Molecular analysis expands the spectrum of phenotypes associated with GLI3 mutations

Johnston, Jennifer J.; Sapp, Julie C.; Turner, Joyce; Amor, David J.; Aftimos, Salim; Aleck, Kyrieckos; Bocian, Maureen; Bodurtha, Joann; Cox, Gerald F.; Curry, Cynthia J.; Day, Ruth; Donnai, Dian; Field, Michael; Fujiwara, Ikuma; Gabbett, Michael T.; Gal, Moran; Graham, John M.; Hedera, Peter; Hennekam, Raoul C. M.; Hersh, Joseph H.; Hopkin, Robert J.; Kayserili, Hülya; Kidd, Alexa; Kimonis, Virginia; Lin, Angela E.; Lynch, Sally Ann; Maisenbacher, Melissa; Mansour, Sahar; McGaughran, Julie; Mehta, Lakshmi; Murphy, Helen; Raygada, Margarita; Robin, Nathaniel H.; Rope, Alan F.; Rosenbaum, Kenneth N.; Schaefer, Gerald; Shealy, Amy; Smith, Wendy E.; Soller, Maria; Sommer, Annmarie; Stalker, Heather J.; Steiner, Bernhard; Stephan, Mark J.; Tilstra, David; Tomkins, Susan; Trapane, Pamela; Tsai, Anne Chun Hui; Allen, Margot I. Van; Vasudevan, Pradeep; Zabel, Bernhard; Zunich, Janice; Black, Graeme C M; Biesecker, Leslie G.

doi:10.1002/humu.21328

Cited by 113 publications

(154 citation statements)

References 36 publications

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“…22 Interestingly, corpus callosum anomalies were found in nine patients, including seven patients with a truncating mutation located in the third end of GLI3. In the two previous series reported by Johnston et al,9,10 four GCPS patients with corpus callosum dysgenesis were also carrying a GLI3 truncating mutation lying in the C-terminal domain of the protein further confirming our finding that corpus callosum dysgenesis is fully part of GCPS spectrum and is mainly caused by terminal truncating mutations. Overlapping features with acrocallosal syndrome (ACLS, MIM# 200990) associating callosal dysgenesis, hypertelorism, intellectual disability and PD 23 are explained by an impaired GLI3 processing in patients with KIF7 mutations.…”

Section: Discussionsupporting

confidence: 90%

“…24 Facial dysmorphism, as well as vermis dysgenesis with brainstem anomalies (molar tooth sign), strongly indicated the diagnosis of ACLS. Conversely, two GLI3 mutated cases with corpus callosum dysgenesis have been reported as ACLS 25,26 and a third similar patient has been reported by Johnston et al 10 All three mutations were missense and clustered in the same region between aa 903 and 934 suggesting a potential severe phenotype associated with alterations of this region. Whatever, mutation analysis in both genes is therefore essential as the distinction between these two syndromes is of obvious significance for genetic counseling considering the difference in heredity and neurodevelopmental outcome and patients with a GLI3 mutation may be diagnosed as GCPS.…”

Section: Discussionmentioning

confidence: 78%

“…8 Previous reports demonstrate a robust genotype-phenotype correlation of GLI3 mutations. 9,10 Truncating mutations in the middle third of the gene generally cause PHS, resulting in a constitutive repressor protein. By contrast, haploinsufficiency resulting from chromosomal rearrangements, but also missense, splicing or truncating mutations elsewhere in the gene cause GCPS by loss of the DNA-binding capacity 11 or activation of nonsense-mediated mRNA decay, 12 or by the formation of an unstable or mislocalized protein.…”

Section: Introductionmentioning

confidence: 99%

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New insights into genotype–phenotype correlation for GLI3 mutations

et al. 2014

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The phenotypic spectrum of GLI3 mutations includes autosomal dominant Greig cephalopolysyndactyly syndrome (GCPS) and Pallister-Hall syndrome (PHS). PHS was first described as a lethal condition associating hypothalamic hamartoma, postaxial or central polydactyly, anal atresia and bifid epiglottis. Typical GCPS combines polysyndactyly of hands and feet and craniofacial features. Genotype-phenotype correlations have been found both for the location and the nature of GLI3 mutations, highlighting the bifunctional nature of GLI3 during development. Here we report on the molecular and clinical study of 76 cases from 55 families with either a GLI3 mutation (49 GCPS and 21 PHS), or a large deletion encompassing the GLI3 gene (6 GCPS cases). Most of mutations are novel and consistent with the previously reported genotype-phenotype correlation. Our results also show a correlation between the location of the mutation and abnormal corpus callosum observed in some patients with GCPS. Fetal PHS observations emphasize on the possible lethality of GLI3 mutations and extend the phenotypic spectrum of malformations such as agnathia and reductional limbs defects. GLI3 expression studied by in situ hybridization during human development confirms its early expression in target tissues.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionmentioning

confidence: 78%

Section: Introductionmentioning

confidence: 99%

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New insights into genotype–phenotype correlation for GLI3 mutations

et al. 2014

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“…Our findings herein that the FG and Lujan mutations in MED12 also elicit aberrant GLI3-dependent SHH signaling not only suggests an additional basis for cognitive dysfunction through altered brain development (30,31), but may further explain a broad range of clinically diverse non-CNS phenotypes associated with these syndromal disorders. In this regard, many of the digit, craniofacial, corpus callosal, and anorectal malformations that typify FG and/or Lujan syndromes are similarly observed, to varying extents, in congenital anomaly syndromes (GCPS and PHS) arising from mutations in GLI3 (14,32,33). Thus, mutagenic impairment of two interacting components within a common signaling pathway could serve to explain the phenotypic overlap observed in these monogenic syndromes.…”

Section: Discussionmentioning

confidence: 99%

“…However, the underlying basis by which genetic disruption of MED12 elicits the broad spectrum of clinical phenotypes observed in FG and Lujan syndromes remains unknown. Notably, several phenotypes associated with FG and/or Lujan syndromes including macrocephaly, corpus callosal defects, hypertolerism, syndactyly, and cognitive impairment, overlap with a subset of those variously appearing in Greig cephalopolysyndactyly syndrome (GCPS) and/or Pallister-Hall syndrome (PHS) arising from mutations in GLI3, a Sonic Hedgehog (SHH) signaling effector and direct interaction target of MED12 (12,14).…”

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confidence: 99%

MED12 mutations link intellectual disability syndromes with dysregulated GLI3-dependent Sonic Hedgehog signaling

Zhou

Spaeth

Kim

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Recurrent missense mutations in the RNA polymerase II Mediator subunit MED12 are associated with X-linked intellectual disability (XLID) and multiple congenital anomalies, including craniofacial, musculoskeletal, and behavioral defects in humans with FG (or Opitz-Kaveggia) and Lujan syndromes. However, the molecular mechanism(s) underlying these phenotypes is poorly understood. Here we report that MED12 mutations R961W and N1007S causing FG and Lujan syndromes, respectively, disrupt a Mediator-imposed constraint on GLI3-dependent Sonic Hedgehog (SHH) signaling. We show that the FG/R961W and Lujan/N1007S mutations disrupt the gene-specific association of MED12 with a second Mediator subunit, CDK8, identified herein to be a suppressor of GLI3 transactivation activity. In FG/R961W and Lujan/N1007S patient-derived cells, we document enhanced SHH pathway activation and GLI3-target gene induction coincident with impaired recruitment of CDK8 onto promoters of GLI3-target genes, but not non-GLI3-target genes. Together, these findings suggest that dysregulated GLI3-dependent SHH signaling contributes to phenotypes of individuals with FG and Lujan syndromes and further reveal a basis for the gene-specific manifestation of pathogenic mutations in a global transcriptional coregulator.

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GLI Proteins in Human Genetic Disease

Zhulyn

Hui

2012

Encyclopedia of Life Sciences

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GLI1, GLI2 and GLI3 transcription factors are the key effectors of mammalian Hedgehog signalling. Mutations in these transcription factors are implicated in severe congenital malformations and malignancies in humans and in mice. Analysis of mouse models has revealed that the patterning and development of multiple organ systems is dependent on a tightly regulated balance of Gli activator and repressor activity. Consequently, mutations in the Hh pathway machinery that affect Gli function or processing result in phenotypes with a striking resemblance to GLI‐associated disorders. The primary cilium was identified as a critical component of Hh signalling due to the phenotypic overlap between Hh‐pathway mutants and mice with defects in ciliogenesis. Many mutations in genes regulating cilia structure and function have been identified in human ciliopathies. This new class of diseases shares significant phenotypic overlap with GLI‐related syndromes. Phenotypic analysis of mice with compromised cilia function has revealed new aspects of Gli regulation demonstrating the utility of mouse models in the characterisation of novel disease phenotypes. Key Concepts: Balance of GLI activator and repressor is required for normal development. Shift of the balance towards low or high GLI3R levels results in severe congenital malformations. Shift of the balance towards high GLI activator results in cancer. Mutations affecting different domains of bifunctional transcription factor Gli3 give rise to distinct phenotypes. Mutations affecting Hh pathway machinery affect Gli processing and activity and result in Gli‐related phenotypes. The primary cilium is critical for Hh signal transduction. Mutations in regulators of primary cilia structure and function result in ciliopathies, which share many overlapping phenotypes with GLI‐associated syndromes.

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Molecular analysis expands the spectrum of phenotypes associated with GLI3 mutations

Cited by 113 publications

References 36 publications

New insights into genotype–phenotype correlation for GLI3 mutations

New insights into genotype–phenotype correlation for GLI3 mutations

MED12 mutations link intellectual disability syndromes with dysregulated GLI3-dependent Sonic Hedgehog signaling

GLI Proteins in Human Genetic Disease

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