Project description:Cytochrome c oxidase assembly factor 7 (COA7) is a metazoan-specific assembly factor, critical for the biogenesis of mitochondrial complex IV (cytochrome c oxidase). Although mutations in COA7 have been linked to complex IV assembly defects and neurological conditions such as peripheral neuropathy, ataxia and leukoencephalopathy, the precise role COA7 plays in the biogenesis of complex IV is not known. Here we show that the absence of COA7 leads to arrest of the complex IV assembly pathway after the initial step where the COX1 module is built, progression from which requires the incorporation of copper, through the biogenesis of the CuA site. The crystal structure of COA7, determined to 2.4 Å resolution, reveals a ‘banana-shaped’ molecule composed of five helix-turn-helix repeats, tethered by disulfide bonds. We find that in solution, purified COA7 binds heme with micromolar affinity, through axial ligation to the central iron atom by histidine and methionine residues. COA7 interacts transiently with the copper metallochaperones SCO1 and SCO2 that function in copper delivery to COX2 and catalyzes the reduction of disulfide bonds within these proteins, which constitute the protein copper binding sites. We therefore propose that COA7 is a heme-binding disulfide reductase that acts in the biogenesis of the CuA site, that underpins complex IV assembly.

Project description:Mitochondria are complex organelles containing 13 proteins encoded by mitochondrial DNA and over 1000 proteins encoded on nuclear DNA. Many mitochondrial proteins are associated with the inner or outer mitochondrial membranes, either peripherally or as integral membrane proteins, while others reside in either of the two soluble mitochondrial compartments, the mitochondrial matrix and the intermembrane space. The biogenesis of the five complexes of the oxidative phosphorylation system are exemplars of this complexity. These large multi-subunit complexes are built through the tightly controlled coalescence of more than 80 proteins with both membrane integral and peripheral associations, with progression between different assembly steps dependent on soluble, membrane integral and peripherally associated assembly factor proteins. Understanding the membrane association of subunits and assembly factors during each assembly step is critical to understanding OXPHOS complex biogenesis. Here we couple sodium carbonate extraction with quantitative mass spectrometry to track changes in the membrane association of the mitochondrial proteome across multiple human complex III knockout cell lines. In addition to identifying the membrane association status of over 840 human mitochondrial proteins, we identify a previously undetected intermediate step of complex III biogenesis. Sodium carbonate extraction with quantitative mass spectrometry (SCE-MS) is thus an easy to apply tool with general utility in the study of mitochondrial respiratory chain biogenesis.

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:Intrinsic apoptosis is principally regulated by the BCL-2 family of proteins, but some non-BCL-2 proteins also serve as important regulators. To identify novel apoptosis regulators, we performed a genome-wide CRISPR-Cas9 library screen, and it identified the mitochondrial E3 ubiquitin ligase MARCHF5/MITOL/RNF153 as an important regulator of BAK apoptotic function. Deleting MARCHF5 in multiple BAX-deficient cell lines conferred profound resistance to BH3-mimetic drugs. The loss of MARCHF5 or its E3 ubiquitin ligase activity surprisingly drove BAK to adopt an active conformation, with resistance to BH3-mimetics afforded by the formation of inhibitory complexes with pro-survival proteins MCL-1 and BCL-XL. Importantly, these changes to BAK conformation and pro-survival association occurred independently of BH3-only proteins. This study identifies a mechanism by which MARCHF5 regulates apoptotic cell death and provides new insight into how cancer cells respond to BH3-mimetic drugs. These data also highlight the emerging role of ubiquitin signalling in apoptosis that may be exploited therapeutically.

Project description:Biogenesis of complex IV of the mitochondrial respiratory chain requires assembly factors for subunit maturation, co-factor attachment and stabilization of intermediate assemblies. A pathogenic mutation in Coa6, leading to substitution of a conserved tryptophan to a cysteine residue, results in a loss of complex IV activity and cardiomyopathy. Here we demonstrate that the complex IV defect correlates with a severe loss in complex IV assembly in patient heart but not fibroblasts. Complete loss of Coa6 activity using gene-editing in HEK293T cells resulted in a profound growth defect due to complex IV deficiency, caused by impaired biogenesis of the copper-bound mtDNA encoded subunit COX2 and subsequent accumulation of complex IV assembly intermediates. We show that the pathogenic mutation in Coa6 does not affect its import into mitochondria but impairs its maturation and stability. Furthermore we find that Coa6 binds copper with a high affinity and also associates with mitochondrial copper chaperones, revealing that Coa6 is intricately involved in the copper-dependent biogenesis of COX2.

Project description:Human Tim8a and Tim8b are paralogous intermembrane space proteins of the small TIM chaperone family. Yeast small TIMs function in the trafficking of proteins to the outer and inner mitochondrial membranes. This putative import function for hTim8a and hTim8b has been challenged in human models, but their true molecular function in cells has not been defined. Likewise, why human cells possess two Tim8 proteins and any potential redundancy is not clear. We demonstrate that hTim8a and hTim8b function in the assembly of cytochrome c oxidase (Complex IV). Using affinity enrichment mass spectrometry, we catalogue the interaction network of hTim8a, hTim8b and hTim13, identifying subunits and assembly factors of the Complex IV COX2 module. hTim8-deficient cells have a COX2/COX3 module defect, albeit less severe than a COX17KO cell line, and exhibit an accumulation of the S2 subcomplex. This suggests that hTim8a and hTim8b are required for assembly of Complex IV via interactions with intermembrane-space exposed subunits. We propose hTim8-hTim13 complexes act as chaperones to stabilise the intermediate S3 subcomplex, promoting assembly of monomeric Complex IV.

Project description:Herpesviruses are an ancient family of highly-prevalent human and animal pathogens that acquire their membrane envelopes in the cytoplasm of infected cells. While multiple conserved viral proteins are known to be required for efficient herpesvirus production, many of these proteins lack identifiable structural homologues and the molecular details of herpesvirus assembly remain unclear. We have characterized the complex of assembly proteins pUL7 and pUL51 from herpes simplex virus (HSV)-1, an α-herpesvirus, using multi-angle light scattering and small-angle X-ray scattering with chemical crosslinking. HSV-1 pUL7 and pUL51 form a stable 1:2 complex that is capable of higher-order oligomerization in solution. We solved the crystal structure of this complex, revealing a core heterodimer comprising pUL7 bound to residues 41–125 of pUL51. While pUL7 adopts a previously-unseen compact fold, the extended helix-turn-helix conformation of pUL51 resembles the cellular endosomal complex required for transport (ESCRT)- III component CHMP4B, suggesting a direct role for pUL51 in promoting membrane scission during virus assembly. We demonstrate that the interaction between pUL7 and pUL51 homologues is conserved acrosshuman α-, β- and γ-herpesviruses, as is their association with trans-Golgi membranes in cultured cells. However, pUL7 and pUL51 homologues do not form complexes with their respective partners from different virus families, suggesting that the molecular details of the interaction interface have diverged. Our results demonstrate that the pUL7:pUL51 complex is conserved across the herpesviruses and provide a structural framework for understanding its role in herpesvirus assembly.

Project description:Oxidative phosphorylation (OXPHOS) is essential for the synthesis of the vast majority of ATP in eukaryotic cells. It is carried out by multi-protein assemblies that form the electron transport chain (ETC), which are coupled to the mitochondrial ATP synthase, which uses the proton gradient generated by the ETC to drive ATP synthesis. The assembly of the OXPHOS protein machinery requires the coordinated integration of proteins encoded in the nuclear and the mitochondrial genomes, imposing an additional layer of complexity. While the biogenesis of the individual OXPHOS complexes is well understood, it remains unknown how the assembly of the ETC and ATP synthase is coordinated to achieve the correct stoichiometry of the OXPHOS machinery. Here, we identify the mitochondrial regulatory hub for respiratory assembly (MiRA), which serves as a platform on which complex IV and complex V biogenesis are synchronised to ensure balanced assembly of the ETC and complex V. At the molecular level, this is achieved by a stop-and-go safeguarding mechanism: The novel mitochondrial protein Mra1 binds to and slows down complex IV assembly. Two Go signals are then required for assembly to proceed: Binding of the complex IV assembly factor Rcf2 and interaction with the mitoribosome, which translates the complex V subunit Atp9. Both Go signals induce the clipping and subsequent degradation of Mra1, relieving the molecular break and allowing parallel maturation of complexes IV and V. The absence of the stop-and-go safety mechanism results in the formation of immature complexes, decreased ATP levels and reduced cell viability. The antagonistic activities at MiRA provide a regulated orchestration of complex IV and V assembly which is essential to avoid the predominance of either complex and an unbalanced ratio of OXPHOS complexes, thus ensuring the correct stoichiometry of protein machineries encoded by two different genomes.

Project description:According to the fluidity model, complexes of the electron transport chain (ETC) in the inner mitochondrial membrane partition between free complexes and supercomplexes. However, conclusive proof of the physiological requirement of supercomplex formation is lacking, and the mechanisms regulating their formation remain enigmatic. Here, we show that genetic perturbations affecting the biogenesis or maturation of ETC Complex III (CIII) stimulates the formation of a specialized extra-large supercomplex (SC-XL) with a predicted stoichiometry of CI2+CIII2. SC-XL formation increases mitochondrial cristae density and sustains normal ETC output despite a 70% reduction in electron flow through CIII, effectively rescuing mild to moderate CIII deficiency. Increasing the SC-XL:free CIII2 ratio significantly reduced CIII ROS production and propensity for CI ROS triggered by reverse electron transport, leading to enhanced ETC efficiency. Furthermore, higher SC-XL:free CIII2 ratio reprogrammed mitochondria towards fatty acid oxidation, enhancing endurance exercise capacity and protection against ischemic heart failure in mice. Our study reveals an unanticipated plasticity in the mammalian ETC to buttress against intrinsic perturbations via structural adaptations, and suggests that ETC reprogramming via controlled regulation of SC-XL formation is a potential therapeutic strategy for remediating diseases characterized by a decline in ETC bioenergetics and oxidative damage.

Project description:Oxidative phosphorylation (OXPHOS) is essential for the synthesis of the vast majority of ATP in eukaryotic cells. It is carried out by multi-protein assemblies that form the electron transport chain (ETC), which are coupled to the mitochondrial ATP synthase, which uses the proton gradient generated by the ETC to drive ATP synthesis. The assembly of the OXPHOS protein machinery requires the coordinated integration of proteins encoded in the nuclear and the mitochondrial genomes, imposing an additional layer of complexity. While the biogenesis of the individual OXPHOS complexes is well understood, it remains unknown how the assembly of the ETC and ATP synthase is coordinated to achieve the correct stoichiometry of the OXPHOS machinery. Here, we identify the mitochondrial regulatory hub for respiratory assembly (MiRA), which serves as a platform on which complex IV and complex V biogenesis are synchronised to ensure balanced assembly of the ETC and complex V. At the molecular level, this is achieved by a stop-and-go safeguarding mechanism: The novel mitochondrial protein Mra1 binds to and slows down complex IV assembly. Two Go signals are then required for assembly to proceed: Binding of the complex IV assembly factor Rcf2 and interaction with the mitoribosome, which translates the complex V subunit Atp9. Both Go signals induce the clipping and subsequent degradation of Mra1, relieving the molecular brake and allowing parallel maturation of complexes IV and V. The absence of the stop-and-go safety mechanism results in the formation of immature complexes, decreased ATP levels and reduced cell viability. The antagonistic activities at MiRA provide a regulated orchestration of complex IV and V assembly which is essential to avoid the predominance of either complex and an unbalanced ratio of OXPHOS complexes, thus ensuring the correct stoichiometry of protein machineries encoded by two different genomes.