Interaction between Mitochondria and the Actin Cytoskeleton in Budding Yeast Requires Two Integral Mitochondrial Outer Membrane Proteins,Mmm1p and Mdm10p

Transfer of mitochondria to daughter cells during yeast cell division is essential for viable progeny. The actin cytoskeleton is required for this process, potentially as a track to direct mitochondrial movement into the bud. Sedimentation assays reveal two different components required for mitochondria–actin interactions: (1) mitochondrial actin binding protein(s) (mABP), a peripheral mitochondrial outer membrane protein(s) with ATP-sensitive actin binding activity, and (2) a salt-inextractable, presumably integral, membrane protein(s) required for docking of mABP on the organelle. mABP activity is abolished by treatment of mitochondria with high salt. Addition of either the salt-extracted mitochondrial peripheral membrane proteins (SE), or a protein fraction with ATP-sensitive actin-binding activity isolated from SE, to salt-washed mitochondria restores this activity. mABP docking activity is saturable, resistant to high salt, and inhibited by pre-treatment of salt-washed mitochondria with papain. Two integral mitochondrial outer membrane proteins, Mmm1p (Burgess, S.M., M. Delannoy, and R.E. Jensen. 1994. J.Cell Biol. 126:1375–1391) and Mdm10p, (Sogo, L.F., and M.P. Yaffe. 1994. J.Cell Biol. 126:1361– 1373) are required for these actin–mitochondria interactions. Mitochondria isolated from an mmm1-1 temperature-sensitive mutant or from an mdm10 deletion mutant show no mABP activity and no mABP docking activity. Consistent with this, mitochondrial motility in vivo in mmm1-1 and mdm10Δ mutants appears to be actin independent. Depolymerization of F-actin using latrunculin-A results in loss of long-distance, linear movement and a fivefold decrease in the velocity of mitochondrial movement. Mitochondrial motility in mmm1-1 and mdm10Δ mutants is indistinguishable from that in latrunculin-A–treated wild-type cells. We propose that Mmm1p and Mdm10p are required for docking of mABP on the surface of yeast mitochondria and coupling the organelle to the actin cytoskeleton.Mitochondria are indispensable organelles for normal eukaryotic cell function. Since mitochondria cannot be synthesized de novo, these organelles are inherited, i.e., transferred from mother to daughter during cell division. In the yeast Saccharomyces cerevisiae, vegetative cell division occurs by budding, a form of proliferation in which growth is directed toward the developing bud. Previous studies indicate that mitochondria undergo a series of cell cycle–linked motility events during normal inheritance in yeast (Simon et al., 1997). These are: (a) polarization of mitochondria towards the site of bud emergence in G₁ phase; (b) linear, polarized movement of mitochondria from mother cells to developing buds in S phase; (c) immobilization of newly inherited mitochondria in the bud tip during S and G₂ phases; and (d) release of immobilized mitochondria from the bud tip during M phase.There is mounting evidence that the actin cytoskeleton controls mitochondrial morphology and inheritance during vegetative yeast cell growth. The two major actin structures of yeast observed by light microscopy are patches and cables. Actin cables are bundles of actin filaments that extend from the mother into the bud. Mitochondria colocalize with these actin cables (Drubin et al., 1993; Lazzarino et al., 1994). Moreover, mutations such as deletion of the tropomyosin I gene, TPM1, or the mitochondrial distribution and morphology gene, MDM20, which selectively destabilize actin cables, result in the loss of polarized mitochondrial movement and reduce transfer of mitochondria into buds (Herman et al., 1997; Simon et al., 1997). Together, these studies indicate that normal mitochondrial inheritance in yeast requires association of mitochondria with actin cables.Cell-free studies reveal a possible mechanism underlying actin control of mitochondrial inheritance. Sedimentation assays document binding of mitochondria to the lateral surface of F-actin. This mitochondrial actin-binding activity is ATP-sensitive, saturable, reversible, and mediated by protein(s) on the mitochondrial surface (Lazzarino et al., 1994). In addition, ATP-driven, actin-dependent motor activity has been identified on the surface of mitochondria (Simon et al., 1995). These observations support a model of mitochondrial inheritance whereby mitochondria use an actin-dependent motor to drive their movement from mother to daughter cells along actin cable tracks.Yeast genetic screens have revealed several genes, collectively referred to as mdm (mitochondrial distribution and morphology) and mmm (maintenance of mitochondrial morphology), which are required for mitochondrial inheritance (McConnell et al., 1990; Burgess et al., 1994; Sogo and Yaffe, 1994). We have focused on two of these genes: MDM10 and MMM1. Deletion of MDM10 leads to the development of giant spherical mitochondria, presumably by the collapse of elongated mitochondria into a spherical mass (Sogo and Yaffe, 1994). Deletion of MMM1 (Burgess et al., 1994) produces a similar phenotype. In both mutants, the fraction of buds without mitochondria is high, indicating defective mitochondrial inheritance. The proteins encoded by these genes, Mdm10p and Mmm1p, appear to be integral membrane proteins in the mitochondrial outer membrane. Here, we report tests of the hypothesis that Mmm1p and Mdm10p are required to link mitochondria to the cytoskeleton.