Project description:The mammalian heart has poor regenerative capacity following injury. In contrast, certain lower vertebrates such as zebrafish retain a robust capacity for regeneration into adult life. Here we use an integrated approach to identify evolutionary conserved regenerative miRNA-dependant regulatory circuits in the heart. We identified novel miRNA-dependant networks involved in critical biological pathways, which are differentially utilized between the infarcted mouse heart and the regenerating zebrafish heart. 2 conditions, 6 biological replicates per condition

Project description:The mammalian heart has poor regenerative capacity following injury. In contrast, certain lower vertebrates such as zebrafish retain a robust capacity for regeneration into adult life. Here we use an integrated approach to identify evolutionary conserved regenerative miRNA-dependant regulatory circuits in the heart. We identified novel miRNA-dependant networks involved in critical biological pathways, which are differentially utilized between the infarcted mouse heart and the regenerating zebrafish heart. 2 conditions, 4 biological replicates per condition

Project description:The mammalian heart has poor regenerative capacity following injury. In contrast, certain lower vertebrates such as zebrafish retain a robust capacity for regeneration into adult life. Here we use an integrated approach to identify evolutionary conserved regenerative miRNA-dependant regulatory circuits in the heart. We identified novel miRNA-dependant networks involved in critical biological pathways, which are differentially utilized between the infarcted mouse heart and the regenerating zebrafish heart. 2 conditions, 4 biological replicates per condition

Project description:The mammalian heart has poor regenerative capacity following injury. In contrast, certain lower vertebrates such as zebrafish retain a robust capacity for regeneration into adult life. Here we use an integrated approach to identify evolutionary conserved regenerative miRNA-dependant regulatory circuits in the heart. We identified novel miRNA-dependant networks involved in critical biological pathways, which are differentially utilized between the infarcted mouse heart and the regenerating zebrafish heart. 2 conditions, 3 biological replicates per condition

Project description:We investigated the role and programming of early immune responses during zebrafish heart regeneration. We found zebrafish treated with anti-inflammatory steroid, beclomethasone, would suffer significantly reduction of its heart regenerative ability, leading to excessive collagen deposition in wound. Microarray approach was used to evaluate the differential expression of heart transcriptome between normal and impaired healing zebrafish, which provides an overall assessment of significant genes that were important for triggering regeneration in the hemostasis-inflammation phase. Three sets of samples each containing 10 zebrafish hearts were used: sham operation, DMSO-1dpa, beclomethasone-1dpa. (dpa= days post amputation) Objects were pre-exposed to water containing 0.25M-NM-<M beclomethasone or DMSO for 1 day. After ventricular resection surgery, objects were sacrificed with their ventricles harvested at the next day (i.e. 1dpa)

Project description:Deciphering the genetic and epigenetic regulation of injury-induced heart regeneration in organisms capable of robust cardiac renewal represents an attractive inroad towards regenerating the human heart. In the highly regenerative zebrafish heart, cardiomyocytes near the wound edge undergo dramatic gene expression changes concomitant with sarcomere disassembly, loss of cell-cell adhesion, and detachment from the extracellular matrix (ECM), which leaves them poised to divide and give rise to new muscle cells that colonize the wound. Using integrated high-throughput transcriptional and chromatin analyses, we identified correlations between gene expression changes and activating H3K4me3 and/or repressive H3K27me3 dynamics in cardiomyocytes following injury. Within the category of downregulated genes that gain H3K27me3, transcripts encoding sarcomere and cytoskeletal components were significantly overrepresented. To investigate a functional requirement for H3K27me3-mediated gene silencing during zebrafish heart regeneration, we generated an inducible transgenic strain expressing a mutant version of histone 3, H3.3K27M, which allowed us to inhibit H3K27me3 catalysis in cardiomyocytes during the regenerative window. Hearts composed of H3.3K27M-expressing cardiomyocytes fail to regenerate with wound edge myocardium showing heightened expression of structural genes and prominent sarcomere structures. Although cell cycle re-entry was unperturbed, cytokinesis and wound invasion were significantly compromised. Collectively, our study identifies a requirement for H3K27me3-mediated silencing of structural genes during zebrafish heart regeneration and suggests that repression of similar structural components in the border zone of the infarcted human heart might improve its regenerative capacity.

Project description:For a short period of time in mammalian neonates, the mammalian heart can regenerate via cardiomyocyte proliferation. This regenerative capacity is largely absent in adults. In other organisms, including zebrafish, damaged hearts can regenerate throughout their lifespans. Many studies have been performed to understand the mechanisms of cardiomyocyte de-differentiation and proliferation during heart regeneration however, the underlying reason why adult zebrafish and young mammalian cardiomyocytes are primed to enter cell cycle have not been identified. Here we show the primed state of a pro-regenerative cardiomyocyte is dictated by its amino acid profile and metabolic state. Adult zebrafish cardiomyocyte regeneration is a result of amino acid-primed mTOR activation. Zebrafish and neonatal mouse cardiomyocytes display elevated glutamine levels, predisposing them to amino acid-driven activation of mTORC1. Injury initiates Wnt/β-catenin signalling that instigates primed mTORC1 activation, Lin28 expression and metabolic remodeling necessary for zebrafish cardiomyocyte regeneration. These studies reveal a unique mTORC1 primed state in zebrafish and mammalian regeneration competent cardiomyocytes.

Project description:The mammalian heart has poor regenerative capacity following injury. In contrast, certain lower vertebrates such as zebrafish retain a robust capacity for regeneration into adult life. Here we use an integrated approach to identify evolutionary conserved regenerative miRNA-dependant regulatory circuits in the heart. We identified novel miRNA-dependant networks involved in critical biological pathways, which are differentially utilized between the infarcted mouse heart and the regenerating zebrafish heart.

Project description:The mammalian heart has poor regenerative capacity following injury. In contrast, certain lower vertebrates such as zebrafish retain a robust capacity for regeneration into adult life. Here we use an integrated approach to identify evolutionary conserved regenerative miRNA-dependant regulatory circuits in the heart. We identified novel miRNA-dependant networks involved in critical biological pathways, which are differentially utilized between the infarcted mouse heart and the regenerating zebrafish heart.

Project description:The mammalian heart has poor regenerative capacity following injury. In contrast, certain lower vertebrates such as zebrafish retain a robust capacity for regeneration into adult life. Here we use an integrated approach to identify evolutionary conserved regenerative miRNA-dependant regulatory circuits in the heart. We identified novel miRNA-dependant networks involved in critical biological pathways, which are differentially utilized between the infarcted mouse heart and the regenerating zebrafish heart.