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Project description:Primary mitochondrial respiratory chain (RC) diseases are heterogeneous in etiology and manifestations but collectively impair cellular energy metabolism. To identify a common cellular response to RC disease, systems biology level transcriptome investigations were performed in human RC disease skeletal muscle and fibroblasts. Global transcriptional and post-transcriptional dysregulation in a tissue-specific fashion was identified across diverse RC complex and genetic etiologies. RC disease muscle was characterized by decreased transcription of cytosolic ribosomal proteins to reduce energy-intensive anabolic processes, increased transcription of mitochondrial ribosomal proteins, shortened 5'-UTRs to improve translational efficiency, and stabilization of 3'-UTRs containing AU-rich elements. These same modifications in a reversed direction typified RC disease fibroblasts. RC disease also dysregulated transcriptional networks related to basic nutrient-sensing signaling pathways, which collectively mediate many aspects of tissue-specific cellular responses to primary RC disease. These findings support the utility of a systems biology approach to improve mechanistic understanding of mitochondrial RC disease. To identify a common cellular response to primary RC that might improve mechanistic understanding and lead to targeted therapies for human RC disease, we performed collective transcriptome profiling in skeletal muscle biopsy specimens and fibroblast cell lines (FCLs) of a diverse cohort of human mitochondrial disease subjects relative to controls. Systems biology investigations of common cellular responses to primary RC disease revealed a collective pattern of transcriptional, post-transcriptional and translational dysregulation occurring in a highly tissue-specific fashion. Affymetrix Human Exon 1.0ST microarray analysis was performed on 29 skeletal muscle samples and Fibroblast cell lines from mitochondrial disease patients and age- and gender-matched controls.

Project description:Primary mitochondrial respiratory chain (RC) diseases are heterogeneous in etiology and manifestations but collectively impair cellular energy metabolism. To identify a common cellular response to RC disease, systems biology level transcriptome investigations were performed in human RC disease skeletal muscle and fibroblasts. Global transcriptional and post-transcriptional dysregulation in a tissue-specific fashion was identified across diverse RC complex and genetic etiologies. RC disease muscle was characterized by decreased transcription of cytosolic ribosomal proteins to reduce energy-intensive anabolic processes, increased transcription of mitochondrial ribosomal proteins, shortened 5'-UTRs to improve translational efficiency, and stabilization of 3'-UTRs containing AU-rich elements. These same modifications in a reversed direction typified RC disease fibroblasts. RC disease also dysregulated transcriptional networks related to basic nutrient-sensing signaling pathways, which collectively mediate many aspects of tissue-specific cellular responses to primary RC disease. These findings support the utility of a systems biology approach to improve mechanistic understanding of mitochondrial RC disease. To identify a common cellular response to primary RC that might improve mechanistic understanding and lead to targeted therapies for human RC disease, we performed collective transcriptome profiling in skeletal muscle biopsy specimens and fibroblast cell lines (FCLs) of a diverse cohort of human mitochondrial disease subjects relative to controls. Systems biology investigations of common cellular responses to primary RC disease revealed a collective pattern of transcriptional, post-transcriptional and translational dysregulation occurring in a highly tissue-specific fashion.

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Project description:Parkinson disease (PD) is a neurodegenerative disease believed to initiate in the brainstem and then spread throughout the brain. The mechanism by which this occurs is not yet fully understood, but here we show that damaged mitochondrial DNA (mtDNA) plays an important role in this process, which can be initiated by dysregulation of the IFNb/IFNAR signalling pathway. We report that lack of neuronal IFNb/IFNAR, which is associated to the development of PD, causes oxidization, mutation, and deletion in mtDNA. Damaged mtDNA is subsequently extruded extracellularly and can induce PD symptoms like motor and cognitive impairments in healthy mouse brains. It even leads to neurodegeneration in brain regions far from the injection site, suggesting that damaged mtDNA triggers the propagation of PD hallmarks through the brain. We further show that the mechanism by which damaged mtDNA causes pathology in healthy neurons is independent of cGAS and IFNb/IFNAR, but it is mediated by activation of dual Toll-like receptor (TLR)4/9 pathways. Through a proteomic analysis of extracellular vesicles containing the damaged mtDNA, we identified the TLR4 activator Ribosomal Protein S3 (Rps3) and established that Rps3 is a key effector protein involved in damaged mtDNA extrusion and recognition. Collectively, these results reveal a new molecular pathway by which damaged mtDNA can initiate and propagate Parkinson's Disease, paving the way for potential new therapies or disease monitoring.

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