Primary Ciliary Dyskinesia Associated Disease-Causing Variants in CCDC39 and CCDC40 Cause Axonemal Absence of Inner Dynein Arm Heavy Chains DNAH1, DNAH6, and DNAH7

Disease-causing bi-allelic DNA variants in and are frequent causes of the hereditary disorder of primary ciliary dyskinesia (PCD). The encoded proteins form a molecular ruler complex, crucial for maintaining the 96 nm repeat units along the ciliary axonemes. Defects of those proteins cause a stiff,...

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Bibliographic Details
Published in:Cells (Basel, Switzerland) Switzerland), 2024-07, Vol.13 (14), p.1200
Main Authors: Wilken, Alina, Höben, Inga Marlena, Wolter, Alexander, Loges, Niki Tomas, Olbrich, Heike, Aprea, Isabella, Dworniczak, Bernd, Raidt, Johanna, Omran, Heymut
Format: Article
Language:English
Subjects:
Analysis
Antibodies
axonemal disorganization
Axonemal Dyneins - genetics
Axonemal Dyneins - metabolism
Axoneme - metabolism
Axonemes
Biopsy
Cilia
Cilia - metabolism
Cilia - pathology
Ciliary Motility Disorders - genetics
Ciliary Motility Disorders - metabolism
Ciliary Motility Disorders - pathology
Cytoskeletal Proteins
diagnostics
Dynein
Dyneins - genetics
Dyneins - metabolism
Dyskinesia
Humans
IDA
Immunofluorescence
Lung diseases
Male
Membranes
Microscopy
motile cilia
Movement disorders
Mutation - genetics
Next-generation sequencing
PCD
Primary ciliary dyskinesia
Proteins
Respiration
Respiratory tract infection
ruler
Siblings
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Summary:Disease-causing bi-allelic DNA variants in and are frequent causes of the hereditary disorder of primary ciliary dyskinesia (PCD). The encoded proteins form a molecular ruler complex, crucial for maintaining the 96 nm repeat units along the ciliary axonemes. Defects of those proteins cause a stiff, rapid, and flickery ciliary beating pattern, recurrent respiratory infections, axonemal disorganization, and abnormal assembly of GAS8, CCDC39, and DNALI1. We performed molecular characterization of the defects in the 96 nm axonemal ruler due to disease-causing variants in and and analyzed the effect on additional axonemal components. We identified a cohort of 51 individuals with disease-causing variants in and via next-generation sequencing techniques and demonstrated that the IDA heavy chains DNAH1, DNAH6, and DNAH7 are conspicuously absent within the respiratory ciliary axonemes by immunofluorescence analyses. Hence, we show for the first time that the centrin2 (CETN2) containing IDAs are also affected. These findings underscore the crucial role of CCDC39 and CCDC40 in the assembly and function of IDAs in human respiratory cilia. Thus, our data improve the diagnostics of axonemal ruler defects by further characterizing the associated molecular IDA defects.
ISSN:2073-4409
2073-4409
DOI:10.3390/cells13141200