Genetic compensation of γ CaMKII, an evolutionarily conserved gene.

CaMKII is a Ca/CaM-dependent protein kinase encoded by a family of conserved genes found throughout all metazoan species and expressed from fertilization into adulthood. One of these genes, camk2g1, is particularly important during early development as determined by pharmacologic, dominant negative and antisense morpholino approaches in zebrafish. Four other teleost fish species (cavefish, medaka, stickleback, and tilapia), exhibit sequence conservation of camk2g1 and duplication of the same CaMKII genes.

TEADs, Yap, Taz, Vgll4s transcription factors control the establishment of Left-Right asymmetry in zebrafish.

In many vertebrates, establishment of Left-Right (LR) asymmetry results from the activity of a ciliated organ functioning as the LR Organizer (LRO). While regulation of the formation of this structure by major signaling pathways has been described, the transcriptional control of LRO formation is poorly understood. Using the zebrafish model, we show that the transcription factors and cofactors mediating or regulating the transcriptional outcome of the Hippo signaling pathway play a pivotal role in controlling the expression of genes essential to the formation of the LRO including ligands and receptors of signaling pathways involved in this process and most genes required for motile ciliogenesis.

Generation of Ectopic Morphogen Gradients in the Zebrafish Blastula.

In the zebrafish embryo, cells of the early blastula animal pole are all equivalent and are fully pluripotent until the midblastula transition that occurs at the tenth cell cycle (512 to 1K cells). This naive territory of the embryo is therefore perfectly suited to assay for morphogen activity. Here we describe different methods to generate ectopic morphogen gradients, either in vivo at the animal pole of the embryo, or in vitro in animal pole explants or in aggregates of animal pole blastomeres (also named embryoid bodies).

BMP and retinoic acid regulate anterior-posterior patterning of the non-axial mesoderm across the dorsal-ventral axis.

Despite the fundamental importance of patterning along the dorsal-ventral (DV) and anterior-posterior (AP) axes during embryogenesis, uncertainty exists in the orientation of these axes for the mesoderm. Here we examine the origin and formation of the zebrafish kidney, a ventrolateral mesoderm derivative, and show that AP patterning of the non-axial mesoderm occurs across the classic gastrula stage DV axis while DV patterning aligns along the animal-vegetal pole. We find that BMP signalling acts early to establish broad anterior and posterior territories in the non-axial mesoderm while retinoic acid (RA) functions later, but also across the classic DV axis.