Distinct requirements for <i>wnt9a</i> and <i>irf6</i> in extension and integration mechanisms during zebrafish palate morphogenesis

Dougherty, Max; Kamel, George; Grimaldi, Michael; Gfrerer, Lisa; Shubinets, Valeriy; Ethier, Renee; Hickey, Graham; Cornell, Robert A.; Liao, Eric C.

doi:10.1242/dev.080473

Cited by 86 publications

(129 citation statements)

References 40 publications

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“…For example, mammalian and fish palates have distinct morphologies and are comprised of non-homologous elements (Dougherty, et al 2013; Murray and Schutte 2004; Swartz, et al 2011). Despite this, their development requires the action of homologous cell- and tissue-level processes including migration of cranial neural crest cells, as well as the coordinated outgrowth and fusion of multiple processes and structures (Dougherty, et al 2013; Murray and Schutte 2004). Further, homologous genes regulate these cellular mechanisms.…”

Section: Harnessing Natural Variation In Evolutionary Mutants To Undementioning

confidence: 99%

“…Further, homologous genes regulate these cellular mechanisms. For instance, loss of irf6 or the microRNA Mirn140 and Pdgf signaling network results in conspicuous orofacial clefting in both humans and zebrafish (Dougherty, et al 2013; Eberhart, et al 2008; Kondo, et al 2002; Li, et al 2010; Rattanasopha, et al 2012). These insights confirm the deep homology of the vertebrate skull.…”

Section: Harnessing Natural Variation In Evolutionary Mutants To Undementioning

confidence: 99%

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Cichlid fishes as a model to understand normal and clinical craniofacial variation

Powder

Albertson

2016

Developmental Biology

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We have made great strides towards understanding the etiology of craniofacial disorders, especially for ‘simple’ Mendelian traits. However, the facial skeleton is a complex trait, and the full spectrum of genetic, developmental, and environmental factors that contribute to its final geometry remain unresolved. Forward genetic screens are constrained with respect to complex traits due to the types of genes and alleles commonly identified, developmental pleiotropy, and limited information about the impact of environmental interactions. Here, we discuss how studies in an evolutionary model – African cichlid fishes – can complement traditional approaches to understand the genetic and developmental origins of complex shape. Cichlids exhibit an unparalleled range of natural craniofacial morphologies that model normal human variation, and in certain instance mimic human facial dysmorphologies. Moreover, the evolutionary history and genomic architecture of cichlids make them an ideal system to identify the genetic basis of these phenotypes via quantitative trait loci (QTL) mapping and population genomics. Given the molecular conservation of developmental genes and pathways, insights from cichlids are applicable to human facial variation and disease. We review recent work in this system, which has identified lbh as a novel regulator of neural crest cell migration, determined the Wnt and Hedgehog pathways mediate species-specific bone morphologies, and examined how plastic responses to diet modulate adult facial shapes. These studies have not only revealed new roles for existing pathways in craniofacial development, but have identified new genes and mechanisms involved in shaping the craniofacial skeleton. In all, we suggest that combining work in traditional laboratory and evolutionary models offers significant potential to provide a more complete and comprehensive picture of the myriad factors that are involved in the development of complex traits.

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Section: Harnessing Natural Variation In Evolutionary Mutants To Undementioning

confidence: 99%

Section: Harnessing Natural Variation In Evolutionary Mutants To Undementioning

confidence: 99%

Cichlid fishes as a model to understand normal and clinical craniofacial variation

Powder

Albertson

2016

Developmental Biology

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“…Comparable phenotypes have been observed in zebrafish “midline” mutants, ranging from a complete absence of the anterior neurocranium to the formation of two unfused, parallel rods or a single rod instead of a plate (Eberhart et al, 2008; Eberhart, Swartz, Crump, & Kimmel, 2006; Kimmel, Miller, & Moens, 2001; Swartz, Sheehan-Rooney, Dixon, & Eberhart, 2011; Wada et al, 2005). Importantly, zebrafish mutant for Pdgf, Shh, or Bmp pathway components, or deficient in irf6 , all show cleft or midline phenotypes resembling those of their mammalian counterparts (Table 1; Dougherty et al, 2013; Eberhart et al, 2008, 2006; Swartz et al, 2011; Wada et al, 2005). These findings indicate that a conserved genetic network regulates the formation of this part of the face across vertebrates and support the use of the zebrafish anterior neurocranium as a model for the mammalian hard palate.…”

Section: Zebrafish Craniofacial Anatomymentioning

confidence: 99%

“…Within the first stream of neural crest, the initial, premigratory rostral–caudal position alongside the brain determines whether NCCs will migrate over or behind the eye (Dougherty et al, 2012; Wada et al, 2005), as well as whether their progeny will contribute to the anterior neurocranium or the upper or lower jaw (Dougherty et al, 2013, 2012; Eberhart et al, 2006; Wada et al, 2005). Additional analyses demonstrated that NCCs at certain anterior–posterior and mediolateral coordinates within each arch reproducibly contribute not only to particular skeletal elements but also to specific domains of said elements (Fig.…”

Section: Imaging Craniofacial Developmentmentioning

confidence: 99%

Zebrafish Craniofacial Development

Mork

Crump

2015

Current Topics in Developmental Biology

156

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The formation of the face and skull involves a complex series of developmental events mediated by cells derived from the neural crest, endoderm, mesoderm, and ectoderm. Although vertebrates boast an enormous diversity of adult facial morphologies, the fundamental signaling pathways and cellular events that sculpt the nascent craniofacial skeleton in the embryo have proven to be highly conserved from fish to man. The zebrafish Danio rerio, a small freshwater cyprinid fish from eastern India, has served as a popular model of craniofacial development since the 1990s. Unique strengths of the zebrafish model include a simplified skeleton during larval stages, access to rapidly developing embryos for live imaging, and amenability to transgenesis and complex genetics. In this chapter, we describe the anatomy of the zebrafish craniofacial skeleton; its applications as models for the mammalian jaw, middle ear, palate, and cranial sutures; the superior imaging technology available in fish that has provided unprecedented insights into the dynamics of facial morphogenesis; the use of the zebrafish to decipher the genetic underpinnings of craniofacial biology; and finally a glimpse into the most promising future applications of zebrafish craniofacial research.

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“…4C–D) were observed. Further, we noted that the ethmoid cartilage, thought to be analogous to the mammalian palate in non-amniotes [69], was significantly reduced or absent. These defects were accompanied by a reduced midface area that was at least in part due to a decrease in cell proliferation in the dorsal facial prominences.…”

Section: Introductionmentioning

confidence: 99%

Using frogs faces to dissect the mechanisms underlying human orofacial defects

Dickinson

2016

Seminars in Cell & Developmental Biology

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In this review I discuss how Xenopus laevis is an effective model to dissect the mechanisms underlying orofacial defects. This species has been particularly useful in studying the understudied structures of the developing face including the embryonic mouth and primary palate. The embryonic mouth is the first opening between the foregut and the environment and is critical for adult mouth development. The final step in embryonic mouth formation is the perforation of a thin layer of tissue covering the digestive tube called the buccopharyngeal membrane. When this tissue does not perforate in humans it can pose serious health risks for the fetus and child. The primary palate forms just dorsal to the embryonic mouth and in non-amniotes it functions as the roof of the adult mouth. Defects in the primary palate result in a median oral cleft that appears similar across the vertebrates. In humans, these median clefts are often severe and surgically difficult to repair. Xenopus has several qualities that make it advantageous for craniofacial research. The free living embryo has an easily accessible face and we have also developed several new tools to analyze the development of the region. Further, Xenopus is readily amenable to chemical screens allowing us to uncover novel gene-environment interactions during orofacial development, as well as to define underlying mechanisms governing such interactions. In conclusion, we are utilizing Xenopus in new and innovative ways to contribute to craniofacial research.

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Distinct requirements for wnt9a and irf6 in extension and integration mechanisms during zebrafish palate morphogenesis

Cited by 86 publications

References 40 publications

Cichlid fishes as a model to understand normal and clinical craniofacial variation

Cichlid fishes as a model to understand normal and clinical craniofacial variation

Zebrafish Craniofacial Development

Using frogs faces to dissect the mechanisms underlying human orofacial defects

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