De novo mutations in inhibitors of Wnt, BMP, and Ras/ERK signaling pathways in non-syndromic midline craniosynostosis

Timberlake, Andrew T.; Furey, Charuta G.; Choi, Jungmin; Nelson‐Williams, Carol; Loring, Erin; Galm, Amy; Kahle, Kristopher T.; Steinbacher, Derek M.; Larysz, Dawid; Persing, John A.; Lifton, Richard P.

doi:10.1073/pnas.1709255114

Cited by 79 publications

(108 citation statements)

References 51 publications

(62 reference statements)

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“…The involvement of FGF (fibroblast growth factor), FGFR (fibroblast growth factor receptor), and MAPK/ERK signaling pathways in CRS has long been discussed in the literature (Marie et al, 2005; Shukla et al, 2007; Kim et al, 2015; Kosty and Vogel, 2015; Pfaff et al, 2016; Timberlake et al, 2017). However, our top hit gene-set is KEGG’s cancer pathway, and this link between CRS and cancer is to our knowledge rarely discussed in the literature.…”

Section: Resultsmentioning

confidence: 99%

“…These 17 new genes found through this process were added to the CRS genes list: AXIN2 (Yilmaz et al, 2018), BBS9 (Justice et al, 2012; Sewda et al, 2019), BCOR (O’Byrne et al, 2017) (for Oculo-facio-cardio-dental syndrome, or microphthalmia syndrome), BGLAP (Sowińska-Seidler et al, 2018), COLEC10 (for 3MC syndrome) (Munye et al, 2017), FGFRL1 (Rieckmann et al, 2009) (for Antley-Bixler syndrome), GCK (for Greig cephalopolysyndactyly syndrome) (Zung et al, 2011), LMNA (Sowińska-Seidler et al, 2018), PPP3CA (Mizuguchi et al, 2018), PTH2R (Kim et al, 2015), RAF1 (for Noonan syndrome with multiple lentigines, or leopard syndrome) (Rodríguez et al, 2019), SIX2 (for frontonasal dysplasia syndrome) (Hufnagel et al, 2016), SMURF1, SPRY1, SPRY4 (Timberlake et al, 2016, 2017), TCOF1 (for Treacher Collins syndrome) (Horiuchi et al, 2004), TNFRSF11B (for Juvenile Paget disease) (Saki et al, 2013).…”

Section: Resultsmentioning

confidence: 99%

“…Most of these genes are identified through a combination of family studies, candidate gene investigation, mouse model validation, etc. Recently, there are new strategies, such as GWAS (genome-wide association study) on common genetic variants (Justice et al, 2012), and exome sequencing followed by summing all rare variants (Timberlake et al, 2017). Without distinguishing different gene mapping methods, we proceed by a systematic search of all PUBMED titles/abstracts that contain the word of “craniosynostosis and “genetic, finding all gene names, then followed by a manual check of the original literature.…”

Section: Introductionmentioning

confidence: 99%

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A Higher Proportion of Craniosynostosis Genes Are Cancer Driver Genes

Misra

Shih

Yan

et al. 2019

Preprint

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Craniosynostosis (CRS) is a congenital abnormality deformity with a heterogenous genetic contribution. Previously, there are two attempts to collect genes that are genetically associated with craniosynostosis and some related syndromes with 57 (Twigg and Wilkie, 2015) and 39 (Goos and Mathijssen, 2019) genes identified, respectively. We expanded this list of craniosynostosis genes by adding another 17 genes with an updated literature search. These genes are shown to be more likely to be intolerant to functional mutations. Of these 113 craniosynostosis genes, 21 (19% vs. 1.5% baseline frequency) are cancer driver genes, a 14-fold enrichment. The cancer-craniosynostosis connection is further validated by an over-representation analysis of craniosynostosis genes in KEGG cancer pathway and several cancer related gene-sets. Many cancer-craniosynostosis overlapping genes participate in intracellular signaling pathways, which play a role in both development and cancer. This connection can be viewed from the oncogenesis recapitulates ontogenesis framework. Nineteen craniosynostosis genes are transcription factor genes (16.8% vs. 8.2% baseline), and craniosynostosis genes are also enriched in targets of certain transcription factors or micro RNAs.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Higher Proportion of Craniosynostosis Genes Are Cancer Driver Genes

Misra

Shih

Yan

et al. 2019

Preprint

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“…The investigation of signalling cues is very important for understanding the pathophysiology of craniosynostosis. A recent study, in fact, has identified a number of de novo mutations in negative regulators of the Wnt, BMP and Ras/ERK pathways, occurring in non-syndromic midline craniosynostosis patients 25 . These pathways, knowingly implicated in positive regulation of osteogenesis, are, among other signals previously studied 18 , good candidates for dura mater’s regulatory milieu in the context of suture patency and fusion.…”

Section: Discussionmentioning

confidence: 99%

The osteogenic potential of the neural crest lineage may contribute to craniosynostosis

Doro

Liu

Grigoriadis

et al. 2018

Preprint

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The craniofacial skeleton is formed from the neural crest and mesodermal lineages, both of which contribute mesenchymal precursors during formation of the skull bones. The large majority of cranial sutures also include a proportion of neural crest derived mesenchyme. While some studies have addressed the relative healing abilities of neural crest and mesodermal bone, relatively little attention has been paid to differences in intrinsic osteogenic potential. Here we use mouse models to compare neural crest osteoblasts (from frontal bones or dura mater) to mesodermal osteoblasts (from parietal bones). Using in vitro culture approaches we find that neural crest-derived osteoblasts readily generate bony nodules while mesodermal osteoblasts do so less efficiently. Furthermore, we find that co-culture of neural crest-derived osteoblasts with mesodermal osteoblasts is sufficient to nucleate ossification centres. All together, this suggests that the intrinsic osteogenic abilities of neural crest-derived mesenchyme may be a primary driver behind craniosynostosis.

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“…Genotyping of this SNP in the SMAD6 mutation-positive individuals provides strong evidence of epistatic interaction between SMAD6 and BMP2 . This 2-locus model is estimated to be the genetic cause in approximately 3.5% of all the craniosynostosis cases [Timberlake et al, 2016], and the results have been replicated by Timberlake et al [2017]. Activation of BMP receptors leads to phosphorylation of receptor SMADs, which can complex with SMAD4, translocate to the nucleus, and partner with RUNX2 to induce transcription of genes that promote osteoblast differentiation [Hata et al, 1998;Javed et al, 2008] as summarized by Timberlake et al [2016].…”

Section: Slc25a24mentioning

confidence: 93%

Genetic Causes of Craniosynostosis: An Update

Goos

Mathijssen²

2018

Mol Syndromol

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In 1993, Jabs et al. were the first to describe a genetic origin of craniosynostosis. Since this discovery, the genetic causes of the most common syndromes have been described. In 2015, a total of 57 human genes were reported for which there had been evidence that mutations were causally related to craniosynostosis. Facilitated by rapid technological developments, many others have been identified since then. Reviewing the literature, we characterize the most common craniosynostosis syndromes followed by a description of the novel causes that were identified between January 2015 and December 2017.

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De novo mutations in inhibitors of Wnt, BMP, and Ras/ERK signaling pathways in non-syndromic midline craniosynostosis

Cited by 79 publications

References 51 publications

A Higher Proportion of Craniosynostosis Genes Are Cancer Driver Genes

A Higher Proportion of Craniosynostosis Genes Are Cancer Driver Genes

The osteogenic potential of the neural crest lineage may contribute to craniosynostosis

Genetic Causes of Craniosynostosis: An Update

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