Self-Redirection of Metabolic Flux toward Squalene and Ethanol Pathways by Engineered Yeast

Manzoor, Robina; Ahmed, Maqbool; Riaz, Naveeda; Kiani, Bushra Hafeez; Ullah, Kalim; Rashid, Yasmeen; Nawaz, Ali; Awan, Muhammad Umer Farooq; Khan, Hooria; Imtiaz, Umera; Rasheed, Yasir; Kaleem, Imdad; Rasool, Aamir

doi:10.3390/metabo10020056

Cited by 5 publications

(4 citation statements)

References 61 publications

(79 reference statements)

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“…Later, two iron and copper repressible promoters P AFT1 and P CTR1 , respectively are characterized and used to repress the ERG1 gene in S. cerevisiae towards squalene bioproduction. ERG1 repression with metal ion repressible P CTR1 promoter has enhanced squalene up to twofold when compared to P AFT1 promoter (Manzoor et al 2020). In the same study, TFBS TEF1 and TFBS HHF2 were engineered into different constitutive promoters thereby enhancing the strength of the yeast constitutive promoters.…”

Section: Promoter Based Engineering Strategies Towards Squalene Synth...mentioning

confidence: 96%

“…ERG1 gene codes for squalene monooxygenase in the MVA pathway downstream of squalene in S. cerevisiae. Being an essential gene, disruption of ERG1 leads to a lethal phenotype and therefore repression of ERG1 gene by promoter replacement has become a prominent strategy in the development of cell factories towards squalene biosynthesis (Hull et al 2014;Manzoor et al 2020;Liu et al 2020a, b;Zhu et al 2021). Also, the usage of repressible promoters provides better economic feasibility when compared to the enzyme inhibitors at an industrial level.…”

Section: Promoter Based Engineering Strategies Towards Squalene Synth...mentioning

confidence: 99%

“…The engineered promoters such as P HHF2 , P IRA1 , P RHO1 , and P PET9 with TFBS TEF1 were utilized to drive the transcription of HMG1, IDI1, ERG20, and ERG9 genes respectively. This study resulted in a strain with squalene improvement to nearly 74-fold (Manzoor et al 2020). Further, P HXT1 is a glucose inducible promoter and causes repression when the glucose levels in the medium become low or zero.…”

Section: Promoter Based Engineering Strategies Towards Squalene Synth...mentioning

confidence: 99%

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Recent advances in the microbial production of squalene

Paramasivan

Mutturi

2022

World J Microbiol Biotechnol

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Squalene is a triterpene hydrocarbon, a biochemical precursor for all steroids in plants and animals. It is a principal component of human surface lipids, in particular of sebum. Squalene has several applications in the food, pharmaceutical, and medical sectors. It is essentially used as a dietary supplement, vaccine adjuvant, moisturizer, cardio-protective agent, anti-tumor agent and natural antioxidant. With the increased demand for squalene along with regulations on shark-derived squalene, there is a need to find alternatives for squalene production which are low-cost as well as sustainable. Microbial platforms are being considered as a potential option to meet such challenges. Considerable progress has been made using both wild-type and engineered microbial strains for improved productivity and yields of squalene. Native strains for squalene production are usually limited by low growth rates and lesser titers. Metabolic engineering, which is a rational strain engineering tool, has enabled the development of microbial strains such as Saccharomyces cerevisiae and Yarrowia lipolytica, to overproduce the squalene in high titers. This review focuses on key strain engineering strategies involving both in-silico and in-vitro techniques. Emphasis is made on gene manipulations for improved precursor pool, enzyme modifications, cofactor regeneration, up-regulation of limiting reactions, and downregulation of competing reactions during squalene production. Process strategies and challenges related to both upstream and downstream during mass cultivation are detailed.

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Section: Promoter Based Engineering Strategies Towards Squalene Synth...mentioning

confidence: 96%

Section: Promoter Based Engineering Strategies Towards Squalene Synth...mentioning

confidence: 99%

Section: Promoter Based Engineering Strategies Towards Squalene Synth...mentioning

confidence: 99%

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Recent advances in the microbial production of squalene

Paramasivan

Mutturi

2022

World J Microbiol Biotechnol

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“…The coaccumulation and co-occurrence of terpenoids in LDs provide an opportunity to achieve the high-yield production and storage of terpenoids in LDs. Through the overexpression of diacylglycerol acyltransferase ( DGA1 ) to stimulate the biogenesis of lipid droplets and inhibition of ERG1 expression by employing AFT1p and CTR1p repressible promoters, the squalene titer reached 255.11 mg/L, which was 73.49 times that of the wild-type strain. , Another study showed that the overexpression of DGA1 in the engineered strain of S. cerevisiae with the overexpression of tHMGR can enhance the lipid bodies biosynthesis, leading to 12-fold increase in the squalene production compared with the original strain . These results provided a feasible scheme for the further efficient synthesis of hydrophobic compounds in S. cerevisiae .…”

Section: Regulation Strategy For Efficient Biosynthesis Of Squalenementioning

confidence: 99%

Advanced Strategies for the Efficient Production of Squalene by Microbial Fermentation

Wang

et al. 2022

Ind. Eng. Chem. Res.

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Squalene is an isoprene compound, which shows excellent properties, such as antioxidant and anticancer and so on. Currently, squalene has been widely used in medicine, cosmetics, vaccine adjuvants, and other fields. The traditional methods for squalene production mainly include natural extraction and chemical synthesis, which cannot meet the increasing market demand. Squalene production through microbial fermentation has become a promising alternative owing to its high efficiency and environmental friendliness. To improve the squalene production, a series of strategies including metabolic engineering and fermentation optimization and so on have been recruited. Accordingly, this review will comprehensively discuss various strategies including the isolation of high squalene producer, metabolic regulation of synthetic pathway and process optimization to improve the synthetic efficiency of squalene. Challenges and future perspectives for microbial squalene synthesis were also proposed.

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