Metabolic Engineering of Komagataella phaffii for Xylose Utilization from Cellulosic Biomass

Jongbeom Park; Sujeong Park; Grace Evelina; Sunghee Kim; Yong Su Jin; Won Jae Chi; In Jung Kim; Soo Rin Kim

doi:10.3390/molecules29235695

Metabolic Engineering of Komagataella phaffii for Xylose Utilization from Cellulosic Biomass

Jongbeom Park, Sujeong Park, Grace Evelina, Sunghee Kim, Yong Su Jin, Won Jae Chi, In Jung Kim, Soo Rin Kim

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

Abstract

Cellulosic biomass hydrolysates are rich in glucose and xylose, but most microorganisms, including Komagataella phaffii, are unable to utilize xylose effectively. To address this limitation, we engineered a K. phaffii strain optimized for xylose metabolism through the xylose oxidoreductase pathway and promoter optimization. A promoter library with varying strengths was used to fine-tune the expression levels of the XYL1, XYL2, and XYL3 genes, resulting in a strain with a strong promoter for XYL2 and weaker promoters for XYL1 and XYL3. This engineered strain exhibited superior growth, achieving 14 g cells/L and a maximal growth rate of 0.4 g cells/L-h in kenaf hydrolysate, outperforming a native strain by 17%. This study is the first to report the introduction of the xylose oxidoreductase pathway into K. phaffii, demonstrating its potential as an industrial platform for producing yeast protein and other products from cellulosic biomass.

Original language	English (US)
Article number	5695
Journal	Molecules
Volume	29
Issue number	23
DOIs	https://doi.org/10.3390/molecules29235695
State	Published - Dec 2024

Keywords

Komagataella phaffii
xylose metabolism
promoter library
lignocellulose
kenaf

ASJC Scopus subject areas

Analytical Chemistry
Chemistry (miscellaneous)
Molecular Medicine
Pharmaceutical Science
Drug Discovery
Physical and Theoretical Chemistry
Organic Chemistry

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10.3390/molecules29235695License: CC BY

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title = "Metabolic Engineering of Komagataella phaffii for Xylose Utilization from Cellulosic Biomass",

abstract = "Cellulosic biomass hydrolysates are rich in glucose and xylose, but most microorganisms, including Komagataella phaffii, are unable to utilize xylose effectively. To address this limitation, we engineered a K. phaffii strain optimized for xylose metabolism through the xylose oxidoreductase pathway and promoter optimization. A promoter library with varying strengths was used to fine-tune the expression levels of the XYL1, XYL2, and XYL3 genes, resulting in a strain with a strong promoter for XYL2 and weaker promoters for XYL1 and XYL3. This engineered strain exhibited superior growth, achieving 14 g cells/L and a maximal growth rate of 0.4 g cells/L-h in kenaf hydrolysate, outperforming a native strain by 17%. This study is the first to report the introduction of the xylose oxidoreductase pathway into K. phaffii, demonstrating its potential as an industrial platform for producing yeast protein and other products from cellulosic biomass.",

keywords = "Komagataella phaffii, xylose metabolism, promoter library, lignocellulose, kenaf",

author = "Jongbeom Park and Sujeong Park and Grace Evelina and Sunghee Kim and Jin, {Yong Su} and Chi, {Won Jae} and Kim, {In Jung} and Kim, {Soo Rin}",

note = "This research was funded by the National Institute of Biological Resources (NIBR) under the Ministry of Environment (MOE) of the Republic of Korea (grant number NIBR202402105), and by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MISIT) (grant number 2022R1A2C1093074).",

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AU - Park, Jongbeom

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AU - Kim, Sunghee

AU - Jin, Yong Su

AU - Chi, Won Jae

AU - Kim, In Jung

AU - Kim, Soo Rin

N1 - This research was funded by the National Institute of Biological Resources (NIBR) under the Ministry of Environment (MOE) of the Republic of Korea (grant number NIBR202402105), and by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MISIT) (grant number 2022R1A2C1093074).

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N2 - Cellulosic biomass hydrolysates are rich in glucose and xylose, but most microorganisms, including Komagataella phaffii, are unable to utilize xylose effectively. To address this limitation, we engineered a K. phaffii strain optimized for xylose metabolism through the xylose oxidoreductase pathway and promoter optimization. A promoter library with varying strengths was used to fine-tune the expression levels of the XYL1, XYL2, and XYL3 genes, resulting in a strain with a strong promoter for XYL2 and weaker promoters for XYL1 and XYL3. This engineered strain exhibited superior growth, achieving 14 g cells/L and a maximal growth rate of 0.4 g cells/L-h in kenaf hydrolysate, outperforming a native strain by 17%. This study is the first to report the introduction of the xylose oxidoreductase pathway into K. phaffii, demonstrating its potential as an industrial platform for producing yeast protein and other products from cellulosic biomass.

AB - Cellulosic biomass hydrolysates are rich in glucose and xylose, but most microorganisms, including Komagataella phaffii, are unable to utilize xylose effectively. To address this limitation, we engineered a K. phaffii strain optimized for xylose metabolism through the xylose oxidoreductase pathway and promoter optimization. A promoter library with varying strengths was used to fine-tune the expression levels of the XYL1, XYL2, and XYL3 genes, resulting in a strain with a strong promoter for XYL2 and weaker promoters for XYL1 and XYL3. This engineered strain exhibited superior growth, achieving 14 g cells/L and a maximal growth rate of 0.4 g cells/L-h in kenaf hydrolysate, outperforming a native strain by 17%. This study is the first to report the introduction of the xylose oxidoreductase pathway into K. phaffii, demonstrating its potential as an industrial platform for producing yeast protein and other products from cellulosic biomass.

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Metabolic Engineering of Komagataella phaffii for Xylose Utilization from Cellulosic Biomass

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