Lipoic acid is a sulfur-containing cofactor required for the function of several multienzyme complexes involved in the oxidative decarboxylation of ␣-keto acids and glycine. Mechanistic details of lipoic acid metabolism are unclear in eukaryotes, despite two well defined pathways for synthesis and covalent attachment of lipoic acid in prokaryotes. We report here the involvement of four genes in the synthesis and attachment of lipoic acid in Saccharomyces cerevisiae. LIP2 and LIP5 are required for lipoylation of all three mitochondrial target proteins: Lat1 and Kgd2, the respective E2 subunits of pyruvate dehydrogenase and ␣-ketoglutarate dehydrogenase, and Gcv3, the H protein of the glycine cleavage enzyme. LIP3, which encodes a lipoate-protein ligase homolog, is necessary for lipoylation of Lat1 and Kgd2, and the enzymatic activity of Lip3 is essential for this function. Finally, GCV3, encoding the H protein target of lipoylation, is itself absolutely required for lipoylation of Lat1 and Kgd2. We show that lipoylated Gcv3, and not glycine cleavage activity per se, is responsible for this function. Demonstration that a target of lipoylation is required for lipoylation is a novel result. Through analysis of the role of these genes in protein lipoylation, we conclude that only one pathway for de novo synthesis and attachment of lipoic acid exists in yeast. We propose a model for protein lipoylation in which Lip2, Lip3, Lip5, and Gcv3 function in a complex, which may be regulated by the availability of acetyl-CoA, and which in turn may regulate mitochondrial gene expression.Several oxidative decarboxylation reactions are carried out in prokaryotes and eukaryotes by multienzyme complexes. The function of these complexes requires the action of a sulfurcontaining cofactor, lipoic acid (6,8-thioctic acid) (1, 2). Lipoic acid is covalently attached via an amide linkage to a specific lysine residue on the surface of the conserved lipoyl domain of the E2 subunits of pyruvate dehydrogenase (PDH), 3 ␣-ketoglutarate dehydrogenase (␣-KDH), the branched chain ␣-keto acid dehydrogenase complexes, and the H protein of the glycine cleavage (GC) enzyme (3). The lipoyl moiety serves as a swinging arm that shuttles reaction intermediates between active sites within the complexes (1). Despite the well characterized function of lipoic acid as a prosthetic group, the mechanisms of its synthesis and attachment to proteins are the subject of ongoing investigations (4 -7). These reactions are best understood in Escherichia coli, which has two well defined pathways for lipoic acid synthesis and attachment: a de novo pathway and a salvage pathway (8). Octanoic acid, synthesized on the acyl carrier protein (ACP) (9), is the substrate for the de novo pathway. Lipoyl synthase (LipA) catalyzes the addition of two sulfur atoms to form lipoic acid from octanoic acid either before or after transfer to the target protein (10) by lipoyl(octanoyl)-ACP:protein transferase (LipB) (11, 12). The preferred order of these two reactions is attachment of oct...
Eukaryotes harbor a highly conserved mitochondrial pathway for fatty acid synthesis (FAS), which is completely independent of the eukaryotic cytosolic FAS apparatus. The activities of the mitochondrial FAS system are catalyzed by soluble enzymes, and the pathway thus resembles its prokaryotic counterparts. Except for octanoic acid, which is the direct precursor for lipoic acid synthesis, other end products and functions of the mitochondrial FAS pathway are still largely enigmatic. In addition to low cellular levels of lipoic acid, disruption of genes encoding mitochondrial FAS enzymes in yeast results in a respiratory-deficient phenotype and small rudimentary mitochondria. Recently, two distinct links between mitochondrial FAS and RNA processing have been discovered in vertebrates and yeast, respectively. In vertebrates, the mitochondrial 3-hydroxyacyl-acyl carrier protein dehydratase and the RPP14 subunit of RNase P are encoded by the same bicistronic transcript in an evolutionarily conserved arrangement that is unusual for eukaryotes. In yeast, defects in mitochondrial FAS result in inefficient RNase P cleavage in the organelle. The intersection of mitochondrial FAS and RNA metabolism in both systems provides a novel mechanism for the coordination of intermediary metabolism in eukaryotic cells.
Recent studies have revealed that mitochondria are able to synthesize fatty acids in a malonyl-CoA/acyl carrier protein (ACP)-dependent manner. This pathway resembles bacterial fatty acid synthesis (FAS) type II, which uses discrete, nuclearly encoded proteins. Experimental evidence, obtained mainly through using yeast as a model system, indicates that this pathway is essential for mitochondrial respiratory function. Curiously, the deficiency in mitochondrial FAS cannot be complemented by inclusion of fatty acids in the culture medium or by products of the cytosolic FAS complex. Defects in mitochondrial FAS in yeast result in the inability to grow on nonfermentable carbon sources, the loss of mitochondrial cytochromes a/a3 and b, mitochondrial RNA processing defects, and loss of cellular lipoic acid. Eukaryotic FAS II generates octanoyl-ACP, a substrate for mitochondrial lipoic acid synthase. Endogenous lipoic acid synthesis challenges the hypothesis that lipoic acid can be provided as an exogenously supplied vitamin. Purified eukaryotic FAS II enzymes are catalytically active in vitro using substrates with an acyl chain length of up to 16 carbon atoms. However, with the exception of 3-hydroxymyristoyl-ACP, a component of respiratory complex I in higher eukaryotes, the fate of long-chain fatty acids synthesized by the mitochondrial FAS pathway remains an enigma. The linkage of FAS II genes to published animal models for human disease supports the hypothesis that mitochondrial FAS dysfunction leads to the development of disorders in mammals.
Distinct metabolic pathways can intersect in ways that allow hierarchical or reciprocal regulation. In a screen of respiration-deficient Saccharomyces cerevisiae gene deletion strains for defects in mitochondrial RNA processing, we found that lack of any enzyme in the mitochondrial fatty acid type II biosynthetic pathway (FAS II) led to inefficient 5 processing of mitochondrial precursor tRNAs by RNase P. In particular, the precursor containing both RNase P RNA (RPM1) and tRNA Pro accumulated dramatically. Subsequent Pet127-driven 5 processing of RPM1 was blocked. The FAS II pathway defects resulted in the loss of lipoic acid attachment to subunits of three key mitochondrial enzymes, which suggests that the octanoic acid produced by the pathway is the sole precursor for lipoic acid synthesis and attachment. The protein component of yeast mitochondrial RNase P, Rpm2, is not modified by lipoic acid in the wild-type strain, and it is imported in FAS II mutant strains. Thus, a product of the FAS II pathway is required for RNase P RNA maturation, which positively affects RNase P activity. In addition, a product is required for lipoic acid production, which is needed for the activity of pyruvate dehydrogenase, which feeds acetyl-coenzyme A into the FAS II pathway. These two positive feedback cycles may provide switch-like control of mitochondrial gene expression in response to the metabolic state of the cell.Intersections of biological pathways previously thought to be distinct have emerged recently from genome-wide functional screens in model organisms (52,62,63). Through a genomewide screen of Saccharomyces cerevisiae, we have discovered the intersection of mitochondrial type II fatty acid synthesis (FAS II) with mitochondrial RNA processing.There are two distinct fatty acid synthesis pathways in eukaryotes. Fatty acid synthesis type I (FAS I) is catalyzed by cytosolic multifunctional enzyme complexes that produce the bulk of fatty acids in the cell (45). FAS II occurs in mitochondria and chloroplasts (as well as in prokaryotes) and is catalyzed by the sequential action of individual enzymes (21, 51). The mitochondrial FAS II pathway produces octanoic acid, which is the precursor molecule for the synthesis of lipoic acid. Lipoic acid is the "swinging arm" cofactor that serves to shuttle reaction intermediates between the active sites of several mitochondrial keto acid dehydrogenase complexes (35). In yeast, lipoic acid is covalently bound to conserved lysine residues on three different proteins, the E2 subunit of pyruvate dehydrogenase (PDH) (34) and ␣-ketoglutarate dehydrogenase (␣-KDH) (38) and on the H protein of the glycine cleavage enzyme (GC) (33).Mitochondrial genes are expressed through a coordinated effort between the nuclear and the mitochondrial genomes. Mitochondrial DNA in eukaryotes encodes a small number of proteins that are components of the respiratory chain complexes and ATP synthase, as well as mitochondrial rRNAs and most tRNAs (1, 15). Other proteins required for mitochondrial function are encod...
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