Beckwith – wiedemann and iMAGe syndromes : two very different diseases caused by mutations on the same gene

Genomic imprinting is an epigenetically regulated mechanism leading to parental-origin allele-specific expression. Beckwith–Wiedemann syndrome (BWS) is an imprinting disease related to 11p15.5 genetic and epigenetic alterations, among them loss-of-function CDKN1C mutations. Intriguing is that CDKN1C gain-of-function variations were recently found in patients with IMAGe syndrome (intrauterine growth restriction, metaphyseal dysplasia, congenital adrenal hypoplasia, and genital anomalies). BWS and IMAGe share an imprinted mode of inheritance; familial analysis demonstrated the presence of the phenotype exclusively when the mutant CDKN1C allele is inherited from the mother. Interestingly, both IMAGe and BWS are characterized by growth disturbances, although with opposite clinical phenotypes; IMAGe patients display growth restriction whereas BWS patients display overgrowth. CDKN1C codifies for CDKN1C/KIP2, a nuclear protein and potent tight-binding inhibitor of several cyclin/Cdk complexes, playing a role in maintenance of the nonproliferative state of cells. The mirror phenotype of BWS and IMAGe can be, at least in part, explained by the effect of mutations on protein functions. All the IMAGe-associated mutations are clustered in the proliferating cell nuclear antigen-binding domain of CDKN1C and cause a dramatic increase in the stability of the protein, which probably results in a functional gain of growth inhibition properties. In contrast, BWS mutations are not clustered within a single domain, are loss-of-function, and promote cell proliferation. CDKN1C is an example of allelic heterogeneity associated with opposite syndromes.

[1]  T. Ogata,et al.  IMAGe syndrome: clinical and genetic implications based on investigations in three Japanese patients , 2014, Clinical endocrinology.

[2]  A. Jeltsch,et al.  Genomic imprinting--the struggle of the genders at the molecular level. , 2013, Angewandte Chemie.

[3]  M. Vazquez,et al.  Beckwith-Wiedemann Syndrome: Growth Pattern and Tumor Risk according to Molecular Mechanism, and Guidelines for Tumor Surveillance , 2013, Hormone Research in Paediatrics.

[4]  M. Nakanishi,et al.  Increased Protein Stability of CDKN1C Causes a Gain-of-Function Phenotype in Patients with IMAGe Syndrome , 2013, PloS one.

[5]  C. Augello,et al.  Quantitative DNA methylation analysis improves epigenotype-phenotype correlations in Beckwith-Wiedemann syndrome , 2013, Epigenetics.

[6]  H. Soejima,et al.  Epigenetic and genetic alterations of the imprinting disorder Beckwith–Wiedemann syndrome and related disorders , 2013, Journal of Human Genetics.

[7]  R. Weksberg,et al.  Molecular Findings in Beckwith–Wiedemann Syndrome , 2013, American journal of medical genetics. Part C, Seminars in medical genetics.

[8]  E. Maher,et al.  An imprinted IMAGe: insights into growth regulation through genomic analysis of a rare disease , 2012, Genome Medicine.

[9]  S. Nelson,et al.  Mutations in the PCNA-binding domain of CDKN1C cause IMAGE Syndrome , 2012, Nature Genetics.

[10]  H. Ardinger,et al.  CDKN1C mutations and genital anomalies , 2012, American journal of medical genetics. Part A.

[11]  S. Perrotta,et al.  p57Kip2 and Cancer: Time for a Critical Appraisal , 2011, Molecular Cancer Research.

[12]  Diana S. Johnson,et al.  IMAGe syndrome: Case report with a previously unreported feature and review of published literature , 2010, American journal of medical genetics. Part A.

[13]  D. Bick,et al.  Is it the patient or the IVF? Beckwith-Wiedemann syndrome in both spontaneous and assisted reproductive conceptions. , 2010, Fertility and sterility.

[14]  J. Wesselink,et al.  CDKN1C (p57Kip2) analysis in Beckwith–Wiedemann syndrome (BWS) patients: Genotype–phenotype correlations, novel mutations, and polymorphisms , 2010, American journal of medical genetics. Part A.

[15]  I. Cetin,et al.  Epigenetic modulation of the IGF2/H19 imprinted domain in human embryonic and extra-embryonic compartments and its possible role in fetal growth restriction , 2010, Epigenetics.

[16]  R. Weksberg,et al.  Beckwith–Wiedemann syndrome , 2010, European Journal of Human Genetics.

[17]  A. Westerveld,et al.  Lessons from BWS twins: complex maternal and paternal hypomethylation and a common source of haematopoietic stem cells , 2009, European Journal of Human Genetics.

[18]  P. Lapunzina,et al.  CDKN1C mutations in HELLP/preeclamptic mothers of Beckwith-Wiedemann Syndrome (BWS) patients. , 2009, Placenta.

[19]  C. Clericuzio,et al.  Diagnostic criteria and tumor screening for individuals with isolated hemihyperplasia , 2009, Genetics in Medicine.

[20]  G. Nishimura,et al.  Radiological evolution in IMAGe association: A case report , 2008, American journal of medical genetics. Part A.

[21]  R. Weksberg,et al.  Beckwith‐Wiedemann syndrome in adults: Observations from one family and recommendations for care , 2008, American journal of medical genetics. Part A.

[22]  Meredith Wilson,et al.  The clinical phenotype of mosaicism for genome‐wide paternal uniparental disomy: Two new reports , 2008, American journal of medical genetics. Part A.

[23]  D. Amor,et al.  Tumour surveillance in Beckwith–Wiedemann syndrome and hemihyperplasia: A critical review of the evidence and suggested guidelines for local practice , 2006, Journal of paediatrics and child health.

[24]  S. Marx Molecular genetics of multiple endocrine neoplasia types 1 and 2 , 2005, Nature Reviews Cancer.

[25]  M. Cohen,et al.  Beckwith-Wiedemann Syndrome: Historical, Clinicopathological, and Etiopathogenetic Perspectives , 2005, Pediatric and developmental pathology : the official journal of the Society for Pediatric Pathology and the Paediatric Pathology Society.

[26]  S. Testelin,et al.  Cleft Palate and Beckwith-Wiedemann Syndrome , 2005, The Cleft palate-craniofacial journal : official publication of the American Cleft Palate-Craniofacial Association.

[27]  J. Halliday,et al.  Beckwith-Wiedemann syndrome and IVF: a case-control study. , 2004, American journal of human genetics.

[28]  M. Zacharin,et al.  IMAGe syndrome: a complex disorder affecting growth, adrenal and gonadal function, and skeletal development. , 2004, The Journal of pediatrics.

[29]  J. Haines,et al.  Wiedemann-Beckwith syndrome: presentation of clinical and cytogenetic data on 22 new cases and review of the literature , 1986, Human Genetics.

[30]  H. Wiedemann Tumours and hemihypertrophy associated with Wiedemann-Beckwith syndrome , 1983, European Journal of Pediatrics.

[31]  M. Faddy,et al.  Rare congenital disorders, imprinted genes, and assisted reproductive technology , 2003, The Lancet.

[32]  Giuseppe Simoni,et al.  The Role of Imprinted Genes in Fetal Growth , 2002, Neonatology.

[33]  R. Weksberg,et al.  Tumor development in the Beckwith-Wiedemann syndrome is associated with a variety of constitutional molecular 11p15 alterations including imprinting defects of KCNQ1OT1. , 2001, Human molecular genetics.

[34]  J. Ruijter,et al.  Increased tumour risk for BWS patients correlates with aberrant H19 and not KCNQ1OT1 methylation: occurrence of KCNQ1OT1 hypomethylation in familial cases of BWS. , 2001, Human molecular genetics.

[35]  J. Batch,et al.  Hyperinsulinism and Beckwith-Wiedemann syndrome , 2001, Archives of disease in childhood. Fetal and neonatal edition.

[36]  M. Kay,et al.  IMAGe, a new clinical association of intrauterine growth retardation, metaphyseal dysplasia, adrenal hypoplasia congenita, and genital anomalies. , 1999, The Journal of clinical endocrinology and metabolism.

[37]  W. Reik,et al.  Analysis of germline CDKN1C (p57KIP2) mutations in familial and sporadic Beckwith-Wiedemann syndrome (BWS) provides a novel genotype-phenotype correlation , 1999, Journal of medical genetics.

[38]  M. Tucker,et al.  Risk of cancer during the first four years of life in children from The Beckwith-Wiedemann Syndrome Registry. , 1998, The Journal of pediatrics.

[39]  Y. Fukushima,et al.  An imprinted gene p57KIP2 is mutated in Beckwith–Wiedemann syndrome , 1996, Nature Genetics.

[40]  A. Feinberg,et al.  Imprinting of the gene encoding a human cyclin-dependent kinase inhibitor, p57KIP2, on chromosome 11p15. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[41]  H. Matsuura,et al.  Anesthetic considerations of two sisters with Beckwith-Wiedemann syndrome. , 1996, Anesthesia progress.

[42]  T. Mukai,et al.  Genomic imprinting of p57KIP2, a cyclin–dependent kinase inhibitor, in mouse , 1995, Nature Genetics.

[43]  J. Graham,et al.  Longitudinal observations on 15 children with Wiedemann-Beckwith syndrome. , 1995, American journal of medical genetics.

[44]  J. Massagué,et al.  Cloning of p57KIP2, a cyclin-dependent kinase inhibitor with unique domain structure and tissue distribution. , 1995, Genes & development.

[45]  I. Temple,et al.  Clinical features and natural history of Beckwith‐Wiedemann syndrome: presentation of 74 new cases , 1994, Clinical genetics.

[46]  D. Chitayat,et al.  Neuroblastoma in a child with Wiedemann-Beckwith syndrome. , 1990, American journal of medical genetics.

[47]  M. Bene [The Wiedemann-Beckwith syndrome]. , 1978, Revista de pediatrie, obstetrica si ginecologie. Pediatria.

[48]  G. Gemme,et al.  [Beckwith-Wiedemann syndrome. Presentation of 5 cases]. , 1975, Minerva pediatrica.

[49]  Nan Faion T. Wu,et al.  The Beckwith-Wiedemann Syndrome , 1974, Clinical pediatrics.