zebrafish cardiomyocytes experience replication stress, which BMP signaling alleviates via a conserved mechanism of replication fork restart, suggesting a potential for anti-aging and regenerative therapies. [ABSTRACT FROM AUTHOR]

Published
2025
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2. A perfusion-independent high-throughput method to isolate liver sinusoidal endothelial cells.

Author

Babin-Ebell Gonçalves, Anna, Mao, Yifang, Baljkas, Tinja, Wiedmann, Felix, Eis, Larissa, Pilz, Franziska, Winkler, Manuel, Kürschner-Zacharias, Sina W., Hoffarth, Marlene, Funaya, Charlotta, Shahidi, Réza, Géraud, Cyrill, Wu, Chi-Chung, Schmidt, Constanze, Goerdt, Sergij, Reiners-Koch, Philipp-Sebastian, and Singhal, Mahak

Subjects
POSTMORTEM changes, CELL separation, ENDOTHELIAL cells, GOVERNMENT aid, LIVER
Abstract

Liver sinusoidal endothelial cells (LSECs) critically regulate homeostatic liver function and liver pathogenesis. However, the isolation of LSECs remains a major technological bottleneck in studying molecular mechanisms governing LSEC functions. Current techniques to isolate LSECs, relying on perfusion-dependent liver digestion, are cumbersome with limited throughput. We here describe a perfusion-independent high-throughput procedure to isolate LSECs with high purity. Indifferently from previous perfusion-independent approaches, chopped liver tissue was incubated in the digestion mix for 30 minutes with intermittent mixing with a serological pipette. This led to the safeguarding of LSEC integrity and yielded 10 ± 1.0 million LSECs per adult mouse liver, which is far higher than previous perfusion-independent protocols and comparable yield to established perfusion-dependent protocols for isolating LSECs. Combining magnetic and fluorescence-activated cell sorting (FACS), LSECs from different zones of the hepatic sinusoid can now be isolated in high numbers in less than two hours for downstream applications including proteomics. Our protocol enables the isolation of LSECs from fibrotic liver tissues from mice and healthy liver tissues from higher vertebrate species (pigs), where traditional perfusion-based digestion protocols have very limited application. In conclusion, these technical advancements reduce post-mortem changes in the LSEC state and aid in reliable investigation of LSEC functions. A perfusion-independent method to isolate ultrapure liver sinusoidal endothelial cells for downstream applications, including primary cultures and hepatic zone-specific endothelial cell isolations. [ABSTRACT FROM AUTHOR]

Published
2025
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5. BMP signaling promotes heart regeneration via alleviation of replication stress

Author

Dalvoy Vasudevarao, Mohankrishna, primary, Posadas-pena, Denise Silvia, additional, Ihle, Michaela, additional, Bongiovanni, Chiara, additional, Maity, Pallab, additional, Redaelli, Simone, additional, Happ, Kathrin, additional, Geissler, Dominik, additional, Mohammadi, Hossein Falah, additional, Rall-Scharpf, Melanie, additional, Wu, Chi-Chung, additional, Beisaw, Arica, additional, Scharffetter-Kochanek, Karin, additional, D'Uva, Gabriele, additional, Wiesmueller, Lisa, additional, and Weidinger, Gilbert, additional

Published
2024
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11. Cardiomyocyte maturation and its reversal during cardiac regeneration.

Author

Beisaw, Arica and Wu, Chi‐Chung

Subjects
CARDIAC regeneration, REGENERATION (Biology), MYOCARDIAL infarction, HEART failure, CAUSES of death
Abstract

Cardiovascular disease is a leading cause of death worldwide. Due to the limited proliferative and regenerative capacity of adult cardiomyocytes, the lost myocardium is not replenished efficiently and is replaced by a fibrotic scar, which eventually leads to heart failure. Current therapies to cure or delay the progression of heart failure are limited; hence, there is a pressing need for regenerative approaches to support the failing heart. Cardiomyocytes undergo a series of transcriptional, structural, and metabolic changes after birth (collectively termed maturation), which is critical for their contractile function but limits the regenerative capacity of the heart. In regenerative organisms, cardiomyocytes revert from their terminally differentiated state into a less mature state (ie, dedifferentiation) to allow for proliferation and regeneration to occur. Importantly, stimulating adult cardiomyocyte dedifferentiation has been shown to promote morphological and functional improvement after myocardial infarction, further highlighting the importance of cardiomyocyte dedifferentiation in heart regeneration. Here, we review several hallmarks of cardiomyocyte maturation, and summarize how their reversal facilitates cardiomyocyte proliferation and heart regeneration. A detailed understanding of how cardiomyocyte dedifferentiation is regulated will provide insights into therapeutic options to promote cardiomyocyte de‐maturation and proliferation, and ultimately heart regeneration in mammals. Key Findings: We reviewed key features of cardiomyocyte maturation, including myofibril, metabolism, and polyploidy.We reviewed recent advances in the role of cardiomyocyte dedifferentiation in cardiac repair/regeneration in both regenerative and non‐regenerative models.We reviewed recent advances in cardiomyocyte regeneration, including cardiomyocyte invasion of injured tissue and cardiomyocyte re‐differentiation following proliferation. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Rnf20 shapes the endothelial control of heart morphogenesis and function

Author

Kessler, Linda, primary, Gao, Rui, additional, Tetik-Elsherbiny, Nalan, additional, Lityagina, Olga, additional, Zhailauova, Azhar, additional, Ren, Yonggang, additional, Trogisch, Felix A., additional, Cordero, Julio, additional, Dou, Yanliang, additional, Wang, Yinuo, additional, Chichelnitskiy, Evgeny, additional, Kraske, Joscha Alexander, additional, Schäfer, Patricia Laura, additional, Wu, Chi-Chung, additional, Barreto, Guillermo, additional, Potente, Michael, additional, Wieland, Thomas, additional, Ola, Roxana, additional, Heineke, Joerg, additional, and Dobreva, Gergana, additional

Published
2022
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20. Is zebrafish heart regeneration 'complete'?: Lineage-restricted cardiomyocytes proliferate to pre-injury numbers but some fail to differentiate in fibrotic hearts

Author

Medische Fysiologie, Circulatory Health, Cardiologie onderzoek 2, Onderzoek, Bertozzi, Alberto, Wu, Chi-Chung, Nguyen, Phong D, Vasudevarao, Mohankrishna Dalvoy, Mulaw, Medhanie A, Koopman, Charlotte D, de Boer, Teun P, Bakkers, Jeroen, Weidinger, Gilbert, Medische Fysiologie, Circulatory Health, Cardiologie onderzoek 2, Onderzoek, Bertozzi, Alberto, Wu, Chi-Chung, Nguyen, Phong D, Vasudevarao, Mohankrishna Dalvoy, Mulaw, Medhanie A, Koopman, Charlotte D, de Boer, Teun P, Bakkers, Jeroen, and Weidinger, Gilbert

Published
2021

22. Is zebrafish heart regeneration “complete”? Lineage-restricted cardiomyocytes proliferate to pre-injury numbers but some fail to differentiate in fibrotic hearts

Author

Bertozzi, Alberto, primary, Wu, Chi-Chung, additional, Nguyen, Phong D., additional, Vasudevarao, Mohankrishna Dalvoy, additional, Mulaw, Medhanie A., additional, Koopman, Charlotte D., additional, de Boer, Teun P., additional, Bakkers, Jeroen, additional, and Weidinger, Gilbert, additional

Published
2020
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23. Is zebrafish heart regeneration 'complete'?: Lineage-restricted cardiomyocytes proliferate to pre-injury numbers but some fail to differentiate in fibrotic hearts

Author

Bertozzi, Alberto, Wu, Chi-Chung, Nguyen, Phong D, Vasudevarao, Mohankrishna Dalvoy, Mulaw, Medhanie A, Koopman, Charlotte D, de Boer, Teun P, Bakkers, Jeroen, Weidinger, Gilbert, Bertozzi, Alberto, Wu, Chi-Chung, Nguyen, Phong D, Vasudevarao, Mohankrishna Dalvoy, Mulaw, Medhanie A, Koopman, Charlotte D, de Boer, Teun P, Bakkers, Jeroen, and Weidinger, Gilbert

Abstract

Adult zebrafish are frequently described to be able to "completely" regenerate the heart. Yet, the extent to which cardiomyocytes lost to injury are replaced is unknown, since only indirect evidence for cardiomyocyte proliferation exists. We established stereological methods to quantify the number of cardiomyocytes at several time-points post cryoinjury. Intriguingly, after cryoinjuries that killed about 1/3 of the ventricular cardiomyocytes, pre-injury cardiomyocyte numbers were restored already within 30 days. Yet, many hearts retained small residual scars, and a subset of cardiomyocytes bordering these fibrotic areas remained smaller, lacked differentiated sarcomeric structures, and displayed defective calcium signaling. Thus, a subset of regenerated cardiomyocytes failed to fully mature. While lineage-tracing experiments have shown that regenerating cardiomyocytes are derived from differentiated cardiomyocytes, technical limitations have previously made it impossible to test whether cardiomyocyte trans-differentiation contributes to regeneration of non-myocyte cell lineages. Using Cre responder lines that are expressed in all major cell types of the heart, we found no evidence for cardiomyocyte transdifferentiation into endothelial, epicardial, fibroblast or immune cell lineages. Overall, our results imply a refined answer to the question whether zebrafish can completely regenerate the heart: in response to cryoinjury, preinjury cardiomyocyte numbers are indeed completely regenerated, while restoration of cardiomyocyte differentiation and function, as well as resorption of scar tissue, is less robustly achieved.

Published
2020

27. Spatially Resolved Genome-wide Transcriptional Profiling Identifies BMP Signaling as Essential Regulator of Zebrafish Cardiomyocyte Regeneration

Author

Wu, Chi Chung, Kruse, Fabian, Vasudevarao, Mohankrishna Dalvoy, Junker, Jan Philipp, Zebrowski, David C., Fischer, Kristin, Noël, Emily S., Grün, Dominic, Berezikov, Eugene, Engel, Felix B., Van Oudenaarden, Alexander, Weidinger, Gilbert, Bakkers, Jeroen, Wu, Chi Chung, Kruse, Fabian, Vasudevarao, Mohankrishna Dalvoy, Junker, Jan Philipp, Zebrowski, David C., Fischer, Kristin, Noël, Emily S., Grün, Dominic, Berezikov, Eugene, Engel, Felix B., Van Oudenaarden, Alexander, Weidinger, Gilbert, and Bakkers, Jeroen

Published
2016

28. Spatially Resolved Genome-wide Transcriptional Profiling Identifies BMP Signaling as Essential Regulator of Zebrafish Cardiomyocyte Regeneration

Author

Hubrecht Institute with UMC, CMM Sectie Molecular Cancer Research, Cancer, Medische Fysiologie, Circulatory Health, Wu, Chi Chung, Kruse, Fabian, Vasudevarao, Mohankrishna Dalvoy, Junker, Jan Philipp, Zebrowski, David C., Fischer, Kristin, Noël, Emily S., Grün, Dominic, Berezikov, Eugene, Engel, Felix B., Van Oudenaarden, Alexander, Weidinger, Gilbert, Bakkers, Jeroen, Hubrecht Institute with UMC, CMM Sectie Molecular Cancer Research, Cancer, Medische Fysiologie, Circulatory Health, Wu, Chi Chung, Kruse, Fabian, Vasudevarao, Mohankrishna Dalvoy, Junker, Jan Philipp, Zebrowski, David C., Fischer, Kristin, Noël, Emily S., Grün, Dominic, Berezikov, Eugene, Engel, Felix B., Van Oudenaarden, Alexander, Weidinger, Gilbert, and Bakkers, Jeroen

Published
2016

31. Developmental alterations in centrosome integrity contribute to the post-mitotic state of mammalian cardiomyocytes

Author

Zebrowski, David C, primary, Vergarajauregui, Silvia, additional, Wu, Chi-Chung, additional, Piatkowski, Tanja, additional, Becker, Robert, additional, Leone, Marina, additional, Hirth, Sofia, additional, Ricciardi, Filomena, additional, Falk, Nathalie, additional, Giessl, Andreas, additional, Just, Steffen, additional, Braun, Thomas, additional, Weidinger, Gilbert, additional, and Engel, Felix B, additional

Published
2015
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33. Author response: Developmental alterations in centrosome integrity contribute to the post-mitotic state of mammalian cardiomyocytes

Author

Zebrowski, David C, primary, Vergarajauregui, Silvia, additional, Wu, Chi-Chung, additional, Piatkowski, Tanja, additional, Becker, Robert, additional, Leone, Marina, additional, Hirth, Sofia, additional, Ricciardi, Filomena, additional, Falk, Nathalie, additional, Giessl, Andreas, additional, Just, Steffen, additional, Braun, Thomas, additional, Weidinger, Gilbert, additional, and Engel, Felix B, additional

Published
2015
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36. Regeneration of Cryoinjury Induced Necrotic Heart Lesions in Zebrafish Is Associated with Epicardial Activation and Cardiomyocyte Proliferation

Author

Weidinger, Gilbert, Schnabel, Kristin, Wu, Chi-Chung, Kurth, Thomas, Weidinger, Gilbert, Schnabel, Kristin, Wu, Chi-Chung, and Kurth, Thomas

Abstract

In mammals, myocardial cell death due to infarction results in scar formation and little regenerative response. In contrast, zebrafish have a high capacity to regenerate the heart after surgical resection of myocardial tissue. However, whether zebrafish can also regenerate lesions caused by cell death has not been tested. Here, we present a simple method for induction of necrotic lesions in the adult zebrafish heart based on cryoinjury. Despite widespread tissue death and loss of cardiomyocytes caused by these lesions, zebrafish display a robust regenerative response, which results in substantial clearing of the necrotic tissue and little scar formation. The cellular mechanisms underlying regeneration appear to be similar to those activated in response to ventricular resection. In particular, the epicardium activates a developmental gene program, proliferates and covers the lesion. Concomitantly, mature uninjured cardiomyocytes become proliferative and invade the lesion. Our injury model will be a useful tool to study the molecular mechanisms of natural heart regeneration in response to necrotic cell death.

Published
2011

37. The role of polyglutamine oligomer in pathogenesis of polyglutamine diseases.

Author

Wu, Chi Chung., Chinese University of Hong Kong Graduate School. Division of Life Sciences., Wu, Chi Chung., and Chinese University of Hong Kong Graduate School. Division of Life Sciences.

Abstract

Wu, Chi Chung., "September 2010.", Thesis (M.Phil.)--Chinese University of Hong Kong, 2010., Includes bibliographical references (leaves 86-96)., s in English and Chinese., p.i, (Chinese version) --- p.iii, Acknowledgments --- p.iv, List of Abbreviations --- p.v, List of Tables --- p.vii, List of Figures --- p.viii, Chapter 1. --- INTRODUCTION, Chapter 1.1. --- Neurodegenerative disorders 一 a brief overview --- p.1, Chapter 1.2. --- Polyglutamine diseases --- p.1, Chapter 1.3. --- Polyglutamine protein conformers and toxicity --- p.5, Chapter 1.4. --- in vivo modeling of polyglutamine diseases in Drosophila, Chapter 1.4.1. --- GAL4/UAS transgene expression system in Drosophila --- p.13, Chapter 1.4.2. --- Temporal control of transgene expression systemin Drosophila --- p.15, Chapter 1.4.3. --- Drosophila as a model to study polyglutamine diseases --- p.16, Chapter 1.5. --- in vitro polyglutamine diseases models --- p.19, Chapter 1.6. --- Aim of study --- p.23, Chapter 2. --- MATERIALS AND METHODS, Chapter 2.1. --- Drosophila culture and manipulation, Chapter 2.1.1. --- Drosophila culture --- p.25, Chapter 2.1.2. --- Pseudopupil assay of adult retinal degeneration --- p.25, Chapter 2.2. --- Sodium Dodecyl Sulfate-Polyacrylamide Gel Electrophoresis (SDS-PAGE), Chapter 2.2.1. --- Protein extraction from adult Drosophila heads --- p.26, Chapter 2.2.2. --- Preparation of SDS-polyacrylamide gel and electrophoresis --- p.27, Chapter 2.2.3. --- Western blotting --- p.28, Chapter 2.2.4. --- Immunodetection --- p.29, Chapter 2.3. --- Solubilization of SDS-insoluble protein --- p.31, Chapter 2.4. --- Filter retardation assay --- p.31, Chapter 2.5. --- Immunoprecipitation --- p.32, Chapter 2.6. --- Nucleocytoplasmic fractionation --- p.33, Chapter 2.7. --- PCR cloning, Chapter 2.7.1 . --- Drosophila DNA preparation --- p.34, Chapter 2.7.2. --- Construction of pGEX4T3-MJDflQ27/81 expression plasmid --- p.34, Chapter 2.8. --- in vitro aggregation assay, Chapter 2.8.1. --- Expression and purification of GST-MJDAQ27/81 protein --- p.36, Chapter 2.8.2. --- in vitro aggregation --- p.37, Chapter 2.8.3. --- Native slot-blot --- p.38, Chapter 2.9. --- Reagents and buffers, Chapter 2.9.1. --- Reagents for Drosophila culture --- p.39, Chapter 2.9.2. --- Reagents for SDS-PAGE --- p.39, Chapter 2.9.3. --- Reagents for filter retardation assay --- p.42, Chapter 2.9.4. --- Reagents for immunoprecipitation --- p.43, Chapter 2.9.5. --- Reagents for nucleocytoplasmic fractionation --- p.43, Chapter 2.9.6. --- Reagents for PCR cloning --- p.44, Chapter 2.9.7. --- Reagents for in vitro aggregation assay --- p.46, Chapter 3. --- Establishment of a GAL80ts-mediated transgenic Drosophila model of Machado-Joseph Disease (MJD), Chapter 3.1. --- Introduction --- p.48, Chapter 3.2. --- Results, Chapter 3.2.1. --- GAL80ts-mediated expression of expanded full-length MJD protein caused progressive neuronal degenerationin Drosophila --- p.49, Chapter 3.2.2. --- Detection of SDS-insoluble expanded full-length MJD protein and its correlation with neuronal degeneration, Chapter 3.2.2.1. --- Progressive neuronal degeneration is not mediated by progressive accumulation of expanded full-length MJD protein --- p.51, Chapter 3.2.2.2. --- SDS-soluble expanded full-length MJD protein does not correlate with progressive neuronal degeneration --- p.53, Chapter 3.2.2.3. --- Progressive accumulation of SDS-insoluble expanded full-length MJD protein correlate with progressive neuronal degeneration --- p.55, Chapter 3.3. --- Discussion --- p.57, Chapter 4. --- Detection of conformational changes of expanded full-length MJD protein and its association with neuronal degeneration, Chapter 4.1. --- Introduction --- p.60, Chapter 4.2. --- Results, Chapter 4.2.1. --- Expanded full-length MJD protein underwent conformational changes from monomer to fibrils and such conformational changes correlated with neuronal degeneration --- p.61, Chapter 4.2.2. --- Mechanistic studies of how conformational changes of expanded full-length MJD protein triggers neuronal degeneration, Chapter 4.2.2.1. --- Expanded full-length MJD protein gradually accumulated in the nucleus during the course of neurodegeneration --- p.62, Chapter 4.2.2.2. --- Fibrillar expanded full-length MJD protein caused transcriptional dysregulation of endogenous Hsp70 gene --- p.66, Chapter 4.2.3. --- Consolidation of the role of fibrillar expanded full-length MJD protein in neuronal degeneration --- p.67, Chapter 4.3. --- Discussion --- p.72, Chapter 5. --- Attempts to generate new conformation-specific antibody against recombinant expanded full-length MJD proteins, Chapter 5.1. --- Introduction --- p.75, Chapter 5.2. --- Results, Chapter 5.2.1. --- Recombinant expanded full-length MJD protein underwent conformational changes during in vitro aggregation --- p.75, Chapter 5.3. --- Discussion --- p.77, Chapter 6. --- GENERAL DISCUSSION --- p.81, Chapter 7. --- CONCLUSION --- p.84, Chapter 8. --- REFERENCES --- p.86, http://library.cuhk.edu.hk/record=b5894444, Use of this resource is governed by the terms and conditions of the Creative Commons “Attribution-NonCommercial-NoDerivatives 4.0 International” License (http://creativecommons.org/licenses/by-nc-nd/4.0/)

Published
2010

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