Clinical genetics of craniosynostosis

Purpose of review When providing accurate clinical diagnosis and genetic counseling 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 nonsyndromic midline synostosis. The added value of exome or whole genome sequencing in the diagnosis of difficult cases is highlighted. Summary Strategies to optimize clinical genetic diagnostic pathways by combining both targeted and next-generation sequencing are discussed. In addition to improved genetic counseling, recent discoveries spotlight the important roles of signaling 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.

[1]  Emmanuel Messas,et al.  Candidate Gene Resequencing in a Large Bicuspid Aortic Valve-Associated Thoracic Aortic Aneurysm Cohort: SMAD6 as an Important Contributor , 2017, Front. Physiol..

[2]  E. Zackai,et al.  Tracheal cartilaginous sleeves in children with syndromic craniosynostosis , 2016, Genetics in Medicine.

[3]  G. Shaw,et al.  Fetal constraint as a potential risk factor for craniosynostosis , 2010, American journal of medical genetics. Part A.

[4]  P. Lapunzina,et al.  Expanding the mutation spectrum in 182 Spanish probands with craniosynostosis: identification and characterization of novel TCF12 variants , 2014, European Journal of Human Genetics.

[5]  J. Hurst,et al.  Diagnostic value of exome and whole genome sequencing in craniosynostosis , 2016, Journal of Medical Genetics.

[6]  S. Knight,et al.  Prevalence and Complications of Single-Gene and Chromosomal Disorders in Craniosynostosis , 2010, Pediatrics.

[7]  T. Ho,et al.  Abstract 5: The Suture Provides a Niche for Mesenchymal Stem Cells of Craniofacial Bones , 2015 .

[8]  J. Hurst,et al.  Etiological heterogeneity and clinical characteristics of metopic synostosis: Evidence from a tertiary craniofacial unit , 2010, American journal of medical genetics. Part A.

[9]  C. Bonaïti‐pellié,et al.  Genetic study of nonsyndromic coronal craniosynostosis. , 1995, American journal of medical genetics.

[10]  A. Drousiotou,et al.  A Novel Large Deletion Encompassing the Whole of the Galactose-1-Phosphate Uridyltransferase (GALT) Gene and Extending into the Adjacent Interleukin 11 Receptor Alpha (IL11RA) Gene Causes Classic Galactosemia Associated with Additional Phenotypic Abnormalities. , 2014, JIMD reports.

[11]  O. Adetayo,et al.  Craniosynostosis and Guanine Nucleotide-binding Protein Alpha Stimulating Mutation: Risk of Bleeding Diathesis and Circulatory Collapse in Patients Undergoing Cranial Vault Reconstruction , 2017, The Journal of craniofacial surgery.

[12]  H. Skirton,et al.  A Qualitative Study to Explore the Views and Attitudes towards Prenatal Testing in Adults Who Have Muenke Syndrome and their Partners , 2017, Journal of Genetic Counseling.

[13]  Alexander Kanapin,et al.  Mutations in TCF12, encoding a basic helix-loop-helix partner of TWIST1, are a frequent cause of coronal craniosynostosis , 2013, Nature Genetics.

[14]  A. Hoischen,et al.  Mutations in the interleukin receptor IL11RA cause autosomal recessive Crouzon-like craniosynostosis , 2013, Molecular genetics & genomic medicine.

[15]  E. Giannoulatou,et al.  Visualizing the origins of selfish de novo mutations in individual seminiferous tubules of human testes , 2016, Proceedings of the National Academy of Sciences.

[16]  D. Rizopoulos,et al.  Increase of prevalence of craniosynostosis. , 2016, Journal of cranio-maxillo-facial surgery : official publication of the European Association for Cranio-Maxillo-Facial Surgery.

[17]  O. Sarig,et al.  Segmental basal cell naevus syndrome caused by an activating mutation in smoothened , 2016, The British journal of dermatology.

[18]  A. Wilkie,et al.  Paternal age effect mutations and selfish spermatogonial selection: causes and consequences for human disease. , 2012, American journal of human genetics.

[19]  S. Twigg,et al.  A Genetic-Pathophysiological Framework for Craniosynostosis. , 2015, American journal of human genetics.

[20]  J. Laplanche,et al.  Clinical spectrum and outcomes in families with coronal synostosis and TCF12 mutations , 2014, European Journal of Human Genetics.

[21]  Hongyu Zhao,et al.  Two locus inheritance of non-syndromic midline craniosynostosis via rare SMAD6 and common BMP2 alleles , 2016, eLife.

[22]  Jeremy C. Sinkin,et al.  Genetic and Epigenetic Influences of Twins on the Pathogenesis of Craniosynostosis: A Meta-Analysis , 2012, Plastic and reconstructive surgery.

[23]  F. Brunelle,et al.  Skull base morphology in fibroblast growth factor receptor type 2-related faciocraniosynostosis: a descriptive analysis. , 2015, Neurosurgery.

[24]  K. Lyons,et al.  Bent bone dysplasia-FGFR2 type, a distinct skeletal disorder, has deficient canonical FGF signaling. , 2012, American journal of human genetics.

[25]  K. Lyons,et al.  Cell mixing at a neural crest-mesoderm boundary and deficient ephrin-Eph signaling in the pathogenesis of craniosynostosis. , 2006, Human molecular genetics.

[26]  Alexander F. Wilson,et al.  A genome-wide association study identifies susceptibility loci for nonsyndromic sagittal craniosynostosis near BMP2 and within BBS9 , 2012, Nature Genetics.

[27]  R. Keating,et al.  Progressive postnatal pansynostosis: an insidious and pernicious form of craniosynostosis. , 2015, Journal of neurosurgery. Pediatrics.

[28]  G. Bejerano,et al.  Chitayat syndrome: hyperphalangism, characteristic facies, hallux valgus and bronchomalacia results from a recurrent c.266A>G p.(Tyr89Cys) variant in the ERF gene , 2016, Journal of Medical Genetics.

[29]  E. Zackai,et al.  Beare–Stevenson syndrome: Two new patients, including a novel finding of tracheal cartilaginous sleeve , 2015, American journal of medical genetics. Part A.

[30]  Daniele Merico,et al.  Molecular Diagnostic Yield of Chromosomal Microarray Analysis and Whole-Exome Sequencing in Children With Autism Spectrum Disorder. , 2015, JAMA.

[31]  S. Knight,et al.  Identification of Intragenic Exon Deletions and Duplication of TCF12 by Whole Genome or Targeted Sequencing as a Cause of TCF12‐Related Craniosynostosis , 2016, Human mutation.

[32]  S. Iseki,et al.  Tissue origins and interactions in the mammalian skull vault. , 2002, Developmental biology.

[33]  A. Elliott,et al.  Clinical and radiographic delineation of Bent Bone Dysplasia‐FGFR2 type or Bent Bone Dysplasia with Distinctive Clavicles and Angel‐shaped Phalanges , 2016, American journal of medical genetics. Part A.

[34]  M. Barba,et al.  Genetic advances in craniosynostosis , 2017, American journal of medical genetics. Part A.

[35]  B. Keavney,et al.  Nonsynonymous variants in the SMAD6 gene predispose to congenital cardiovascular malformation , 2012, Human mutation.

[36]  A. Wilkie,et al.  Cellular evidence for selfish spermatogonial selection in aged human testes , 2014, Andrology.

[37]  A. Wilkie,et al.  Gonadal mosaicism and non‐invasive prenatal diagnosis for ‘reassurance’ in sporadic paternal age effect (PAE) disorders , 2017, Prenatal diagnosis.

[38]  S. Cortnum,et al.  Raised intracranial pressure as a result of pansynostosis in a child with Albright’s hereditary osteodystrophy , 2017, Child's Nervous System.

[39]  D. Krakow,et al.  Bent bone dysplasia syndrome reveals nucleolar activity for FGFR2 in ribosomal DNA transcription. , 2014, Human molecular genetics.

[40]  Andrew J. Hill,et al.  Analysis of protein-coding genetic variation in 60,706 humans , 2015, bioRxiv.

[41]  A. Wilkie,et al.  TCF12 microdeletion in a 72‐year‐old woman with intellectual disability , 2015, American journal of medical genetics. Part A.

[42]  E. Mornet Hypophosphatasia. , 2007, Orphanet journal of rare diseases.

[43]  D. Horn,et al.  A Recurrent Mosaic Mutation in SMO, Encoding the Hedgehog Signal Transducer Smoothened, Is the Major Cause of Curry-Jones Syndrome. , 2016, American journal of human genetics.

[44]  J. Zins,et al.  Opinion Leaders and Evidence-Based Medicine in Craniofacial Surgery , 2014, The Journal of craniofacial surgery.

[45]  J. Richtsmeier,et al.  Mutation Screening of Candidate Genes in Patients with Nonsyndromic Sagittal Craniosynostosis , 2016, Plastic and reconstructive surgery.

[46]  S. Bowdin,et al.  Heterozygous mutations in ERF cause syndromic craniosynostosis with multiple suture involvement , 2015, American journal of medical genetics. Part A.

[47]  C. Forrest,et al.  Craniofacial Syndromes and Surgery , 2013, Plastic and reconstructive surgery.

[48]  R. Marcucio,et al.  FGFR‐associated craniosynostosis syndromes and gastrointestinal defects , 2016, American journal of medical genetics. Part A.

[49]  A. Wilkie,et al.  A novel mutation, Ala315Ser, in FGFR2: a gene–environment interaction leading to craniosynostosis? , 2000, European Journal of Human Genetics.

[50]  T. Vogel,et al.  Insights into the development of molecular therapies for craniosynostosis. , 2015, Neurosurgical focus.

[51]  M. Proctor,et al.  X-linked hypophosphatemic rickets and sagittal craniosynostosis: three patients requiring operative cranial expansion: case series and literature review , 2016, Child's Nervous System.

[52]  D. David,et al.  The ophthalmic sequelae of Pfeiffer syndrome and the long-term visual outcomes after craniofacial surgery. , 2016, Journal of AAPOS : the official publication of the American Association for Pediatric Ophthalmology and Strabismus.

[53]  Sven Kreiborg,et al.  Inactivation of IL11 signaling causes craniosynostosis, delayed tooth eruption, and supernumerary teeth. , 2011, American journal of human genetics.

[54]  Takashi Iezaki,et al.  Genetic analysis of Runx2 function during intramembranous ossification , 2016, Development.

[55]  W. Hsu,et al.  Stem cells of the suture mesenchyme in craniofacial bone development, repair and regeneration , 2016, Nature Communications.

[56]  E. Zackai,et al.  Mutations in CDC45, Encoding an Essential Component of the Pre-initiation Complex, Cause Meier-Gorlin Syndrome and Craniosynostosis. , 2016, American journal of human genetics.

[57]  S. Bickler,et al.  Gastrointestinal disorders in Curry–Jones syndrome: Clinical and molecular insights from an affected newborn , 2017, American journal of medical genetics. Part A.

[58]  Yonit A. Addissie,et al.  Muenke syndrome: An international multicenter natural history study , 2016, American journal of medical genetics. Part A.

[59]  A. Rasmussen,et al.  Expansion of the variable expression of Muenke syndrome: Hydrocephalus without craniosynostosis , 2016, American journal of medical genetics. Part A.

[60]  S. Knight,et al.  Reduced dosage of ERF causes complex craniosynostosis in humans and mice and links ERK1/2 signaling to regulation of osteogenesis , 2013, Nature Genetics.

[61]  C. Loomis,et al.  Regulation of cranial morphogenesis and cell fate at the neural crest-mesoderm boundary by engrailed 1 , 2012, Development.

[62]  Alexander F. Wilson,et al.  A genome wide association study identifies susceptibility loci for nonsyndromic sagittal craniosynostosis near BMP 2 and within BBS 9 , 2012 .