Improved linalool production in Saccharomyces cerevisiae by combining directed evolution of linalool synthase and overexpression of the complete mevalonate pathway

2020 ◽  
Vol 161 ◽  
pp. 107655
Author(s):  
Pingping Zhou ◽  
Yi Du ◽  
Nannan Xu ◽  
Chunlei Yue ◽  
Lidan Ye
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Directed Evolution ◽  
Mevalonate Pathway ◽  
Linalool Synthase

scholarly journals Screening and directed evolution of transporters to improve xylodextrin utilization in the yeast Saccharomyces cerevisiae

2017 ◽  
Author(s):  
Chenlu Zhang ◽  
Ligia Acosta-Sampson ◽  
Vivian Yaci Yu ◽  
Jamie H. D. Cate
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Directed Evolution ◽  
Plant Biomass ◽  
Carbon Sources ◽  
Industrial Applications ◽  
Yeast Saccharomyces Cerevisiae ◽  
Cellulosic Biofuel ◽  
Economic Production ◽  
Report Analysis ◽  
Selection Medium

AbstractThe economic production of cellulosic biofuel requires efficient and full utilization of all abundant carbohydrates naturally released from plant biomass by enzyme cocktails. Recently, we reconstituted the Neurospora crassa xylodextrin transport and consumption system in Saccharomyces cerevisiae, enabling growth of yeast on xylodextrins aerobically. However, the consumption rate of xylodextrin requires improvement for industrial applications, including consumption in anaerobic conditions. As a first step in this improvement, we report analysis of orthologues of the N. crassa transporters CDT-1 and CDT-2. Transporter ST16 from Trichoderma virens enables faster aerobic growth of S. cerevisiae on xylodextrins compared to CDT-2. ST16 is a xylodextrin-specific transporter, and the xylobiose transport activity of ST16 is not inhibited by cellobiose. Other transporters identified in the screen also enable growth on xylodextrins including xylotriose. Taken together, these results indicate that multiple transporters might prove useful to improve xylodextrin utilization in S. cerevisiae. Efforts to use directed evolution to improve ST16 from a chromosomally-integrated copy were not successful, due to background growth of yeast on other carbon sources present in the selection medium. Future experiments will require increasing the baseline growth rate of the yeast population on xylodextrins, to ensure that the selective pressure exerted on xylodextrin transport can lead to isolation of improved xylodextrin transporters.

scholarly journals Combinatorial Metabolic Engineering in Saccharomyces cerevisiae for the Enhanced Production of the FPP-Derived Sesquiterpene Germacrene

2020 ◽  
Vol 7 (4) ◽  
pp. 135
Author(s):  
Jan Niklas Bröker ◽  
Boje Müller ◽  
Dirk Prüfer ◽  
Christian Schulze Gronover
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Metabolic Engineering ◽  
Metabolic Flux ◽  
Mevalonate Pathway ◽  
Plant Secondary Metabolites ◽  
Product Formation ◽  
Culture Conditions ◽  
Efficient Production ◽  
Enhanced Production ◽  
Engineering Strategy

Farnesyl diphosphate (FPP)-derived isoprenoids represent a diverse group of plant secondary metabolites with great economic potential. To enable their efficient production in the heterologous host Saccharomyces cerevisiae, we refined a metabolic engineering strategy using the CRISPR/Cas9 system with the aim of increasing the availability of FPP for downstream reactions. The strategy included the overexpression of mevalonate pathway (MVA) genes, the redirection of metabolic flux towards desired product formation and the knockout of genes responsible for competitive reactions. Following the optimisation of culture conditions, the availability of the improved FPP biosynthesis for downstream reactions was demonstrated by the expression of a germacrene synthase from dandelion. Subsequently, biosynthesis of significant amounts of germacrene-A was observed in the most productive strain compared to the wild type. Thus, the presented strategy is an excellent tool to increase FPP-derived isoprenoid biosynthesis in yeast.

scholarly journals Transcriptional regulation of a sterol-biosynthetic enzyme by sterol levels in Saccharomyces cerevisiae.

1996 ◽  
Vol 16 (8) ◽  
pp. 3981-3989 ◽  
Author(s):  
D Dimster-Denk ◽  
J Rine
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Transcriptional Regulation ◽  
Feedback Control ◽  
Dna Sequences ◽  
Promoter Region ◽  
Mevalonate Pathway ◽  
Transcriptional Level ◽  
Biosynthetic Enzyme ◽  
Animal Cells ◽  
Regulatory Response

Sterols and all nonsterol isoprenoids are derived from the highly conserved mevalonate pathway. In animal cells, this pathway is regulated in part at the transcriptional level through the action of sterol response element-binding proteins acting at specific DNA sequences near promoters. Here we extend at least part of this regulatory paradigm to the ERG10 gene, which encodes a sterol-biosynthetic enzyme of Saccharomyces cerevisiae. Specifically, the discovery of sterol-mediated feedback control of ERG10 transcription is reported. Deletion analysis of the ERG10 promoter region identified sequences involved in the expression of ERG10. This regulatory axis appeared to involve sterol levels, as a late block in the pathway that depletes sterol, but not nonsterol isoprenoids, was able to elicit the regulatory response.

scholarly journals Directed Evolution of Xylose Isomerase for Improved Xylose Catabolism and Fermentation in the Yeast Saccharomyces cerevisiae

2012 ◽  
Vol 78 (16) ◽  
pp. 5708-5716 ◽  
Author(s):  
Sun-Mi Lee ◽  
Taylor Jellison ◽  
Hal S. Alper
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Ethanol Production ◽  
Directed Evolution ◽  
Ethanol Yield ◽  
Xylose Isomerase ◽  
Mutant Enzyme ◽  
Xylose Utilization ◽  
Xylose Consumption ◽  
Content Type ◽  
Consumption Rates

ABSTRACTThe heterologous expression of a highly functional xylose isomerase pathway inSaccharomyces cerevisiaewould have significant advantages for ethanol yield, since the pathway bypasses cofactor requirements found in the traditionally used oxidoreductase pathways. However, nearly all reported xylose isomerase-based pathways inS. cerevisiaesuffer from poor ethanol productivity, low xylose consumption rates, and poor cell growth compared with an oxidoreductase pathway and, additionally, often require adaptive strain evolution. Here, we report on the directed evolution of thePiromycessp. xylose isomerase (encoded byxylA) for use in yeast. After three rounds of mutagenesis and growth-based screening, we isolated a variant containing six mutations (E15D, E114G, E129D, T142S, A177T, and V433I) that exhibited a 77% increase in enzymatic activity. When expressed in a minimally engineered yeast host containing agre3knockout andtal1andXKS1overexpression, the strain expressing this mutant enzyme improved its aerobic growth rate by 61-fold and both ethanol production and xylose consumption rates by nearly 8-fold. Moreover, the mutant enzyme enabled ethanol production by these yeasts under oxygen-limited fermentation conditions, unlike the wild-type enzyme. Under microaerobic conditions, the ethanol production rates of the strain expressing the mutant xylose isomerase were considerably higher than previously reported values for yeast harboring a xylose isomerase pathway and were also comparable to those of the strains harboring an oxidoreductase pathway. Consequently, this study shows the potential to evolve a xylose isomerase pathway for more efficient xylose utilization.

scholarly journals Saccharomyces cerevisiae in directed evolution

Bioengineered ◽  
2012 ◽  
Vol 3 (3) ◽  
pp. 174-179 ◽  
Author(s):  
David Gonzalez-Perez ◽  
Eva Garcia-Ruiz ◽  
Miguel Alcalde
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Directed Evolution

Biosensor‐Enabled Directed Evolution to Improve Muconic Acid Production in Saccharomyces cerevisiae

2017 ◽  
Vol 12 (10) ◽  
pp. 1600687 ◽  
Author(s):  
John M. Leavitt ◽  
James M. Wagner ◽  
Cuong C. Tu ◽  
Alice Tong ◽  
Yanyi Liu ◽  
...  
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Directed Evolution ◽  
Acid Production ◽  
Muconic Acid

scholarly journals Overproduction of Geranylgeraniol by Metabolically Engineered Saccharomyces cerevisiae

2009 ◽  
Vol 75 (17) ◽  
pp. 5536-5543 ◽  
Author(s):  
Kenro Tokuhiro ◽  
Masayoshi Muramatsu ◽  
Chikara Ohto ◽  
Toshiya Kawaguchi ◽  
Shusei Obata ◽  
...  
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Metabolic Flux ◽  
Mevalonate Pathway ◽  
Fusion Gene ◽  
Pharmaceutical Products ◽  
Test Tube ◽  
Ethanol Solution ◽  
Multicopy Integration ◽  
Engineered Saccharomyces Cerevisiae ◽  
Rate Limiting

ABSTRACT (E, E, E)-Geranylgeraniol (GGOH) is a valuable starting material for perfumes and pharmaceutical products. In the yeast Saccharomyces cerevisiae, GGOH is synthesized from the end products of the mevalonate pathway through the sequential reactions of farnesyl diphosphate synthetase (encoded by the ERG20 gene), geranylgeranyl diphosphate synthase (the BTS1 gene), and some endogenous phosphatases. We demonstrated that overexpression of the diacylglycerol diphosphate phosphatase (DPP1) gene could promote GGOH production. We also found that overexpression of a BTS1-DPP1 fusion gene was more efficient for producing GGOH than coexpression of these genes separately. Overexpression of the hydroxymethylglutaryl-coenzyme A reductase (HMG1) gene, which encodes the major rate-limiting enzyme of the mevalonate pathway, resulted in overproduction of squalene (191.9 mg liter−1) rather than GGOH (0.2 mg liter−1) in test tube cultures. Coexpression of the BTS1-DPP1 fusion gene along with the HMG1 gene partially redirected the metabolic flux from squalene to GGOH. Additional expression of a BTS1-ERG20 fusion gene resulted in an almost complete shift of the flux to GGOH production (228.8 mg liter−1 GGOH and 6.5 mg liter−1 squalene). Finally, we constructed a diploid prototrophic strain coexpressing the HMG1, BTS1-DPP1, and BTS1-ERG20 genes from multicopy integration vectors. This strain attained 3.31 g liter−1 GGOH production in a 10-liter jar fermentor with gradual feeding of a mixed glucose and ethanol solution. The use of bifunctional fusion genes such as the BTS1-DPP1 and ERG20-BTS1 genes that code sequential enzymes in the metabolic pathway was an effective method for metabolic engineering.

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