Mgr2 functions as lateral gatekeeper for preprotein sorting in the mitochondrial inner membrane.

The majority of preproteins destined for mitochondria carry N-terminal presequences. The presequence translocase of the inner mitochondrial membrane (TIM23 complex) plays a central role in protein sorting. Preproteins are either translocated through the TIM23 complex into the matrix or are laterally released into the inner membrane. We report that the small hydrophobic protein Mgr2 controls the lateral release of preproteins. Mgr2 interacts with preproteins in transit through the TIM23 complex. Overexpression of Mgr2 delays preprotein release, whereas a lack of Mgr2 promotes preprotein sorting into the inner membrane. Preproteins with a defective inner membrane sorting signal are translocated into the matrix in wild-type mitochondria but are released into the inner membrane in Mgr2-deficient mitochondria. We conclude that Mgr2 functions as a lateral gatekeeper of the mitochondrial presequence translocase, providing quality control for the membrane sorting of preproteins.

Definition of a High-Confidence Mitochondrial Proteome at Quantitative Scale.

Mitochondria perform central functions in cellular bioenergetics, metabolism, and signaling, and their dysfunction 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 experimental approach to define the proteome of yeast mitochondria. We classified > 3,300 proteins of mitochondria and mitochondria-associated fractions and defined 901 high-confidence mitochondrial proteins, expanding the set of mitochondrial proteins by 82. Our analysis includes protein abundance under fermentable and nonfermentable growth, submitochondrial localization, single-protein experiments, and subcellular classification of mitochondria-associated fractions. We identified mitochondrial interactors of respiratory chain supercomplexes, ATP synthase, AAA proteases, the mitochondrial contact site and cristae organizing system (MICOS), and the coenzyme Q biosynthesis cluster, as well as 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.

Distinct Roles of Mic12 and Mic27 in the Mitochondrial Contact Site and Cristae Organizing System.

The mitochondrial inner membrane consists of two morphologically distinct domains, the inner boundary membrane and large invaginations termed cristae. Narrow membrane structures, the crista junctions, link these two domains. Maintenance of this elaborate architecture depends on the evolutionarily conserved mitochondrial contact site and cristae organizing system (MICOS), a multisubunit inner membrane protein complex. MICOS consists of two functional modules, a Mic60-Mic19 subcomplex that forms Mic60-mediated contact sites with the outer mitochondrial membrane and a Mic10-Mic12-Mic26-Mic27 membrane-sculpting subcomplex that contains large Mic10 oligomers. Deletion of MIC10 or MIC60 results in the loss of most crista junctions. Distinct views have been discussed about how the MICOS modules cooperate with each other. We searched for components required for the structural organization of MICOS and identified Mic12 and Mic27 as crucial factors with specific roles in MICOS complex formation. Mic27 promotes the stability of the Mic10 oligomers in the membrane-sculpting subcomplex, whereas Mic12 is required for the coupling of the two MICOS subcomplexes. We conclude that in addition to the MICOS core components Mic10 and Mic60, Mic12 and Mic27 play specific roles in the organization of the MICOS complex.