The yeast Saccharomyces cerevisiae is a powerful experimental system to study biochemical, cell biological and molecular biological aspects of lipid synthesis. Most but not all genes encoding enzymes involved in fatty acid, phospholipid, sterol or sphingolipid biosynthesis of this unicellular eukaryote have been cloned, and many gene products have been functionally characterized. Less information is available about genes and gene products governing the transport of lipids between organelles and within membranes, turnover and degradation of complex lipids, regulation of lipid biosynthesis, and linkage of lipid metabolism to other cellular processes. Here we summarize current knowledge about lipid biosynthetic pathways in S. cerevisiae and describe the characteristic features of the gene products involved. We focus on recent discoveries in these fields and address questions on the regulation of lipid synthesis, subcellular localization of lipid biosynthetic steps, cross‐talk between organelles during lipid synthesis and subcellular distribution of lipids. Finally, we discuss distinct functions of certain key lipids and their possible roles in cellular processes. © 1998 John Wiley & Sons, Ltd.
We have cloned the Saccharomyces cerevisiae C-4 sterol methyl oxidase ERG25 gene. The sterol methyl oxidase performs the first of three enzymic steps required to remove the two C-4 methyl groups leading to cholesterol (animal), ergosterol (fungal), and stigmasterol (plant) biosynthesis. An ergosterol auxotroph, erg25, which fails to demethylate and concomitantly accumulates 4,4-dimethylzymosterol, was isolated after mutagenesis. A complementing clone consisting of a 1.35-kb Dra I fragment encoded a 309-amino acid polypeptide (calculated molecular mass, 36.48 kDa). The amino acid sequence shows a C-terminal endoplasmic reticulum retrieval signal KKXX and three histidine-rich clusters found in eukaryotic membrane desaturases and in a bacterial alkane hydroxylase and xylene monooxygenase. The sterol profile of an ERG25 disruptant was consistent with the erg25 allele obtained by mutagenesis.In the synthesis of sterols, required components of eukaryotic membranes, an initial sterol (lanosterol in animals and fungi and cycloartenol in plants) undergoes three demethylations prior to formation of the end product sterol. The first demethylation occurs directly with lanosterol or cycloartenol and results in removal of the C-14 methyl group. The fungal demethylation is performed by the product of the ERG11 gene (Fig.
Research on the ergosterol biosynthetic pathway in fungi has focused on the identification of the specific sterol structure required for normal membrane structure and function and for completion of the cell cycle. The pathway and its end product are also the targets for a number of antifungal drugs. Identification of essential steps in ergo-sterol biosynthesis could provide new targets for the development of novel therapeutic agents. Nine of the eleven genes in the portion of the pathway committed exclusively to ergosterol biosynthesis have been cloned, and their essentiality for aerobic growth has been determined. The first three genes, ERG9 (squalene synthase), ERG1 (squalene epoxidase), and ERG7 (lanosterol synthase), have been cloned and found to be essential for aerobic viability since their absence would result in the cell being unable to synthesize a sterol molecule. The remaining eight genes encode enzymes which metabolize the first sterol, lanosterol, to ultimately form ergosterol. The two earliest genes, ERG11 (lanosterol demethylase) and ERG24 (C-14 reductase), have been cloned and found to be essential for aerobic growth but are suppressed by mutations in the C-5 desaturase (ERG3) gene and fen1 and fen2 mutations, respectively. The remaining cloned genes, ERG6 (C-24 methylase), ERG2 (D8AE7 isomerase), ERG3 (C-5 desaturase), and ERG4 (C-24(28) reductase), have been found to be nonessential. The remaining genes not yet cloned are the C-4 demethylase and the C-22 desaturase (ERG5).
The identification of the precise structural features of yeast sterol molecules required for the essential "sparking" function has been a controversial area of research. Recent cloning and gene disruption studies in Saccharomyces cerevisiae have shown that C-24 methylation (ERG6), C-5 desaturation (ERG3) and delta 8-delta 7 isomerization (ERG2) are not required, while C-14 demethylation (ERG11) and C-14 reduction (ERG24) are each required for aerobic viability. Earlier observations had indicated that C-14 demethylase deficient strains could be restored to aerobic growth by suppressor mutations that caused a deficiency in C-5 desaturase. These strains were reported to synthesize some ergosterol, indicating that they contained leaky mutations in both ERG11 and ERG3, thereby making it impossible to determine whether the removal of the C-14 methyl group was required for aerobic viability. The availability of the ERG11 and ERG3 genes has been used in this study to construct strains that contain null mutants in both ERG11 and ERG3. Results show that these double disruption strains are viable and that spontaneously arising suppressors of the ERG11 disruption are erg3 mutants. The erg11 mutants of S. cerevisiae are compared to similar mutants of Candida albicans that are viable in the absence of the erg3 lesion.
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