Your search keyword '"Marina Leone"' showing total 20 results

1. Microtubule Organization in Striated Muscle Cells

Author

Robert Becker, Marina Leone, and Felix B. Engel

Subjects

centrosome, MTOC, non-centrosomal MTOC, skeletal muscle, cardiomyocytes, cell cycle, Cytology, QH573-671

Abstract

Distinctly organized microtubule networks contribute to the function of differentiated cell types such as neurons, epithelial cells, skeletal myotubes, and cardiomyocytes. In striated (i.e., skeletal and cardiac) muscle cells, the nuclear envelope acts as the dominant microtubule-organizing center (MTOC) and the function of the centrosome—the canonical MTOC of mammalian cells—is attenuated, a common feature of differentiated cell types. We summarize the mechanisms known to underlie MTOC formation at the nuclear envelope, discuss the significance of the nuclear envelope MTOC for muscle function and cell cycle progression, and outline potential mechanisms of centrosome attenuation.

Published

2020

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

Author

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

Subjects

cardiomyocyte, newt, primary cilium, MTOC, terminal differentiation, centrosome, Medicine, Science, Biology (General), QH301-705.5

Abstract

Mammalian cardiomyocytes become post-mitotic shortly after birth. Understanding how this occurs is highly relevant to cardiac regenerative therapy. Yet, how cardiomyocytes achieve and maintain a post-mitotic state is unknown. Here, we show that cardiomyocyte centrosome integrity is lost shortly after birth. This is coupled with relocalization of various centrosome proteins to the nuclear envelope. Consequently, postnatal cardiomyocytes are unable to undergo ciliogenesis and the nuclear envelope adopts the function as cellular microtubule organizing center. Loss of centrosome integrity is associated with, and can promote, cardiomyocyte G0/G1 cell cycle arrest suggesting that centrosome disassembly is developmentally utilized to achieve the post-mitotic state in mammalian cardiomyocytes. Adult cardiomyocytes of zebrafish and newt, which are able to proliferate, maintain centrosome integrity. Collectively, our data provide a novel mechanism underlying the post-mitotic state of mammalian cardiomyocytes as well as a potential explanation for why zebrafish and newts, but not mammals, can regenerate their heart.

Published

2015

3. Movie 3 from IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Felix B. Engel, Stefan Gaubatz, Marcus Krüger, Markus Eckstein, Silvia Vergarajauregui, Grit Weinstock, Marco Gründl, Janica L. Wiederstein, Fulvia Ferrazzi, Salvador Cazorla-Vázquez, and Marina Leone

Abstract

HeLa cell stably expressing α-tubulin tagged with mCherry overexpressing IQGAP3 tagged with GFP (late anaphase/telophase to cytokinesis).

Published

2023

4. Table S3 from IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Felix B. Engel, Stefan Gaubatz, Marcus Krüger, Markus Eckstein, Silvia Vergarajauregui, Grit Weinstock, Marco Gründl, Janica L. Wiederstein, Fulvia Ferrazzi, Salvador Cazorla-Vázquez, and Marina Leone

Abstract

IQGAP3 expression in human cervical cancers

Published

2023

5. Movie 2 from IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Felix B. Engel, Stefan Gaubatz, Marcus Krüger, Markus Eckstein, Silvia Vergarajauregui, Grit Weinstock, Marco Gründl, Janica L. Wiederstein, Fulvia Ferrazzi, Salvador Cazorla-Vázquez, and Marina Leone

Abstract

HeLa cell stably transfected with mCherry-α-tubulin transfected with siIQ3#1.

Published

2023

6. Data from IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Felix B. Engel, Stefan Gaubatz, Marcus Krüger, Markus Eckstein, Silvia Vergarajauregui, Grit Weinstock, Marco Gründl, Janica L. Wiederstein, Fulvia Ferrazzi, Salvador Cazorla-Vázquez, and Marina Leone

Abstract

Controlling cell proliferation is critical for organism development, tissue homeostasis, disease, and regeneration. IQGAP3 has been shown to be required for proper cell proliferation and migration, and is associated to a number of cancers. Moreover, its expression is inversely correlated with the overall survival rate in the majority of cancers. Here, we show that IQGAP3 expression is elevated in cervical cancer and that in these cancers IQGAP3 high expression is correlated with an increased lethality. Furthermore, we demonstrate that IQGAP3 is a target of YAP, a regulator of cell cycle gene expression. IQGAP3 knockdown resulted in an increased percentage of HeLa cells in S phase, delayed progression through mitosis, and caused multipolar spindle formation and consequentially aneuploidy. Protein–protein interaction studies revealed that IQGAP3 interacts with MMS19, which is known in Drosophila to permit, by competitive binding to Xpd, Cdk7 to be fully active as a Cdk-activating kinase (CAK). Notably, IQGAP3 knockdown caused decreased MMS19 protein levels and XPD knockdown partially rescued the reduced proliferation rate upon IQGAP3 knockdown. This suggests that IQGAP3 modulates the cell cycle via the MMS19/XPD/CAK axis. Thus, in addition to governing proliferation and migration, IQGAP3 is a critical regulator of mitotic progression and genome stability.Implications:Our data indicate that, while IQGAP3 inhibition might be initially effective in decreasing cancer cell proliferation, this approach harbors the risk to promote aneuploidy and, therefore, the formation of more aggressive cancers.

Published

2023

7. Movie 1 from IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Felix B. Engel, Stefan Gaubatz, Marcus Krüger, Markus Eckstein, Silvia Vergarajauregui, Grit Weinstock, Marco Gründl, Janica L. Wiederstein, Fulvia Ferrazzi, Salvador Cazorla-Vázquez, and Marina Leone

Abstract

HeLa cell stably transfected with mCherry-α-tubulin transfected with siCtrl.

Published

2023

8. Supplementary Figures 1-4 from IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Felix B. Engel, Stefan Gaubatz, Marcus Krüger, Markus Eckstein, Silvia Vergarajauregui, Grit Weinstock, Marco Gründl, Janica L. Wiederstein, Fulvia Ferrazzi, Salvador Cazorla-Vázquez, and Marina Leone

Abstract

Figure S1: IQGAP3 depletion does not affect apoptotic HeLa rate but affects cell proliferation. Figure S2: Efficiency of siRNA-mediated YAP/TAZ and B-MYB knockdown strategy in HeLa cells. Figure S3: IQGAP3 knockdown strategy in Hct116 cells. Figure S4: IQGAP3 binds to both Cdk11p58 and uMAP4.

Published

2023

9. Movie 4 from IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Felix B. Engel, Stefan Gaubatz, Marcus Krüger, Markus Eckstein, Silvia Vergarajauregui, Grit Weinstock, Marco Gründl, Janica L. Wiederstein, Fulvia Ferrazzi, Salvador Cazorla-Vázquez, and Marina Leone

Abstract

HeLa cell stably expressing α-tubulin tagged with mCherry overexpressing IQGAP3 tagged with GFP (metaphase to cytokinesis).

Published

2023

10. IQGAP3, a YAP Target, Is Required for Proper Cell-Cycle Progression and Genome Stability

Author

Fulvia Ferrazzi, Grit Weinstock, Janica L Wiederstein, Stefan Gaubatz, Felix B. Engel, Marco Gründl, Markus Eckstein, Silvia Vergarajauregui, Marina Leone, Marcus Krüger, and Salvador Cazorla-Vázquez

Subjects

Cancer Research, Mitosis, Cell Cycle Proteins, Biology, Genomic Instability, Cell Line, Cell Movement, Cell Line, Tumor, Animals, Humans, Protein Interaction Maps, Molecular Biology, Tissue homeostasis, Cell Proliferation, Gene knockdown, Cell growth, Cell Cycle, GTPase-Activating Proteins, Cell cycle, HCT116 Cells, Cell Cycle Gene, HEK293 Cells, Oncology, Cancer research, Drosophila, Cyclin-dependent kinase 7, Multipolar spindles, HeLa Cells, Signal Transduction, Transcription Factors

Abstract

Controlling cell proliferation is critical for organism development, tissue homeostasis, disease, and regeneration. IQGAP3 has been shown to be required for proper cell proliferation and migration, and is associated to a number of cancers. Moreover, its expression is inversely correlated with the overall survival rate in the majority of cancers. Here, we show that IQGAP3 expression is elevated in cervical cancer and that in these cancers IQGAP3 high expression is correlated with an increased lethality. Furthermore, we demonstrate that IQGAP3 is a target of YAP, a regulator of cell cycle gene expression. IQGAP3 knockdown resulted in an increased percentage of HeLa cells in S phase, delayed progression through mitosis, and caused multipolar spindle formation and consequentially aneuploidy. Protein–protein interaction studies revealed that IQGAP3 interacts with MMS19, which is known in Drosophila to permit, by competitive binding to Xpd, Cdk7 to be fully active as a Cdk-activating kinase (CAK). Notably, IQGAP3 knockdown caused decreased MMS19 protein levels and XPD knockdown partially rescued the reduced proliferation rate upon IQGAP3 knockdown. This suggests that IQGAP3 modulates the cell cycle via the MMS19/XPD/CAK axis. Thus, in addition to governing proliferation and migration, IQGAP3 is a critical regulator of mitotic progression and genome stability. Implications: Our data indicate that, while IQGAP3 inhibition might be initially effective in decreasing cancer cell proliferation, this approach harbors the risk to promote aneuploidy and, therefore, the formation of more aggressive cancers.

Published

2021

11. Advances in heart regeneration based on cardiomyocyte proliferation and regenerative potential of binucleated cardiomyocytes and polyploidization

Author

Marina Leone and Felix B. Engel

Subjects

Cell Nucleus, Cardiac function curve, Cell type, business.industry, Mechanism (biology), Regeneration (biology), fungi, food and beverages, Heart, Context (language use), General Medicine, Cell cycle, Regenerative Medicine, medicine.disease, Bioinformatics, Polyploidy, Heart failure, Animals, Humans, Regeneration, Medicine, Myocytes, Cardiac, Myocardial infarction, business, Cell Proliferation

Abstract

One great achievement in medical practice is the reduction in acute mortality of myocardial infarction due to identifying risk factors, antiplatelet therapy, optimized hospitalization and acute percutaneous coronary intervention. Yet, the prevalence of heart failure is increasing presenting a major socio-economic burden. Thus, there is a great need for novel therapies that can reverse damage inflicted to the heart. In recent years, data have accumulated suggesting that induction of cardiomyocyte proliferation might be a future option for cardiac regeneration. Here, we review the relevant literature since September 2015 concluding that it remains a challenge to verify that a therapy induces indeed cardiomyocyte proliferation. Most importantly, it is unclear that the detected increase in cardiomyocyte cell cycle activity is required for an associated improved function. In addition, we review the literature regarding the evidence that binucleated and polyploid mononucleated cardiomyocytes can divide, and put this in context to other cell types. Our analysis shows that there is significant evidence that binucleated cardiomyocytes can divide. Yet, it remains elusive whether also polyploid mononucleated cardiomyocytes can divide, how efficient proliferation of binucleated cardiomyocytes can be induced, what mechanism regulates cell cycle progression in these cells, and what fate and physiological properties the daughter cells have. In summary, we propose to standardize and independently validate cardiac regeneration studies, encourage the field to study the proliferative potential of binucleated and polyploid mononucleated cardiomyocytes, and to determine whether induction of polyploidization can enhance cardiac function post-injury.

Published

2019

12. Isolation, Culture, and Live-Cell Imaging of Primary Rat Cardiomyocytes

Author

AlessanRSS Reis, Marina Leone, and Felix Engel

Subjects

0301 basic medicine, Cardiac function curve, Cell type, Vascular smooth muscle, Heart disease, Cell division, Cell, 030204 cardiovascular system & hematology, Biology, medicine.disease, Embryonic stem cell, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Live cell imaging, medicine

Abstract

The heart is a complex organ consisting of a variety of different cardiomyocytes (ventricular vs. atrial, left vs. right ventricular, working vs. nodal) as well as other cell types, including endothelial cells and vascular smooth muscle cells. Pericytes, neurons, and immune cells are less abundant, yet still important. Whereas cardiomyocytes account for around 75% of the heart volume, 50-70% of the cells in the heart are non-myocytes. This complexity of the heart underlines the difficulties in interpreting data obtained in vivo. In the field of cardiac regeneration, it remains unclear whether it is possible to induce a significant number of cardiomyocytes to proliferate and whether the often-observed improvement in cardiac function after experimental therapies is due to the induction of cardiomyocyte proliferation. Therefore, the reductionist approach inherent to cultures of isolated cells continues to be of great importance, even though it is important to study heart disease in vivo due to interactions of the different cell types. Cultured cardiomyocytes allow for easy manipulation of cell behavior (e.g., cell division) and its analysis (e.g., live-cell imaging). In addition, isolated cells in culture are a valuable tool for pharmacological and toxicological studies. This chapter offers a practical guide to isolate and culture primary neonatal and adult rat cardiomyocytes and a detailed protocol for live-cell imaging of embryonic and neonatal cardiomyocytes.

Published

2020

13. Microtubule Organization in Striated Muscle Cells

Author

Marina Leone, Robert Becker, and Felix B. Engel

Subjects

0301 basic medicine, Cellular differentiation, cardiomyocytes, Review, Biology, Microtubules, 03 medical and health sciences, 0302 clinical medicine, Medizinische Fakultät, Microtubule, medicine, Myocyte, Animals, Humans, ddc:610, skeletal muscle, lcsh:QH301-705.5, Centrosome, Muscle Cells, Myogenesis, Cell Cycle, Skeletal muscle, Microtubule organizing center, General Medicine, Cell cycle, Muscle, Striated, Cell biology, 030104 developmental biology, medicine.anatomical_structure, MTOC, lcsh:Biology (General), non-centrosomal MTOC, 030217 neurology & neurosurgery, Microtubule-Organizing Center

Abstract

Distinctly organized microtubule networks contribute to the function of differentiated cell types such as neurons, epithelial cells, skeletal myotubes, and cardiomyocytes. In striated (i.e., skeletal and cardiac) muscle cells, the nuclear envelope acts as the dominant microtubule-organizing center (MTOC) and the function of the centrosome—the canonical MTOC of mammalian cells—is attenuated, a common feature of differentiated cell types. We summarize the mechanisms known to underlie MTOC formation at the nuclear envelope, discuss the significance of the nuclear envelope MTOC for muscle function and cell cycle progression, and outline potential mechanisms of centrosome attenuation.

Published

2020

14. IFN-γ-response mediator GBP-1 represses human cell proliferation by inhibiting the Hippo signaling transcription factor TEAD

Author

Jürgen Behrens, Bea Unterer, Marina Leone, Clara Tenkerian, Felix B. Engel, Heinrich Sticht, Nathalie Britzen-Laurent, Mekala Gunasekaran, Thomas Wittenberg, Elisabeth Naschberger, Veit Wiesmann, Michael Stürzl, and Publica

Subjects

0301 basic medicine, medicine.medical_treatment, Protein domain, Mutation, Missense, colorectal cancer, GTPase, medicine.disease_cause, Biochemistry, Protein Structure, Secondary, 03 medical and health sciences, Interferon-gamma, 0302 clinical medicine, Mediator, Protein Domains, GTP-Binding Proteins, medicine, Humans, Molecular Biology, Transcription factor, Research Articles, Mutation, Cell growth, Chemistry, Cell Biology, Cell biology, interferons, 030104 developmental biology, Cytokine, cell proliferation, guanylate-binding proteins, Hippo signaling, 030220 oncology & carcinogenesis, Research Article, HeLa Cells, Transcription Factors

Abstract

Interferon-gamma (IFN-γ) is a pleiotropic cytokine that exerts important functions in inflammation, infectious diseases, and cancer. The large GTPase human guanylate-binding protein 1 (GBP-1) is among the most strongly IFN-γ-induced cellular proteins. Previously, it has been shown that GBP-1 mediates manifold cellular responses to IFN-γ including the inhibition of proliferation, spreading, migration, and invasion and through this exerts anti-tumorigenic activity. However, the mechanisms of GBP-1 anti-tumorigenic activities remain poorly understood. Here, we elucidated the molecular mechanism of the human GBP-1-mediated suppression of proliferation by demonstrating for the first time a cross-talk between the anti-tumorigenic IFN-γ and Hippo pathways. The α9-helix of GBP-1 was found to be sufficient to inhibit proliferation. Protein-binding and molecular modeling studies revealed that the α9-helix binds to the DNA-binding domain of the Hippo signaling transcription factor TEA domain protein (TEAD) mediated by the 376VDHLFQK382 sequence at the N-terminus of the GBP-1-α9-helix. Mutation of this sequence resulted in abrogation of both TEAD interaction and suppression of proliferation. Further on, the interaction caused inhibition of TEAD transcriptional activity associated with the down-regulation of TEAD-target genes. In agreement with these results, IFN-γ treatment of the cells also impaired TEAD activity, and this effect was abrogated by siRNA-mediated inhibition of GBP-1 expression. Altogether, this demonstrated that the α9-helix is the proliferation inhibitory domain of GBP-1, which acts independent of the GTPase activity through the inhibition of the Hippo transcription factor TEAD in mediating the anti-proliferative cell response to IFN-γ.

Published

2018

15. Cardiomyocyte binucleation is associated with aberrant mitotic microtubule distribution, mislocalization of RhoA and IQGAP3, as well as defective actomyosin ring anchorage and cleavage furrow ingression

Author

Marina Leone, Gentian Musa, and Felix B. Engel

Subjects

rho GTP-Binding Proteins, 0301 basic medicine, Time Factors, RHOA, Physiology, Mitosis, Spindle Apparatus, Microtubules, Time-Lapse Imaging, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Physiology (medical), Animals, Myocytes, Cardiac, Cleavage furrow, Cells, Cultured, Cell Proliferation, Cytokinesis, Cell Nucleus, Microscopy, Video, biology, Chemistry, Actomyosin, Rats, Cell biology, Protein Transport, Midbody, 030104 developmental biology, ras GTPase-Activating Proteins, biology.protein, Cell Nucleus Division, Cardiology and Cardiovascular Medicine, Cleavage furrow ingression, Astral microtubules, 030217 neurology & neurosurgery, Signal Transduction

Abstract

AimsAfter birth mammalian cardiomyocytes initiate a last cell cycle which results in binucleation due to cytokinesis failure. Despite its importance for cardiac regenerative therapies, this process is poorly understood. Here, we aimed at a better understanding of the difference between cardiomyocyte proliferation and binucleation and providing a new tool to distinguish these two processes.Methods and resultsMonitoring of cell division by time-lapse imaging revealed that rat cardiomyocyte binucleation stems from a failure to properly ingress the cleavage furrow. Astral microtubule required for actomyosin ring anchorage and thus furrow ingression were not symmetrically distributed at the periphery of the equatorial region during anaphase in binucleating cardiomyocytes. Consequently, RhoA, the master regulator of actomyosin ring formation and constriction, non-muscle myosin IIB, a central component of the actomyosin ring, as well as IQGAP3 were abnormally localized during cytokinesis. In agreement with improper furrow ingression, binucleation in vitro and in vivo was associated with a failure of RhoA and IQGAP3 to localize to the stembody of the midbody.ConclusionTaken together, these results indicate that naturally occurring cytokinesis failure in primary cardiomyocytes is due to an aberrant mitotic microtubule apparatus resulting in inefficient anchorage of the actomyosin ring to the plasma cell membrane. Thus, cardiomyocyte binucleation and division can be discriminated by the analysis of RhoA as well as IQGAP3 localization.

Published

2018

16. Pseudo-bipolar spindle formation and cell division in postnatal binucleated cardiomyocytes

Author

Felix B. Engel and Marina Leone

Subjects

0301 basic medicine, Centriole, Cell division, Mitosis, 030204 cardiovascular system & hematology, Biology, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, Live cell imaging, Tubulin, Animals, Myocytes, Cardiac, Molecular Biology, Centrioles, Cytokinesis, Cell Nucleus, Cell Cycle, Cell cycle, Cell biology, Rats, 030104 developmental biology, Centrosome, Cardiology and Cardiovascular Medicine, Multipolar spindles, Cell Division

Abstract

Background The majority of adult human, mouse and rat cardiomyocytes is not diploid mononucleated. Nevertheless, the current literature on heart regeneration based on cardiomyocyte proliferation focuses mainly on the proliferation capacity of diploid mononucleated cardiomyocytes, instead of the more abundant mononucleated polyploid or binucleated cardiomyocytes. Here, we aimed at a better understanding of the process of mitosis and cell division in postnatal binucleated cardiomyocytes. Methods and results Postnatal rat binucleated cardiomyocytes were stimulated to re-enter the cell cycle either by fetal bovine serum or a combination of fibroblast growth factor 1 and p38 MAP kinase inhibitor. Phase-contrast videos revealed that binucleated cardiomyocytes form one metaphase plate and preferentially undergo afterwards cytokinesis failure. The maximum rate of cell division of video-recorded binucleated cardiomyocytes was around 6%. Immunofluorescence analyses of centriole number in mitotic binucleated cardiomyocytes revealed that these cells contain more than four centrioles, which can be paired as well as unpaired. In agreement with multiple and/or unpaired centrioles, multipolar spindle formation was observed in mitotic binucleated cardiomyocytes using fluorescence live imaging of tubulin-GFP. Multipoles were transient and resolved into pseudo-bipolar spindles both in case of cell division and cytokinesis failure. Notably, centrioles were in most cases unevenly distributed among daughter cells. Conclusions Our results indicate that postnatal binucleated cardiomyocytes upon stimulation can enter mitosis, cope with their multiple and/or unpaired centrioles by forming pseudo-bipolar spindles, and divide.

Published

2019

17. GSK3ß‐dependent dysregulation of neurodevelopment in SPG11‐patient induced pluripotent stem cell model

Author

Beate Winner, Tom Boerstler, Holger Wend, Himanshu K. Mishra, Zacharias Kohl, Marina Leone, Steven Havlicek, Jürgen Winkler, Martina Brückner, Iryna Prots, Fred H. Gage, Francesc Pérez-Brangulí, Felix B. Engel, Georgia Minakaki, Lukas Anneser, Leah Boyer, Jürgen Behrens, André Reis, Angelika Lampert, Martin Hampl, Gerhard Schuierer, and Jochen Klucken

Subjects

0301 basic medicine, Hereditary spastic paraplegia, Autophagy, Neurogenesis, Biology, medicine.disease, Phenotype, Neural stem cell, Gene expression profiling, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Neurology, medicine, Neurology (clinical), ddc:610, Amyotrophic lateral sclerosis, Induced pluripotent stem cell, Neuroscience, 030217 neurology & neurosurgery, Research Articles, Research Article

Abstract

Annals of neurology 79(5), 826-840 (2016). doi:10.1002/ana.24633, Published by Wiley-Blackwell, Hoboken, NJ

Published

2016

18. Cardiomyocyte proliferation in cardiac development and regeneration: a guide to methodologies and interpretations

Author

Ajit Magadum, Marina Leone, and Felix B. Engel

Subjects

Cardiac function curve, Biomedical Research, Heart Diseases, Physiology, Cellular differentiation, Organogenesis, Cardiac regeneration, Physiology (medical), Animals, Humans, Regeneration, Cell Lineage, Myocytes, Cardiac, Cardiomyocyte proliferation, Zebrafish, Cell Proliferation, biology, Cell growth, Regeneration (biology), Cell Differentiation, Heart, Anatomy, biology.organism_classification, Salamandridae, Cell biology, Models, Animal, Biological Assay, Signal transduction, Cardiology and Cardiovascular Medicine, Signal Transduction

Abstract

The newt and the zebrafish have the ability to regenerate many of their tissues and organs including the heart. Thus, a major goal in experimental medicine is to elucidate the molecular mechanisms underlying the regenerative capacity of these species. A wide variety of experiments have demonstrated that naturally occurring heart regeneration relies on cardiomyocyte proliferation. Thus, major efforts have been invested to induce proliferation of mammalian cardiomyocytes in order to improve cardiac function after injury or to protect the heart from further functional deterioration. In this review, we describe and analyze methods currently used to evaluate cardiomyocyte proliferation. In addition, we summarize the literature on naturally occurring heart regeneration. Our analysis highlights that newt and zebrafish heart regeneration relies on factors that are also utilized in cardiomyocyte proliferation during mammalian fetal development. Most of these factors have, however, failed to induce adult mammalian cardiomyocyte proliferation. Finally, our analysis of mammalian neonatal heart regeneration indicates experiments that could resolve conflicting results in the literature, such as binucleation assays and clonal analysis. Collectively, cardiac regeneration based on cardiomyocyte proliferation is a promising approach for improving adult human cardiac function after injury, but it is important to elucidate the mechanisms arresting mammalian cardiomyocyte proliferation after birth and to utilize better assays to determine formation of new muscle mass.

Published

2015

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

Author

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

Subjects

medicine.medical_specialty, heart regeneration, QH301-705.5, Cellular differentiation, Science, Short Report, cardiomyocyte, General Biochemistry, Genetics and Molecular Biology, Internal medicine, Ciliogenesis, medicine, Animals, newt, Myocytes, Cardiac, rat, Biology (General), Zebrafish, Mitosis, mouse, Microtubule nucleation, Cell Proliferation, General Immunology and Microbiology, biology, General Neuroscience, other, Microtubule organizing center, Cell Differentiation, Heart, General Medicine, Cell Biology, terminal differentiation, biology.organism_classification, Salamandridae, zebrafish, Cell biology, Rats, Endocrinology, Developmental Biology and Stem Cells, MTOC, centrosome, Centrosome, cardiomyocyte proliferation, Medicine, Stem cell, primary cilium

Abstract

Mammalian cardiomyocytes become post-mitotic shortly after birth. Understanding how this occurs is highly relevant to cardiac regenerative therapy. Yet, how cardiomyocytes achieve and maintain a post-mitotic state is unknown. Here, we show that cardiomyocyte centrosome integrity is lost shortly after birth. This is coupled with relocalization of various centrosome proteins to the nuclear envelope. Consequently, postnatal cardiomyocytes are unable to undergo ciliogenesis and the nuclear envelope adopts the function as cellular microtubule organizing center. Loss of centrosome integrity is associated with, and can promote, cardiomyocyte G0/G1 cell cycle arrest suggesting that centrosome disassembly is developmentally utilized to achieve the post-mitotic state in mammalian cardiomyocytes. Adult cardiomyocytes of zebrafish and newt, which are able to proliferate, maintain centrosome integrity. Collectively, our data provide a novel mechanism underlying the post-mitotic state of mammalian cardiomyocytes as well as a potential explanation for why zebrafish and newts, but not mammals, can regenerate their heart. DOI: http://dx.doi.org/10.7554/eLife.05563.001, eLife digest Muscle cells in the heart contract in regular rhythms to pump blood around the body. In humans, rats and other mammals, the vast majority of heart muscle cells lose the ability to divide shortly after birth. Therefore, the heart is unable to replace cells that are lost over the life of the individual, for example, during a heart attack. If too many of these cells are lost, the heart will be unable to pump effectively, which can lead to heart failure. Currently, the only treatment option in humans with heart failure is to perform a heart transplant. Some animals, such as newts and zebrafish, are able to replace lost heart muscle cells throughout their lifetimes. Thus, these species are able to fully regenerate their hearts even after 20% has been removed. This suggests that it might be possible to manipulate human heart muscle cells to make them divide and regenerate the heart. Recent research has suggested that structures called centrosomes, known to be required to separate copies of the DNA during cell division, are used as a hub to integrate the initial signals that determine whether a cell should divide or not. Here, Zebrowski et al. studied the centrosomes of heart muscle cells in rats, newts and zebrafish. The experiments show that the centrosomes in rat heart muscle cells are dissembled shortly after birth. Centrosomes are made of several proteins and, in the rat cells, these proteins moved to the membrane that surrounded the nucleus. On the other hand, the centrosomes in the heart muscle cells of the adult newts and zebrafish remained intact. Further experiments found that that breaking apart the centrosomes of heart muscle cells taken from newborn rats stops these cells from dividing. Zebrowski et al.'s findings suggest that the loss of centrosomes after birth is a possible reason why the hearts of adult humans and other mammals are unable to regenerate after injury. In the future, these findings may aid the development of methods to regenerate human heart muscle and new treatments that may limit division of cancer cells. DOI: http://dx.doi.org/10.7554/eLife.05563.002

Published

2015

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

Author

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

Subjects

Centrosome, Biology, Mitosis, Cell biology

Published

2015