Truncating mutations in exons 20 and 21 of OFD1 can cause primary ciliary dyskinesia without associated syndromic symptoms

Background Primary ciliary dyskinesia (PCD) is a motile ciliopathy, whose symptoms include airway infections, male infertility and situs inversus. Apart from the typical forms of PCD, rare syndromic PCD forms exist. Mutations of the X-linked OFD1 gene cause several syndromic ciliopathies, including oral-facial-digital syndrome type 1, Joubert syndrome type 10 (JBTS10), and Simpson-Golabi-Behmel syndrome type 2, the latter causing the X-linked syndromic form of PCD. Neurological and skeletal symptoms are characteristic for these syndromes, with their severity depending on the location of the mutation within the gene. Objectives To elucidate the role of motile cilia defects in the respiratory phenotype of PCD patients with C-terminal OFD1 mutations. Methods Whole-exome sequencing in a group of 120 Polish PCD patients, mutation screening of the OFD1 coding sequence, analysis of motile cilia, and magnetic resonance brain imaging. Results Four novel hemizygous OFD1 mutations, in exons 20 and 21, were found in men with a typical PCD presentation but without severe neurological, skeletal or renal symptoms characteristic for other OFD1-related syndromes. Magnetic resonance brain imaging in two patients did not show a molar tooth sign typical for JBTS10. Cilia in the respiratory epithelium were sparse, unusually long and displayed a defective motility pattern. Conclusion Consistent with the literature, truncations of the C-terminal part of OFD1 (exons 16–22) almost invariably cause a respiratory phenotype (due to motile cilia defects) while their impact on the primary cilia function is limited. We suggest that exons 20–21 should be included in the panel for regular mutation screening in PCD.

[1]  Silvio C. E. Tosatto,et al.  MobiDB 3.0: more annotations for intrinsic disorder, conformational diversity and interactions in proteins , 2017, Nucleic Acids Res..

[2]  Silvio C. E. Tosatto,et al.  MobiDB‐lite: fast and highly specific consensus prediction of intrinsic disorder in proteins , 2017, Bioinform..

[3]  V. Belcastro,et al.  The centrosomal OFD1 protein interacts with the translation machinery and regulates the synthesis of specific targets , 2017, Scientific Reports.

[4]  F. Koll,et al.  Basal body positioning and anchoring in the multiciliated cell Paramecium tetraurelia: roles of OFD1 and VFL3 , 2017, Cilia.

[5]  C. Boerkoel,et al.  Abnormal glycosylation in Joubert syndrome type 10 , 2017, Cilia.

[6]  Shane A. McCarthy,et al.  X-linked primary ciliary dyskinesia due to mutations in the cytoplasmic axonemal dynein assembly factor PIH1D3 , 2017, Nature Communications.

[7]  H. Zhang,et al.  [Clinical and genetic analysis of a family with Joubert syndrome type 10 caused by OFD1 gene mutation]. , 2017, Zhonghua er ke za zhi = Chinese journal of pediatrics.

[8]  E. Valente,et al.  Motile and non‐motile cilia in human pathology: from function to phenotypes , 2017, The Journal of pathology.

[9]  H. Omran,et al.  European Respiratory Society guidelines for the diagnosis of primary ciliary dyskinesia , 2017, European Respiratory Journal.

[10]  G. Pals,et al.  Mutations in PIH1D3 Cause X-Linked Primary Ciliary Dyskinesia with Outer and Inner Dynein Arm Defects , 2016, American journal of human genetics.

[11]  M. Madan Babu,et al.  The contribution of intrinsically disordered regions to protein function, cellular complexity, and human disease , 2016, Biochemical Society transactions.

[12]  M. Knowles,et al.  Primary Ciliary Dyskinesia. , 2016, Clinics in chest medicine.

[13]  F. Cunningham,et al.  The Ensembl Variant Effect Predictor , 2016, Genome Biology.

[14]  C. Thauvin-Robinet,et al.  Update on oral-facial-digital syndromes (OFDS) , 2016, Cilia.

[15]  B. Dimitrov,et al.  PICADAR: a diagnostic predictive tool for primary ciliary dyskinesia , 2016, European Respiratory Journal.

[16]  A. Munnich,et al.  Identification of a novel ARL13B variant in a Joubert syndrome-affected patient with retinal impairment and obesity , 2014, European Journal of Human Genetics.

[17]  A. Avital,et al.  MCIDAS mutations result in a mucociliary clearance disorder with reduced generation of multiple motile cilia , 2014, Nature Communications.

[18]  H. Omran,et al.  Mutations in CCNO result in congenital mucociliary clearance disorder with reduced generation of multiple motile cilia , 2014, Nature Genetics.

[19]  A. Munnich,et al.  OFD1 mutations in males: phenotypic spectrum and ciliary basal body docking impairment , 2013, Clinical genetics.

[20]  E. Haan,et al.  RPGR mutations might cause reduced orientation of respiratory cilia , 2013, Pediatric pulmonology.

[21]  Y. Fukushima,et al.  Exome sequencing in a family with an X‐linked lethal malformation syndrome: clinical consequences of hemizygous truncating OFD1 mutations in male patients , 2013, Clinical genetics.

[22]  D. Horn,et al.  Novel Mutations Including Deletions of the Entire OFD1 Gene in 30 Families with Type 1 Orofaciodigital Syndrome: A Study of the Extensive Clinical Variability , 2013, Human mutation.

[23]  Roberta Tammaro,et al.  Ofd1 Controls Dorso-Ventral Patterning and Axoneme Elongation during Embryonic Brain Development , 2012, PloS one.

[24]  E. Ziętkiewicz,et al.  Mutations in Radial Spoke Head Genes and Ultrastructural Cilia Defects in East-European Cohort of Primary Ciliary Dyskinesia Patients , 2012, PloS one.

[25]  Á. Carracedo,et al.  A novel mutation in the OFD1 (Cxorf5) gene may contribute to oral phenotype in patients with oral-facial-digital syndrome type 1. , 2011, Oral diseases.

[26]  Andrew M Fry,et al.  Centriolar satellites are assembly points for proteins implicated in human ciliopathies, including oral-facial-digital syndrome 1 , 2011, Journal of Cell Science.

[27]  D. Lindhout,et al.  Is hearing loss a feature of Joubert syndrome, a ciliopathy? , 2010, International journal of pediatric otorhinolaryngology.

[28]  S. Levy,et al.  Candidate exome capture identifies mutation of SDCCAG8 as the cause of a retinal-renal ciliopathy , 2010, Nature Genetics.

[29]  Enza Maria Valente,et al.  Joubert Syndrome and related disorders , 2010, Orphanet journal of rare diseases.

[30]  J. García-Verdugo,et al.  Ofd1, a human disease gene, regulates the length and distal structure of centrioles. , 2010, Developmental cell.

[31]  B. Franco,et al.  The molecular basis of oral‐facial‐digital syndrome, type 1 , 2009, American journal of medical genetics. Part C, Seminars in medical genetics.

[32]  J. Veltman,et al.  OFD1 is mutated in X-linked Joubert syndrome and interacts with LCA5-encoded lebercilin. , 2009, American journal of human genetics.

[33]  Nicholas Katsanis,et al.  Mechanistic insights into Bardet-Biedl syndrome, a model ciliopathy. , 2009, The Journal of clinical investigation.

[34]  Stephen W. Wilson,et al.  Convergent extension movements and ciliary function are mediated by ofd1, a zebrafish orthologue of the human oral-facial-digital type 1 syndrome gene , 2008, Human molecular genetics.

[35]  D. Hughes Primary ciliary dyskinesia. , 2008, Paediatrics & child health.

[36]  Colin A. Johnson,et al.  Mutations in the cilia gene ARL13B lead to the classical form of Joubert syndrome. , 2008, American journal of human genetics.

[37]  S. Cairo,et al.  Functional characterization of the OFD1 protein reveals a nuclear localization and physical interaction with subunits of a chromatin remodeling complex. , 2007, Molecular biology of the cell.

[38]  Wei Chen,et al.  A novel X-linked recessive mental retardation syndrome comprising macrocephaly and ciliary dysfunction is allelic to oral–facial–digital type I syndrome , 2006, Human Genetics.

[39]  A. Moore,et al.  RPGR is mutated in patients with a complex X linked phenotype combining primary ciliary dyskinesia and retinitis pigmentosa , 2005, Journal of Medical Genetics.

[40]  G. Mortier,et al.  Clinical, molecular, and genotype–phenotype correlation studies from 25 cases of oral–facial–digital syndrome type 1: a French and Belgian collaborative study , 2005, Journal of Medical Genetics.

[41]  P. Dollé,et al.  Oral-facial-digital type I protein is required for primary cilia formation and left-right axis specification , 2006, Nature Genetics.

[42]  G. Gerlitz,et al.  Novel Functional Features of the LIS-H Domain: Role in Protein Dimerization, Half-Life and Cellular Localization , 2005, Cell cycle.

[43]  R. Jenkins,et al.  Efficient transfection of non‐proliferating human airway epithelial cells with a synthetic vector system , 2004, The journal of gene medicine.

[44]  A. Webster,et al.  RPGR mutation associated with retinitis pigmentosa, impaired hearing, and sinorespiratory infections , 2003, Journal of medical genetics.

[45]  I. Järvelä,et al.  Four novel mutations in the OFD1 (Cxorf5) gene in Finnish patients with oral-facial-digital syndrome 1 , 2002, Journal of medical genetics.

[46]  A. Ballabio,et al.  Identification of the gene for oral-facial-digital type I syndrome. , 2001, American journal of human genetics.

[47]  J. Goodship,et al.  Centiles for adult head circumference. , 1992, Archives of disease in childhood.