TY - JOUR
T1 - Comprehensive EHMT1 variants analysis broadens genotype-phenotype associations and molecular mechanisms in Kleefstra syndrome
AU - Rots, Dmitrijs
AU - Bouman, Arianne
AU - Yamada, Ayumi
AU - Levy, Michael
AU - Dingemans, Alexander J.M.
AU - de Vries, Bert B.A.
AU - Ruiterkamp-Versteeg, Martina
AU - de Leeuw, Nicole
AU - Ockeloen, Charlotte W.
AU - Pfundt, Rolph
AU - de Boer, Elke
AU - Kummeling, Joost
AU - van Bon, Bregje
AU - van Bokhoven, Hans
AU - Kasri, Nael Nadif
AU - Venselaar, Hanka
AU - Alders, Marielle
AU - Kerkhof, Jennifer
AU - McConkey, Haley
AU - Kuechler, Alma
AU - Elffers, Bart
AU - van Beeck Calkoen, Rixje
AU - Hofman, Susanna
AU - Smith, Audrey
AU - Valenzuela, Maria Irene
AU - Srivastava, Siddharth
AU - Frazier, Zoe
AU - Maystadt, Isabelle
AU - Piscopo, Carmelo
AU - Merla, Giuseppe
AU - Balasubramanian, Meena
AU - Santen, Gijs W.E.
AU - Metcalfe, Kay
AU - Park, Soo Mi
AU - Pasquier, Laurent
AU - Banka, Siddharth
AU - Donnai, Dian
AU - Weisberg, Daniel
AU - Strobl-Wildemann, Gertrud
AU - Wagemans, Annemieke
AU - Vreeburg, Maaike
AU - Baralle, Diana
AU - Foulds, Nicola
AU - Scurr, Ingrid
AU - Brunetti-Pierri, Nicola
AU - van Hagen, Johanna M.
AU - Bijlsma, Emilia K.
AU - Hakonen, Anna H.
AU - Vanhoutte, Els K.
AU - Brunner, Han G.
AU - Et al.
AU - Shinkai, Yoichi
AU - Kleefstra, Tjitske
N1 - Funding Information:
This work was supported by Aspasia grant of the Dutch Research Council (015.014.036 to T.K.), the Netherlands Organisation for Health Research and Development grants (10250022110003 to T.K. and Arianne Bouman and 91718310 to T.K.). These results contribute to the overall goals of the Solve-RD project, which has received funding from the European Union's Horizon 2020 research and innovation program under grant agreement no. 779257 (L.E.L.M.V. T.K. H.G.B. and S.B.). Several authors of this publication are members of the European Reference Network on Rare Congenital Malformations and Rare Intellectual Disability ERN-ITHACA (EU Framework Partnership Agreement ID: 3HP-HP-FPA ERN-01-2016/739516). S.B. acknowledges the support of the NIHR Manchester Biomedical Research Centre (NIHR203308) and the MRC Epigenomics of Rare Diseases Node (MR/Y008170/1). We thank the GeneDx, Deciphering Developmental Delay (DDD) for providing the individuals, samples, and/or molecular diagnostic data. We thank Michael Kwint for the technical assistance. We thank Wendy Hocking for reaching the KLEFS1 community. A.M.M. is an employee of GeneDx, LLC. B.S. is a shareholder in EpiSign Inc. a biotechnology company involved in commercialization of EpiSign technology.
Funding Information:
This work was supported by Aspasia grant of the Dutch Research Council ( 015.014.036 to T.K.), the Netherlands Organisation for Health Research and Development grants ( 10250022110003 to T.K. and A.B. and 91718310 to T.K.).
Funding Information:
S.B. acknowledges the support of the NIHR Manchester Biomedical Research Centre ( NIHR203308 ) and the MRC Epigenomics of Rare Diseases Node ( MR/Y008170/1 ). We thank the GeneDx, Deciphering Developmental Delay (DDD) for providing the individuals, samples, and/or molecular diagnostic data. We thank Michael Kwint for the technical assistance. We thank Wendy Hocking for reaching the KLEFS1 community.
Funding Information:
These results contribute to the overall goals of the Solve-RD project, which has received funding from the European Union\u2019s Horizon 2020 research and innovation program under grant agreement no. 779257 (L.E.L.M.V., T.K., H.G.B., and S.B.). Several authors of this publication are members of the European Reference Network on Rare Congenital Malformations and Rare Intellectual Disability ERN-ITHACA (EU Framework Partnership Agreement ID: 3HP-HP-FPA ERN-01-2016/739516).
Publisher Copyright:
© 2024 American Society of Human Genetics
PY - 2024/8/8
Y1 - 2024/8/8
N2 - The shift to a genotype-first approach in genetic diagnostics has revolutionized our understanding of neurodevelopmental disorders, expanding both their molecular and phenotypic spectra. Kleefstra syndrome (KLEFS1) is caused by EHMT1 haploinsufficiency and exhibits broad clinical manifestations. EHMT1 encodes euchromatic histone methyltransferase-1—a pivotal component of the epigenetic machinery. We have recruited 209 individuals with a rare EHMT1 variant and performed comprehensive molecular in silico and in vitro testing alongside DNA methylation (DNAm) signature analysis for the identified variants. We (re)classified the variants as likely pathogenic/pathogenic (molecularly confirming Kleefstra syndrome) in 191 individuals. We provide an updated and broader clinical and molecular spectrum of Kleefstra syndrome, including individuals with normal intelligence and familial occurrence. Analysis of the EHMT1 variants reveals a broad range of molecular effects and their associated phenotypes, including distinct genotype-phenotype associations. Notably, we showed that disruption of the “reader” function of the ankyrin repeat domain by a protein altering variant (PAV) results in a KLEFS1-specific DNAm signature and milder phenotype, while disruption of only “writer” methyltransferase activity of the SET domain does not result in KLEFS1 DNAm signature or typical KLEFS1 phenotype. Similarly, N-terminal truncating variants result in a mild phenotype without the DNAm signature. We demonstrate how comprehensive variant analysis can provide insights into pathogenesis of the disorder and DNAm signature. In summary, this study presents a comprehensive overview of KLEFS1 and EHMT1, revealing its broader spectrum and deepening our understanding of its molecular mechanisms, thereby informing accurate variant interpretation, counseling, and clinical management.
AB - The shift to a genotype-first approach in genetic diagnostics has revolutionized our understanding of neurodevelopmental disorders, expanding both their molecular and phenotypic spectra. Kleefstra syndrome (KLEFS1) is caused by EHMT1 haploinsufficiency and exhibits broad clinical manifestations. EHMT1 encodes euchromatic histone methyltransferase-1—a pivotal component of the epigenetic machinery. We have recruited 209 individuals with a rare EHMT1 variant and performed comprehensive molecular in silico and in vitro testing alongside DNA methylation (DNAm) signature analysis for the identified variants. We (re)classified the variants as likely pathogenic/pathogenic (molecularly confirming Kleefstra syndrome) in 191 individuals. We provide an updated and broader clinical and molecular spectrum of Kleefstra syndrome, including individuals with normal intelligence and familial occurrence. Analysis of the EHMT1 variants reveals a broad range of molecular effects and their associated phenotypes, including distinct genotype-phenotype associations. Notably, we showed that disruption of the “reader” function of the ankyrin repeat domain by a protein altering variant (PAV) results in a KLEFS1-specific DNAm signature and milder phenotype, while disruption of only “writer” methyltransferase activity of the SET domain does not result in KLEFS1 DNAm signature or typical KLEFS1 phenotype. Similarly, N-terminal truncating variants result in a mild phenotype without the DNAm signature. We demonstrate how comprehensive variant analysis can provide insights into pathogenesis of the disorder and DNAm signature. In summary, this study presents a comprehensive overview of KLEFS1 and EHMT1, revealing its broader spectrum and deepening our understanding of its molecular mechanisms, thereby informing accurate variant interpretation, counseling, and clinical management.
KW - DNA methylation
KW - EHMT1
KW - H3K9
KW - Kleefstra syndrome
KW - NDD
KW - neurodevelopmental disorders
U2 - 10.1016/j.ajhg.2024.06.008
DO - 10.1016/j.ajhg.2024.06.008
M3 - Article
SN - 0002-9297
VL - 111
SP - 1605
EP - 1625
JO - American Journal of Human Genetics
JF - American Journal of Human Genetics
IS - 8
ER -