Methanol-based biosynthesis of p-coumaric acid by engineered Pichia pastoris

Mengyuan Chen; Jiayu Fang; Shuxian Wang; Guoxia Liu; Yanping Zhang; Yin Li; Kaizhi Jia; Taicheng Zhu

doi:10.1186/s40643-026-01068-7

Bioresources and Bioprocessing ›› 2026, Vol. 13 ›› Issue (1) :68 DOI: 10.1186/s40643-026-01068-7

Research

research-article

Methanol-based biosynthesis of p-coumaric acid by engineered Pichia pastoris

Author information +

History +

PDF

Abstract

p-Coumaric acid (p-CA) is a key aromatic precursor for the biosynthesis of flavonoids, stilbenoids, and other high-value phenylpropanoids. While microbial production of p-CA typically relies on sugar-based substrates, methanol offers a sustainable and cost-effective alternative, though its use for aromatic biosynthesis remains unexplored. Here, we report the first de novo production of p-CA from methanol using engineered methylotrophic yeast Pichia pastoris. Through heterologous expression of a tyrosine ammonia-lyase and implementing a balanced push–pull strategy in the shikimate pathway using feedback-resistant variants of DAHP synthase (ARO4) and chorismate mutase (ARO7), carbon flux from methanol-derived C3 and C4 precursors was effectively redirected toward aromatic biosynthesis. Shake-flask studies revealed strong gene-dosage-dependent p-CA production, but strains with high-copy numbers suffered metabolic burden under high-density fermentation. Fed-batch bioreactor cultivation demonstrated that a moderate-copy strain achieved the highest titer of 704 ± 6 mg/L, outperforming high-copy variants in robustness and scalability. This study establishes P. pastoris as a promising chassis for methanol-based aromatic production and highlights the critical trade-off between pathway amplification and cellular fitness in C1 biomanufacturing.

Keywords

p-Coumaric acid / Methanol / Pichia pastoris / Shikimate pathway / Copy number

Cite this article

Download citation ▾

Mengyuan Chen, Jiayu Fang, Shuxian Wang, Guoxia Liu, Yanping Zhang, Yin Li, Kaizhi Jia, Taicheng Zhu. Methanol-based biosynthesis of p-coumaric acid by engineered Pichia pastoris. Bioresources and Bioprocessing, 2026, 13(1): 68 DOI:10.1186/s40643-026-01068-7

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Araújo FF, Farias D, Neri-Numa IA, Pastore GM. Polyphenols and their applications: an approach in food chemistry and innovation potential. Food Chem, 2021, 338: 127535

[2]	Bae J, Jin S, Kang S, et al.. Recent progress in the engineering of c1-utilizing microbes. Curr Opin Biotech, 2022, 78: 102836

[3]	Cámara E, Landes N, Albiol J, et al.. Increased dosage of AOX1 promoter-regulated expression cassettes leads to transcription attenuation of the methanol metabolism in pichia pastoris. Sci Rep-Uk, 2017, 7: 44302

[4]	Feng L, Xu J, Ye C, et al.. Metabolic engineering of pichia pastoris for the production of triacetic acid lactone. J Fungi, 2023, 9: 494

[5]	Gassler T, Heistinger L, Mattanovich D, et al.. CRISPR/cas9-mediated homology-directed genome editing in pichia pastoris. 1923, 2019 United States

[6]	Gu Y, Ma J, Zhu Y, et al.. Engineering Yarrowia lipolytica as a chassis for de novo synthesis of five aromatic-derived natural products and chemicals. Acs Synth Biol, 2020, 9: 2096-2106

[7]	Guo F, Qiao Y, Xin F, et al.. Bioconversion of c1 feedstocks for chemical production using pichia pastoris. Trends Biotechnol, 2023, 41: 1066-1079

[8]	Jeong C, Han SH, Lim CG, et al.. Metabolic engineering of for enhanced production of -coumaric acid via l-phenylalanine biosynthesis pathway. Bioproc Biosyst Eng, 2025, 48: 565-576

[9]	Jiang X, Li M, Wang Z, et al.. CRISPR-mediated rDNA integration and fluorescence screening for pathway optimization in pichia pastoris. Chem Bio Eng, 2024, 1: 940-951

[10]	Kuivanen J, Kannisto M, Mojzita D, et al.. Engineering of Saccharomyces cerevisiae for anthranilate and methyl anthranilate production. Microb Cell Fact, 2021, 20: 34

[11]	Kumokita R, Bamba T, Inokuma K, et al.. Construction of an l-tyrosine chassis in enhances aromatic secondary metabolite production from glycerol. Acs Synth Biol, 2022, 11: 2098-2107

[12]	Kumokita R, Yoshida T, Shirai T, et al.. Aromatic secondary metabolite production from glycerol was enhanced by amino acid addition in pichia pastoris. Appl Microbiol Biot, 2023, 107: 7391-7401

[13]	Li Z, Gao C, Ye C, et al.. Systems engineering of Escherichia coli for high-level shikimate production. Metab Eng, 2023, 75: 1-11

[14]	Li K, Liu X, Liu C, et al.. Improved methanol utilization of komagataella phaffii by rebuilding metabolic network based on new alcohol-aldehyde transformation system. J Biotechnol, 2025, 406: 60-70

[15]	Liu Q, Yu T, Li X, et al.. Rewiring carbon metabolism in yeast for high level production of aromatic chemicals. Nat Commun, 2019, 10: 4976

[16]	Liu D, Liu Z, Shan X, et al.. Efficient synthesis of shikimic acid in Escherichia coli through self-feedback regulation and accelerated evolution. J Agr Food Chem, 2025, 73: 21445-21452

[17]	Meng L, Diao M, Wang Q, et al.. Efficient biosynthesis of resveratrol via combining phenylalanine and tyrosine pathways in Saccharomyces cerevisiae. Microb Cell Fact, 2023, 22: 46

[18]	Miao L, Li Y, Zhu T. Metabolic engineering of methylotrophic pichia pastoris for the production of β-alanine. Bioresour Bioprocess, 2021, 8: 89

[19]	Qi H, Li Y, Cai M, et al.. High-copy genome integration and stable production of p-coumaric acid via a POT1-mediated strategy in Saccharomyces cerevisiae. J Appl Microbiol, 2022, 133: 707-719

[20]	Qian X, Wang T, Zhao L et al (2021) Effect of gene copy number on the expression of bovine lactoferrin functional fragment and cell survival in recombinant pichia pastoris. Food Ferment Ind. https://doi.org/10.13995/j.cnki.11-1802/ts.025190

[21]	Qiu C, Wang X, Zuo J, et al.. Systems engineering Escherichia coli for efficient productionp -coumaric acid from glucose. Biotechnol Bioeng, 2024, 121: 2147-2162

[22]	Ru Z, Liu M, Chen Q, et al.. High-level de novo production of (2s)-naringenin in Yarrowia lipolytica using metabolic and enzyme engineering. ACS Agricultural Sci &Amp Technol, 2025, 5: 784-793

[23]	Tang H, Wu L, Guo S, et al.. Metabolic engineering of yeast for the production of carbohydrate-derived foods and chemicals from c1–3 molecules. Nat Catal, 2023, 7: 21-34

[24]	Wang J, Chen C, Guo Q, et al.. Advances in flavonoid and derivative biosynthesis: systematic strategies for the construction of yeast cell factories. Acs Synth Biol, 2024, 13: 2667-2683

[25]	Wang S, Fang J, Zhang Y, et al.. Progress and perspectives of natural cell factories for chemical production from methanol. Sheng Wu Gong Cheng Xue Bao (Chinese J Biotechnology), 2024, 40: 2747-2760

[26]	Wang S, Fang J, Wang M, et al.. Rewiring the methanol assimilation pathway in the methylotrophic yeast pichia pastoris for high-level production of erythritol. Bioresource Technol, 2025, 427: 132430

[27]	Wang S, Fang J, Zhang Y et al (2025b) Engineering methylotrophic yeasts as cell factories for chemical production using methanol as a feedstock. GCB Bioenergy. https://doi.org/10.1111/gcbb.70068

[28]	Williamson G. Bioavailability of food polyphenols: current state of knowledge. Annu Rev Food Sci T, 2025, 16: 315-332

[29]	Zang X, Yang Y, Zhan C, Bai Z. Methanol metabolism in synthetic methylotrophic microorganisms. Biotechnol Adv, 2025, 83: 108623

[30]	Zhang X, Zhang L, Sun X, et al.. Global regulator DksA as a key target for naringenin biosynthesis identified via whole-cell directed evolution. Int J Biol Macromol, 2025, 333: 148717

[31]	Zhao B, Li Y, Zhang Y, et al.. Low-carbon and overproduction of cordycepin from methanol using engineered pichia pastoris cell factory. Bioresource Technol, 2024, 413: 131446

[32]	Zhao Y, Xiao Z, Wang Y, et al.. Xylose-driven metabolic reprogramming in Saccharomyces cerevisiae for enhancing p-coumaric acid production. Acs Synth Biol, 2025, 14: 2514-2524

[33]	Zhou L, Cai X, Wang Y, et al.. Chemistry and biology of natural stilbenes: an update. Nat Prod Rep, 2025, 42: 359-405

[34]	Zhu T, Guo M, Sun C, et al.. A systematical investigation on the genetic stability of multi-copy pichia pastoris strains. Biotechnol Lett, 2009, 31: 679-684

[35]	Zhu T, Guo M, Tang Z, et al.. Efficient generation of multi-copy strains for optimizing secretory expression of porcine insulin precursor in yeast pichia pastoris. J Appl Microbiol, 2009, 107: 954-963

[36]	Zhu T, Sun H, Wang M, Li Y. Pichia pastoris as a versatile cell factory for the production of industrial enzymes and chemicals: current status and future perspectives. Biotechnol J, 2019, 14: e1800694

[37]	Zhu J, Yang S, Cao Q, et al.. Engineering Yarrowia lipolytica as a cellulolytic cell factory for production of p-coumaric acid from cellulose and hemicellulose. J Agr Food Chem, 2024, 72: 5867-5877

[38]	Zhuang M, Song J, Hu X, Wang X. Metabolic engineering of nissle 1917 for efficient production of -coumaric acid. Acs Synth Biol, 2026, 15: 210-222