Project description:The mitochondrial matrix is unique in that it must integrate folding and assembly of proteins derived from nuclear and mitochondrial genomes. In C. elegans, the mitochondrial unfolded protein response (UPRmt) senses matrix protein misfolding and induces a program of nuclear gene expression, including mitochondrial chaperonins, to promote mitochondrial proteostasis. While misfolded mitochondrial matrix-localized ornithine trans-carbamylase (OTC) induces chaperonin expression, our understanding of mammalian UPRmt is rudimentary, reflecting a lack of acute triggers for UPRmt activation. This limitation has prevented analysis of the cellular responses to matrix protein misfolding and the effects of UPRmt on mitochondrial translation to control protein folding loads. Here, we combine pharmacological inhibitors of matrix-localized HSP90/TRAP1 or LON protease, which promote chaperonin expression, with global transcriptional and proteomic analysis to reveal an extensive and acute response of human cells to UPRmt. This response involved widespread induction of nuclear genes, including matrix-localized proteins involved in folding, pre-RNA processing and translation. Functional studies revealed rapid but reversible translation inhibition in mitochondria occurring concurrently with defects in pre-RNA processing due to transcriptional repression and LON-dependent turnover of the mitochondrial pre-RNA processing nuclease MRPP3. This study reveals that acute mitochondrial protein folding stress activates both increased chaperone availability within the matrix and reduced matrix-localized protein synthesis through translational inhibition, and provides a framework for further dissection of mammalian UPRmt. triplicate experiment of 3 conditions (untreated, GTPP treatment, CDDO treatment)

Project description:The mitochondrial matrix is unique in that it must integrate folding and assembly of proteins derived from nuclear and mitochondrial genomes. In C. elegans, the mitochondrial unfolded protein response (UPRmt) senses matrix protein misfolding and induces a program of nuclear gene expression, including mitochondrial chaperonins, to promote mitochondrial proteostasis. While misfolded mitochondrial matrix-localized ornithine trans-carbamylase (OTC) induces chaperonin expression, our understanding of mammalian UPRmt is rudimentary, reflecting a lack of acute triggers for UPRmt activation. This limitation has prevented analysis of the cellular responses to matrix protein misfolding and the effects of UPRmt on mitochondrial translation to control protein folding loads. Here, we combine pharmacological inhibitors of matrix-localized HSP90/TRAP1 or LON protease, which promote chaperonin expression, with global transcriptional and proteomic analysis to reveal an extensive and acute response of human cells to UPRmt. This response involved widespread induction of nuclear genes, including matrix-localized proteins involved in folding, pre-RNA processing and translation. Functional studies revealed rapid but reversible translation inhibition in mitochondria occurring concurrently with defects in pre-RNA processing due to transcriptional repression and LON-dependent turnover of the mitochondrial pre-RNA processing nuclease MRPP3. This study reveals that acute mitochondrial protein folding stress activates both increased chaperone availability within the matrix and reduced matrix-localized protein synthesis through translational inhibition, and provides a framework for further dissection of mammalian UPRmt. triplicate experiment of 2 conditions (untreated, GTPP treatment)

Project description:Across eukaryotic species, mild mitochondrial stress can have beneficial effects on the lifespan of organisms. Mitochondrial dysfunction activates an unfolded protein response (UPRmt), a stress signaling mechanism designed to ensure mitochondrial homeostasis. Perturbation of mitochondria during larval development in C. elegans not only delays aging but also maintains UPRmt signaling, suggesting an epigenetic mechanism that modulates both longevity and mitochondrial proteostasis throughout life. Here we identify the conserved histone lysine demethylases jmjd-1.2/PHF8 and jmjd-3.1/JMJD3 as positive regulators of lifespan in response to mitochondrial dysfunction across species. Reduction-of-function of the demethylases potently suppresses longevity and UPRmt induction while gain-of-function is sufficient to extend lifespan in an UPRmt-dependent manner. A systems genetics approach in the BXD mouse reference population further indicated conserved roles of the mammalian orthologs in longevity and UPRmt signaling. These findings illustrate an evolutionary conserved epigenetic mechanism that determines the rate of aging downstream of mitochondrial perturbations.

Project description:When mitochondrial proteostasis breaks down, quality control pathways including the UPRmt and PINK1/Parkin mitophagy are activated in response. However, beyond the upregulation of chaperones and proteases, we have a limited understanding of how the UPRmt remodels and restores damaged mito-proteomes. Here, we have developed a functional proteomics framework, termed MitoPQ (Mitochondrial Proteostasis Quantification), to dissect the UPRmt’s role in maintaining proteostasis during stress. We discover essential roles for the UPRmt in both protecting and repairing proteostasis, with oxidative phosphorylation metabolism being a central target of the UPRmt. Transcriptome analyses together with MitoPQ reveal that UPRmt transcription factors drive independent signaling arms that act in concert to maintain proteostasis. Unidirectional interplay between the UPRmt and PINK1/Parkin mitophagy was found to promote oxidative phosphorylation recovery when the UPRmt failed. Collectively, this study defines the network of proteostasis mediated by the UPRmt and highlights the value of functional proteomics in decoding stressed proteomes.

Project description:The mitochondrial unfolded protein response (UPRmt) safeguards mitochondria from proteotoxic damage by activating a dedicated transcriptional response in the nucleus to restore proteostasis. How the mitochondrial protein misfolding information is signalled to the nucleus as part of the human UPRmt remains unclear. Here, we showed that UPRmt signalling is carried out by the co-occurrence of two individual signals – ROS production in mitochondria and accumulation of orphan mitochondrial proteins in the cytosol. Combining proteomics and genetic approaches, we identified that mitochondrial protein misfolding caused the release of ROS into the intermembrane space (IMS), which was essential for UPRmt signalling. ROS released from mitochondria oxidized the cytosolic HSP40 protein DNAJA1 to enhance recruitment of cytosolic HSP70 to orphan mitochondrial proteins that accumulated in parallel in the cytosol due to mitochondrial import defect. This recruitment leads to the release of HSF1 from HSP70 and its subsequent translocation to the nucleus to activate transcription of UPRmt related genes. Strikingly, we found that combining ROS and the accumulation of orphan mitochondrial proteins in the cytosol was sufficient and necessary to activate the UPRmt. Our findings reveal that monitoring of ROS and orphan mitochondrial proteins in cytosol allows an elegant surveillance to control the UPRmt via HSF1 activation in human cells. These observations reveal a novel link between mitochondrial and cytosolic proteostasis and provide molecular insight into UPRmt signalling.

Project description:The mitochondrial unfolded protein response (UPRmt) safeguards mitochondria from proteotoxic damage by activating a dedicated transcriptional response in the nucleus to restore proteostasis. How the mitochondrial protein misfolding information is signalled to the nucleus as part of the human UPRmt remains unclear. Here, we showed that UPRmt signalling is carried out by the co-occurrence of two individual signals – ROS production in mitochondria and accumulation of orphan mitochondrial proteins in the cytosol. Combining proteomics and genetic approaches, we identified that mitochondrial protein misfolding caused the release of ROS into the intermembrane space (IMS), which was essential for UPRmt signalling. ROS released from mitochondria oxidized the cytosolic HSP40 protein DNAJA1 to enhance recruitment of cytosolic HSP70 to orphan mitochondrial proteins that accumulated in parallel in the cytosol due to mitochondrial import defect. This recruitment leads to the release of HSF1 from HSP70 and its subsequent translocation to the nucleus to activate transcription of UPRmt related genes. Strikingly, we found that combining ROS and the accumulation of orphan mitochondrial proteins in the cytosol was sufficient and necessary to activate the UPRmt. Our findings reveal that monitoring of ROS and orphan mitochondrial proteins in cytosol allows an elegant surveillance to control the UPRmt via HSF1 activation in human cells. These observations reveal a novel link between mitochondrial and cytosolic proteostasis and provide molecular insight into UPRmt signalling.

Project description:The mitochondrial matrix is unique in that it must integrate folding and assembly of proteins derived from nuclear and mitochondrial genomes. In C. elegans, the mitochondrial unfolded protein response (UPRmt) senses matrix protein misfolding and induces a program of nuclear gene expression, including mitochondrial chaperonins, to promote mitochondrial proteostasis. While misfolded mitochondrial matrix-localized ornithine trans-carbamylase (OTC) induces chaperonin expression, our understanding of mammalian UPRmt is rudimentary, reflecting a lack of acute triggers for UPRmt activation. This limitation has prevented analysis of the cellular responses to matrix protein misfolding and the effects of UPRmt on mitochondrial translation to control protein folding loads. Here, we combine pharmacological inhibitors of matrix-localized HSP90/TRAP1 or LON protease, which promote chaperonin expression, with global transcriptional and proteomic analysis to reveal an extensive and acute response of human cells to UPRmt. This response involved widespread induction of nuclear genes, including matrix-localized proteins involved in folding, pre-RNA processing and translation. Functional studies revealed rapid but reversible translation inhibition in mitochondria occurring concurrently with defects in pre-RNA processing due to transcriptional repression and LON-dependent turnover of the mitochondrial pre-RNA processing nuclease MRPP3. This study reveals that acute mitochondrial protein folding stress activates both increased chaperone availability within the matrix and reduced matrix-localized protein synthesis through translational inhibition, and provides a framework for further dissection of mammalian UPRmt.

Project description:The mitochondrial matrix is unique in that it must integrate folding and assembly of proteins derived from nuclear and mitochondrial genomes. In C. elegans, the mitochondrial unfolded protein response (UPRmt) senses matrix protein misfolding and induces a program of nuclear gene expression, including mitochondrial chaperonins, to promote mitochondrial proteostasis. While misfolded mitochondrial matrix-localized ornithine trans-carbamylase (OTC) induces chaperonin expression, our understanding of mammalian UPRmt is rudimentary, reflecting a lack of acute triggers for UPRmt activation. This limitation has prevented analysis of the cellular responses to matrix protein misfolding and the effects of UPRmt on mitochondrial translation to control protein folding loads. Here, we combine pharmacological inhibitors of matrix-localized HSP90/TRAP1 or LON protease, which promote chaperonin expression, with global transcriptional and proteomic analysis to reveal an extensive and acute response of human cells to UPRmt. This response involved widespread induction of nuclear genes, including matrix-localized proteins involved in folding, pre-RNA processing and translation. Functional studies revealed rapid but reversible translation inhibition in mitochondria occurring concurrently with defects in pre-RNA processing due to transcriptional repression and LON-dependent turnover of the mitochondrial pre-RNA processing nuclease MRPP3. This study reveals that acute mitochondrial protein folding stress activates both increased chaperone availability within the matrix and reduced matrix-localized protein synthesis through translational inhibition, and provides a framework for further dissection of mammalian UPRmt.

Project description:Mitochondria are the central hub of energy and metabolism of the cell,acting as one of the most important organelles of living cells.Under mitochondrial stresses, cells will trigger mitochondrial unfolded protein response (UPRmt) to maintain mitochondrial homeostasis.We have verified that splicing facotrs are required for the activation of UPRmt.Knocking down of splicing fator prp-19 could supresse UPRmt activation.We analysis the differencial alternative splicing of worms on L4440 RNAi or prp-19 RNAi and untreated or treated with atp-2 RNAi, we found that inhibition of prp-19 interrupts splicing homeostasis of c.elegans.

Project description:Mitochondria are important organelles, but their function is often challenged by toxic products of metabolism as well as by pathogen attack. The mitochondrial unfolded protein response (UPRmt) monitors mitochondrial function in general: it is responsible for buffering the mitochondrial protein folding environment, and controlling mitochondria-nuclear balance of the electron transport chain (ETC) components. Besides, UPRmt plays essential roles in aging and lifespan. Here we found that knocking down histone deacetylase hda-1 robustly attenuated UPRmt and lifespan extension. We identified HDA-1 as a required factor for UPRmt activation and HDA-1 is associated with the homeobox domain-containing protein DVE-1.So, we performed ChIP-seq of worms to find DNA regions on which HDA-1 and DVE-1 bound, and if their binding depend on each other.