| 1. |
- Li, Xiaowei, 1986, et al.
(författare)
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Metabolic network remodelling enhances yeast’s fitness on xylose using aerobic glycolysis
- 2021
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Ingår i: Nature Catalysis. - : Springer Science and Business Media LLC. - 2520-1158. ; 4:9, s. 783-796
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Tidskriftsartikel (refereegranskat)abstract
- The reprogramming of metabolism in response to switching the carbon source from glucose to non-preferred carbon sources is well-studied for yeast. However, understanding how metabolic networks respond to utilize a non-natural carbon source such as xylose is limited due to the incomplete knowledge of cellular response mechanisms. Here we applied a combination of metabolic engineering, systems biology and adaptive laboratory evolution to gain insights into how yeast can perform a global rewiring of cellular processes to efficiently accompany metabolic transitions. Through metabolic engineering, we substantially enhanced the cell growth on xylose after the growth on glucose. Transcriptome analysis of the engineered strains demonstrated that multiple pathways were involved in the cellular reprogramming. Through genome resequencing of the evolved strains and reverse engineering, we further identified that SWI/SNF chromatin remodelling, osmotic response and aldehyde reductase were responsible for the improved growth. Combined, our analysis showed that glycerol-3-phosphate and xylitol serve as two key metabolites that affect cellular adaptation to growth on xylose. [Figure not available: see fulltext.].
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| 2. |
- Pereira, Rui, 1986, et al.
(författare)
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Metabolic Engineering of Yeast
- 2021
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Ingår i: Metabolic Engineering: Concepts and Applications: Volume 13a and 13b. - : Wiley. ; , s. 689-733
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Bokkapitel (övrigt vetenskapligt/konstnärligt)abstract
- This chapter focuses on a few examples that can serve as illustrations of how powerful yeast metabolic engineering stands today. Yeast, especially S. cerevisiae, plays an essential role in bioethanol production. Rapid ethanol production by yeast cells makes the fermentation process less susceptible to contamination. Higher alcohols are attractive due to some advantages compared with bioethanol, such as higher energy density, better blending into gasoline, higher octane value, lower hygroscopicity, and less corrosivity. The ethanol production process in the industry is mainly achieved through simultaneous saccharification and fermentation. Production of insulin, by volume the largest pharmaceutical protein produced, has paved the way for a wide use of S. cerevisiae for production of recombinant proteins. Virus like particles are proteins of virus capsid, which are produced by recombinant DNA technology and are important for the development of viral vaccines as they can self-assemble and display similar immunogenic properties as native viruses.
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| 3. |
- Zhan, Chunjun, 1986, et al.
(författare)
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Strategies and challenges with the microbial conversion of methanol to high-value chemicals
- 2021
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Ingår i: Biotechnology and Bioengineering. - : Wiley. - 0006-3592 .- 1097-0290. ; 118:10, s. 3655-3668
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Forskningsöversikt (refereegranskat)abstract
- As alternatives to traditional fermentation substrates, methanol (CH3OH), carbon dioxide (CO2) and methane (CH4) represent promising one-carbon (C1) sources that are readily available at low-cost and share similar metabolic pathway. Of these C1 compounds, methanol is used as a carbon and energy source by native methylotrophs, and can be obtained from CO2 and CH4 by chemical catalysis. Therefore, constructing and rewiring methanol utilization pathways may enable the use of one-carbon sources for microbial fermentations. Recent bioengineering efforts have shown that both native and nonnative methylotrophic organisms can be engineered to convert methanol, together with other carbon sources, into biofuels and other commodity chemicals. However, many challenges remain and must be overcome before industrial-scale bioprocessing can be established using these engineered cell refineries. Here, we provide a comprehensive summary and comparison of methanol metabolic pathways from different methylotrophs, followed by a review of recent progress in engineering methanol metabolic pathways in vitro and in vivo to produce chemicals. We discuss the major challenges associated with establishing efficient methanol metabolic pathways in microbial cells, and propose improved designs for future engineering.
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| 4. |
- Wang, Yanyan, 1989, et al.
(författare)
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Expression of antibody fragments in Saccharomyces cerevisiae strains evolved for enhanced protein secretion
- 2021
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Ingår i: Microbial Cell Factories. - : Springer Science and Business Media LLC. - 1475-2859. ; 20:1
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Tidskriftsartikel (refereegranskat)abstract
- Monoclonal antibodies, antibody fragments and fusion proteins derived thereof have revolutionized the practice of medicine. Major challenges faced by the biopharmaceutical industry are however high production costs, long processing times and low productivities associated with their production in mammalian cell lines. The yeast Saccharomyces cerevisiae, a well-characterized eukaryotic cell factory possessing the capacity of posttranslational modifications, has been industrially exploited as a secretion host for production of a range of products, including pharmaceuticals. However, due to the incompatible surface glycosylation, few antibody molecules have been functionally expressed in S. cerevisiae. Here, three non-glycosylated antibody fragments from human and the Camelidae family were chosen for expression in a S. cerevisiae strain (HA) previously evolved for high α-amylase secretion. These included the Fab fragment Ranibizumab (Ran), the scFv peptide Pexelizumab (Pex), and a nanobody consisting of a single V-type domain (Nan). Both secretion and biological activities of the antibody fragments were confirmed. In addition, the secretion level of each protein was compared in the wild type (LA) and two evolved strains (HA and MA) with different secretory capacities. We found that the secretion of Ran and Nan was positively correlated with the strains’ secretory capacity, while Pex was most efficiently secreted in the parental strain. To investigate the mechanisms for different secretion abilities in these selected yeast strains for the different antibody fragments, RNA-seq analysis was performed. The results showed that several bioprocesses were significantly enriched for differentially expressed genes when comparing the enriched terms between HA.Nan vs. LA.Nan and HA.Pex vs. LA.Pex, including amino acid metabolism, protein synthesis, cell cycle and others, which indicates that there are unique physiological needs for each antibody fragment secretion.
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