Metabolic Engineering of <i>Saccharomyces cerevisiae</i> for High-Level Production of Chlorogenic Acid from Glucose

Xiao, Feng; Lian, Jiazhang; Tu, Shuai; Xie, Linlin; Li, Jun; Zhang, Fuming; Linhardt, Robert J.; Huang, Huichao; Zhong, Weihong

doi:10.1021/acssynbio.1c00487

Cited by 13 publications

(10 citation statements)

References 59 publications

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“…This method is superior to the previous dual fermentation system. In addition to bacteria, by modifying the shikimic acid metabolic pathway of Saccharomyces cerevisiae and increasing the expression of key genes for CGA synthesis, the yield of CGA can be significantly increased by 6.4 times (Xiao et al ., 2022). This breaks through the food safety bottleneck of the inability of pre fermentation products to be used for food processing.…”

Section: Dietary Source and Metabolism Of Chlorogenic Acidmentioning

confidence: 99%

Recent advance in the biological activity of chlorogenic acid and its application in food industry

Niu

Chen

et al. 2023

Int J of Food Sci Tech

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SummaryIn recent years, people have been paying more attention to food safety and dietary health. An increasing number of natural active ingredients are used in the field of food and nutrition. chlorogenic acid (CGA), as a phenolic acid compound extensive present in the diet, has been reported to have a variety of beneficial biological activities in alleviating and preventing various diet‐related chronic diseases. Moreover, it has various applications in food safety and food nutrition as a new type of food additive. In this context, this paper reviews the role of CGA as an antioxidant, antibacterial, hypotensive, hypoglycemic, anti‐obesity and gastrointestinal health agent starting from its distribution, source, in vivo metabolism and isolation. Furthermore, the practical application of chlorogenic acid in active food packaging, food quality control and nutritional dietary supplements is discussed. Finally, the future development and challenges of CGA in the field of food is described, providing new ideas for the application of CGA in food safety and dietary supplements and future research.

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Section: Dietary Source and Metabolism Of Chlorogenic Acidmentioning

confidence: 99%

Recent advance in the biological activity of chlorogenic acid and its application in food industry

Niu

Chen

et al. 2023

Int J of Food Sci Tech

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“…Further improvements have been achieved by introducing into S. cerevisiae the de novo 5-CQA synthesis pathway, including PAL2, C4H, 4CL1, C3′H, CPR1, CPR2, HQT2, YdiB, CYB5 and implementing the following modifications ( Figure 6 ): (1) unlocking the shikimate pathway and optimizing carbon distribution by overexpressing the L-phenylalanine feedback-insensitive DAHP synthase (ARO3 K222L ), L-tyrosine feedback-insensitive DAHP synthase (ARO4 K229L ), pyruvate kinase 1 mutant with reduced catalytic activity (PYK1 D146N ) and transketolase (TKL1); (2) optimizing the L-phenylalanine branch and pathway balancing by overexpressing the l-tyrosine feedback-insensitive chorismate mutase (ARO7 G141S ), endogenous prephenate dehydratase (PHA2), NADH kinase (POS5), and cytochrome b5 (Cyb5); (3) increasing the copy number of 5-CQA pathway genes encoding hydroxycinnamoyl-CoA quinate transferase 2 (HQT2) and cytochrome P450 98A3 (C3′H) [ 151 ]. The engineered S. cerevisiae strain produced 5-CQA to 234.8 ± 11.1 mg/L in shake flask culture and 806.8 ± 1.7 mg/L in fed-batch fermentation [ 151 ].…”

Section: Biosynthesis Of Hcqas In Non-modified and Modified Micro-org...mentioning

confidence: 99%

Advances in Production of Hydroxycinnamoyl-Quinic Acids: From Natural Sources to Biotechnology

Valanciene

Malys

2022

Antioxidants

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Hydroxycinnamoyl-quinic acids (HCQAs) are polyphenol esters formed of hydroxycinnamic acids and (-)-quinic acid. They are naturally synthesized by plants and some micro-organisms. The ester of caffeic acid and quinic acid, the chlorogenic acid, is an intermediate of lignin biosynthesis. HCQAs are biologically active dietary compounds exhibiting several important therapeutic properties, including antioxidant, antimicrobial, anti-inflammatory, neuroprotective, and other activities. They can also be used in the synthesis of nanoparticles or drugs. However, extraction of these compounds from biomass is a complex process and their synthesis requires costly precursors, limiting the industrial production and availability of a wider variety of HCQAs. The recently emerged production through the bioconversion is still in an early stage of development. In this paper, we discuss existing and potential future strategies for production of HCQAs.

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“…All strains used or constructed were listed in Table 1, gene knockout and insertion of DNA fragments in Saccharomyces cerevisiae were operated by CRISPR/Cas9 system (Stovicek et al, 2015). YT00 (CEN.PK2-1C, IX1 :: TEFp-SpCas9-ADH2t ) (Xiao et al, 2022) was adopted as the host strain for the integration of sakuranetin synthesis pathway genes. LiAc/ssDNA/PEG method was used to co-transform an equal amount of purified linearized fragments (50-100 ng/kb) with the corresponding gRNA plasmids (˜300-500 ng) into S. cerevisiae , and YPD agar plate containing 200 μg/mL G418 was used for the selection of the resulting strains.…”

Section: Strain Construction and Cultivation Conditionsmentioning

confidence: 99%

“…The gene cluster of the abovementioned four enzymes under four constitutive promoters (Fig. 2A), was introduced into strain YT02 (Xiao et al, 2022) (Table 1). The resulting strain YHS01 (YT02, X3 ::PGK1p-At4CL1-HXT7t-TPI1p-PhCHS-TPI1t-ENO2p-MsCHI-PGK1t-TEF1p-OsNOMT-TEF1t ) produced 4.28 mg/L sakuranetin (Fig.…”

Section: S Cerevisiaementioning

confidence: 99%

De Novo Biosynthesis of Sakuranetin from Glucose by Engineered Saccharomyces cerevisiae

Zhong

Xiao

et al. 2022

Preprint

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Sakuranetin is a plant-natural product, which has increasingly been utilized in cosmetic and pharmaceutical industries for its extensive anti-inflammatory, anti-tumor, and immunomodulatory effects. Sakuranetin was mostly produced via extraction technology from plants, which is limited to natural conditions and biomass supply. In this study, a novel strategy to produce sakuranetin via de novo synthesis from glucose by engineering S. cerevisiae was introduced . After a series of heterogenous genes integration, a biosynthetic pathway of sakuranetin from glucose was successfully constructed in S. cerevisiae which sakuranetin yield reached only 4.28 mg/L. Then, a multi-module metabolic engineering strategy was applied for improving sakuranetin yield in S. cerevisiae: (1) adjusting the copy number of sakuranetin synthesis genes; (2) removing the rate-limiting factor of aromatic amino pathway and optimizing the synthetic pathway of aromatic amino acids to enhance the supply of carbon flux for sakuranetin; (3) introducing acetyl-CoA carboxylase mutants ACC1 and knocking-out YPL062W to strengthen the supply of malonyl-CoA which is another synthetic precursor of sakuranetin. The resultant mutant S. cerevisiae exhibited a more than 10-fold increase of sakuranetin titer (50.62 mg/L) in shaking flasks. Furthermore, the sakuranetin titer increased to 158.65 mg/L in a 1-L bioreactor, which is the highest sakuranetin titer among all publications reported yield of the engineered microbial cell.

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Metabolic Engineering of Saccharomyces cerevisiae for High-Level Production of Chlorogenic Acid from Glucose

Cited by 13 publications

References 59 publications

Recent advance in the biological activity of chlorogenic acid and its application in food industry

Recent advance in the biological activity of chlorogenic acid and its application in food industry

Advances in Production of Hydroxycinnamoyl-Quinic Acids: From Natural Sources to Biotechnology

De Novo Biosynthesis of Sakuranetin from Glucose by Engineered Saccharomyces cerevisiae

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