The yeast mitochondrial carrier Leu5p and its human homologue Graves' disease protein are required for accumulation of coenzyme A in the matrix.

The transport of metabolites, coenzymes, and ions across the mitochondrial inner membrane is still poorly understood. In most cases, membrane transport is facilitated by the so-called mitochondrial carrier proteins. The yeast Saccharomyces cerevisiae contains 35 members of the carrier family, but a function has been identified for only 13 proteins. Here, we investigated the yeast carrier Leu5p (encoded by the gene YHR002w) and its close human homologue Graves' disease protein. Leu5p is inserted into the mitochondrial inner membrane along the specialized import pathway used by carrier proteins. Deletion of LEU5 (strain Deltaleu5) was accompanied by a 15-fold reduction of mitochondrial coenzyme A (CoA) levels but did not affect the cytosolic CoA content. As a consequence, the activities of several mitochondrial CoA-dependent enzymes were strongly decreased in Deltaleu5 cells. Our in vitro and in vivo analyses assign a function to Leu5p in the accumulation of CoA in mitochondria, presumably by serving as a transporter of CoA or a precursor thereof. Expression of the Graves' disease protein in Deltaleu5 cells can replace the function of Leu5p, demonstrating that the human protein represents the orthologue of yeast Leu5p. The function of the human protein might not be directly linked to the disease, as antisera derived from patients with active Graves' disease do not recognize the protein after expression in yeast, suggesting that it does not represent a major autoantigen. The two carrier proteins characterized herein are the first components for which a role in the subcellular distribution of CoA has been identified.

Mitochondrial Isa2p plays a crucial role in the maturation of cellular iron-sulfur proteins.

The assembly of iron-sulfur (Fe/S) clusters in a living cell is mediated by a complex machinery which, in eukaryotes, is localised within mitochondria. Here, we report on a new component of this machinery, the protein Isa2p of the yeast Saccharomyces cerevisiae. The protein shares sequence similarity with yeast Isa1p and the bacterial IscA proteins which recently have been shown to perform a function in Fe/S cluster biosynthesis. Like the Isa1p homologue, Isa2p is localised in the mitochondrial matrix as a soluble protein. Deletion of the ISA2 gene results in the loss of mitochondrial DNA and a strong growth defect. Simultaneous deletion of the ISA1 gene does not further exacerbate this growth phenotype suggesting that the Isa proteins perform a non-essential function. When Isa2p was depleted by regulated gene expression, mtDNA was maintained, but cells grew slowly on non-fermentable carbon sources. The maturation of both mitochondrial and cytosolic Fe/S proteins was strongly impaired in the absence of Isa2p. Thus, Isa2p is a new member of the Fe/S cluster biosynthesis machinery of the mitochondrial matrix and may be involved in the binding of an intermediate of Fe/S cluster assembly.

An internal targeting signal directing proteins into the mitochondrial intermembrane space.

Import of most nucleus-encoded preproteins into mitochondria is mediated by N-terminal presequences and requires a membrane potential and ATP hydrolysis. Little is known about the chemical nature and localization of other mitochondrial targeting signals or of the mechanisms by which they facilitate membrane passage. Mitochondrial heme lyases lack N-terminal targeting information. These proteins are localized in the intermembrane space and are essential for the covalent attachment of heme to c type cytochromes. For import of heme lyases, the translocase of the mitochondrial outer membrane complex is both necessary and sufficient. Here, we report the identification of the targeting signal of mitochondrial heme lyases in the third quarter of these proteins. The targeting sequence is highly conserved among all known heme lyases. Its chemical character is hydrophilic because of a large fraction of both positively and negatively charged amino acid residues. These features clearly distinguish this signal from classical presequences. When inserted into a cytosolic protein, the targeting sequence directs the fusion protein into the intermembrane space, even in the absence of a membrane potential or ATP hydrolysis. The heme lyase targeting sequence represents the first topogenic signal for energy-independent transport into the intermembrane space and harbors two types of information. It assures accurate recognition and translocation by the translocase of the mitochondrial outer membrane complex, and it is responsible for driving the import reaction by undergoing high-affinity interactions with components of the intermembrane space.

A fraction of yeast Cu,Zn-superoxide dismutase and its metallochaperone, CCS, localize to the intermembrane space of mitochondria. A physiological role for SOD1 in guarding against mitochondrial oxidative damage.

Cu,Zn-superoxide dismutase (SOD1) is an abundant, largely cytosolic enzyme that scavenges superoxide anions. The biological role of SOD1 is somewhat controversial because superoxide is thought to arise largely from the mitochondria where a second SOD (manganese SOD) already resides. Using bakers' yeast as a model, we demonstrate that Cu,Zn-SOD1 helps protect mitochondria from oxidative damage, as sod1Delta mutants show elevated protein carbonyls in this organelle. In accordance with this connection to mitochondria, a fraction of active SOD1 localizes within the intermembrane space (IMS) of mitochondria together with its copper chaperone, CCS. Neither CCS nor SOD1 contains typical N-terminal presequences for mitochondrial uptake; however, the mitochondrial accumulation of SOD1 is strongly influenced by CCS. When CCS synthesis is repressed, mitochondrial SOD1 is of low abundance, and conversely IMS SOD1 is very high when CCS is largely mitochondrial. The mitochondrial form of SOD1 is indeed protective against oxidative damage because yeast cells enriched for IMS SOD1 exhibit prolonged survival in the stationary phase, an established marker of mitochondrial oxidative stress. Cu,Zn-SOD1 in the mitochondria appears important for reactive oxygen physiology and may have critical implications for SOD1 mutations linked to the fatal neurodegenerative disorder, amyotrophic lateral sclerosis.

Isa1p is a component of the mitochondrial machinery for maturation of cellular iron-sulfur proteins and requires conserved cysteine residues for function.

In eukaryotes, mitochondria execute a central task in the assembly of cellular iron-sulfur (Fe/S) proteins. The organelles synthesize their own set of Fe/S proteins, and they initiate the generation of extramitochondrial Fe/S proteins. In the present study, we identify the mitochondrial matrix protein Isa1p of Saccharomyces cerevisiae as a new member of the Fe/S cluster biosynthesis machinery. Isa1p belongs to a family of homologous proteins present in prokaryotes and eukaryotes. Deletion of the ISA1 gene results in the loss of mitochondrial DNA precluding the use of the Deltaisa1 strain for functional analysis. Cells in which Isa1p was depleted by regulated gene expression maintained the mitochondrial DNA, yet the cells displayed retarded growth on nonfermentable carbon sources. This finding indicates the importance of Isa1p for mitochondrial function. Deficiency of Isa1p caused a defect in mitochondrial Fe/S protein assembly. Moreover, Isa1p was required for maturation of cytosolic Fe/S proteins. Two cysteine residues in a conserved sequence motif characterizing the Isa1p protein family were found to be essential for Isa1p function in the biogenesis of both intra- and extramitochondrial Fe/S proteins. Our findings suggest a function for Isa1p in the binding of iron or an intermediate of Fe/S cluster assembly.

Requirements for the mitochondrial import and localization of dihydroorotate dehydrogenase.

In animals, dihydroorotate dehydrogenase (DHODH) is a mitochondrial protein that carries out the fourth step in de novo pyrimidine biosynthesis. Because this is the only enzyme of this pathway that is localized to mitochondria and because the enzyme is cytosolic in some bacteria and fungi, we carried out studies to understand the mode of targeting of animal DHODH and its submitochondrial localization. Analysis of fractionated rat liver mitochondria revealed that DHODH is an integral membrane protein exposed to the intermembrane space. In vitro-synthesized Drosophila, rat and human DHODH proteins were efficiently imported into the intermembrane space of isolated yeast mitochondria. Import did not alter the size of the in vitro synthesized protein, nor was there a detectable size difference when compared to the DHODH protein found in vivo. Thus, there is no apparent proteolytic processing of the protein during import either in vitro or in vivo. Import of rat DHODH into isolated yeast mitochondria required inner membrane potential and was at least partially dependent upon matrix ATP, indicating that its localization uses the well described import machinery of the mitochondrial inner membrane. The DHODH proteins of animals differ from the cytosolic proteins found in some bacteria and fungi by the presence of an N-terminal segment that resembles mitochondrial-targeting presequences. Deletion of the cationic portion of this N-terminal sequence from the rat DHODH protein blocked its import into isolated yeast mitochondria, whereas deletion of the adjacent hydrophobic segment resulted in import of the protein into the matrix. Thus, the N-terminus of the DHODH protein contains a bipartite signal that governs import and correct insertion into the mitochondrial inner membrane.

The essential role of mitochondria in the biogenesis of cellular iron-sulfur proteins.

Iron-sulfur (Fe/S) proteins play an important role in electron transfer processes and in various enzymatic reactions. In eukaryotic cells, known Fe/S proteins are localised in mitochondria, the cytosol and the nucleus. The biogenesis of these proteins has only recently become the focus of investigations. Mitochondria are the major site of Fe/S cluster biosynthesis in the cell. The organelles contain an Fe/S cluster biosynthesis apparatus that resembles that of prokaryotic cells. This apparatus consists of some ten proteins including a cysteine desulfurase producing elemental sulfur for biogenesis, a ferredoxin involved in reduction, and two chaperones. The mitochondrial Fe/S cluster synthesis apparatus not only assembles mitochondrial Fe/S proteins, but also initiates formation of extra-mitochondrial Fe/S proteins. This involves the export of sulfur and possibly iron from mitochondria to the cytosol, a reaction performed by the ABC transporter Atm1p of the mitochondrial inner membrane. A possible substrate of Atm1p is an Fe/S cluster that may be stabilised for transport. Constituents of the cytosol involved in the incorporation of the Fe/S cluster into apoproteins have not been described yet. Many of the mitochondrial proteins involved in Fe/S cluster formation are essential, illustrating the central importance of Fe/S proteins for life. Defects in Fe/S protein biogenesis are associated with the abnormal accumulation of iron within mitochondria and are the cause of an iron storage disease.

Apocytochrome c requires the TOM complex for translocation across the mitochondrial outer membrane.

The import of proteins into the mitochondrial intermembrane space differs in various aspects from the classical import pathway into the matrix. Apocytochrome c defines one of several pathways known to reach the intermembrane space, yet the components and pathways involved in outer membrane translocation are poorly defined. Here, we report the reconstitution of the apocytochrome c import reaction using proteoliposomes harbouring purified components. Import specifically requires the protease-resistant part of the TOM complex and is driven by interactions of the apoprotein with internal parts of the complex (involving Tom40) and the 'trans-side receptor' cytochrome c haem lyase. Despite the necessity of TOM complex function, the translocation pathway of apocytochrome c does not overlap with that of presequence-containing preproteins. We conclude that the TOM complex is a universal preprotein translocase that mediates membrane passage of apocytochrome c and other preproteins along distinct pathways. Apocytochrome c may provide a paradigm for the import of other small proteins into the intermembrane space such as factors used in apoptosis and protection from stress.

Peptide nucleic acid delivery to human mitochondria.

Peptide nucleic acids (PNAs) are synthetic polynucleobase molecules, which bind to DNA and RNA with high affinity and specificity. Although PNAs have enormous potential as anti-sense agents, the success of PNA-mediated gene therapy will require efficient cellular uptake and sub-cellular trafficking. At present these mechanisms are poorly understood. To address this, we have studied the uptake of biotinylated PNAs into cultured cell lines using fluorescence confocal microscopy. In human myoblasts, initial punctate staining was followed by the release of PNAs into the cytosol and subsequent localisation and concentration in the nucleus. To determine whether PNAs could also be used as therapeutic agents for mtDNA disease, we attempted to localise PNAs to the mitochondrial matrix. When attached to the presequence peptide of the nuclear-encoded human cytochrome c oxidase (COX) subunit VIII, the biotinylated PNA was successfully imported into isolated organelles in vitro. Furthermore, delivery of the biotinylated peptide-PNA to mitochondria in intact cells was confirmed by confocal microscopy. These studies demonstrate that biotinylated PNAs can be directed across cell membranes and to a specific sub-cellular compartment within human cells - highlighting the importance of these novel molecules for human gene therapy.