Xylitol production is increased by expression of codon-optimized Neurospora crassa xylose reductase gene in Candida tropicalis

Jeon, Woo Young; Yoon, Byoung Hoon; Ko, Byoung Sam; Shim, Woo Yong; Kim, Jung Hoe

doi:10.1007/s00449-011-0618-8

Cited by 63 publications

(22 citation statements)

References 26 publications

(43 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Gene disruption of C. tropicalis was performed by homologous recombination [31, 32]. The URA3 gene (with promoter and terminator, GenBank accession number AB006207.1) was amplified by PCR from the genomic DNA of wild-type C. tropicalis with primers URA3-F and URA3-R [31].…”

Section: Methodsmentioning

confidence: 99%

Furfural tolerance and detoxification mechanism in Candida tropicalis

Wang

Cheng

Joshua

et al. 2016

Biotechnol Biofuels

View full text Add to dashboard Cite

BackgroundCurrent biomass pretreatment by hydrothermal treatment (including acid hydrolysis, steam explosion, and high-temperature steaming) and ionic liquids generally generate inhibitors to the following fermentation process. Furfural is one of the typical inhibitors generated in hydrothermal treatment of biomass. Furfural could inhibit cell growth rate and decrease biofuel productivity of microbes. Candida tropicalis is a promising microbe for the production of biofuels and value-added chemicals using hemicellulose hydrolysate as carbon source. In this study, C. tropicalis showed a comparable ability of furfural tolerance during fermentation. We investigated the mechanism of C. tropicalis’s robust tolerance to furfural and relevant metabolic responses to obtain more information for metabolic engineering of microbes for efficient lignocellulose fermentation.Results Candida tropicalis showed comparable intrinsic tolerance to furfural and a fast rate of furfural detoxification. C. tropicalis’s half maximal inhibitory concentration for furfural with xylose as the sole carbon source was 3.69 g/L, which was higher than that of most wild-type microbes reported in the literature to our knowledge. Even though furfural prolonged the lag phase of C. tropicalis, the final biomass in the groups treated with 1 g/L furfural was slightly greater than that in the control groups. By real-time PCR analysis, we found that the expression of ADH1 in C. tropicalis (ctADH1) was induced by furfural and repressed by ethanol after furfural depletion. The expression of ctADH1 could be regulated by both furfural and ethanol. After the disruption of gene ctADH1, we found that C. tropicalis’s furfural tolerance was weakened. To further confirm the function of ctADH1 and enhance Escherichia coli’s furfural tolerance, ctADH1 was overexpressed in E. coli BL21 (DE3). The rate of furfural degradation in E. coli BL21 (DE3) with pET-ADH1 (high-copy plasmid) and pCS-ADH1 (medium-copy plasmid) was increased by 1.59-fold and 1.28-fold, respectively.Conclusions Candida tropicalis was a robust strain with intrinsic tolerance to inhibitor furfural. The mechanism of furfural detoxification and metabolic responses were identified by multiple analyses. Alcohol dehydrogenase 1 was confirmed to be responsible for furfural detoxification. C. tropicalis showed a complex regulation system during furfural detoxification to minimize adverse effects caused by furfural. Furthermore, the mechanism we uncovered in this work was successfully applied to enhance E. coli’s furfural tolerance by heterologous expression of ctADH1. The study provides deeper insights into strain modification for biofuel production by efficient lignocellulose fermentation.Electronic supplementary materialThe online version of this article (doi:10.1186/s13068-016-0668-x) contains supplementary material, which is available to authorized users.

show abstract

Section: Methodsmentioning

confidence: 99%

Furfural tolerance and detoxification mechanism in Candida tropicalis

Wang

Cheng

Joshua

et al. 2016

Biotechnol Biofuels

View full text Add to dashboard Cite

show abstract

“…The use of codons that are overrepresented in naturally highly expressed proteins in recombinant sequences usually improves expression levels compared to random codon usage, particularly in eukaryotic hosts (Kotula & Curtis, 1991;Nagata et al, 1999;Outchkourov et al, 2002;Sinclair & Choy, 2002;Slimko & Lester, 2003;Yadava & Ockenhouse, 2003;Mossadegh et al, 2004;Hu et al, 2006;Lombardi et al, 2009;Mirzaei et al, 2010;Jeon et al, 2012). The situation may be distinct in prokaryotes, where codon usage was found to have only minor effects on gene expression levels (Kudla et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Translation elongation can control translation initiation on eukaryotic mRNAs

Chu

Kazana

Bellanger

et al. 2013

EMBO J

182

216

View full text Add to dashboard Cite

Synonymous codons encode the same amino acid, but differ in other biophysical properties. The evolutionary selection of codons whose properties are optimal for a cell generates the phenomenon of codon bias. Although recent studies have shown strong effects of codon usage changes on protein expression levels and cellular physiology, no translational control mechanism is known that links codon usage to protein expression levels. Here, we demonstrate a novel translational control mechanism that responds to the speed of ribosome movement immediately after the start codon. High initiation rates are only possible if start codons are liberated sufficiently fast, thus accounting for the observation that fast codons are overrepresented in highly expressed proteins. In contrast, slow codons lead to slow liberation of the start codon by initiating ribosomes, thereby interfering with efficient translation initiation. Codon usage thus evolved as a means to optimise translation on individual mRNAs, as well as global optimisation of ribosome availability.

show abstract

“…Although SsXR were used widely in engineering xylose fermentation strains, the activity of SsXR is not strong enough (the kcat/Km value of SsXR for NADPH is only 167 μM/min) and much weaker than XR from N. crassa, which prefers NADPH to NADH (kcat/Km for NADPH and NADH were 2000 and 19 μM/min, respectively) (Woodyer et al, 2005). Additionally, NcXR has been found to be more thermotolerant with a half-life of 94 min at 40 1C and has been proven to be effectively expressed in K. marxianus for xylitol production at elevated temperatures (Jeon et al, 2011;Woodyer et al, 2005;Zhang et al, 2014;. In this study, NcXR was proven more efficient during ethanol production with xylose in a XR-XDH pathway at elevated temperatures.…”

Section: Discussionmentioning

confidence: 97%