Targeted NGS gene panel identifies mutations in RSPH1 causing primary ciliary dyskinesia and a common mechanism for ciliary central pair agenesis due to radial spoke defects

Alexandros Onoufriadis, Amelia Shoemark, Miriam Schmidts, Mitali Patel, Gina Jimenez, Hui Liu, Biju Thomas, Mellisa Dixon, Robert A. Hirst, Andrew Rutman, Thomas Burgoyne, Christopher Williams, Juliet Scully, Florence Bolard, Jean Jacques Lafitte, Philip L. Beales, Claire Hogg, Pinfen Yang, Eddie M.K. Chung, Richard D. EmesChristopher O'Callaghan, UK10K Consortium, Patrice Bouvagnet, Hannah M. Mitchison (Lead / Corresponding author)

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    73 Citations (Scopus)
    27 Downloads (Pure)

    Abstract

    Primary ciliary dyskinesia (PCD) is an inherited chronic respiratory obstructive disease with randomized body laterality and infertility, resulting from cilia and sperm dysmotility. PCD is characterized by clinical variability and extensive genetic heterogeneity, associated with different cilia ultrastructural defects and mutations identified in >20 genes. Next generation sequencing (NGS) technologies therefore present a promising approach for genetic diagnosis which is not yet in routine use.We developed a targeted panel-based NGS pipeline to identify mutations by sequencing of selected candidate genes in 70 genetically undefined PCD patients. This detected loss-of-function RSPH1 mutations in four individuals with isolated central pair (CP) agenesis and normal body laterality, from two unrelated families. Ultrastructural analysis in RSPH1-mutated cilia revealed transposition of peripheraloutermicrotubules intothe 'empty'CPspace, accompaniedbyadistinctive intermittent lossof the central pair microtubules. We find that mutations in RSPH1, RSPH4A and RSPH9, which all encode homologs of components of the 'head' structure of ciliary radial spoke complexes identified in Chlamydomonas, cause clinical phenotypes that appear to be indistinguishable except at the gene level. By high-resolution immunofluorescence we identified a loss of RSPH4A and RSPH9 along with RSPH1 from RSPH1-mutated cilia, suggesting RSPH1 mutations may result in loss of the entire spoke head structure. CP loss is seen in up to 28% of PCD cases, in whom laterality determination specified by CP-less embryonic node cilia remains undisturbed.We propose this defect could arise from instability or agenesis of the ciliary central microtubules due to loss of their normal radial spoke head tethering.

    Original languageEnglish
    Pages (from-to)3362-3374
    Number of pages13
    JournalHuman Molecular Genetics
    Volume23
    Issue number13
    Early online date11 Feb 2014
    DOIs
    Publication statusPublished - 1 Jul 2014

    Keywords

    • mutation
    • kartagener's syndrome
    • genes
    • microtubules
    • cilia
    • massively-parallel genome sequencing

    ASJC Scopus subject areas

    • Molecular Biology
    • Genetics
    • Genetics(clinical)

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