Project description:Short chain enoyl-CoA hydratase 1 (ECHS1) is involved in the second step of mitochondrial fatty acid β-oxidation (FAO), catalysing the hydration of short chain enoyl-CoA esters to short chain 3-hyroxyl-CoA esters. Genetic deficiency in ECHS1 (ECHS1D) is associated with a specific subset of Leigh Syndrome, a disease typically caused by defects in oxidative phosphorylation (OXPHOS). Here, we examined the molecular pathogenesis of ECHS1D using a CRISPR/Cas9 edited human cell ‘knockout’ model and fibroblasts from ECHS1D patients. Transcriptome analysis of ECHS1 ‘knockout’ cells showed reductions in key mitochondrial pathways, including the TCA cycle, receptor mediated mitophagy and nucleotide biosynthesis. Subsequent proteomic analyses confirmed these reductions and revealed additional defects in mitochondrial oxidoreductase activity and fatty acid β-oxidation. Functional analysis of ECHS1 ‘knockout’ cells showed reduced mitochondrial oxygen consumption rates when metabolising glucose or OXPHOS complex I-linked substrates, as well as decreased complex I and complex IV enzyme activities. ECHS1 ‘knockout’ cells also exhibited decreased OXPHOS protein complex steady-state levels (complex I, complex III2, complex IV, complex V and supercomplexes CIII2/CIV and CI/CIII2/CIV). Patient fibroblasts exhibit varied reduction of mature OXPHOS complex steady-state levels, with defects detected in CIII2, CIV, CV and the CI/CIII2/CIV supercomplex. Overall, these findings highlight the contribution of defective OXPHOS function, in particular complex I deficiency, to the molecular pathogenesis of ECHS1D.

Project description:Short chain enoyl-CoA hydratase 1 (ECHS1) is involved in the second step of mitochondrial fatty acid β-oxidation (FAO), catalysing the hydration of short chain enoyl-CoA esters to short chain 3-hyroxyl-CoA esters. Genetic deficiency in ECHS1 (ECHS1D) is associated with a specific subset of Leigh Syndrome, a disease typically caused by defects in oxidative phosphorylation (OXPHOS). Here, we examined the molecular pathogenesis of ECHS1D using a CRISPR/Cas9 edited human cell ‘knockout’ model and fibroblasts from ECHS1D patients. Transcriptome analysis of ECHS1 ‘knockout’ cells showed reductions in key mitochondrial pathways, including the TCA cycle, receptor mediated mitophagy and nucleotide biosynthesis. Subsequent proteomic analyses confirmed these reductions and revealed additional defects in mitochondrial oxidoreductase activity and fatty acid β-oxidation. Functional analysis of ECHS1 ‘knockout’ cells showed reduced mitochondrial oxygen consumption rates when metabolising glucose or OXPHOS complex I-linked substrates, as well as decreased complex I and complex IV enzyme activities. ECHS1 ‘knockout’ cells also exhibited decreased OXPHOS protein complex steady-state levels (complex I, complex III2, complex IV, complex V and supercomplexes CIII2/CIV and CI/CIII2/CIV). Patient fibroblasts exhibit varied reduction of mature OXPHOS complex steady-state levels, with defects detected in CIII2, CIV, CV and the CI/CIII2/CIV supercomplex. Overall, these findings highlight the contribution of defective OXPHOS function, in particular complex I deficiency, to the molecular pathogenesis of ECHS1D.

Project description:The mammalian oxidative phosphorylation (OXPHOS) system in the inner mitochondrial membrane comprises respiratory chain complexes I-IV (CI-CIV) and ATP synthase. Together, these protein complexes harvest metabolic energy to generate ATP, the cellular energy currency. The inner mitochondrial membrane is abundant in OXPHOS complexes and CI, CIII and CIV exhibit specific protein-protein interactions to form stable supercomplex assemblies, exemplified by the respirasome (CI-CIII2-CIV). Respirasomes are conserved in evolution, and as well documented by biochemical and structural methods. However, their physiological roles are much debated, despite a substantial literature suggesting their importance in facilitating catalysis and regulating turnover in response to metabolic demand. To investigate the in vivo role of respirasomes, we deleted a short conserved, charged loop in the UQCRC1 subunit of CIII that contacts CI. The resulting homozygous knock-in mice show profoundly decreased levels of respirasomes on blue native polyacrylamide gel electrophoresis (BN-PAGE) and complexome profiling proteomics analyses of different tissues, although the individual complexes appear unaffected. In vivo The spatial organization of respirasomes in vivo was altered in knock-in mice as shown by cross-linking experiments on intact mitochondria. Surprisingly, the mutant mice are healthy, with normal respiratory chain capacity and normal exercise tolerance. Therefore, respirasomes are dispensable for OXPHOS function in vivo.

Project description:The existence of respiratory supercomplexes (SCs) has been well acknowledged especially with the development of cryo-EM in the past few years, but their physiological relevance remains elusive. Dynamics of OXPHOS complexes is tightly correlated to cell fate switch, but whether SCs involve in this process is unknown. During C2C12 myogenesis, CIII2 and CIV as well as the subunits of CIII and CIV were slightly increasing, while SC III2+IV was decreasing, which indicates that SC reorganization may regulate myogenesis. Knockdown Cox7a2l decreased SCs III2+IV, I+III2+IV2 and I+III2+IV3, but had little effect on I+III2+IV. Transcriptome and quantitative-proteome analysis indicated that Cox7a2l silence activated myogenic gene expression and repressed cell cycle-associated gene expression. Besides, knockdown of Cox7a2l decreased CII abundance and accumulated succinate, which in turn suppressed certain key transcription factors, such as HMGA1 which is important for stemness maintenance. Our results indicated that respiratory supercomplex reorganization changed succinate homeostasis and myogenesis related gene expression profiles, thus switching cell fate.

Project description:Mitochondrial complex III (CIII2) and complex IV (CIV) which can associate into a higher-order supercomplex (SC III2 IV) play key roles in respiration. However, structures of these plant complexes remain unknown. We present atomic models of CIII2, CIV and SC III2 IV from Vigna radiata determined by single-particle cryoEM. The structures reveal plant-specific differences in the MPP domain of CIII2 and define the subunit composition of CIV. Conformational heterogeneity analysis of CIII2 revealed long-range, coordinated movements across the complex as well as the motion of CIII2s iron-sulfur head domain. The CIV structure suggests that, in plants, proton translocation does not occur via the H-channel. The supercomplex interface differs significantly from that in yeast and bacteria in its interacting subunits angle of approach and limited interactions in the mitochondrial matrix. These structures challenge long-standing assumptions about the plant complexes, generate new mechanistic hypotheses and allow for the generation of more selective agricultural inhibitors.

Project description:Reversible acetylation of mitochondrial proteins is a regulatory mechanism central to adaptive metabolic responses. Yet, how such functionally relevant protein acetylation is achieved remains unexplored. Here, we reveal an unprecedented role of the MYST family lysine acetyltransferase MOF in energy metabolism via mitochondrial protein acetylation. Loss of MOF-KANSL complex members led to mitochondrial defects including fragmentation, reduced cristae density and impaired mitochondrial electron transport chain (mtETC) complex IV (CIV) integrity in primary mouse embryonic fibroblasts. We demonstrate COX17, a CIV assembly factor, as a bona fide acetylation target of MOF. Loss of COX17 or expression of its non-acetylatable mutant phenocopied the mitochondrial defects observed upon MOF depletion. The acetylation-mimetic COX17 rescues these defects and maintains CIV activity even in the absence of MOF, suggesting an activatory role of mtETC protein acetylation. Fibroblasts from MOF syndrome patients with intellectual disability also revealed respiratory defects that could be restored by alternative oxidase, acetylation-mimetic COX17 or mitochondrially targeted MOF. Overall, our findings highlight the critical role of MOF-KANSL complex in mitochondrial physiology and provide new insights into MOF syndrome.​

Project description:Mitochondria perform central functions in cellular bioenergetics, metabolism and signaling and their malfunction has been linked to numerous diseases. The available studies cover only part of the mitochondrial proteome and a separation of core mitochondrial proteins from associated fractions has not been achieved. We developed an integrative, quantitative MS-based experimental approach to define the high confidence proteome of yeast mitochondria and to identify new mitochondrial proteins. The analysis includes protein abundance under fermentable and non-fermentable growth, submitochondrial localization, single-protein analysis and subcellular classification of mitochondria-associated fractions. We identified novel mitochondrial interactors of respiratory chain supercomplexes, ATP synthase, AAA proteases, the mitochondrial contact site and cristae organizing system (MICOS) and coenzyme Q biosynthesis cluster as well as new mitochondrial proteins with dual cellular localization. The integrative proteome provides a high confidence source for the characterization of physiological and pathophysiological functions of mitochondria and their integration into the cellular environment.

Project description:We studied dynamics within mitochondrial complexes in MEFs from CLPP-/- and wildtype mice.

Project description:In response to cold, mammals activate brown fat for respiratory-dependent thermogenesis reliant on the electron transport chain. Yet, the structural basis of respiratory complex adaptation to cold remains elusive. Herein we combined thermoregulatory physiology and cryo-EM to study endogenous respiratory supercomplexes exposed to different temperatures. A cold-induced conformation of CI:III2 (termed type 2) was identified with a ~25 rotation of CIII2 around its inter-dimer axis, shortening inter-complex Q exchange space, and exhibiting different catalytic states which favor electron transfer. Large-scale supercomplex simulations in lipid membrane reveal how unique lipid-protein arrangements stabilize type 2 complexes to enhance catalytic activity. Together, our cryo-EM studies, multiscale simulations and biochemical analyses unveil the mechanisms and dynamics of respiratory adaptation at the structural and energetic level.

Project description:The oxidative phosphorylation (OXPHOS) system is dynamic and the respiratory complexes (RCs) coexist with super-assembled quaternary structures called supercomplexes (SCs). How assembly occurs and the physiological role of supercomplex assembly is still under intensive investigation. The Cox7a family member Cox7a2l, also known as Scaf1, promotes CIII-CIV super assembly and energetic efficiency in zebrafish, mice, and humans. Here we studied the role of a second member of the Cox7a family, Cox7a1 in SC assembly and striated muscle physiology. We found that this protein drives CIV homodimer formation, which increases CIV activity. The substantial reduction in CIV2 formation led to a profound metabolic rearrangement with a consequent non-pathological loss of skeletal muscle performance. Ablation of Cox7a1 also rewired heart metabolism. Already in homeostatic conditions, cox7a1-/- hearts revealed a pro-regenerative metabolic profile. While overall cardiac function was not affected, the absence of Cox7a1 altered the cardiac regenerative response. The effects of cox7a1 and cox7a2l loss of function on skeletal muscle and myocardium physiology and injury response were not identical, revealing that there is a high specificity of Cox7a isoform in controlling OXPHOS assembly and striated muscle metabolism. While in both cases overall OXPHOS activity is modified, the loss of CIII-CIV heterodimer formation or CIV homodimer formation have very distinct metabolic and physiological consequences, highlighting the complexity of OXPHOS function and the importance of cox7a1 in striated muscle maturation.