Disruption of signaling pathways such as those mediated by Shh or Pdgf causes craniofacial disease, including cleft palate. The role that microRNAs play in modulating palatogenesis, however, is completely unknown. We show, in zebrafish, that the microRNA Mirn140 negatively regulates Pdgf signaling during palatal development and we provide a mechanism for how disruption of Pdgf signaling causes palatal clefting. The pdgf-receptor alpha (pdgfra) 3' UTR contains a Mirn140 binding site functioning in the negative regulation of Pdgfra protein levels in vivo. Both pdgfra mutants and Mirn140-injected embryos share panoply of facial defects including clefting of the crestderived cartilages that develop in the roof of the larval mouth. Concomitantly, the oral ectoderm beneath where these cartilages develop loses pitx2 and shha expression. Mirn140 modulates Pdgfmediated attraction of cranial neural crest cells to the oral ectoderm, where crest-derived signals are necessary for oral ectodermal gene expression. Both Mirn140 loss-of-function and pdgfra overexpression alters palatal shape and causes neural crest cells to accumulate around the optic stalk, a source of the ligand Pdgfaa. Conserved molecular genetics and expression patterns of mirn140 and pdgfra suggest that their regulatory interactions are ancient methods of palatogenesis that provide a candidate mechanism for cleft palate.Cleft palate and other craniofacial diseases are common in humans and have complex cellular and genetic etiologies. In amniotes, the palate serves to separate the nasal and oral cavities and is generated through an intricate series of morphogenic events that include early neural crest cell migration and cell-cell signaling during the formation of facial prominences, as well as later generation and fusion of palatal shelves. While later events involving palatal shelves have not been described in zebrafish, palatal precursors migrate both rostral and caudal to the eye to condense upon the oral ectoderm in amniotes 1 as well as zebrafish 2,3 and evidence continues to accumulate that the early signaling environment governing palatogenesis is also largely equivalent [3][4][5][6] . For instance, Hh signaling is crucial for palatogenesis in humans and zebrafish 3,4,7 . Zebrafish and amniotes also share expression patterns of palatogenic genes such as Shh 4,8 , Fgf8 4,9,10 and Pdgf receptor alpha (Pdgfra) [11][12][13] .In mouse, the Pdgf family consists of four soluble ligands, Pdgfa, Pdgfb, Pdgfc, and Pdgfd as well as two receptor tyrosine kinases, Pdgfra and Pdgfrb 14 . Pdgf signaling regulates a myriad of biological processes as demonstrated by analyses of mouse Pdgf ligand and receptor mutants 14 . Mice null for Pdgfra have a facial clefting phenotype that includes cleft palate 12,13 . This facial phenotype is fully recapitulated in mice doubly mutant for Pdgfa and Pdgfc 15. Most Pdgfc mutants have cleft palate 15 MicroRNAs (miRNAs) provide a unique mechanism for modulating signaling pathways [17][18][19][20] . Skeletogenic, including...
Hedgehog (Hh) signaling plays multiple roles in the development of the anterior craniofacial skeleton. We show that the earliest function of Hh is indirect, regulating development of the stomodeum, or oral ectoderm. A subset of post-migratory neural crest cells, that gives rise to the cartilages of the anterior neurocranium and the pterygoid process of the palatoquadrate in the upper jaw, condenses upon the upper or roof layer of the stomodeal ectoderm in the first pharyngeal arch. We observe that in mutants for the Hh co-receptor smoothened (smo) the condensation of this specific subset of crest cells fails, and expression of several genes is lost in the stomodeal ectoderm. Genetic mosaic analyses with smo mutants show that for the crest cells to condense the crucial target tissue receiving the Hh signal is the stomodeum, not the crest. Blocking signaling with cyclopamine reveals that the crucial stage, for both crest condensation and stomodeal marker expression, is at the end of gastrulation -some eight to ten hours before crest cells migrate to associate with the stomodeum. Two Hh genes, shh and twhh, are expressed in midline tissue at this stage, and we show using mosaics that for condensation and skeletogenesis only the ventral brain primordium, and not the prechordal plate, is an important Hh source. Thus, we propose that Hh signaling from the brain primordium is required for proper specification of the stomodeum and the stomodeum, in turn, promotes condensation of a subset of neural crest cells that will form the anterior neurocranial and upper jaw cartilage.
Human palatal clefting is debilitating and difficult to rectify surgically. Animal models enhance our understanding of palatogenesis and are essential in strategies designed to ameliorate palatal malformations in humans. Recent studies have shown that the zebrafish palate, or anterior neurocranium, is under similar genetic control to the amniote palatal skeleton. We extensively analyzed palatogenesis in zebrafish to determine the similarity of gene expression and function across vertebrates. By 36 hpf palatogenic cranial neural crest cells reside in homologous regions of the developing face compared to amniote species. Transcription factors and signaling molecules regulating mouse palatogenesis are expressed in similar domains during palatogenesis in zebrafish. Functional investigation of a subset of these genes, fgf10a, tgfb2, pax9 and smad5 revealed their necessity in zebrafish palatogenesis. Collectively, these results suggest that the gene regulatory networks regulating palatogenesis may be conserved across vertebrate species, demonstrating the utility of zebrafish as a model for palatogenesis.
Human birth defects are highly variable and this phenotypic variability can be influenced by both the environment and genetics. However, the synergistic interactions between these two variables are not well understood. Fetal alcohol spectrum disorders (FASD) is the umbrella term used to describe the wide range of deleterious outcomes following prenatal alcohol exposure. Although FASD are caused by prenatal ethanol exposure, FASD are thought to be genetically modulated, although the genes regulating sensitivity to ethanol teratogenesis are largely unknown. To identify potential ethanol-sensitive genes, we tested five known craniofacial mutants for ethanol sensitivity: cyp26b1, gata3, pdgfra, smad5 and smoothened. We found that only platelet-derived growth factor receptor alpha (pdgfra) interacted with ethanol during zebrafish craniofacial development. Analysis of the PDGF family in a human FASD genome-wide dataset links PDGFRA to craniofacial phenotypes in FASD, prompting a mechanistic understanding of this interaction. In zebrafish, untreated pdgfra mutants have cleft palate due to defective neural crest cell migration, whereas pdgfra heterozygotes develop normally. Ethanol-exposed pdgfra mutants have profound craniofacial defects that include the loss of the palatal skeleton and hypoplasia of the pharyngeal skeleton. Furthermore, ethanol treatment revealed latent haploinsufficiency, causing palatal defects in ∼62% of pdgfra heterozygotes. Neural crest apoptosis partially underlies these ethanol-induced defects in pdgfra mutants, demonstrating a protective role for Pdgfra. This protective role is mediated by the PI3K/mTOR pathway. Collectively, our results suggest a model where combined genetic and environmental inhibition of PI3K/mTOR signaling leads to variability within FASD.
Mef2 genes encode highly conserved transcription factors involved in somitic and cardiac mesoderm development in diverse bilaterians. Vertebrates have multiple mef2 genes. In mice, mef2c is required for heart and vascular development. We show that a zebrafish mef2c gene (mef2ca) is required in cranial neural crest (CNC) for proper head skeletal patterning. mef2ca mutants have head skeletal phenotypes resembling those seen upon partial loss-of-function of endothelin1 (edn1). Furthermore, mef2ca interacts genetically with edn1, arguing that mef2ca functions within the edn1 pathway. mef2ca is expressed in CNC and this expression does not require edn1 signaling. Mosaic analyses reveal that mef2ca is required in CNC for pharyngeal skeletal morphogenesis. Proper expression of many edn1-dependent target genes including hand2, bapx1, and gsc, depends upon mef2ca function. mef2ca plays a critical role in establishing the proper nested expression patterns of dlx genes. dlx5a and dlx6a, known Edn1 targets, are downregulated in mef2ca mutant pharyngeal arch CNC. Surprisingly, dlx4b and dlx3b are oppositely affected in mef2ca mutants. dlx4b expression is abolished while the edn1-dependent dlx3b is ectopically expressed in more dorsal CNC. Together our results support a model in which CNC cells require mef2ca downstream of edn1 signaling for proper craniofacial development.
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