Metabolic and plasmid engineering to produce D-phenyllactic acid from glucose-xylose co-substrates in <i>Escherichia coli</i>. [PDF]
Appl Environ MicrobiolNoda S +8 more
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Positive selection of efficient ethanol producers from xylose at 45 °C in the yeast Ogataea polymorpha. [PDF]
Sci RepVasylyshyn R +3 more
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Proteomic insights into the physiology and metabolism of oleaginous yeasts and filamentous fungi. [PDF]
Front MicrobiolGluth A +6 more
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Targeted urinary metabolomics combined with machine learning to identify biomarkers related to central carbon metabolism for IBD. [PDF]
Front Mol BiosciLei ML +9 more
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Single Mutation in <i>iolT1</i> in <i>ptsG</i>-Deficient <i>Corynebacterium glutamicum</i> Enables Growth Boost in Xylose-Containing Media. [PDF]
MicroorganismsHofer K +4 more
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Engineering of xylose metabolism in Escherichia coli for the production of valuable compounds
Critical Reviews in Biotechnology, 2021The lignocellulosic sugar d-xylose has recently gained prominence as an inexpensive alternative substrate for the production of value-added compounds using genetically modified organisms.
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Xylose metabolism and its metabolic engineering applications
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Metabolism of D-Xylose by Moulds
Nature, 1960THE filamentous fungi have been called ubiquitous and omnivorous, and certainly they are widely distributed in Nature where they play a most important part in the decomposition of complex organic matter and as pathogens for many plants. Since much of the plant-derived organic matter in Nature contains a large amount of pentoses, mostly in the form of ...
C, CHIANG, S G, KNIGHT
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Oxidative d-xylose metabolism of Gluconobacter oxydans
Applied Microbiology and Biotechnology, 1988Gluconobacter oxydans subsp. suboxydans ATCC 621 oxidizes d-xylose to xylonic acid very efficiently, although it cannot grow on xylose as sole carbon source. The oxidation of xylose was found to be catalyzed by a membrane-bound xylose dehydrogenase. The xylono-γ-lactone formed in the oxidation reaction is subsequently hydrolyzed to xylonic acid by a γ ...
Viikari, Liisa, Buchert, Johanna
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