Noble, Alexandra R; Masek, Markus; Hofmann, Claudia; Cuoco, Arianna; Rusterholz, Tamara D S; Özkoc, Hayriye; Greter, Nadja R; Phelps, Ian G; Vladimirov, Nikita; Kollmorgen, Sepp; Stoeckli, Esther; Bachmann-Gagescu, Ruxandra (2024). Shared and unique consequences of Joubert Syndrome gene dysfunction on the zebrafish central nervous system. Biology Open, 13(11):bio060421.
Abstract
Joubert Syndrome (JBTS) is a neurodevelopmental ciliopathy defined by a highly specific midbrain-hindbrain malformation, variably associated with additional neurological features. JBTS displays prominent genetic heterogeneity with >40 causative genes that encode proteins localising to the primary cilium, a sensory organelle that is essential for transduction of signalling pathways during neurodevelopment, among other vital functions. JBTS proteins localise to distinct ciliary subcompartments, suggesting diverse functions in cilium biology. Currently, there is no unifying pathomechanism to explain how dysfunction of such diverse primary cilia-related proteins results in such a highly specific brain abnormality. In order to identify the shared consequence of JBTS gene dysfunction, we carried out transcriptomic analysis using zebrafish mutants for the JBTS-causative genes cc2d2aw38, cep290fh297, inpp5ezh506, talpid3i264 and togaram1zh510and the Bardet-Biedl syndrome-causative gene bbs1k742. We identified no commonly dysregulated signalling pathways in these mutants and yet all mutants displayed an enrichment of altered gene sets related to central nervous system function. We found that JBTS mutants have altered primary cilia throughout the brain, however do not display abnormal brain morphology. Nonetheless, behavioural analyses revealed reduced locomotion and loss of postural control which, together with the transcriptomic results, hint at underlying abnormalities in neuronal activity and/or neuronal circuit function. These zebrafish models therefore offer the unique opportunity to study the role of primary cilia in neuronal function beyond early patterning, proliferation and differentiation.
Item Type: | Journal Article, refereed, original work |
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Communities & Collections: | 04 Faculty of Medicine > Center for Microscopy and Image Analysis
04 Faculty of Medicine > Institute of Medical Genetics
07 Faculty of Science > Institute of Molecular Life Sciences
04 Faculty of Medicine > Brain Research Institute
08 Research Priority Programs > Adaptive Brain Circuits in Development and Learning (AdaBD) |
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Dewey Decimal Classification: | 610 Medicine & health
570 Life sciences; biology |
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Uncontrolled Keywords: | Genetics, Genetics (clinical), Primary cilia, Joubert syndrome, central nervous system, zebrafish, Cc2d2a, Talpid3 |
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Language: | English |
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Date: | 12 November 2024 |
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Deposited On: | 17 Oct 2024 12:37 |
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Last Modified: | 15 Nov 2024 07:05 |
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Publisher: | The Company of Biologists Ltd. |
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ISSN: | 2046-6390 |
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OA Status: | Gold |
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Free access at: | Publisher DOI. An embargo period may apply. |
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Publisher DOI: | https://doi.org/10.1242/bio.060421 |
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Related URLs: | https://api.semanticscholar.org/CorpusID:267740876 https://doi.org/10.1101/2024.02.15.580456 |
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PubMed ID: | 39400299 |
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Other Identification Number: | Corpus ID: 267740876 |
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Project Information: | - Funder: University of Zurich (UZH)
- Grant ID: URPP AdaBD
- Project Title: University Research Priority Program AdaBD: Adaptive Brain Circuits in Development and Learning, Zurich, Switzerland
- : Project Websitehttps://adabd.uzh.ch/en.html
- Funder: SNSF
- Grant ID: 170681
- Project Title: Understanding the molecular mechanisms underlying phenotypic variability in ciliopathies
- : Project Websitehttps://data.snf.ch/grants/grant/170681
- Funder: SNSF
- Grant ID: 198895
- Project Title: Understanding the molecular mechanisms underlying phenotypic variability in ciliopathies
- : Project Websitehttps://data.snf.ch/grants/grant/198895
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