Clinical spectrum and outcomes in families with coronal synostosis and TCF12 mutations

Rocco, Federico Di; Baujat, Geneviève; Arnaud, Éric; Rénier, Dominique; Laplanche, Jean‐Louis; Cormier‐Daire, Valérie; Collet, Corinne

doi:10.1038/ejhg.2014.57

Cited by 38 publications

(39 citation statements)

References 7 publications

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“…The single largest contributor to these diagnoses is TCF12 , which encodes a partner protein of TWIST1 particularly critical for coronal suture development [27]. Two follow-up studies have confirmed the importance of TCF12 mutations in coronal craniosynostosis, both in the context of familial mutations [37], and in a more general screen of craniosynostosis [29]. Given the haploinsufficiency mechanism of TCF12 mutations, heterozygous deletions are also expected to be pathogenic and this has been confirmed in two reports [38, 39].…”

Section: Non-syndromic Craniosynostosismentioning

confidence: 99%

Clinical genetics of craniosynostosis

Wilkie

Johnson²,

Wall³

2017

Current Opinion in Pediatrics

154

169

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Purpose of review When providing accurate clinical diagnosis and genetic counselling in craniosynostosis, the challenge is heightened by knowledge that etiology in any individual case may be entirely genetic, entirely environmental, or anything in between. This review will scope out how recent genetic discoveries from next-generation sequencing have impacted on the clinical genetic evaluation of craniosynostosis. Recent findings Survey of a 13-year birth cohort of patients treated at a single craniofacial unit demonstrates that a genetic cause of craniosynostosis can be identified in one quarter of cases. The substantial contributions of mutations in two genes, TCF12 and ERF, is confirmed. Important recent discoveries are mutations of CDC45 and SMO in specific craniosynostosis syndromes, and of SMAD6 in non-syndromic midline synostosis. The added value of exome or whole genome sequencing in the diagnosis of difficult cases is highlighted. Summary Strategies to optimise clinical genetic diagnostic pathways by combining both targeted and next-generation sequencing are discussed. As well as improved genetic counselling, recent discoveries spotlight the important roles of signalling through the bone morphogenetic protein and hedgehog pathways in cranial suture biogenesis, as well as a key requirement for adequate cell division in suture maintenance.

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Section: Non-syndromic Craniosynostosismentioning

confidence: 99%

Clinical genetics of craniosynostosis

Wilkie

Johnson²,

Wall³

2017

Current Opinion in Pediatrics

154

169

View full text Add to dashboard Cite

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“…Although 81% of the individuals with TCF12 mutations presented with apparent cNCS, some of the affected individuals had developmental delays and dysmorphic features overlapping with the Saethre-Chotzen syndrome [Sharma et al, 2013]. More recently, the phenotypic spectrum of TCF12 mutations has been extended to include possible facial and limb anomalies, and intellectual disability [Di Rocco et al, 2014; Le Tanno et al, 2014; Paumard-Hernandez et al, 2015; Piard et al, 2015]. Based on these observations, it is reasonable to recommend TCF12 testing for all patients with cCS, with or without associated anomalies.…”

Section: Genetic Etiopathogenesis Of Craniosynostosismentioning

confidence: 99%

Genetic advances in craniosynostosis

Lattanzi

Barba

Pietro

et al. 2017

American J of Med Genetics Pt A

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Craniosynostosis, the premature ossification of one or more skull sutures, is a clinically and genetically heterogeneous congenital anomaly affecting approximately 1 in 2,500 live births. In most cases, it occurs as an isolated congenital anomaly, i.e. nonsyndromic craniosynostosis (NCS), the genetic and environmental causes of which remain largely unknown. Recent data suggest that at least some of the midline NCS cases may be explained by two loci inheritance. In approximately 25–30% of patients craniosynostosis presents as a feature of a genetic syndrome due to chromosomal defects or mutations in genes within interconnected signaling pathways. The aim of this review is to provide a detailed and comprehensive update on the genetic and environmental factors associated with NCS, integrating the scientific findings achieved during the last decade. Focus on the neurodevelopmental, imaging and treatment aspects of NCS is also provided.

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“…Facial growth appears not greatly affected ( Fig. 10 ) [Di Rocco et al, 2014;Goos et al, 2016]. The phenotype is variable, including non-penetrance of the TCF12 gene, which encodes a basic helix-loop-helix transcription factor [Sharma et al, 2013].…”

Section: Tcf12-related Craniosynostosismentioning

confidence: 99%

Syndromic Craniosynostosis: Complexities of Clinical Care

et al. 2019

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Patients with syndromic craniosynostosis have a molecularly identified genetic cause for the premature closure of their cranial sutures and associated facial and extra-cranial features. Their clinical complexity demands comprehensive management by an extensive multidisciplinary team. This review aims to marry genotypic and phenotypic knowledge with clinical presentation and management of the craniofacial syndromes presenting most frequently to the craniofacial unit at Great Ormond Street Hospital for Children NHS Foundation Trust.

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Clinical spectrum and outcomes in families with coronal synostosis and TCF12 mutations

Cited by 38 publications

References 7 publications

Clinical genetics of craniosynostosis

Clinical genetics of craniosynostosis

Genetic advances in craniosynostosis

Syndromic Craniosynostosis: Complexities of Clinical Care

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