Emerging role of a systems biology approach to elucidate factors of reduced penetrance: transcriptional changes in THAP1-linked dystonia as an example

Sokhna Haissatou Diaw; Fabian Ott; Alexander Münchau; Katja Lohmann; Hauke Busch

doi:10.1515/medgen-2022-2126

Emerging role of a systems biology approach to elucidate factors of reduced penetrance: transcriptional changes in THAP1-linked dystonia as an example

Sokhna Haissatou Diaw, Fabian Ott, Alexander Münchau, Katja Lohmann^*, Hauke Busch

^*Corresponding author for this work

Abstract

Pathogenic variants in THAP1 can cause dystonia with a penetrance of about 50 %. The underlying mechanisms are unknown and can be considered as means of endogenous disease protection. Since THAP1 encodes a transcription factor, drivers of this variability putatively act at the transcriptome level. Several transcriptome studies tried to elucidate THAP1 function in diverse cellular and mouse models, including mutation carrier-derived cells and iPSC-derived neurons, unveiling various differentially expressed genes and affected pathways. These include nervous system development, dopamine signalling, myelination, or cell-cell adhesion. A network diffusion analysis revealed mRNA splicing, mitochondria, DNA repair, and metabolism as significant pathways that may represent potential targets for therapeutic interventions.

Original language	English
Journal	Medizinische Genetik
Volume	34
Issue number	2
Pages (from-to)	131-141
Number of pages	11
ISSN	0936-5931
DOIs	https://doi.org/10.1515/medgen-2022-2126
Publication status	Published - 01.06.2022

Research Areas and Centers

Research Area: Medical Genetics

DFG Research Classification Scheme

2.23-06 Molecular and Cellular Neurology and Neuropathology

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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abstract = "Pathogenic variants in THAP1 can cause dystonia with a penetrance of about 50 %. The underlying mechanisms are unknown and can be considered as means of endogenous disease protection. Since THAP1 encodes a transcription factor, drivers of this variability putatively act at the transcriptome level. Several transcriptome studies tried to elucidate THAP1 function in diverse cellular and mouse models, including mutation carrier-derived cells and iPSC-derived neurons, unveiling various differentially expressed genes and affected pathways. These include nervous system development, dopamine signalling, myelination, or cell-cell adhesion. A network diffusion analysis revealed mRNA splicing, mitochondria, DNA repair, and metabolism as significant pathways that may represent potential targets for therapeutic interventions.",

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AU - Busch, Hauke

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Emerging role of a systems biology approach to elucidate factors of reduced penetrance: transcriptional changes in THAP1-linked dystonia as an example

Abstract

Research Areas and Centers

DFG Research Classification Scheme

UN SDGs

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