Early Migrating Neural Crest Cells Can Form Ventral Neural Tube Derivatives When Challenged by Transplantation

Once neural crest cells undergo an epithelial–mesenchymal transition to leave the neural tube, it has been classically assumed that they are fated to differentiate within the neural crest lineage. To test this idea, we challenged the developmental potential of recently emigrated neural crest cells by transplanting them into the ventral portion of the neural tube at the open neural plate stage. Newly migrating neural crest cells were isolated in tissue culture, labeled with the lipophilic dye DiI, and microinjected into the ventral portion of the neural plate. After 2 days, some neural crest cells became incorporated into the neuroepithelium in positions characteristic of floor plate cells and motor neurons. Some of the labeled cells within the ventral neural tube expressed FP-1, characteristic of floor plate cells. A few labeled cells were found in positions characteristic of motor neurons and expressed islet-1. In contrast, neural crest cells transplanted onto neural crest pathways expressed the HNK-1 epitope, but no ventral neural tube markers. Injection of neural crest cells into the mesenchyme adjacent to the notochord or culturing them in the presence of Sonic hedgehog failed to elicit FP-1 expression. These results suggest that migrating neural crest cells are flexible in their fate and retain the ability to form neural tube derivatives even after emigrating from the neural tube

Kat2a and Kat2b Acetyltransferase Activity Regulates Craniofacial Cartilage and Bone Differentiation in Zebrafish and Mice

Cranial neural crest cells undergo cellular growth, patterning, and differentiation within the branchial arches to form cartilage and bone, resulting in a precise pattern of skeletal elements forming the craniofacial skeleton. However, it is unclear how cranial neural crest cells are regulated to give rise to the different shapes and sizes of the bone and cartilage. Epigenetic regulators are good candidates to be involved in this regulation, since they can exert both broad as well as precise control on pattern formation. Here, we investigated the role of the histone acetyltransferases Kat2a and Kat2b in craniofacial development using TALEN/CRISPR/Cas9 mutagenesis in zebrafish and the Kat2ahat/hat (also called Gcn5) allele in mice. kat2a and kat2b are broadly expressed during embryogenesis within the central nervous system and craniofacial region. Single and double kat2a and kat2b zebrafish mutants have an overall shortening and hypoplastic nature of the cartilage elements and disruption of the posterior ceratobranchial cartilages, likely due to smaller domains of expression of both cartilage- and bone-specific markers, including sox9a and col2a1, and runx2a and runx2b, respectively. Similarly, in mice we observe defects in the craniofacial skeleton, including hypoplastic bone and cartilage and altered expression of Runx2 and cartilage markers (Sox9, Col2a1). In addition, we determined that following the loss of Kat2a activity, overall histone 3 lysine 9 (H3K9) acetylation, the main epigenetic target of Kat2a/Kat2b, was decreased. These results suggest that Kat2a and Kat2b are required for growth and differentiation of craniofacial cartilage and bone in both zebrafish and mice by regulating H3K9 acetylation