Project description:Proliferation of heart muscle cells (cardiomyocytes) is the basis for heart development and regeneration. In mammals, cardiomyocytes become binucleated, which is thought to limit their proliferative capacity, but mechanisms are unknown. Here, we show the detailed mechanisms of formation of binucleated cardiomyocytes and how these mechanisms are dysregulated in congenital heart disease (CHD). Cardiomyocytes become binucleated by failing the last stage of cytokinesis, abscission. We identified the underlying molecular mechanism with single-cell transcriptional profiling, which showed repression of the cytokinesis gene Ect2, a Rho-guanine-nucleotide exchange factor. Inactivating Ect2 tripled the proportion of binucleated cardiomyocytes and reduced the number of cardiomyocytes by 34% in newborn mice, which was lethal. Cardiomyocyte-specific overexpression of Ect2 in transgenic mice decreased cytokinesis failure. We demonstrate that the Ect2 gene is regulated by the Hippo tumor suppressor pathway, and upstream of that, by β-adrenergic receptor signaling. In neonatal mice, stimulating β-adrenergic signaling pathway output with forskolin decreased the number of cardiomyocytes, and administration of β-blockers increased the number of cardiomyocytes. Finally, we show that patients with tetralogy of Fallot with pulmonary stenosis (ToF/PS), a common type of CHD, develop a 2.2-fold increase in bi- and multi-nucleated cardiomyocytes. Using in vivo labeling of one ToF/PS patient with 15N-thymidine, followed by imaging mass spectrometry, we demonstrate that this increase happens after birth. Organotypic cultures of myocardium from infants with ToF/PS showed that cardiomyocyte binucleation could be reduced with β-blockers. These results demonstrate how cardiomyocyte proliferation stops and provide the basis for new therapeutic strategies to increase cardiomyocyte proliferation in patients with CHD.

Project description:Mammalian cardiomyocytes lose the ability to proliferate shortly after birth. This accounts for the limited regeneration capacity of the mammalian heart. A characteristic feature of growth arrested cardiomyocytes is binucleation, but the molecular mechanisms are not well understood. In rodents, binucleation of cardiomyocytes starts after birth and occurs through incomplete cytokinesis. Here we demonstrate an important and unexpected role of GAS2L3, a recently identified actin and tubulin binding protein, for cardiomyocyte cytokinesis during heart development in mice. Mice deficient in GAS2L3 die shortly after birth due to dilated cardiomyopathy. Cardiomyocyte-specific deletion of GAS2L3 confirmed that the phenotype resulted from the loss of GAS2L3 in cardiomyocytes. We show that a deficiency in GAS2L3 leads to a strong reduction in cardiomyocyte numbers due to reduced proliferation. In addition, the loss of Gas2l3 resulted in premature binucleation of cardiomyocytes and in induction of a p53-transcriptional program including the cell cycle inhibitor p21. Collectively, these data identify an important role for GAS2L3 in cardiomyocyte cytokinesis during development.

Project description:The mammalian heart is incapable of regenerating a sufficient number of cardiomyocytes to ameliorate the loss of contractile muscle after acute myocardial injury, often resulting in heart failure. Several reports have demonstrated that mononucleated (MoNuc) cardiomyocytes are more responsive to pro-proliferative stimuli than are binucleated (BiNuc) cardiomyocytes. However, techniques to isolate and characterize these two different cardiomyocyte populations have been lacking. We have developed a novel fluorescence associated cell sorting method to isolate highly enriched populations of MoNuc and BiNuc cardiomyocytes at various times of development. Transcriptome analysis reveals an underlying biological signature that defines the differences between MoNucs and BiNucs, including a central role for the E2f/Rb transcriptional network in establishing the divergent ability of these two populations to re-enter and complete the cell cycle. Moreover, inducing binucleation by genetically blocking the ability of cardiomyocytes to complete cytokinesis leads to a reduction in E2f target gene expression, linking the E2f pathway with nucleation. These data identify key molecular differences between MoNuc and BiNuc mammalian cardiomyocytes that can be used to leverage cardiomyocyte proliferation for promoting injury repair in the heart.

Project description:Study on changes in gene expression in primary cultures of neonatal rat ventricular cardiomyocytes to electric stimulation. Through comparing non-stimulated, stimulated and blebbistatin supplemented and stimulated cultures we set out to identify the genes that are specifically activated by electric pulsing separate from cardiomyocyte contractions. After initial recovery phase, primary cultures of neonatal rat ventricular cardiomyocytes were cultured for 3 days without pulsing, with electric pulsing or with electric pulsing combined with blebbistatin. Per treatment: 3 arrays, with samples obtained from 3 separate series of cardiomyocyte isolation and culturing. Per array: sample prepared from pooled (1:1) RNA from duplicate experiments.

Project description:Mammalian cardiomyocytes rapidly mature after birth, with hallmarks such as cell-cycle exit, binucleation, and metabolic switch to oxidative phosphorylation of lipids. The causes and transcriptional programs regulating cardiomyocyte maturation are not fully understood yet. Thus, we performed single cell RNA-seq of neonatal and postnatal day 7 rat hearts to identify the key factors for this process and found AP-1 as a key factor to regulate cardiomyocyte maturation. To find the mechanism of AP-1 during cardiomyocyte maturation, we performed RNA-seq analysis of neonatal rat ventricular cardiomyocytes and found Ap-1 promote cardiomyocyte maturation by regulating cardiomyocyte metabolism.

Project description:Noncompaction cardiomyopathy is a common congenital cardiomyopathy associated with a deficiency of ventricular cardiomyocytes and impaired pump function. The genetic basis and underlying mechanisms of this disorder remain elusive. Polyploidization is an intrinsic feature of mammalian cardiomyocytes, which occurs shortly after birth and is accompanied by cardiomyocyte cell cycle arrest. We show that genetic deletion of the RNA binding protein with multiple splicing (Rbpms) in mice results in premature onset of cardiomyocyte polyploidization (binucleation) and consequent noncompaction cardiomyopathy. A similar blockade to cytokinesis occurs in human iPSC-derived cardiomyocytes with RBPMS gene deletion. Paired-end RNA sequencing analysis revealed that Rbpms plays an essential role in RNA splicing and mediates isoform switching from the short to the long form of Pdlim5, a heart-specific LIM domain protein that connects the sarcomere with various signaling proteins during heart development. The loss of Rbpms leads to abnormal accumulation of short Pdlim5 isoforms that disrupt cardiomyocyte cytokinesis. Our results link premature cardiomyocyte binucleation to noncompaction cardiomyopathy and highlight the central role of Rbpms in this process.

Project description:Deletion of the miR-1/133a clusters in adult cardiomyocytes results in upregulation of miRNA target genes FGFR1 and OSMR. Additional deletion of these miRNA target genes reveals a co-operative role of these receptors in the control of the cardiomyocyte differentiation state and in repression of cardiomyocyte cell cycle re-entry.

Project description:Study on changes in gene expression in primary cultures of neonatal rat ventricular cardiomyocytes to electric stimulation. Through comparing non-stimulated, stimulated and blebbistatin supplemented and stimulated cultures we set out to identify the genes that are specifically activated by electric pulsing separate from cardiomyocyte contractions.

Project description:Heart muscle cells, cardiomyocytes, are highly differentiated cells that usually do not proliferate . During the non-proliferative state, extracellular signals control cardiomyocyte contractile function. However, during development and regeneration, cardiomyocytes enter the cell cycle and divide. It is unknown how cardiomyocytes modify their intracellular signaling to direct the cell cycle program. Here, we show that the nuclear lamina protein Lamin B2 (Lmnb2) regulates cardiomyocyte cell cycle activity using a gatekeeper mechanism. We identified Lmnb2 as a candidate for regulating intracellular signaling with deep transcriptional profiling of single cardiomyocytes. Lmnb2 was sufficient and necessary for cardiomyocyte cycling in the presence of serum. Lmnb2 increased the nucleoporin NUP98 and permeability of the nuclear membrane for phosphorylated ERK1/2. In vivo, the Lmnb2 gene was required for cardiomyocyte cell cycle activity during development. Increasing the expression of Lmnb2 in neonatal mice promoted cardiomyocyte M-phase and cytokinesis. LmnB2 gene transfer in neonatal mice that received a myocardial injury increased cardiomyocyte division and myocardial function in the injury border zone, indicating that the regenerated cardiomyocytes were functionally integrated. We propose a gatekeeper function of Lmnb2 that can be targeted to increase cardiomyocyte regeneration without the administration of exogenous growth factors.

Project description:The mammalian heart undergoes major transitions during postnatal life to acquire the physiological properties of an adult organ. Postnatal life imposes numerous adaptations including electrophysiological, structural and metabolic maturation of cardiomyocytes1, which occur coincident with loss of proliferative capacity and regenerative potential2,3. The discovery of key upstream drivers of cardiomyocyte maturation and cell cycle arrest remains one of the most important unanswered questions in cardiac biology. Discovery of these drivers would facilitate current attempts to promote cardiomyocyte maturation in vitro for drug discovery and to de-differentiate adult cardiomyocytes in vivo for regenerative medicine. A recent study has suggested that the shift from a low oxygen environment in utero towards a high oxygen environment after birth acts as a key trigger for cardiomyocyte cell cycle exit4. Moreover, it was recently demonstrated that proliferative adult cardiomyocytes reside in a hypoxic niche5 and that exposure of adult mice to gradual hypoxemia is sufficient to drive cell cycle re-entry and regeneration following infarction6. However, it is currently unclear whether postnatal changes in oxygen tension or the associated shifts in cardiomyocyte metabolism are sufficient to promote maturation and cell cycle arrest as human pluripotent stem cell (hPSC)-derived cardiomyocytes fail to mature when cultured at 21% oxygen7,8. There are considerable changes in metabolic substrate provision during early postnatal life. The mammalian heart relies on high concentrations of carbohydrates and the presence of insulin in utero but later switches to fatty acid dominated substrates present in milk and low insulin levels post-birth9. In order to adapt to these changes in substrates, cardiomyocytes upregulate the genes required for fatty acid oxidation after birth10. The importance of these metabolic adaptations for cardiomyocyte maturation has been difficult to study because genetic disruption of fatty acid oxidation components in vivo can have a broad range of negative health impacts11. Therefore, there is a need to develop alternative approaches for studying the impact of cardiomyocyte metabolism on the maturation process. hPSCs are now widely used for the generation of defined human somatic cell types, including cardiomyocytes. These cardiomyocytes have now been used extensively for developmental studies, drug screening, disease modeling, and heart repair. However, lack of maturity and inappropriate responses to pharmacological agents have been identified as limitations in 2D or embryoid body based differentiation strategies12. To improve maturity of hPSC-derived cardiomyocytes, long-term culture can be used13, although long-term cultures may not be amenable to high-throughput screening applications and adult-like maturity is still not achieved14. In an effort to better simulate heart muscle structure and function, cardiac tissue engineering to form 3D engineered heart tissue has been used15-19. However, despite these recent advances in human cardiac tissue engineering, cardiac tissues derived from hPSC still lack many features of fully mature adult heart tissue20. Moreover, engineered heart tissue fabrication, culture, mechanical loading and pacing protocols, and analysis methods using organ baths are costly, labor intensive, and the multiple handling steps induce variability. In order to facilitate higher-throughput experiments, platforms for engineered heart tissue production have been miniaturized, however, screening experiments using semi-automated force of contraction analyses have only been published in 24-well plate formats21. Therefore, we developed a novel 96-well device, the heart dynamometer (Heart-Dyno), for high-throughput functional screening of human cardiac organoids (hCOs) to facilitate screening on a larger scale. The Heart-Dyno is designed to facilitate automated formation of dense muscle bundles from minimal cells and reagents while also facilitating culture and automated force of contraction analysis without any tissue handling. Using the Heart-Dyno, we define serum-free 3D culture conditions that promote structural, electrophysiological, metabolic and proliferative maturation of hPSC-derived cardiac organoids. Furthermore, we uncover a metabolic mechanism governing cardiomyocyte cell cycle arrest through repression of a β-catenin and YAP1 dependent signalling.