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Lipid saturation induces degradation of squalene epoxidase for sterol homeostasis and cell survival

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The authors describe the ER-associated degradation of Erg1 under increased membrane lipid saturation and show its importance in balancing sterol levels for membrane integrity in budding yeast. A fluid membrane… Click to show full abstract

The authors describe the ER-associated degradation of Erg1 under increased membrane lipid saturation and show its importance in balancing sterol levels for membrane integrity in budding yeast. A fluid membrane containing a mix of unsaturated and saturated lipids is essential for life. However, it is unclear how lipid saturation might affect lipid homeostasis, membrane-associated proteins, and membrane organelles. Here, we generate temperature-sensitive mutants of the sole fatty acid desaturase gene OLE1 in the budding yeast Saccharomyces cerevisiae. Using these mutants, we show that lipid saturation triggers the endoplasmic reticulum–associated degradation (ERAD) of squalene epoxidase Erg1, a rate-limiting enzyme in sterol biosynthesis, via the E3 ligase Doa10-Ubc7 complex. We identify the P469L mutation that abolishes the lipid saturation–induced ERAD of Erg1. Overexpressed WT or stable Erg1 mutants all mislocalize into foci in the ole1 mutant, whereas the stable Erg1 causes aberrant ER and severely compromises the growth of ole1, which are recapitulated by doa10 deletion. The toxicity of the stable Erg1 and doa10 deletion is due to the accumulation of lanosterol and misfolded proteins in ole1. Our study identifies Erg1 as a novel lipid saturation–regulated ERAD target, manifesting a close link between lipid homeostasis and proteostasis that maintains sterol homeostasis under the lipid saturation condition for cell survival.

Keywords: squalene epoxidase; sterol homeostasis; saturation; lipid saturation; degradation

Journal Title: Life Science Alliance
Year Published: 2022

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