Control of cranial ectomesenchyme fate by Nr2f nuclear receptors.

Certain cranial neural crest cells are uniquely endowed with the ability to make skeletal cell types otherwise only derived from mesoderm. As these cells migrate into the pharyngeal arches, they downregulate neural crest specifier genes and upregulate so-called ectomesenchyme genes that are characteristic of skeletal progenitors. Although both external and intrinsic factors have been proposed as triggers of this transition, the details remain obscure. Here, we report the Nr2f nuclear receptors as intrinsic activators of the ectomesenchyme program: zebrafish nr2f5 single and nr2f2;nr2f5 double mutants show marked delays in upregulation of ectomesenchyme genes, such as dlx2a, prrx1a, prrx1b, sox9a, twist1a and fli1a, and in downregulation of sox10, which is normally restricted to early neural crest and non-ectomesenchyme lineages. Mutation of sox10 fully rescued skeletal development in nr2f5 single but not nr2f2;nr2f5 double mutants, but the initial ectomesenchyme delay persisted in both. Sox10 perdurance thus antagonizes the recovery but does not explain the impaired ectomesenchyme transition. Unraveling the mechanisms of Nr2f function will help solve the enduring puzzle of how cranial neural crest cells transition to the skeletal progenitor state.

Patterning of cartilaginous condensations in the developing facial skeleton.

Adult endochondral bones are prefigured in the embryo as cellular condensations within fields of more loosely distributed skeletal progenitors. How these early condensations are initiated and shaped has remained enigmatic, despite the wealth of research on later stages of cartilage differentiation and endochondral ossification. Using the simple larval zebrafish facial skeleton as a model, we reevaluate the involvement of the master cartilage regulator Sox9 in shaping facial condensations and find it to be largely dispensable. We then use new lineage-tracing tools to definitively show that precartilaginous condensations originate from neighboring clusters of cells termed mesenchymal condensations. These cartilage-generating mesenchymal condensations express a cohort of transcription factors that are also expressed in odontogenic mesenchyme in mammals, including barx1, lhx6a/8a, and pax9. We hypothesized that the position of each mesenchymal condensation determines the axis of growth of its corresponding precartilaginous condensation, thus influencing its final shape. Consistent with this idea, we find that positive Fgf and inhibitory Jagged-Notch signals intersect to precisely position a mesenchymal condensation in the dorsal half of the second pharyngeal arch, with loss of pathway function leading to predictable shape changes in the resulting cartilage element. Deciphering the full array of signals that control the spatial distribution of mesenchymal condensations and regulate their maturation into precartilaginous condensations thus offers a promising approach for understanding the origins of skeletal form.