par Chahal, Gulrez;Eichenlaub, Michael MP;Tondl, Markus;Pawlak, Michał;Mohenska, Monika;Grimm, Lin;Bottrell, Lauren;Drvodelic, Mark;Alaei, Sara;Hallab, Jeannette;Waylen, Lisa LN;Polo, Jose M;Blanpain, Cédric 
;Palpant, Nathan;Rossello, Fernando J;Änkö, Minna-Liisa;Currie, Peter PD;Hogan, Benjamin BM;Winata, Cecilia;Salimova, Ekaterina;Nim, Hieu HT;Ramialison, Mirana
Référence Scientific Data, 12, 1, page (1620)
Publication Publié, 2025-10
;Palpant, Nathan;Rossello, Fernando J;Änkö, Minna-Liisa;Currie, Peter PD;Hogan, Benjamin BM;Winata, Cecilia;Salimova, Ekaterina;Nim, Hieu HT;Ramialison, MiranaRéférence Scientific Data, 12, 1, page (1620)
Publication Publié, 2025-10
Article révisé par les pairs
| Résumé : | cis-Regulatory elements (cREs) are essential for the spatio-temporal control of gene expression during development and disease. However, cRE activity is highly dependent on cell and tissue type. The developing heart is composed of several cell-types, predominantly cardiomyocytes. Therefore, cardiomyocyte-specific modelling is required to understand the cis-regulation of the developing heart. Zebrafish are an ideal model to study heart development, as they share several physiological features with the human heart during cardiogenesis. Here, we present a comprehensive cardiomyocyte-specific repertoire of cREs isolated from zebrafish larvae. This data combines in vivo transcriptomics and epigenetic profiling, providing insights into cREs and their associated genes involved in heart development. We further perform transgenic reporter assays for the identified cREs associated with popdc2 and bmp10 genes, validating these genomic regions as cardiac regulatory elements. We share this comprehensive, reproducible cardiomyocyte-specific cREs resource as an interrogable web tool for understanding the epigenetic and transcriptomic mechanisms underlying heart development and emergence of congenital heart defects. |
