The C-terminal domain of Fcj1 is required for formation of crista junctions and interacts with the TOB/SAM complex in mitochondria.

Crista junctions (CJs) are tubular invaginations of the inner membrane of mitochondria that connect the inner boundary with the cristae membrane. These architectural elements are critical for mitochondrial function. The yeast inner membrane protein Fcj1, called mitofilin in mammals, was reported to be preferentially located at CJs and crucial for their formation. Here we investigate the functional roles of individual domains of Fcj1. The most conserved part of Fcj1, the C-terminal domain, is essential for Fcj1 function. In its absence, formation of CJ is strongly impaired and irregular, and stacked cristae are present. This domain interacts with full-length Fcj1, suggesting a role in oligomer formation. It also interacts with Tob55 of the translocase of outer membrane ß-barrel proteins (TOB)/sorting and assembly machinery (SAM) complex, which is required for the insertion of ß-barrel proteins into the outer membrane. The association of the TOB/SAM complex with contact sites depends on the presence of Fcj1. The biogenesis of ß-barrel proteins is not significantly affected in the absence of Fcj1. However, down-regulation of the TOB/SAM complex leads to altered cristae morphology and a moderate reduction in the number of CJs. We propose that the C-terminal domain of Fcj1 is critical for the interaction of Fcj1 with the TOB/SAM complex and thereby for stabilizing CJs in close proximity to the outer membrane. These results assign novel functions to both the C-terminal domain of Fcj1 and the TOB/SAM complex.

Formation of cristae and crista junctions in mitochondria depends on antagonism between Fcj1 and Su e/g.

Crista junctions (CJs) are important for mitochondrial organization and function, but the molecular basis of their formation and architecture is obscure. We have identified and characterized a mitochondrial membrane protein in yeast, Fcj1 (formation of CJ protein 1), which is specifically enriched in CJs. Cells lacking Fcj1 lack CJs, exhibit concentric stacks of inner membrane in the mitochondrial matrix, and show increased levels of F(1)F(O)-ATP synthase (F(1)F(O)) supercomplexes. Overexpression of Fcj1 leads to increased CJ formation, branching of cristae, enlargement of CJ diameter, and reduced levels of F(1)F(O) supercomplexes. Impairment of F(1)F(O) oligomer formation by deletion of its subunits e/g (Su e/g) causes CJ diameter enlargement and reduction of cristae tip numbers and promotes cristae branching. Fcj1 and Su e/g genetically interact. We propose a model in which the antagonism between Fcj1 and Su e/g locally modulates the F(1)F(O) oligomeric state, thereby controlling membrane curvature of cristae to generate CJs and cristae tips.

Cristae formation-linking ultrastructure and function of mitochondria.

Mitochondria are double-membrane enclosed eukaryotic organelles with a central role in numerous cellular functions. The ultrastructure of mitochondria varies considerably between tissues, organisms, and the physiological state of cells. Alterations and remodeling of inner membrane structures are evident in numerous human disorders and during apoptosis. The inner membrane is composed of two subcompartments, the cristae membrane and the inner boundary membrane. Recent advances in electron tomography led to the current view that these membrane domains are connected by rather small tubular structures, termed crista junctions. They have been proposed to regulate the dynamic distribution of proteins and lipids as well as of soluble metabolites between individual mitochondrial subcompartments. One example is the release of cytochrome c upon induction of apoptosis. However, only little is known on the molecular mechanisms mediating the formation and maintenance of cristae and crista junctions. Here we review the current knowledge of the factors that determine cristae morphology and how the latter is linked to mitochondrial function. Further, we formulate several theoretical models which could account for the de novo formation of cristae as well as their propagation from existing cristae.