Project description: Not available

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.

Project description: Not available

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:Mitochondrial dysfunction induces a strong adaptive retrograde signaling response, however many of the down-stream effectors remain to be discovered. Here, we studied the shared transcriptional responses to three different mitochondrial respiratory chain inhibitors in human primary skin fibroblasts using QuantSeq 3’RNA-sequencing. We found that mevalonate pathway genes were concurrently downregulated irrespective of the respiratory chain complex affected. Targeted metabolomics demonstrated that impaired mitochondrial respiration at any of the three affected complexes also had functional consequences on the mevalonate pathway, reducing cholesterol precursor metabolites. A deeper study of complex I inhibition showed a reduced activity of ER-bound sterol sensing enzymes through impaired processing of the transcription factor SREBP2 and accelerated degradation of the ER cholesterol sensors SQLE and HMGCR. These adaptations of mevalonate pathway activity neither affected total intracellular cholesterol levels nor the cellular free (non-esterified) cholesterol pool. Measurement of intracellular cholesterol using the fluorescent cholesterol binding dye filipin revealed that complex I inhibition elevated cholesterol on intracellular compartments. Our study shows that mitochondrial respiratory chain dysfunction elevates intracellular free cholesterol levels and therefore attenuates the expression of mevalonate pathway enzymes, which lowers endogenous cholesterol biosynthesis, disrupting the metabolic output of the mevalonate pathway. Intracellular disturbances in cholesterol homeostasis may alter systemic cholesterol management in diseases associated with declining mitochondrial function.

Project description: Not available

Project description: Not available

Project description:Electron transport chain (ETC) biogenesis is tightly coupled to energy levels and availability of ETC subunits. Coenzyme Q: cytochrome c oxidoreductase (complex III or CIII) occupies a central position in the ETC, receiving electrons from diverse fuel sources to control the ubiquinol:ubiquinone (CoQH2/CoQ) ratio. As such, CIII is an attractive node for controlling ETC biogenesis during metabolic stress. Here, we report the discovery of mammalian CoOrdinator of Mitochondrial CYTB or “COM” complexes that regulate CIII biogenesis in a step-wise fashion in response to nutrient and nuclear-encoded ETC subunit availability. The COMA complex, consisting of UQCC1/2 and the membrane anchor C16ORF91 (UQCC4), facilitates the translation of CIII enzymatic core subunit CYTB. Subsequently, microproteins SMIM4 and BRAWNIN, together with COMA subunits form the COMB complex that stabilizes nascent CYTB. Finally, UQCC3-containing COMC promotes CTYB maturation and association with downstream CIII subunits. This stepwise assembly enables cells to adapt to metabolic stress by increasing CIII biogenesis and inducing an integrated stress response when challenged. Furthermore, when nuclear CIII subunits are unavailable for assembly, COMB is required to chaperone nascent CYTB to prevent OXPHOS collapse. Our studies highlight CYTB synthesis as a key regulatory node of ETC biogenesis, and uncover the roles of mito-SEPs in mitochondrial homeostasis during energy stress.

Project description: Not available

Project description: Not available