Enhancing fluxes through the mevalonate pathway in <i>Saccharomyces cerevisiae</i> by engineering the HMGR and β‐alanine metabolism

Lu, Surui; Zhou, Chenyu; Guo, Xiaoqian; Du, Zhengda; Cheng, Yanhao; Wang, Zhaoyue; He, Xiuping

doi:10.1111/1751-7915.14072

Cited by 21 publications

(33 citation statements)

References 57 publications

(97 reference statements)

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“…Similarly, mitochondria have nearly 20-30 times higher acetyl-CoA content than the cytosol (Duran et al, 2020). As shown in Figure 2C, rational organelle compartmentalization can greatly improve the utilization efficiency of the acetyl-CoA pools in different organelles (Son et al, 2022a;Lu et al, 2022). Dong et al (2021) compartmentalized the whole MVA pathway into mitochondria, leading to a 3.7-fold improvement in the production of α-santalene.…”

Section: Monoterpenoids and Sesquiterpenoidsmentioning

confidence: 94%

Compartmentalization engineering of yeasts to overcome precursor limitations and cytotoxicity in terpenoid production

Chen

Xiao

Yao

et al. 2023

Front. Bioeng. Biotechnol.

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Metabolic engineering strategies for terpenoid production have mainly focused on bottlenecks in the supply of precursor molecules and cytotoxicity to terpenoids. In recent years, the strategies involving compartmentalization in eukaryotic cells has rapidly developed and have provided several advantages in the supply of precursors, cofactors and a suitable physiochemical environment for product storage. In this review, we provide a comprehensive analysis of organelle compartmentalization for terpenoid production, which can guide the rewiring of subcellular metabolism to make full use of precursors, reduce metabolite toxicity, as well as provide suitable storage capacity and environment. Additionally, the strategies that can enhance the efficiency of a relocated pathway by increasing the number and size of organelles, expanding the cell membrane and targeting metabolic pathways in several organelles are also discussed. Finally, the challenges and future perspectives of this approach for the terpenoid biosynthesis are also discussed.

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Section: Monoterpenoids and Sesquiterpenoidsmentioning

confidence: 94%

Compartmentalization engineering of yeasts to overcome precursor limitations and cytotoxicity in terpenoid production

Chen

Xiao

Yao

et al. 2023

Front. Bioeng. Biotechnol.

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“…On the other hand, yeast and bacteria use NADH more than NADPH as a reduced cofactor of catabolism [ 4 ]. Thus, increasing the intracellular NADPH level or eliminating NADPH consumption is a common strategy to facilitate NADPH-dependent products, including terpenoid [ 14 , 15 ]. For example, Liu et al compared the effects of six native enzymes involved in NAPDH regeneration in Yarrowia lipolytica and found that mannitol dehydrogenase benefits the increase in squalene production [ 16 ].…”

Section: Introductionmentioning

confidence: 99%

Cofactor Engineering for Efficient Production of α-Farnesene by Rational Modification of NADPH and ATP Regeneration Pathway in Pichia pastoris

Chen

Liu

Zhang

et al. 2023

IJMS

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α-Farnesene, an acyclic volatile sesquiterpene, plays important roles in aircraft fuel, food flavoring, agriculture, pharmaceutical and chemical industries. Here, by re-creating the NADPH and ATP biosynthetic pathways in Pichia pastoris, we increased the production of α-farnesene. First, the native oxiPPP was recreated by overexpressing its essential enzymes or by inactivating glucose-6-phosphate isomerase (PGI). This revealed that the combined over-expression of ZWF1 and SOL3 increases α-farnesene production by improving NADPH supply, whereas inactivating PGI did not do so because it caused a reduction in cell growth. The next step was to introduce heterologous cPOS5 at various expression levels into P. pastoris. It was discovered that a low intensity expression of cPOS5 aided in the production of α-farnesene. Finally, ATP was increased by the overexpression of APRT and inactivation of GPD1. The resultant strain P. pastoris X33-38 produced 3.09 ± 0.37 g/L of α-farnesene in shake flask fermentation, which was 41.7% higher than that of the parent strain. These findings open a new avenue for the development of an industrial-strength α-farnesene producer by rationally modifying the NADPH and ATP regeneration pathways in P. pastoris.

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“…Further, dosedependent regulation of gene expression will help to optimize flux through a pathway by adjusting the endogenous gene expression levels flexibly and in a cloning free manner. The fact that the adjustment of endogenous protein levels has a positive influence on product yield has already been described several times, e.g., for terpene production, 19 overproduction of Design of sgRNA Entry and Multimerization Vectors. The expression of sgRNAs is based on the previously published tRNA-HDV architecture, 23 which we modified to allow Golden Gate-based cloning of up to four sgRNA cassettes into a single plasmid (see Figure 2 and the Methods section for details).…”

Section: ■ Introductionmentioning

confidence: 99%

“…Further, dose-dependent regulation of gene expression will help to optimize flux through a pathway by adjusting the endogenous gene expression levels flexibly and in a cloning free manner. The fact that the adjustment of endogenous protein levels has a positive influence on product yield has already been described several times, e.g., for terpene production, overproduction of triacylglycerols (TAGs), , and high-level production of aromatic chemicals …”

Section: Introductionmentioning

confidence: 99%

PhiReX 2.0: A Programmable and Red Light-Regulated CRISPR-dCas9 System for the Activation of Endogenous Genes in Saccharomyces cerevisiae

et al. 2023

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Metabolic engineering approaches do not exclusively require fine-tuning of heterologous genes but oftentimes also modulation or even induction of host gene expression, e.g., in order to rewire metabolic fluxes. Here, we introduce the programmable red light switch PhiReX 2.0, which can rewire metabolic fluxes by targeting endogenous promoter sequences through single-guide RNAs (sgRNAs) and activate gene expression in Saccharomyces cerevisiae upon red light stimulation. The split transcription factor is built from the plant-derived optical dimer PhyB and PIF3, which is fused to a DNA-binding domain based on the catalytically dead Cas9 protein (dCas9) and a transactivation domain. This design combines at least two major advantages: first, the sgRNAs, guiding dCas9 to the promoter of interest, can be exchanged in an efficient and straightforward Golden Gate-based cloning approach, which allows for rational or randomized combination of up to four sgRNAs in a single expression array. Second, target gene expression can be rapidly upregulated by short red light pulses in a light dose-dependent manner and returned to the native expression level by applying far-red light without interfering with the cell culture. Using the native yeast gene CYC1 as an example, we demonstrated that PhiReX 2.0 can upregulate CYC1 gene expression by up to 6-fold in a light intensity-dependent and reversible manner using a single sgRNA.

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Enhancing fluxes through the mevalonate pathway in Saccharomyces cerevisiae by engineering the HMGR and β‐alanine metabolism

Cited by 21 publications

References 57 publications

Compartmentalization engineering of yeasts to overcome precursor limitations and cytotoxicity in terpenoid production

Compartmentalization engineering of yeasts to overcome precursor limitations and cytotoxicity in terpenoid production

Cofactor Engineering for Efficient Production of α-Farnesene by Rational Modification of NADPH and ATP Regeneration Pathway in Pichia pastoris

PhiReX 2.0: A Programmable and Red Light-Regulated CRISPR-dCas9 System for the Activation of Endogenous Genes in Saccharomyces cerevisiae

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