40 research outputs found
Identification of the Yeast Mitochondrial Transporter for Oxaloacetate and Sulfate
Saccharomyces cerevisiae encodes 35 members of the mitochondrial carrier family, including the OAC protein. The transport specificities of some family members are known, but most are not. The function of the OAC has been revealed by overproduction in Escherichia coli, reconstitution into liposomes, and demonstration that the proteoliposomes transport malonate, oxaloacetate, sulfate, and thiosulfate. Reconstituted OAC catalyzes both unidirectional transport and exchange of substrates. In S. cerevisiae, OAC is in inner mitochondrial membranes, and deletion of its gene greatly reduces transport of oxaloacetate sulfate, thiosulfate, and malonate. Mitochondria from wild-type cells swelled in isoosmotic solutions of ammonium salts of oxaloacetate, sulfate, thiosulfate, and malonate, indicating that these anions are cotransported with protons. Overexpression of OAC in the deletion strain increased greatly the [(35)S]sulfate/sulfate and [(35)S]sulfate/oxaloacetate exchanges in proteoliposomes reconstituted with digitonin extracts of mitochondria. The main physiological role of OAC appears to be to use the proton-motive force to take up into mitochondria oxaloacetate produced from pyruvate by cytoplasmic pyruvate carboxylase
Biochemical characterization of a new mitochondrial transporter of dephosphocoenzyme A in Drosophila melanogaster
none13noCoA is an essential cofactor that holds a central role in cell metabolism. Although its biosynthetic pathway is conserved across the three domains of life, the subcellular localization of the eukaryotic biosynthetic enzymes and the mechanism behind the cytosolic and mitochondrial CoA pools compartmentalization are still under debate. In humans, the transport of CoA across the inner mitochondrial membrane has been ascribed to two related genes, SLC25A16 and SLC25A42 whereas in D. melanogaster genome only one gene is present, CG4241, phylogenetically closer to SLC25A42. CG4241 encodes two alternatively spliced isoforms, dPCoAC-A and dPCoAC-B. Both isoforms were expressed in Escherichia coli, but only dPCoAC-A was successfully reconstituted into liposomes, where transported dPCoA and, to a lesser extent, ADP and dADP but not CoA, which was a powerful competitive inhibitor. The expression of both isoforms in a Saccharomyces cerevisiae strain lacking the endogenous putative mitochondrial CoA carrier restored the growth on respiratory carbon sources and the mitochondrial levels of CoA. The results reported here and the proposed subcellular localization of some of the enzymes of the fruit fly CoA biosynthetic pathway, suggest that dPCoA may be synthesized and phosphorylated to CoA in the matrix, but it can also be transported by dPCoAC to the cytosol, where it may be phosphorylated to CoA by the monofunctional dPCoA kinase. Thus, dPCoAC may connect the cytosolic and mitochondrial reactions of the CoA biosynthetic pathway without allowing the two CoA pools to get in contact.Vozza, Angelo; Leonardis, Francesco De; Paradies, Eleonora; Grassi, Anna De; Pierri, Ciro Leonardo; Parisi, Giovanni; Marobbio, Carlo Marya Thomas; Lasorsa, Francesco Massimo; Muto, Luigina; Capobianco, Loredana; Dolce, Vincenza; Raho, Susanna; Fiermonte, GiuseppeVozza, Angelo; Leonardis, Francesco De; Paradies, Eleonora; Grassi, Anna De; Pierri, Ciro Leonardo; Parisi, Giovanni; Marobbio, Carlo Marya Thomas; Lasorsa, Francesco Massimo; Muto, Luigina; Capobianco, Loredana; Dolce, Vincenza; Raho, Susanna; Fiermonte, Giusepp
Cytopathic effects of the cytomegalovirus-encoded apoptosis inhibitory protein vMIA
Replication of human cytomegalovirus (CMV) requires the expression of the viral mitochondria–localized inhibitor of apoptosis (vMIA). vMIA inhibits apoptosis by recruiting Bax to mitochondria, resulting in its neutralization. We show that vMIA decreases cell size, reduces actin polymerization, and induces cell rounding. As compared with vMIA-expressing CMV, vMIA-deficient CMV, which replicates in fibroblasts expressing the adenoviral apoptosis suppressor E1B19K, induces less cytopathic effects. These vMIA effects can be separated from its cell death–inhibitory function because vMIA modulates cellular morphology in Bax-deficient cells. Expression of vMIA coincided with a reduction in the cellular adenosine triphosphate (ATP) level. vMIA selectively inhibited one component of the ATP synthasome, namely, the mitochondrial phosphate carrier. Exposure of cells to inhibitors of oxidative phosphorylation produced similar effects, such as an ATP level reduced by 30%, smaller cell size, and deficient actin polymerization. Similarly, knockdown of the phosphate carrier reduced cell size. Our data suggest that the cytopathic effect of CMV can be explained by vMIA effects on mitochondrial bioenergetics
Mitochondrial Carriers for Aspartate, Glutamate and Other Amino Acids: A Review
Members of the mitochondrial carrier (MC) protein family transport various molecules across the mitochondrial inner membrane to interlink steps of metabolic pathways and biochemical processes that take place in different compartments; i.e., are localized partly inside and outside the mitochondrial matrix. MC substrates consist of metabolites, inorganic anions (such as phosphate and sulfate), nucleotides, cofactors and amino acids. These compounds have been identified by in vitro transport assays based on the uptake of radioactively labeled substrates into liposomes reconstituted with recombinant purified MCs. By using this approach, 18 human, plant and yeast MCs for amino acids have been characterized and shown to transport aspartate, glutamate, ornithine, arginine, lysine, histidine, citrulline and glycine with varying substrate specificities, kinetics, influences of the pH gradient, and capacities for the antiport and uniport mode of transport. Aside from providing amino acids for mitochondrial translation, the transport reactions catalyzed by these MCs are crucial in energy, nitrogen, nucleotide and amino acid metabolism. In this review we dissect the transport properties, phylogeny, regulation and expression levels in different tissues of MCs for amino acids, and summarize the main structural aspects known until now about MCs. The effects of their disease-causing mutations and manipulation of their expression levels in cells are also considered as clues for understanding their physiological functions
Unidirectional transport of the mitochondrial GTP/GDP carrier in Saccharomyces cerevisiae
Ggc1p is a yeast mitochondrial carrier protein involved in the GTP/GDP transport. This protein encoded by
YDL198c gene has been shown to be a multicopy suppressor (by an unknown mechanism) of the ability of the
abf2 null mutant to grow at 37°C on glycerol. The ABF2 gene whose product is involved in mitochondrial genome maintenance in S. cerevisiae. Abf2Δ cells loose mtDNA at a high rate when grown in glucose medium
and show a temperature-sensitive defect on non-fermentable carbon sources. The physiological role of Ggc1p in
S. cerevisiae is the GTP transport into mitochondria, in exchange for intramitochondrially generated GDP. In
addition, ggc1Δ cells exhibit lower levels of GTP and increased levels of GDP in their mitochondria; they are
unable to grow on nonfermentable substrates, and they loose mtDNA. In the mitochondrial matrix, GTP is
required as an energy source for protein synthesis; as a substrate for the synthesis of tRNA, mRNA, rRNA, and
RNA primers; and as a phosphate group donor for the activity of GTP-AMP phosphotransferase and G proteins.
In several organisms, GTP is synthesized in the mitochondria by succinyl-CoA ligase, which catalyzes the
conversion of succinyl-CoA to succinate with the generation of GTP, and by nucleoside diphosphate kinase,
which catalyzes the transfer of the phosphate from ATP to a nucleoside diphosphate, to yield nucleotide
triphosphates. In S. cerevisiae, however, succinyl-CoA ligase produces ATP instead of GTP, and the
mitochondrial nucleoside diphosphate kinase is localized in the intermembrane space and it is absent in the
matrix. These observations imply that in S. cerevisiae GTP has to be imported into the mitochondria probably via
a carrier system embedded in the inner mitochondrial membrane. Here, this protein has been overexpressed in E.
coli, reconstituted into phospholipid vesicles, and tested for a variety of potential substrates. When citrate is
present, the carrier changes the transport activity, from an antiport mechanism to an uniport mechanism. A
similar response has also been observed for the protein in the mitochondria. We conclude that uniport transport
of GTP is involved in the homeostasis of guanine nucleotide pool in the mitochondrial matrix