Mdm36 is a mitochondrial fission-promoting protein in Saccharomyces cerevisiae.

The division of mitochondrial membranes is a complex process mediated by the dynamin-related protein Dnm1 in yeast, acting in concert with several cofactors. We have identified Mdm36 as a mitochondria-associated protein required for efficient mitochondrial division. Deltamdm36 mutants contain highly interconnected mitochondrial networks that strikingly resemble known fission mutants. Furthermore, mitochondrial fission induced by depolymerization of the actin cytoskeleton is blocked in Deltamdm36 mutants, and the number of Dnm1 clusters on mitochondrial tips is reduced. Double mutant analyses indicate that Mdm36 acts antagonistically to fusion-promoting components, such as Fzo1 and Mdm30. The cell cortex-associated protein Num1 was shown previously to interact with Dnm1 and promote mitochondrial fission. We observed that mitochondria are highly motile and that their localization is not restricted to the cell periphery in Deltamdm36 and Deltanum1 mutants. Intriguingly, colocalization of Num1 and Dnm1 is abolished in the absence of Mdm36. These data suggest that Mdm36 is required for mitochondrial division by facilitating the formation of protein complexes containing Dnm1 and Num1 at the cell cortex. We propose a model that Mdm36-dependent formation of cell cortex anchors is required for the generation of tension on mitochondrial membranes to promote mitochondrial fission by Dnm1.

Systematic analysis of the twin cx(9)c protein family.

The Mia40-Erv1 disulfide relay system is of high importance for mitochondrial biogenesis. Most so far identified substrates of this machinery contain either two cysteine-x(3)-cysteine (twin Cx(3)C) or two cysteine-x(9)-cysteine (twin Cx(9)C) motifs. While the first group is composed of well-characterized components of the mitochondrial import machinery, the molecular function of twin Cx(9)C proteins still remains unclear. To systematically characterize this protein family, we performed a database search to identify the full complement of Cx(9)C proteins in yeast. Thereby, we identified 14 potential family members, which, with one exception, are conserved among plants, fungi, and animals. Among these, three represent novel proteins, which we named Cmc2 to 4 (for Cx(9)C motif-containing protein) and which we demonstrated to be dependent for import on the Mia40-Erv1 disulfide relay. By testing deletion mutants of all 14 proteins for function of the respiratory chain, we found a critical function of most of these proteins for the assembly or stability of respiratory chain complexes. Our data suggest that already early during the evolution of eukaryotic cells, a multitude of twin Cx(9)C proteins developed, which exhibit largely nonredundant roles critical for the biogenesis of enzymes of the respiratory chain in mitochondria.

Molecular machinery of mitochondrial dynamics in yeast.

Mitochondria are amazingly dynamic organelles. They continuously move along cytoskeletal tracks and frequently fuse and divide. These processes are important for maintenance of mitochondrial functions, for inheritance of the organelles upon cell division, for cellular differentiation and for apoptosis. As the machinery of mitochondrial behavior has been highly conserved during evolution, it can be studied in simple model organisms, such as yeast. During the past decade, several key components of mitochondrial dynamics have been identified and functionally characterized in Saccharomyces cerevisiae. These include the mitochondrial fusion and fission machineries and proteins required for maintenance of tubular shape and mitochondrial motility. Taken together, these findings reveal a comprehensive picture that shows the cellular processes and molecular components required for mitochondrial inheritance and morphogenesis in a simple eukaryotic cell.