Cardiac Regeneration

Galdos, Francisco X; Guo, Yuxuan; Paige, Sharon L.; VanDusen, Nathan J.; Wu, Sean M.; Pu, William T.

doi:10.1161/circresaha.116.309040

Cited by 128 publications

(74 citation statements)

References 222 publications

(275 reference statements)

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“…Recent studies highlight strategies that redeploy developmental signaling pathways to achieve the goals of cardiac regeneration 4 and point to epigenetic barriers to effective regeneration in mammalian hearts 17 Previous work by us and others suggested that Ezh1 is functionally redundant with Ezh2 in differentiated cardiac myocytes 13, 18, 19 . Here, we provide direct evidence that Ezh1 and Ezh2 complement each other in heart development.…”

Section: Discussionmentioning

confidence: 99%

“…This regenerative capacity is lost rapidly, as similar injury at P7 induces scar rather than myocardial regeneration. The mechanisms responsible for CM cell cycle exit remain incompletely understood 4 . Reactivation of some transcriptional regulatory networks essential for heart development, such as those controlled by YAP and TBX20, have been shown to promote adult CM cell cycle activity 4–7 .…”

Section: Introductionmentioning

confidence: 99%

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Divergent Requirements for EZH1 in Heart Development Versus Regeneration

et al. 2017

Circulation Research

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Rationale Polycomb repressive complex 2 (PRC2) is a major epigenetic repressor that deposits methylation on histone H3 on lysine 27 (H3K27me) and controls differentiation and function of many cells, including cardiac myocytes. EZH1 and EZH2 are two alternative catalytic subunits with partial functional redundancy. The relative roles of EZH1 and EZH2 in heart development and regeneration are unknown. Objective We compared the roles of EZH1 versus EZH2 in heart development and neonatal heart regeneration. Methods and Results Heart development was normal in Ezh1−/− (E1KO) and Ezh2f/f::cTNT−Cre (E2KO) embryos. Ablation of both genes in Ezh1−/−::Ezh2f/f::cTNT−Cre (DKO) embryos caused lethal heart malformations, including hypertrabeculation, compact myocardial hypoplasia, and ventricular septal defect. Epigenome and transcriptome profiling showed that de-repressed genes were upregulated in a manner consistent with total “EZH” dose. In neonatal heart regeneration, Ezh1 was required but Ezh2 was dispensible. This finding was further supported by rescue experiments: cardiac myocyte-restricted re-expression of EZH1 but not EZH2 restored neonatal heart regeneration in E1KO. In MI performed outside of the neonatal regenerative window, EZH1 but not EZH2 likewise improved heart function and stimulated CM proliferation. Mechanistically, EZH1 occupied and activated genes related to cardiac growth. Conclusions Our work unravels divergent mechanisms of EZH1 in heart development and regeneration, which will empower efforts to overcome epigenetic barriers to heart regeneration.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Divergent Requirements for EZH1 in Heart Development Versus Regeneration

et al. 2017

Circulation Research

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“…Adult cardiomyocytes (CMs) generate forceful contractions billions of times during the lifespan of an adult human. Specialized features that adapt CMs for this unique activity include their large rod-like shape, nearly crystalline sarcomere organization, robust oxidative metabolic capacity, expression of mature sarcomere gene isoforms, exit from the cell cycle, and an extensive network of transverse tubules (T-tubules), which are plasma membrane invaginations that facilitate synchronized calcium release 1 , 2 . In contrast to adult CMs, these specialized features are absent or underdeveloped in fetal and neonatal CMs, which are smaller, proliferative, glycolytic cells with less organized sarcomeres, fewer and smaller mitochondria, and no T-tubules.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical and stage-specific regulation of murine cardiomyocyte maturation by serum response factor

et al. 2018

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After birth, cardiomyocytes (CM) acquire numerous adaptations in order to efficiently pump blood throughout an animal’s lifespan. How this maturation process is regulated and coordinated is poorly understood. Here, we perform a CRISPR/Cas9 screen in mice and identify serum response factor (SRF) as a key regulator of CM maturation. Mosaic SRF depletion in neonatal CMs disrupts many aspects of their maturation, including sarcomere expansion, mitochondrial biogenesis, transverse-tubule formation, and cellular hypertrophy. Maintenance of maturity in adult CMs is less dependent on SRF. This stage-specific activity is associated with developmentally regulated SRF chromatin occupancy and transcriptional regulation. SRF directly activates genes that regulate sarcomere assembly and mitochondrial dynamics. Perturbation of sarcomere assembly but not mitochondrial dynamics recapitulates SRF knockout phenotypes. SRF overexpression also perturbs CM maturation. Together, these data indicate that carefully balanced SRF activity is essential to promote CM maturation through a hierarchy of cellular processes orchestrated by sarcomere assembly.

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“…Several recent reports have revealed that growth factors, intrinsic signaling pathways, and cell-cycle regulators coordinate cardiomyocyte proliferation during cardiogenesis. The expansion of the two cardiac progenitor fields during early cardiogenesis transpires under the tight control of extrinsic growth regulatory signals, which include the fibroblast growth factor, bone morphogenetic protein, and both canonical and noncanonical Wnt signaling pathways (for a review, see Galdos et al 2017). For example, data from mice revealed that the genetic deletion of the Wnt effector β-catenin in the second heart field gives rise to hearts bearing stunted right ventricles (Ai et al 2007), underscoring the importance of this pathway during early stages of cardiac growth.…”

Section: Speciesmentioning

confidence: 99%