Engineering yeast peroxisome assembly enables the increased production of acetyl-CoA and its derived 5-deoxyflavonoids

Yongxing Li; Bingjie Du; Chun Li; Xudong Feng

doi:10.1038/s41467-025-65444-1

Engineering yeast peroxisome assembly enables the increased production of acetyl-CoA and its derived 5-deoxyflavonoids

Yongxing Li
, Bingjie Du
, Chun Li^*
, Xudong Feng^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Acetyl-CoA serves as a foundational precursor and energy source for various biosynthesis pathways. The insufficient supply of acetyl-CoA in cytosol is usually a bottleneck for exogenous chemical synthesis in engineered microbes such as yeast. Exportation of acetyl-CoA from peroxisome, an exclusive organelle for fatty acids β-oxidation, may be an effective way to solve this problem. In this study, we develop a peroxin (PEX) engineering strategy to modulate peroxisome assembly in S. cerevisiae. Then, robust peroxisomes are constructed with improved acetyl-CoA supply by up to 98%, which further leads to the increased liquiritigenin titer (1102.4 mg/L). We also demonstrate that the PEX–mediated peroxisome engineering strategy can be extended across yeast species. Hybrid peroxisomes with tailored function are constructed in S. cerevisiae by transplanting selected PEXs from Y. lipolytica. Our study provides mechanistic insights into the “PEXs–peroxisome assembly–acetyl-CoA synthesis” relationship.

Original language	English
Article number	10468
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-65444-1
Publication status	Published - Dec 2025
Externally published	Yes

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title = "Engineering yeast peroxisome assembly enables the increased production of acetyl-CoA and its derived 5-deoxyflavonoids",

abstract = "Acetyl-CoA serves as a foundational precursor and energy source for various biosynthesis pathways. The insufficient supply of acetyl-CoA in cytosol is usually a bottleneck for exogenous chemical synthesis in engineered microbes such as yeast. Exportation of acetyl-CoA from peroxisome, an exclusive organelle for fatty acids β-oxidation, may be an effective way to solve this problem. In this study, we develop a peroxin (PEX) engineering strategy to modulate peroxisome assembly in S. cerevisiae. Then, robust peroxisomes are constructed with improved acetyl-CoA supply by up to 98\%, which further leads to the increased liquiritigenin titer (1102.4 mg/L). We also demonstrate that the PEX–mediated peroxisome engineering strategy can be extended across yeast species. Hybrid peroxisomes with tailored function are constructed in S. cerevisiae by transplanting selected PEXs from Y. lipolytica. Our study provides mechanistic insights into the “PEXs–peroxisome assembly–acetyl-CoA synthesis” relationship.",

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AU - Li, Yongxing

AU - Du, Bingjie

AU - Li, Chun

AU - Feng, Xudong

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/12

Y1 - 2025/12

N2 - Acetyl-CoA serves as a foundational precursor and energy source for various biosynthesis pathways. The insufficient supply of acetyl-CoA in cytosol is usually a bottleneck for exogenous chemical synthesis in engineered microbes such as yeast. Exportation of acetyl-CoA from peroxisome, an exclusive organelle for fatty acids β-oxidation, may be an effective way to solve this problem. In this study, we develop a peroxin (PEX) engineering strategy to modulate peroxisome assembly in S. cerevisiae. Then, robust peroxisomes are constructed with improved acetyl-CoA supply by up to 98%, which further leads to the increased liquiritigenin titer (1102.4 mg/L). We also demonstrate that the PEX–mediated peroxisome engineering strategy can be extended across yeast species. Hybrid peroxisomes with tailored function are constructed in S. cerevisiae by transplanting selected PEXs from Y. lipolytica. Our study provides mechanistic insights into the “PEXs–peroxisome assembly–acetyl-CoA synthesis” relationship.

AB - Acetyl-CoA serves as a foundational precursor and energy source for various biosynthesis pathways. The insufficient supply of acetyl-CoA in cytosol is usually a bottleneck for exogenous chemical synthesis in engineered microbes such as yeast. Exportation of acetyl-CoA from peroxisome, an exclusive organelle for fatty acids β-oxidation, may be an effective way to solve this problem. In this study, we develop a peroxin (PEX) engineering strategy to modulate peroxisome assembly in S. cerevisiae. Then, robust peroxisomes are constructed with improved acetyl-CoA supply by up to 98%, which further leads to the increased liquiritigenin titer (1102.4 mg/L). We also demonstrate that the PEX–mediated peroxisome engineering strategy can be extended across yeast species. Hybrid peroxisomes with tailored function are constructed in S. cerevisiae by transplanting selected PEXs from Y. lipolytica. Our study provides mechanistic insights into the “PEXs–peroxisome assembly–acetyl-CoA synthesis” relationship.

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Engineering yeast peroxisome assembly enables the increased production of acetyl-CoA and its derived 5-deoxyflavonoids

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