Metabolic engineering of Pichia pastoris for production of isobutanol and isobutyl acetate

Siripong, Wiparat; Wolf, Philipp; Kusumoputri, Theodora Puspowangi; Downes, Joe; Kocharin, Kanokarn; Tanapongpipat, Sutipa; Runguphan, Weerawat

doi:10.1186/s13068-017-1003-x

Cited by 299 publications

(208 citation statements)

References 36 publications

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“…The isobutanol biosynthesis pathway has been engineered into various microorganisms, such as Escherichia coli [33], Saccharomyces cerevisiae [7,34], Pichia pastoris [35], Bacillus subtilis [36], Corynebacterium glutamicum [8,37], Geobacillus thermoglucosidasius [38], and Synechocystis PCC 6803 [39][40][41]. For example, Atsumi et al engineered E. coli to produce isobutanol up to 22 g/L in shake flasks [33,42], which was further increased to 50 g/L in bioreactors during batch cultures with in situ product removal by gas stripping [43].…”

mentioning

confidence: 99%

Metabolic engineering of Zymomonas mobilis for anaerobic isobutanol production

Qiu

Shen

Yan

et al. 2020

Biotechnol Biofuels

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Background: Biofuels and value-added biochemicals derived from renewable biomass via biochemical conversion have attracted considerable attention to meet global sustainable energy and environmental goals. Isobutanol is a four-carbon alcohol with many advantages that make it attractive as a fossil-fuel alternative. Zymomonas mobilis is a highly efficient, anaerobic, ethanologenic bacterium making it a promising industrial platform for use in a biorefinery. Results: In this study, the effect of isobutanol on Z. mobilis was investigated, and various isobutanol-producing recombinant strains were constructed. The results showed that the Z. mobilis parental strain was able to grow in the presence of isobutanol below 12 g/L while concentrations greater than 16 g/L inhibited cell growth. Integration of the heterologous gene encoding 2-ketoisovalerate decarboxylase such as kdcA from Lactococcus lactis is required for isobutanol production in Z. mobilis. Moreover, isobutanol production increased from nearly zero to 100-150 mg/L in recombinant strains containing the kdcA gene driven by the tetracycline-inducible promoter Ptet. In addition, we determined that overexpression of a heterologous als gene and two native genes (ilvC and ilvD) involved in valine metabolism in a recombinant Z. mobilis strain expressing kdcA can divert pyruvate from ethanol production to isobutanol biosynthesis. This engineering improved isobutanol production to above 1 g/L. Finally, recombinant strains containing both a synthetic operon, als-ilvC-ilvD, driven by Ptet and the kdcA gene driven by the constitutive strong promoter, Pgap, were determined to greatly enhance isobutanol production with a maximum titer about 4.0 g/L. Finally, isobutanol production was negatively affected by aeration with more isobutanol being produced in more poorly aerated flasks. Conclusions: This study demonstrated that overexpression of kdcA in combination with a synthetic heterologous operon, als-ilvC-ilvD, is crucial for diverting pyruvate from ethanol production for enhanced isobutanol biosynthesis. Moreover, this study also provides a strategy for harnessing the valine metabolic pathway for future production of other pyruvate-derived biochemicals in Z. mobilis.

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confidence: 99%

Metabolic engineering of Zymomonas mobilis for anaerobic isobutanol production

Qiu

Shen

Yan

et al. 2020

Biotechnol Biofuels

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“…The vitamin solution contained 0.5 mg/L D-biotin, 1 mg/L calcium pantothenate and 1 mg/L thiamine hydrochloride. Synthetic molasses (SMs) were adapted from elsewhere [ 28 ] with modifications [ 29 , 30 ]. The SM medium contained 20 g/L sucrose (diluted molasses) for the batch fermentation phase and 100 g/L for the fed-batch process.…”

Section: Methodsmentioning

confidence: 99%

Wine Yeast Peroxiredoxin TSA1 Plays a Role in Growth, Stress Response and Trehalose Metabolism in Biomass Propagation

et al. 2020

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Peroxiredoxins are a family of peroxide-degrading enzymes for challenging oxidative stress. They receive their reducing power from redox-controlling proteins called thioredoxins, and these, in turn, from thioredoxin reductase. The main cytosolic peroxiredoxin is Tsa1, a moonlighting protein that also acts as protein chaperone a redox switch controlling some metabolic events. Gene deletion of peroxiredoxins in wine yeasts indicate that TSA1, thioredoxins and thioredoxin reductase TRR1 are required for normal growth in medium with glucose and sucrose as carbon sources. TSA1 gene deletion also diminishes growth in molasses, both in flasks and bioreactors. The TSA1 mutation brings about an expected change in redox parameters but, interestingly, it also triggers a variety of metabolic changes. It influences trehalose accumulation, lowering it in first molasses growth stages, but increasing it at the end of batch growth, when respiratory metabolism is set up. Glycogen accumulation at the entry of the stationary phase also increases in the tsa1Δ mutant. The mutation reduces fermentative capacity in grape juice, but the vinification profile does not significantly change. However, acetic acid and acetaldehyde production decrease when TSA1 is absent. Hence, TSA1 plays a role in the regulation of metabolic reactions leading to the production of such relevant enological molecules.

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“…Microalgae are also characterized by a thicker cell wall structure made up of complex carbohydrates and glycoproteins. Jiang et al (2018) observed the cellular ultrastructure of Chlorella sorokiniana SDEC-18 under a transmission electron microscope and revealed that the plasma membrane is surrounded by a thick cell wall [ 27 ].…”

Section: Microbial Cell Wall and Lipid Compositionmentioning

confidence: 99%

An Overview of Current Pretreatment Methods Used to Improve Lipid Extraction from Oleaginous Microorganisms

2018

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Microbial oils, obtained from oleaginous microorganisms are an emerging source of commercially valuable chemicals ranging from pharmaceuticals to the petroleum industry. In petroleum biorefineries, the microbial biomass has become a sustainable source of renewable biofuels. Biodiesel is mainly produced from oils obtained from oleaginous microorganisms involving various upstream and downstream processes, such as cultivation, harvesting, lipid extraction, and transesterification. Among them, lipid extraction is a crucial step for the process and it represents an important bottleneck for the commercial scale production of biodiesel. Lipids are synthesized in the cellular compartment of oleaginous microorganisms in the form of lipid droplets, so it is necessary to disrupt the cells prior to lipid extraction in order to improve the extraction yields. Various mechanical, chemical and physicochemical pretreatment methods are employed to disintegrate the cellular membrane of oleaginous microorganisms. The objective of the present review article is to evaluate the various pretreatment methods for efficient lipid extraction from the oleaginous cellular biomass available to date, as well as to discuss their advantages and disadvantages, including their effect on the lipid yield. The discussed mechanical pretreatment methods are oil expeller, bead milling, ultrasonication, microwave, high-speed and high-pressure homogenizer, laser, autoclaving, pulsed electric field, and non-mechanical methods, such as enzymatic treatment, including various emerging cell disruption techniques.

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Metabolic engineering of Pichia pastoris for production of isobutanol and isobutyl acetate

Cited by 299 publications

References 36 publications

Metabolic engineering of Zymomonas mobilis for anaerobic isobutanol production

Metabolic engineering of Zymomonas mobilis for anaerobic isobutanol production

Wine Yeast Peroxiredoxin TSA1 Plays a Role in Growth, Stress Response and Trehalose Metabolism in Biomass Propagation

An Overview of Current Pretreatment Methods Used to Improve Lipid Extraction from Oleaginous Microorganisms

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