Multiple functions of Snail family genes during palate development in mice

doi:10.1242/dev.02837

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Development ePress online publication date 21 Mar 2007
doi: 10.1242/dev.02837

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Research article: Development and Disease

Multiple functions of Snail family genes during palate development in mice

Stephen A. Murray, Kathleen F. Oram, and Thomas Gridley^*
^* Author for correspondence (e-mail: tom.gridley{at}jax.org)

Palate development requires precise regulation of gene expressionchanges, morphogenetic movements and alterations in cell physiology.Defects in any of these processes can result in cleft palate,a common human birth defect. The Snail gene family encodes transcriptionalrepressors that play essential roles in the growth and patterningof vertebrate embryos. Here we report the functions of Snail(Snai1) and Slug (Snai2) genes during palate development inmice. Snai2^-/- mice exhibit cleft palate, which is completelypenetrant on a Snai1 heterozygous genetic background. Cleftpalate in Snai1⁺^/^- Snai2^-/- embryos is due to a failure of theelevated palatal shelves to fuse. Furthermore, while tissue-specificdeletion of the Snai1 gene in neural crest cells does not causeany obvious defects, neural-crest-specific Snai1 deletion ona Snai2^-/- genetic background results in multiple craniofacialdefects, including a cleft palate phenotype distinct from thatobserved in Snai1⁺^/^- Snai2^-/- embryos. In embryos with neural-crest-specificSnai1 deletion on a Snai2^-/- background, palatal clefting resultsfrom a failure of Meckel's cartilage to extend the mandibleand thereby allow the palatal shelves to elevate, defects similarto those seen in the Pierre Robin Sequence in humans.

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