Quantitative analyses link modulation of sonic hedgehog signaling to continuous variation in facial growth and shape

Young, Nathan M.; Chong, Huira; Hu, Diane; Hallgrímsson, Benedikt; Marcucio, Ralph

doi:10.1242/dev.052340

Cited by 126 publications

(151 citation statements)

References 36 publications

(49 reference statements)

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“…Alterations in Shh activity in either the forebrain or facial mesenchyme are known to affect the spatial organization and mitotic activity of midfacial growth zones, resulting in a continuous phenotypic spectrum from cyclopia to hypertelorism. 33,46 Therefore, our data are consistent with the loss of Apaf1 cell-death function causing an increase in Shh signaling that results in the craniofacial development defects we see in the Apaf1 yautja mutants ( Figure 6). …”

Section: Resultssupporting

confidence: 88%

“…[47][48] The current understanding is that the size of the Shh expression region is strictly controlled to coordinate craniofacial development. 33,46 We found increased cell proliferation in the FNP mesenchyme, as would be predicted by increased or persistent Shh signaling from the ventral forebrain signaling center. The broadened, diffuse Shh expression patterns we saw in yautja mutants are concordant with published results in which ectopically expanded Shh activity resulted Figure 5 Craniofacial defects: getting at a mechanism.…”

Section: Discussionsupporting

confidence: 58%

“…The box in the first panel of each pair is enlarged in the second panel to show detail of the floor plate and Shh expression (arrows) in a widened midface. 33 Taken together, our data suggest that decreased cell death resulting from loss of Apaf1 function leads to an expansion of Shh-expressing cells and cell proliferation that results in the wide FNP and split-face phenotype (Figure 6b).…”

Section: Discussionmentioning

confidence: 53%

“…[25][26] Directions from these signaling centers drive bone morphogenetic protein (Bmp), retinoid and wingless (Wnt) expression in the mesenchyme and induce outgrowth of the facial prominences. [27][28][29][30][31][32] Shh is important not only for establishing craniofacial signaling centers, but also for controlling proliferation and directing cell migration, 33 which make this signaling molecule a key player in craniofacial development.…”

mentioning

confidence: 99%

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Apaf1 apoptotic function critically limits Sonic hedgehog signaling during craniofacial development

et al. 2013

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Apaf1 is an evolutionarily conserved component of the apoptosome. In mammals, the apoptosome assembles when cytochrome c is released from mitochondria, binding Apaf1 in an ATP-dependent manner and activating caspase 9 to execute apoptosis. Here we identify and characterize a novel mouse mutant, yautja, and find it results from a leucine-to-proline substitution in the winged-helix domain of Apaf1. We show that this allele of Apaf1 is unique, as the yautja mutant Apaf1 protein is stable, yet does not possess apoptotic function in cell culture or in vivo assays. Mutant embryos die perinatally with defects in craniofacial and nervous system development, as well as reduced levels of apoptosis. We further investigated the defects in craniofacial development in the yautja mutation and found altered Sonic hedgehog (Shh) signaling between the prechordal plate and the frontonasal ectoderm, leading to increased mesenchymal proliferation in the face and delayed or absent ossification of the skull base. Taken together, our data highlight the time-sensitive link between Shh signaling and the regulation of apoptosis function in craniofacial development to sculpt the face. We propose that decreased apoptosis in the developing nervous system allows Shhproducing cells to persist and direct a lateral outgrowth of the upper jaw, resulting in the craniofacial defects we see. Finally, the novel yautja Apaf1 allele offers the first in vivo understanding of a stable Apaf1 protein that lacks a function, which should make a useful tool with which to explore the regulation of programmed cell death in mammals.

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Section: Resultssupporting

confidence: 88%

Section: Discussionsupporting

confidence: 58%

Section: Discussionmentioning

confidence: 53%

mentioning

confidence: 99%

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Apaf1 apoptotic function critically limits Sonic hedgehog signaling during craniofacial development

et al. 2013

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“…However, several studies have indicated that the NODAL pathway regulates ventral forebrain patterning through SHH-independent mechanisms (Rohr et al, 2001;Monuki, 2007). SHH might have to reach a threshold concentration to ensure proper forebrain development (Young et al, 2010). The dose-and stage-dependent relationship we observe here is consistent with a threshold effect: slightly reduced NODAL signaling might cause a small downregulation of SHH, which produces a HPE phenotype only when associated with another small decrease in SHH signaling.…”

supporting

confidence: 79%

NODAL and SHH dose-dependent double inhibition promotes an HPE-like phenotype in chick embryos

Mercier¹,

David²,

Ratié³

et al. 2013

Development

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The Genetics of Facial Morphology

Cole

Spritz

2017

Encyclopedia of Life Sciences

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Human facial morphology broadly encompasses several distinct facial structures that alone and together contain enormous variations which contribute to our physical identities as both individuals and members of families and populations. The human face comprises an assemblage of multifactorial complex traits, with clear genetic components and known environmental factors playing key roles in its development and maturation throughout life. Current understanding of the genes and pathways pertaining to normal facial development and morphology comes largely from research on craniofacial malformations in both humans and animal models. Recent advances in methodology for deriving accurate and precise facial traits have allowed for several large genomic studies that have provided new insights into the heritability and genes involved in normal facial variation. Continued research on the genetics of facial morphology will improve quantitative diagnosis, treatment and management of craniofacial syndromes, perhaps enabling us to one day model the human face from deoxyribonucleic acid (DNA). Key Concepts Understanding the genetics of normal human facial morphology and development provides insights relevant to the fields of both medicine and forensics. The known genes and signalling pathways that are involved in craniofacial development have mostly been identified through studies of craniofacial malformations and typically relate to the embryonic development of cranial neural crest cells. Quantifying normal human facial traits that are both accurate and precise is exceedingly important to understanding the genetic architecture of those traits. There exist numerous diverse quantitation methods for studying both the underlying facial skeleton and the overlying soft facial tissues. Overall, the human face is highly heritable. However, large differences in the study design and population attributes pertaining to age, ethnicity and environmental background have led to limited consistency in heritability estimates and genetic conclusions. Five genome‐wide association studies to date have identified largely non‐overlapping genome‐wide significant loci for normal facial morphology, with some of these located in or near genes previously implicated in rare craniofacial syndromes and/or facial development. Animal studies of facial development are a powerful tool both for identifying candidate genes and for functional analyses of candidate genes from human studies.

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Quantitative analyses link modulation of sonic hedgehog signaling to continuous variation in facial growth and shape

Cited by 126 publications

References 36 publications

Apaf1 apoptotic function critically limits Sonic hedgehog signaling during craniofacial development

Apaf1 apoptotic function critically limits Sonic hedgehog signaling during craniofacial development

NODAL and SHH dose-dependent double inhibition promotes an HPE-like phenotype in chick embryos

The Genetics of Facial Morphology

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