Project description:By using transgenic zebrafish lines Tg(nxk2.5:GFP) (Witzel et al. 2012) and Tg(myl7:EGFP) (D'Amico et al. 2007), we have characterized chromatin accessibility of FACS-isolated CM (GFP+) from developing zebrafish heart at 24, 48 and 72 hpf, corresponding to heart tube formation, chamber formation and differentiation and heart maturation, respectively. GFP- cells were used as a control. We have identified cardiac regulatory networks playing a crucial role in heart morphogenesis. To validate their importance in heart development, we employed zebrafish mutants of cardiac transciption factors Gata5, Hand2 and Tbx5a, the disruption of which were previously linked to impaired migration of the cardiac primordia to the embryonic midline, reduced number of myocardial precursors and failure of heart looping, respectively (Reiter et al. 1999; Yelon et al. 2000; Garrity et al. 2002). ATAC-seq was performed from homozygous gata5tm236a/tm236a, tbx5am21/ m21, hand2s6/s6 mutant 72 hpf embryos in Tg(myl7:EGFP) genetic background. Homozygous mutant embryos for analyses were selected on the basis of their phenotypes of cardia bifida (gata5tm236a/tm236a, hand2s6/s6) or heart-string (tbx5am21/ m21) .

Project description:Gata5/6 are essential regulators in zebrafish heart development. To understand how Gata5/6 affects the chromatin accessibility and regulates cardiac gene expression, we FACS-isolated GFP+ and GFP- cells from Tg(gata5:GFP) transgenic embryos in both control and Gata5/6 deficient embryos (injected with Gata5/6 morpholinos) and conducted ATAC-seq. We performed the experiments at 8 hours post fertilization, intending to dissect the role of Gata5/6 in the earliest step in cardiac lineage specification. We did 2-3 biological replicates for each sample. ATAC-seq libraries were made using previously published protocol (Buenrostro et al., Nat. Methods, 2013. DOI: 10.1038/nmeth.2688) and sequenced on Illumina Hiseq2500.

Project description:Zebrafish can regenerate their hearts. As a first response to injury, the epicardium reacts by upregulalion of developmental marker genes. Here we compared in an unbiased manner the expression of the epicardium from uninjured zebrafish hearts and hearts at 3 days postcryoinjury. To label epicardial cells of uninjured hearts we usd pard3:GFP (POon et al 2010) and to label epicardium of the injured heart wt1b:eGFP (Perner et al 2007)

Project description:The essential myosin light chain (ELC) is part of the cardiac myosin motor regulating the contractility of the heart. Recently, we have demonstrated ELC phosphorylation to be responsible not only for basal maintenance of cardiac contractility, but also for the adaptation of sarcomere function to increased demands in adult zebrafish (Scheid et al. Cardiovascular Research, 2016). However, the direct interacting kinases, phosphatases as well as the signaling pathway mediating the ELC phosphorylation are mostly unknown. Here, we aim to identify ELC interacting proteins in zebrafish heart tissue using an ELC-specific precipitation assay followed by mass spectrometry. In brief, ELC specific co-immunoprecipitation was performed by using the Dynabeads Co-immunoprecipitation Kit (Invitrogen, #14321D). Custom-specific polyclonal ELC antibodies (Eurogentec, peptide for immunization: NH2-CAPVPETPKEPEVDLK-CONH2) against zebrafish ELC were covalently coupled to DynabeadsTM M-270 Epoxy (Invitrogen, #14302D) and whole zebrafish heart protein was used as input. All steps were carried out according to the manufacturer's instructions.

Project description:The goal of this study is to analyse the open chromatin regions via ATACseq in zebrafish embryonic endothelial cells at 26-27hpf using Tg(Kdrl:GFP) transgenic zebrafish embryos. 40000-50000 cells were FAC-sorted directly into 100 µl of 1x HBSS/10 mM HEPES/0.25% BSA buffer for Tagmentation (as described by Buenrostro et al. (2013), Nat. Methods 10, 1213-1218), but with 1.5 µl Tn5 transposase (Illumina) in a 50 µl reaction volume. DNA was purified using the QIAquick PCR purification kit (Qiagen). Fragments were amplified for 16 cycles.

Project description:The aim of this study was to identify genes that are regulated by Bmp signaling with the zebrafish heart at the heart cone stage around 21-23 hours post fertilization. In total, 4 samples based on cDNA from extracted cardiac tissue were analyzed: 2 samples of Tg(hsp70l:bmp2b)fr13 transgenic embryos heatshocked at 18 hpf and 2 WT control samples.

Project description:We previously reported that Def (Digestive-organ expansion factor) was a pan-endodermal enriched factor that is essential for the growth of digestive organs in zebrafish using a def mutant line hi429 as model (Chen et al., 2005). To further elucidate Def function, we generated a Def over-expressed zebrafish line, namely Tg (fabp10a:def)-I, in which def expression was under the control of a liver-specific promoter fabp10a. We used microarrays to detail the global programme of gene expression in Tg (fabp10a:def)-I transgenic line compared with wild type zebrafish control, and identified distinct classes of differently regulated genes in Tg (fabp10a:def)-I line.

Project description:Thyroid follicular cells (TFCs) are responsible for generation, storage and release of thyroid hormone. Single-cell analysis of zebrafish thyroid gland demonstrated transcriptional heterogeneity within the TFC population (Gillotay et al., bioRxiv, 2020. doi: 10.1101/2020.01.13.891630. GEO dataset for single-cell RNA-Seq.: GSE133466). Particularly, TFC displayed transcriptional heterogeneity in the expression of pax2a, a transcription factor involved in differentiation and maturation of TFCs. To validate the genetic heterogeneity, we generated a pax2a knock-in line, in which mKO2 expression is driven by endogenous pax2a locus. Using Tg(tg:nls-EGFP); pax2a:mKO2-Knock-in, we sorted for TFCs (GFP+) and separated the pax2a-Low (mKO2-Low) and pax2a-High (mKO2-High) populations for NGS.

Project description:Cardiac-specific PPARalpha transgenic (Tg-PPARalpha) mice show mild cardiac hypertrophy and systolic dysfunction. The failing heart phenotypes observed in Tg-PPARalpha are exacerbated by crossing with cardiac-specific Sirt1 transgenic (Tg-Sirt1) mice, whereas Tg-Sirt1 mice themselves do not show any cardiac hypertrophy or systolic dysfunction. To investigate the mechanism leading to the failing heart phenotypes in TgPPARalpha/Tg-Sirt1 bigenic mice, microarray analyses were performed. The microarray analyses revealed that many ERR target genes were downregulated in Tg-PPARalpha and in Tg-Sirt1, and they were further downregulated in the Tg-PPARalpha/Tg-Sirt1 bigenic mice.

Project description:Heart formation requires the fusion of bilateral cardiomyocyte populations as they move toward the embryonic midline. The bHLH transcription factor Hand2 is essential for cardiac fusion; however, the effector genes that execute this function of Hand2 are unknown. Here, we provide the first evidence for a downstream component of the Hand2 pathway that mediates cardiac morphogenesis. Although hand2 is expressed in cardiomyocytes, mosaic analysis demonstrates that hand2 plays a non-autonomous role in regulating cardiomyocyte movement. Gene expression profiles reveal heightened expression of fibronectin 1 (fn1) in hand2 mutant embryos. Reciprocally, overexpression of hand2 leads to decreased Fibronectin levels. Furthermore, reduction of fn1 function enables rescue of cardiac fusion in hand2 mutants: bilateral cardiomyocyte populations merge and exhibit improved tissue architecture, albeit without major changes in apicobasal polarity. Together, our data provide a novel example of a tissue creating a favorable environment for its morphogenesis: the Hand2 pathway establishes an appropriate environment for cardiac fusion through negative modulation of Fn1 levels. Embryos from three independent hand2 mutant (hanS6 allele) heterozyogous crosses were collected. Examination of Tg(myl7:egfp) expression allow sorting of hand2 mutant embryos from their wild-type siblings.