Regeneration of cryoinjury induced necrotic heart lesions in zebrafish is associated with epicardial activation and cardiomyocyte proliferation.

In mammals, myocardial cell death due to infarction results in scar formation and little regenerative response. In contrast, zebrafish have a high capacity to regenerate the heart after surgical resection of myocardial tissue. However, whether zebrafish can also regenerate lesions caused by cell death has not been tested. Here, we present a simple method for induction of necrotic lesions in the adult zebrafish heart based on cryoinjury. Despite widespread tissue death and loss of cardiomyocytes caused by these lesions, zebrafish display a robust regenerative response, which results in substantial clearing of the necrotic tissue and little scar formation. The cellular mechanisms underlying regeneration appear to be similar to those activated in response to ventricular resection. In particular, the epicardium activates a developmental gene program, proliferates and covers the lesion. Concomitantly, mature uninjured cardiomyocytes become proliferative and invade the lesion. Our injury model will be a useful tool to study the molecular mechanisms of natural heart regeneration in response to necrotic cell death.

Dually inducible TetON systems for tissue-specific conditional gene expression in zebrafish.

Systems for spatial and temporal control of gene expression are essential for developmental studies and are of particular importance for research in adult model organisms. We present two modified dually inducible TetON systems for tissue-specific conditional control of gene expression in zebrafish based on (i) a tetracycline inducible transcriptional activator (TetActivator) fused to the ligand binding domain of a mutated glucocorticoid receptor (TetA-GBD) and (ii) a TetActivator fused with a domain of the Ecdysone receptor (TetA-EcR). Both systems showed strong induction of tetracycline-responsive promoters upon administration of the appropriate ligands (doxycycline and dexamethasone for TetA-GBD, and doxycycline and tebufenozide for TetA-EcR), and undetectable leakiness when compared with classical TetActivators. Combinations of transgenic lines expressing TetA-GBD specifically in the heart or the CNS with different Tet-responsive transgenic lines allows conditional and tissue-specific control of gene expression in embryos and adults. Importantly, induction is fully reversible and tunable by the doses of drugs used. The TetA-EcR system avoids the possible side effects of dexamethasone and displays improved sensitivity both in zebrafish and in mammalian cells. These results show that dually inducible TetON systems are convenient tools for reversible and very tightly controlled conditional gene expression in zebrafish.

PRMT6-mediated methylation of R2 in histone H3 antagonizes H3 K4 trimethylation.

The arginine methyltransferase PRMT6 (protein arginine methyltransferase 6) has been shown recently to regulate DNA repair and gene expression. As arginine methylation of histones is an important mechanism in transcriptional regulation, we asked whether PRMT6 possesses activity toward histones. We show here that PRMT6 methylates histone H3 at R2 and histones H4/H2A at R3 in vitro. Overexpression and knockdown analysis identify PRMT6 as the major H3 R2 methyltransferase in vivo. We find that H3 R2 methylation inhibits H3 K4 trimethylation and recruitment of WDR5, a subunit of the MLL (mixed lineage leukemia) K4 methyltransferase complex, to histone H3 in vitro. Upon PRMT6 overexpression, transcription of Hox genes and Myc-dependent genes, both well-known targets of H3 K4 trimethylation, decreases. This transcriptional repression coincides with enhanced occurrence of H3 R2 methylation and PRMT6 as well as reduced levels of H3 K4 trimethylation and MLL1/WDR5 recruitment at the HoxA2 gene. Upon retinoic acid-induced transcriptional activation of HoxA2 in a cell model of neuronal differentiation, PRMT6 recruitment and H3 R2 methylation are diminished and H3 K4 trimethylation increases at the gene. Our findings identify PRMT6 as the mammalian methyltransferase for H3 R2 and establish the enzyme as a crucial negative regulator of H3 K4 trimethylation and transcriptional activation.