The contribution of de novo coding mutations to meningomyelocele.

Authors

Yoo-Jin Jiny Ha
Ashna Nisal
Isaac Tang
Chanjae Lee
Ishani Jhamb
Cassidy Wallace
Robyn Howarth
Sarah Schroeder
Keng Ioi Vong
Naomi Meave
Fiza Jiwani
Chelsea Barrows
Sangmoon Lee
Nan Jiang
Arzoo Patel
Krisha Bagga
Niyati Banka
Liana Friedman
Francisco A Blanco
Seyoung Yu
Soeun Rhee
Hui Su Jeong
Isaac Plutzer
Michael B Major
Béatrice Benoit
Christian Poüs
Caleb Heffner, The Jackson LaboratoryFollow
Zoha Kibar
Gyang Markus Bot
Hope Northrup
Kit Sing Au
Madison Strain
Allison E Ashley-Koch
Richard H Finnell
Joan T Le
Hal S Meltzer
Camila Araujo
Helio R Machado
Roger E Stevenson
Anna Yurrita
Sara Mumtaz
Awais Ahmed
Mulazim Hussain Khara
Osvaldo M Mutchinick
José Ramón Medina-Bereciartu
Friedhelm Hildebrandt
Gia Melikishvili
Ahmed I Marwan
Valeria Capra
Mahmoud M Noureldeen
Aida M S Salem
Mahmoud Y Issa
Maha S Zaki
Libin Xu
Ji Eun Lee
Donghyuk Shin
Anna Alkelai
Alan R Shuldiner
Stephen F Kingsmore
Stephen A. Murray, The Jackson LaboratoryFollow
Heon Yung Gee
W Todd Miller
Kimberley F Tolias
John B Wallingford
Spina Bifida Sequencing Consortium
Sangwoo Kim
Joseph G Gleeson

Document Type

Article

Publication Date

3-26-2025

Publication Title

Nature

Keywords

JMG

JAX Source

Nature.

ISSN

1476-4687

PMID

40140573

DOI

https://doi.org/10.1038/s41586-025-08676-x

Abstract

Meningomyelocele (also known as spina bifida) is considered to be a genetically complex disease resulting from a failure of the neural tube to close. Individuals with meningomyelocele display neuromotor disability and frequent hydrocephalus, requiring ventricular shunting. A few genes have been proposed to contribute to disease susceptibility, but beyond that it remains unexplained1 . We postulated that de novo mutations under purifying selection contribute to the risk of developing meningomyelocele2 . Here we recruited a cohort of 851 meningomyelocele trios who required shunting at birth and 732 control trios, and found that de novo likely gene disruption or damaging missense mutations occurred in approximately 22.3% of subjects, with 28% of such variants estimated to contribute to disease risk. The 187 genes with damaging de novo mutations collectively define networks including actin cytoskeleton and microtubule-based processes, Netrin-1 signalling and chromatin- modifying enzymes. Gene validation demonstrated partial or complete loss of function, impaired signalling and defective closure of the neural tube in Xenopus embryos. Our results indicate that de novo mutations make key contributions to meningomyelocele risk, and highlight critical pathways required for neural tube closure in human embryogenesis.

Recommended Citation

Ha Y, Nisal A, Tang I, Lee C, Jhamb I, Wallace C, Howarth R, Schroeder S, Vong K, Meave N, Jiwani F, Barrows C, Lee S, Jiang N, Patel A, Bagga K, Banka N, Friedman L, Blanco F, Yu S, Rhee S, Jeong H, Plutzer I, Major M, Benoit B, Poüs C, Heffner C, Kibar Z, Bot G, Northrup H, Au K, Strain M, Ashley-Koch A, Finnell R, Le J, Meltzer H, Araujo C, Machado H, Stevenson R, Yurrita A, Mumtaz S, Ahmed A, Khara M, Mutchinick O, Medina-Bereciartu J, Hildebrandt F, Melikishvili G, Marwan A, Capra V, Noureldeen M, Salem A, Issa M, Zaki M, Xu L, Lee J, Shin D, Alkelai A, Shuldiner A, Kingsmore S, Murray SA, Gee H, Miller W, Tolias K, Wallingford J, , Kim S, Gleeson J. The contribution of de novo coding mutations to meningomyelocele. Nature.