Abstract
Ergosterol synthesis is essential for cellular growth and viability of the budding yeast Saccharomyces cerevisiae, and intracellular sterol distribution and homeostasis are therefore highly regulated in this species. Erg25 is an iron-containing C4-methyl sterol oxidase that contributes to the conversion of 4,4-dimethylzymosterol to zymosterol, a precursor of ergosterol. The ERG29 gene encodes an endoplasmic reticulum (ER)-associated protein, and here we identified a role for Erg29 in the methyl sterol oxidase step of ergosterol synthesis. ERG29 deletion resulted in lethality in respiring cells, but respiration-incompetent (Rho- or Rho0) cells survived, suggesting that Erg29 loss leads to accumulation of oxidized sterol metabolites that affect cell viability. Down-regulation of ERG29 expression in Δerg29 cells indeed led to accumulation of methyl sterol metabolites, resulting in increased mitochondrial oxidants and a decreased ability of mitochondria to synthesize iron-sulfur (Fe-S) clusters due to reduced levels of Yfh1, the mammalian frataxin homolog, which is involved in mitochondrial iron metabolism. Using a high-copy genomic library, we identified suppressor genes that permitted growth of Δerg29 cells on respiratory substrates, and these included genes encoding the mitochondrial proteins Yfh1, Mmt1, Mmt2, and Pet20, which reversed all phenotypes associated with loss of ERG29 Of note, loss of Erg25 also resulted in accumulation of methyl sterol metabolites and also increased mitochondrial oxidants and degradation of Yfh1. We propose that accumulation of toxic intermediates of the methyl sterol oxidase reaction increases mitochondrial oxidants, which affect Yfh1 protein stability. These results indicate an interaction between sterols generated by ER proteins and mitochondrial iron metabolism.
Highlights
Ergosterol synthesis is essential for cellular growth and viability of the budding yeast Saccharomyces cerevisiae, and intracellular sterol distribution and homeostasis are highly regulated in this species
Preliminary studies showed that when cells with a missense mutation in YMR134W/ERG29 were placed on low iron, they had an altered sterol pattern, similar to that seen in mutants in ERG25
We utilized galactose regulation of the ⌬erg29p-estradiolGAL1ERG29 strain to examine the effects of loss of Erg29 on sterol synthesis. ⌬erg29pGAL1ERG29 cells grown in galactose had some increase in the levels of 4,4-DMZ and 4-methyl fecosterol and decreased levels of ergosterol compared with WT cells; in glucose-containing medium, ⌬erg29pGAL1ERG29 cells showed an increase in intermediate sterols and a corresponding decrease in zymosterol and ergosterol (Fig. 1B)
Summary
Ergosterol synthesis is essential for cellular growth and viability of the budding yeast Saccharomyces cerevisiae, and intracellular sterol distribution and homeostasis are highly regulated in this species. Down-regulation of ERG29 expression in ⌬erg cells led to accumulation of methyl sterol metabolites, resulting in increased mitochondrial oxidants and a decreased ability of mitochondria to synthesize iron–sulfur (Fe-S) clusters due to reduced levels of Yfh, the mammalian frataxin homolog, which is involved in mitochondrial iron metabolism. Loss of Yfh, as with mutations in genes in the early steps of mitochondrial Fe-S cluster synthesis, results in increased deposits of insoluble iron, “nanoparticles,” within mitochondria [11]. We determined that deletion of ERG29 resulted in lethality in respiring cells, but cells that had lost the ability to respire (RhoϪ or Rho0) could survive and that ERG29 encodes an endoplasmic reticulum (ER) protein that plays a role in sterol synthesis at the methyl sterol oxidase step. HIS3 from Ref. 20 TRP1 (this study) TRP1 (this study) URA3 (this study) URA3 (this study) URA3 from Ref. 66 URA3 from Ref. 45 LEU2 from Ref. 25 LEU2 from Ref. 25 LEU2 from Ref. 5 LEU2 from Ref. 5 LEU2 (this study) LEU2 from Ref. 25 URA3 from Ref. 25 URA3 from Ref. 25 pression of mitochondrial iron exporter gene MMT1 or MMT2 or by overexpression of YFH1 or PET20, a nuclear gene that encodes a mitochondrial protein involved in protecting mitochondria from oxidant damage [15]
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