Respiratory chains are crucial for cellular energy conversion and consist of multi-subunit complexes that can assemble into supercomplexes. These structures have been intensively characterized in various organisms, but their physiological roles remain unclear. Here, we elucidate their function by leveraging a high-resolution structural model of yeast respiratory supercomplexes that allowed us to inhibit supercomplex formation by mutation of key residues in the interaction interface. Analyses of a mutant defective in supercomplex formation, which still contains fully functional individual complexes, show that the lack of supercomplex assembly delays the diffusion of cytochrome c between the separated complexes, thus reducing electron transfer efficiency. Consequently, competitive cellular fitness is severely reduced in the absence of supercomplex formation and can be restored by overexpression of cytochrome c. In sum, our results establish how respiratory supercomplexes increase the efficiency of cellular energy conversion, thereby providing an evolutionary advantage for aerobic organisms.

Mitochondria, popularly known as powerhouse of the cell, contain specialised mitoribosomes that synthesise essential membrane proteins. These essential proteins are required to form enzyme complexes, which carry out the process of oxidative phosphorylation (OXPHOS). OXPHOS is carried out by five enzyme complexes (Complex I-V), out of which complex I, III and IV pump protons during electron transfer from NADH to O₂ and complex V uses the generated proton gradient to synthesise ATP. Cryo-EM, as a revolutionary technique in structural biology made it possible to determine the structures of mitoribosome assembly intermediates and respiratory chain supercomplexes. These structures have allowed us to investigate the mitoribosome biogenesis pathway in human and yeast and to gain deeper insights into the architecture of supercomplexes. In the first area of research, using cryo-EM we were for the first time able to capture mitoribosomes in different late stages of assembly and to determine their high-resolution structures with novel factors bound. Investigation of this process was previously unreachable due to lack of techniques to trap these mitoribosome complexes in different states of assembly. The structures of these assembly intermediates establish the role of assembly factors such as MALSU1, LOR8F8, mt-ACP, MTG1 and mitoribosomal proteins (MRPs) in mitoribosome biogenesis and to ensure proper maturation of each subunit, reflecting their role in regulating translation. Furthermore, genetic deletion studies of MTG1 and uL16m in yeast show the importance of transiently acting factors and MRPs in the mitoribosome assembly process and their effects on translation. The assembly pathway of mitoribosomes is critical for protein synthesis since defects in the translation process causes inherited human pathologies. Therefore, elucidation of mitoribosomal biogenesis pathways may also contribute to the development of potential new therapeutic opportunities. In the second research area, structures of the respiratory chain supercomplex from yeast were determined. These are the first near-atomic resolution structures that show organization of complex III and complex IV into two distinct classes that form higher order assemblies (III₂IV₁and III₂IV₂). Moreover, the architecture of the supercomplex structures differs from the previously determined respirasomes (I₁III₂IV₁) structures in mammals. We obtained a near-atomic resolution structure of the yeast complex IV, revealed core protein-protein and protein-lipid interactions that hold the supercomplex together. Moreover we found novel subunits required for supercomplex formation in S. cerevisiae. The last part of my study focuses on cryo-EM sample method development where we could successfully demonstrate the usefulness of a simple pressure-assisted sample preparation method for microcrystals, proteins and mitochondria. Our findings show great resolution improvements of selected area electron diffraction patterns of microcrystals, a significant reduction in needed sample concentration for single particle studies and an enrichment of gold nano-particles for tomographic studies.

Respiratory chain complexes execute energy conversion by connecting electron transport with proton translocation over the inner mitochondrial membrane to fuel ATP synthesis. Notably, these complexes form multi-enzyme assemblies known as respiratory supercomplexes. Here we used single-particle cryo-EM to determine the structures of the yeast mitochondria! respiratory supercomplexes III2IV and III2IV2, at 3.2-angstrom and 3.5-angstrom resolutions, respectively. We revealed the overall architecture of the supercomplex, which deviates from the previously determined assemblies in mammals; obtained a near-atomic structure of the yeast complex IV; and identified the protein-protein and protein-lipid interactions implicated in supercomplex formation. Take together, our results demonstrate convergent evolution of supercomplexes in mitochondria that, while building similar assemblies, results in substantially different arrangements and structural solutions to support energy conversion.

Mammalian mitochondrial ribosomes (mitoribosomes) have less rRNA content and 36 additional proteins compared with the evolutionarily related bacterial ribosome. These differences make the assembly of mitoribosomes more complex than the assembly of bacterial ribosomes, but the molecular details of mitoribosomal biogenesis remain elusive. Here, we report the structures of two late-stage assembly intermediates of the human mitoribosomal large subunit (mt-LSU) isolated from a native pool within a human cell line and solved by cryo-EM to similar to 3-angstrom resolution. Comparison of the structures reveals insights into the timing of rRNA folding and protein incorporation during the final steps of ribosomal maturation and the evolutionary adaptations that are required to preserve biogenesis after the structural diversification of mitoribosomes. Furthermore, the structures redefine the ribosome silencing factor (RsfS) family as multifunctional biogenesis factors and identify two new assembly factors (L0R8F8 and mt-ACP) not previously implicated in mitoribosomal biogenesis.