Angelo Iulianella scite author profile

Cleft lip, which results from impaired facial process growth and fusion, is one of the most common cranio facial birth defects. Many genes are known to be involved in the etiology of this disorder; however, our under standing of cleft lip pathogenesis remains incomplete. In the present study, we uncovered a role for sonic hedgehog (SHH) signaling during lip fusion. Mice carrying compound mutations in hedgehog acyltransferase (Hhat) and patched1 (Ptch1) exhibited perturbations in the SHH gradient during frontonasal development, which led to hypoplastic nasal process outgrowth, epithelial seam persistence, and cleft lip. Further investi gation revealed that enhanced SHH signaling restricts canonical WNT signaling in the lambdoidal region by promoting expression of genes encoding WNT inhibitors. Moreover, reduction of canonical WNT signaling perturbed p63/interferon regulatory factor 6 (p63/IRF6) signaling, resulting in increased proliferation and decreased cell death, which was followed by persistence of the epithelial seam and cleft lip. Consistent with our results, mutations in genes that disrupt SHH and WNT signaling have been identified in both mice and humans with cleft lip. Collectively, our data illustrate that altered SHH signaling contributes to the etiology and pathogenesis of cleft lip through antagonistic interactions with other gene regulatory networks, including the canonical WNT and p63/IRF6 signaling pathways.

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Retinoic Acid Regulation of Cdx1: an Indirect Mechanism for Retinoids and Vertebral Specification

Houle

Prinos

Iulianella

et al. 2000

Molecular and Cellular Biology

100

102

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Retinoic acid (RA) is required for diverse developmental programs, including vertebral specification. Both RA receptor disruption and excess RA result in homeotic transformations of the axial skeleton. These effects are believed to occur through altered expression of Hox genes, several of which have been demonstrated to be direct RA targets. Members of the cdx (caudal) homeobox gene family are also implicated in regulating Hox expression. Disruption of cdx1 results in vertebral homeotic transformations and alteration of Hox expression boundaries; similar homeosis is also observed in cdx2 heterozygotes. In Xenopus, gain or loss of Cdx function affects vertebral morphogenesis through a mechanism that also correlates with altered Hox expression. Taken together with the finding of putative Cdx binding motifs in several Hox promoters, these data strongly support a role for Cdx members in direct regulation of expression of at least some Hox genes. Most retinoid-responsive Hox genes have not been demonstrated to be direct RA targets, suggesting that intermediaries are involved. Based on these findings, we hypothesized that one or more cdx members may transduce the effects of RA on Hox transcription. Consistent with this, we present evidence that cdx1 is a direct RA target gene, suggesting an additional pathway for retinoid-dependent vertebral specification.

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Cux2(Cutl2) integrates neural progenitor development with cell-cycle progression during spinal cord neurogenesis

Iulianella

Sharma

Durnin

et al. 2008

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Neurogenesis requires the coordination of neural progenitor proliferation and differentiation with cell-cycle regulation. However, the mechanisms coordinating these distinct cellular activities are poorly understood. Here we demonstrate for the first time that a Cut-like homeodomain transcription factor family member, Cux2 (Cutl2), regulates cell-cycle progression and development of neural progenitors. Cux2 loss-of-function mouse mutants exhibit smaller spinal cords with deficits in neural progenitor development as well as in neuroblast and interneuron differentiation. These defects correlate with reduced cell-cycle progression of neural progenitors coupled with diminished Neurod and p27Kip1 activity. Conversely, in Cux2 gain-of-function transgenic mice, the spinal cord is enlarged in association with enhanced neuroblast formation and neuronal differentiation, particularly with respect to interneurons. Furthermore, Cux2 overexpression induces high levels of Neurod and p27 Kip1. Mechanistically, we discovered through chromatin immunoprecipitation assays that Cux2 binds both the Neurod and p27Kip1 promoters in vivo, indicating that these interactions are direct. Our results therefore show that Cux2 functions at multiple levels during spinal cord neurogenesis. Cux2 initially influences cell-cycle progression in neural progenitors but subsequently makes additional inputs through Neurod and p27 Kip1 to regulate neuroblast formation, cell-cycle exit and cell-fate determination. Thus our work defines novel roles for Cux2 as a transcription factor that integrates cell-cycle progression with neural progenitor development during spinal cord neurogenesis.

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A Molecular Basis for Retinoic Acid-Induced Axial Truncation

Iulianella

Beckett

Petkovich

et al. 1999

Developmental Biology

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Dietary deprivation and gene disruption studies clearly demonstrate that biologically active retinoids, such as retinoic acid (RA), are essential for numerous developmental programs. Similar ontogenic processes are also affected by retinoic acid excess, suggesting that the effects of retinoid administration reflect normal retinoid-dependent events. In the mouse, exogenous retinoic acid can induce both anterior (anencephaly, exencephaly) and posterior (spina bifida) neural tube defects depending on the developmental stage of treatment. Retinoic acid receptor gamma (RARgamma) mediates these effects on the caudal neural tube at 8.5 days postcoitum, as RARgamma-/- mice are completely resistant to spina bifida induced by retinoic acid at this stage. We therefore used this null mouse as a model to examine the molecular nature of retinoid-induced caudal neural tube defects by using a panel of informative markers and comparing their expression between retinoic acid-treated wild-type and RARgamma-/- embryos. Our findings indicate that treatment of wild-type embryos led to a rapid and significant decrease in the caudal expression of all mesodermal markers examined (e.g., brachyury, wnt-3a, cdx-4), whereas somite, neuroepithelial, notochord, floorplate, and hindgut markers were unaffected. RARgamma-/- mutants exhibited normal expression patterns for all markers examined, consistent with the notion that mesodermal defects underlie the etiology of retinoid-induced spina bifida. We also found that posterior somitic, but not caudal presomitic, embryonic tissues contained detectable bioactive retinoids, an observation which correlated with the ability of caudal explants to rapidly clear exogenous RA. Interestingly, transcripts encoding mP450RAI, a cytochrome P450, the product of which is believed to catabolize retinoic acid, were abundant in the retinoid-poor region of the caudal embryo. mP450RAI was rapidly induced by retinoic acid treatment in vivo, consistent with previous studies suggesting that it plays a critical role in retinoid signaling. These data suggest that nascent mesoderm is highly sensitive to retinoic acid and that mP450RAI serves to tightly regulate retinoid levels in the caudal embryo. These findings also raise the possibility that RA may play a role in the generation of posterior mesoderm derivatives in part by affecting brachyury expression.

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