Harnessing the Endogenous 2μ Plasmid of Saccharomyces cerevisiae for Pathway Construction

Yang, Jing; Tian, Yujuan; Liu, Huayi; Kan, Yeyi; Zhou, Yi; Wang, Ying; Luo, Yunzi

doi:10.3389/fmicb.2021.679665

Cited by 5 publications

(5 citation statements)

References 46 publications

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“…In addition, YCp has a yeast centromere (CEN) and an autonomous replication sequence (ARS) and has high mitotic stability and a low copy number. YEp contains a 2 μm plasmid replication source and distribution site (STB or REP3) with a high copy number but low stability [63]. The copy number is the essential factor for ensuring the required level of transcription.…”

Section: Increased Gene Copy Numbermentioning

confidence: 99%

Engineering strategies for enhanced heterologous protein production by Saccharomyces cerevisiae

Zhao,

Ma,

Zhang

et al. 2024

Microb Cell Fact

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Microbial proteins are promising substitutes for animal- and plant-based proteins. S. cerevisiae, a generally recognized as safe (GRAS) microorganism, has been frequently employed to generate heterologous proteins. However, constructing a universal yeast chassis for efficient protein production is still a challenge due to the varying properties of different proteins. With progress in synthetic biology, a multitude of molecular biology tools and metabolic engineering strategies have been employed to alleviate these issues. This review first analyses the advantages of protein production by S. cerevisiae. The most recent advances in improving heterologous protein yield are summarized and discussed in terms of protein hyperexpression systems, protein secretion engineering, glycosylation pathway engineering and systems metabolic engineering. Furthermore, the prospects for efficient and sustainable heterologous protein production by S. cerevisiae are also provided.

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Section: Increased Gene Copy Numbermentioning

confidence: 99%

Engineering strategies for enhanced heterologous protein production by Saccharomyces cerevisiae

Zhao,

Ma,

Zhang

et al. 2024

Microb Cell Fact

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“…On the biosynthetic pathway of L ‐tyrosine, 4‐hydroxyphenylpyruvate (4HPP) can be converted to tyrosol via the heterologous enzymes phenylpyruvate decarboxylase (Aro10) and alcohol dehydrogenases (Adhs) in yeast (J. Jiang et al, 2018; Yang et al, 2021). Due to the strong catalytic activities of the two native enzymes, yeast is a natural producer of tyrosol.…”

Section: Tyrosol Derivativesmentioning

confidence: 99%

Yeast: A platform for the production of _L‐tyrosine derivatives

Guo

et al. 2023

Yeast

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L -Tyrosine derivatives are widely applied in the pharmaceutical, food, and chemical industries. Their production is mainly confined to chemical synthesis and plant extract. Microorganisms, as cell factories, exhibit promising advantages for valuable chemical production to fulfill the increase in the demand of global markets. Yeast has been used to produce natural products owing to its robustness and genetic maneuverability. Focusing on the progress of yeast cell factories for the production of L -tyrosine derivatives, we summarized the emerging metabolic engineering approaches in building L -tyrosoineoverproducing yeast and constructing cell factories of three typical chemicals and their derivatives: tyrosol, p-coumaric acid, and L -DOPA. Finally, the challenges and opportunities of L -tyrosine derivatives production in yeast cell factories were also discussed.aromatic amino acids, cell factory, L -tyrosine derivatives, synthetic biology, yeastis an essential amino acid nutrient with diverse applications in food, medicine, and chemical industries. Its derivatives, including Hydroxytyrosol S. cerevisiae Glucose 5L fed-batch 6970 H. Liu, Wu, et al. (2022) Salidroside S. cerevisiae Glucose 5L fed-batch 26,550 H. Liu, Tian, et al. (2021) p-Coumaric acid derivatives p-coumaric acid S. cerevisiae Glucose 1L fed-batch 12,500 Q. Liu, Yu, et al. (2019) p-coumaric acid S. cerevisiae Xylose 1L fed-batch 242 Borja et al. (2019) Caffeic acid S. cerevisiae Carboxymethylcellulose Shake flask 16.91 M. Cai et al. (2022) Caffeic acid S. cerevisiae Glucose 1.2L fed-batch 5500 R. Chen et al. (2022) Caffeic acid Candida glycerinogenes Glucose and Xylose 5L fed-batch 431.45 X.-H. Wang et al. (2022) Rosmarinic acid S. cerevisiae Glucose Shake flask 208 P. Zhou et al. (2022) Ferulic Acid S. cerevisiae Glucose 1.2L fed-batch 3800 R. Chen et al. (2022) Resveratrol S. cerevisiae Glucose and Ethanol shake flask 187 Costa et al. (2021) Resveratrol S. cerevisiae Lactose Shake flask 210 Costa et al. (2022) Resveratrol Scheffersomyces stipitis Cellobiose Shake flask 529.8 Kobayashi et al. (2021) Resveratrol S. stipitis Sucrose Shake flask 668.6 Kobayashi et al. (2021) Resveratrol Pichia pastoris Glycerol 250 mL fed-batch 1825 Kumokita et al. (2022) Pterostilbene S. cerevisiae Glucose Shake flask 34.93 M. Li et al. (2016) Pinostilbene S. cerevisiae Glucose Shake flask 5.52 M. Li et al. (2016) Naringenin S. cerevisiae Glucose Shake flask 203.49 Tong et al. (2022) Naringenin S. cerevisiae Glucose 5L fed-batch 1184.1 H. Li et al. (2022) Naringenin Yarrowia lipolytica Glucose 3L fed-batch 898 Palmer et al. (2020) Naringenin P. pastoris Glycerol 250 mL fed-batch 1067 Kumokita et al. (2022) Naringenin Y. lipolytica Glucose Shake flask 252.4 Lv et al. (2019) Eriodictyol Y. lipolytica Glucose Shake flask 134.2 Lv et al. (2019) Phloretin S. cerevisiae Glucose 5L fed-batch 619.5 C. Jiang et al. (2020) Apigenin Y. lipolytica Glucose Shake flask 80.74 Vanegas et al. (2018) Luteolin Y. lipolytica Glucose Shake flask 47.9 Vanegas et al. (2018) Kaempferol S. ...

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“…The new strain Trp07 produced 3.94 g/L of DAHP in shake flasks when the S180F mutation was added to the aroG gene to eliminate feedback inhibition of DAHP by L-Trp ( Tang et al, 2023 ) and through the introduction of ARO3 with ARO4 -K229L, which is insensitive to DAHPS , in S. cerevisiae , overexpression of the ARO4 -K229L allele increased the total flux of branched aromatic amino acid metabolism 3 to 4 times in comparison to the control bacterium, CEN. PK ( Luttik et al, 2008b ; Yang et al, 2021 ).…”

Section: Regulation Of L-trp Production In the Key Synthetic Pathwaysmentioning

confidence: 99%

A comprehensive review and comparison of L-tryptophan biosynthesis in Saccharomyces cerevisiae and Escherichia coli

Ren,

Wei,

Zhao

et al. 2023

Front. Bioeng. Biotechnol.

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L-tryptophan and its derivatives are widely used in the chemical, pharmaceutical, food, and feed industries. Microbial fermentation is the most commonly used method to produce L-tryptophan, which calls for an effective cell factory. The mechanism of L-tryptophan biosynthesis in Escherichia coli, the widely used producer of L-tryptophan, is well understood. Saccharomyces cerevisiae also plays a significant role in the industrial production of biochemicals. Because of its robustness and safety, S. cerevisiae is favored for producing pharmaceuticals and food-grade biochemicals. However, the biosynthesis of L-tryptophan in S. cerevisiae has been rarely summarized. The synthetic pathways and engineering strategies of L-tryptophan in E. coli and S. cerevisiae have been reviewed and compared in this review. Furthermore, the information presented in this review pertains to the existing understanding of how L-tryptophan affects S. cerevisiae’s stress fitness, which could aid in developing a novel plan to produce more resilient industrial yeast and E. coli cell factories.

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Harnessing the Endogenous 2μ Plasmid of Saccharomyces cerevisiae for Pathway Construction

Cited by 5 publications

References 46 publications

Engineering strategies for enhanced heterologous protein production by Saccharomyces cerevisiae

Engineering strategies for enhanced heterologous protein production by Saccharomyces cerevisiae

Yeast: A platform for the production of _L‐tyrosine derivatives

A comprehensive review and comparison of L-tryptophan biosynthesis in Saccharomyces cerevisiae and Escherichia coli

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Harnessing the Endogenous 2μ Plasmid of Saccharomyces cerevisiae for Pathway Construction

Cited by 5 publications

References 46 publications

Engineering strategies for enhanced heterologous protein production by Saccharomyces cerevisiae

Engineering strategies for enhanced heterologous protein production by Saccharomyces cerevisiae

Yeast: A platform for the production of L‐tyrosine derivatives

A comprehensive review and comparison of L-tryptophan biosynthesis in Saccharomyces cerevisiae and Escherichia coli

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Product

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Yeast: A platform for the production of _L‐tyrosine derivatives