Kuan Rei Ng scite author profile

Flavonoids are an important class of plant polyphenols that possess a variety of health benefits. In this work, S. cerevisiae was metabolically engineered to produce the flavonoid naringenin, using tyrosine as the precursor. Our strategy to improve naringenin production comprised three modules. In module 1, we employed a modified GAL system to overexpress the genes of the naringenin biosynthesis pathway and investigated their synergistic action. In module 2, we simultaneously up-regulated acetyl-CoA production and down-regulated fatty acid biosynthesis in order to increase the precursor supply, malonyl-CoA. In module 3, we engineered the tyrosine biosynthetic pathway to eliminate the feedback inhibition of tyrosine and also down-regulated competing pathways. It was found that modules 1 and 3 played important roles in improving naringenin production. We succeeded in producing up to ∼90 mg/L of naringenin in our final strain, which is a 20-fold increase as compared to the parental strain.

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Antimicrobial and antioxidant activities of phenolic metabolites from flavonoid-producing yeast: Potential as natural food preservatives

Lyu

Mark

et al. 2019

Food Chemistry

101

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Metabolic Engineering of Saccharomyces cerevisiae for De Novo Production of Kaempferol

Lyu

Zhao

et al. 2019

J. Agric. Food Chem.

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Kaempferol is a polyphenolic compound with various reported health benefits and thus harbors considerable potential for food-engineering applications. In this study, a high-yield kaempferol-producing cell factory was constructed by multiple strategies, including gene screening, elimination of the phenylethanol biosynthetic branch, optimizing the core flavonoid synthetic pathway, supplementation of precursor PEP/E4P, and mitochondrial engineering of F3H and FLS. A total of 86 mg/L of kaempferol was achieved in strain YL-4, to date the highest production titer in yeast. Furthermore, a coculture system and supplementation of surfactants were investigated, to relieve the metabolic burden as well as the low solubility/possible transport limitations of flavonoids, respectively. In the coculture system, the whole pathway was divided across two strains, resulting in 50% increased cell growth. Meanwhile, supplementation of Tween 80 in our engineered strains yielded 220 mg/L of naringenin and 200 mg/L of mixed flavonoidsamong the highest production titer reported via de novo production in yeast.

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Gene Source Screening as a Tool for Naringenin Production in Engineered Saccharomyces cerevisiae

Mark

Lyu

et al. 2019

ACS Omega

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Flavonoids are plant secondary metabolites with great potential in the food industry. Metabolic engineering of Saccharomyces cerevisiae is a sustainable production technique. However, the current naringenin production yield is low because of inefficient enzymatic activity. Hence, this study uses gene source screening as a tool to identify the best gene source for enzymes such as 4-coumarate: coenzyme ligase (4CL) and chalcone synthase (CHS). For the first time, the 4CL gene from Medicago truncatula and the CHS gene from Vitis vinifera were expressed in S. cerevisiae, and this combination provided the highest yield of naringenin, which was 28-fold higher as compared to the reference strain. The combinations obtained similar performance in the Y-28 strains, where the highest production was 28.68 mg/L. Our results demonstrated that the selection and combination of enzymes from the correct gene source could greatly improve naringenin production. For the future, this could help commercialize flavonoid production, which would result in natural food preservatives and additives.

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Food Waste Durian Rind-Derived Cellulose Organohydrogels: Toward Anti-Freezing and Antimicrobial Wound Dressing

Cui

Lee

et al. 2021

ACS Sustainable Chem. Eng.

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Hydrogels synthesized from naturally derived raw materials are attracting increasing attention as compared to synthetic hydrogels. In this study, the use of food waste and side-stream products which were generated from the food industry, commonly associated with environmental concerns, were instead treated as a precious resource for hydrogel fabrication. Cellulose with a high purity was extracted from the food byproduct durian rind and used as a natural raw material to prepare water-based cellulose hydrogels. Glycerol was introduced into the water-based hydrogels to fabricate organohydrogels by a simple one-step water–glycerol replacement. Our results showed that the organohydrogels possessed anti-freezing and non-drying properties, and the mechanical property was enhanced by the use of glycerol. Next, natural yeast phenolics were added into the organohydrogels. This endowed the organohydrogels with antimicrobial activity. The prepared organohydrogels showed no cytotoxicity, and when applied as a wound dressing on pig skin as a proof of concept, they showed strong antibacterial activity. Therefore, this suggested that durian rind-based cellulose organohydrogels have the potential to be applied as antimicrobial wound dressing in medical supplies, even at extreme temperature environments such as −30 °C.

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Kuan Rei Ng

Enhancement of Naringenin Biosynthesis from Tyrosine by Metabolic Engineering of Saccharomyces cerevisiae

Antimicrobial and antioxidant activities of phenolic metabolites from flavonoid-producing yeast: Potential as natural food preservatives

Metabolic Engineering of Saccharomyces cerevisiae for De Novo Production of Kaempferol

Gene Source Screening as a Tool for Naringenin Production in Engineered Saccharomyces cerevisiae

Food Waste Durian Rind-Derived Cellulose Organohydrogels: Toward Anti-Freezing and Antimicrobial Wound Dressing

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