DLX gene expression in the developing chick pharyngeal arches and relationship to endothelin signaling and avian jaw patterning.

BACKGROUND: A hinged jaw that articulates with the skull base is a striking feature of the vertebrate head and has been greatly modified between, and within, vertebrate classes. Genes belonging to the DLX homeobox family are conserved mediators of local signaling pathways that distinguish the dorsal and ventral aspects of the first pharyngeal arch. Specifically, a subset of DLX genes are expressed in the cranial neural crest-derived mandibular ectomesenchyme in response to ventral endothelin signaling, an important step that confers the first arch with maxillary and mandibular identities. Downstream targets of DLX genes then execute the morphogenetic processes that lead to functional jaws. Identifying lineage-specific variations in DLX gene expression and the regulatory networks downstream of DLX action is necessary to understand how different kinds of jaws evolved. RESULTS: Here, we describe and compare the expression of all six DLX genes in the chick pharyngeal arches, focusing on the period of active patterning in the first arch. Disruption of endothelin signaling results in the down-regulation of ventral-specific DLX genes and confirms their functional role in avian jaw patterning. CONCLUSIONS: This expression resource will be important for comparative embryology and for identifying synexpression groups of DLX-regulated genes in the chick.

The insufficiency of Dlx5 for ventral patterning in post-migratory neural crest cells reveals a loss of plasticity in early jaw-forming tissue.

The articulated jaws of vertebrates arise from the first pharyngeal arch, the most rostral of several transient ventral structures in pharyngeal stage embryos. Migratory cranial neural crest cells from the caudal midbrain and rostral hindbrain populate the first arch as ectomesenchyme and supply the progenitors of skeletal and soft tissues that form the upper (maxillary) and lower (mandibular) jaws. Dlx genes encode key transcriptional regulators that profoundly influence jaw development through their actions in first pharyngeal arch patterning. The broadly conserved nested expression of Dlx paralogues in vertebrate embryos points to a retained ancestral role in patterning first arch tissue. Loss-of-function experiments consistently highlight the necessity of Dlx gene function for jaw morphogenesis. Specifically, the combined effects of Dlx5 and Dlx6 are required to specify ventral/mandibular fate and forced expression of Dlx5 in migrating neural crest cells results in the ectopic upregulation of ventral markers in the maxillary arch. Here, we ask whether Dlx5 is also sufficient to respecify post-migratory ectomesenchyme in the maxillary branch as mandibular. Unexpectedly, we show that Dlx5 is not sufficient to activate mandibular marker genes in the maxillary branch of PA1, highlighting a loss of plasticity in post-migratory first arch ectomesenchyme.