Enhanced production of l-sorbose by systematic engineering of dehydrogenases in Gluconobacter oxydans

Liu, Li; Chen, Yue; Yu, Shiqin; Chen, Jian; Zhou, Jingwen

doi:10.1016/j.synbio.2022.02.008

Cited by 10 publications

(10 citation statements)

References 45 publications

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“…L-Sorbose is the intermediate of a fermentation process for manufacturing vitamin C 34 . Although it is rare in nature, L-sorbose can be efficiently produced by the bioconversion from Dsorbitol in Gluconobacter or Acetobacter 35 . Here, we show that the rare sugar L-sorbose induces apoptotic cell death in cancer cells.…”

Section: Discussionmentioning

confidence: 99%

Rare sugar l-sorbose exerts antitumor activity by impairing glucose metabolism

Zhou

Chen

et al. 2023

Commun Biol

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Rare sugars are monosaccharides with low natural abundance. They are structural isomers of dietary sugars, but hardly be metabolized. Here, we report that rare sugar l-sorbose induces apoptosis in various cancer cells. As a C-3 epimer of d-fructose, l-sorbose is internalized via the transporter GLUT5 and phosphorylated by ketohexokinase (KHK) to produce l-sorbose-1-phosphate (S-1-P). Cellular S-1-P inactivates the glycolytic enzyme hexokinase resulting in attenuated glycolysis. Consequently, mitochondrial function is impaired and reactive oxygen species are produced. Moreover, l-sorbose downregulates the transcription of KHK-A, a splicing variant of KHK. Since KHK-A is a positive inducer of antioxidation genes, the antioxidant defense mechanism in cancer cells can be attenuated by l-sorbose-treatment. Thus, l-sorbose performs multiple anticancer activities to induce cell apoptosis. In mouse xenograft models, l-sorbose enhances the effect of tumor chemotherapy in combination with other anticancer drugs. These results demonstrate l-sorbose as an attractive therapeutic reagent for cancer treatment.

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Section: Discussionmentioning

confidence: 99%

Rare sugar l-sorbose exerts antitumor activity by impairing glucose metabolism

Zhou

Chen

et al. 2023

Commun Biol

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“…The former proceeds via a 1,4-hydride shift, 54 while the latter proceeds via a C2-C1 carbon shift. 15 This hydride shift in a long-range carbon is normally achieved by biological enzymes, 55 and it may be difficult to enable this specific molecular rearrangement by a chemical substance containing a single active species. In this case, in postulation, the nucleophile sulfur induces the hydride shift, while Mo has an ionic interaction and forms a metal-sugar complex (as proposed in Scheme 2).…”

Section: Reaction Mechanism Of Fructose Epimerization Over Mosmentioning

confidence: 99%

Molybdenum sulfide-2D nanosheets offering multiple metallic sites enable different sugar epimerization reactions to rare sugars in water

Arumugam¹,

Mahala

Devi

et al. 2023

React. Chem. Eng.

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“…Also, it serves as a potential feedstock for another important variety of rare sugar molecule preparation, such as tagatose via epimerization. , However, as of now, the majority of its production is achieved through a biochemical pathway by utilizing a variety of sugars, including fructose, sorbitol, and glucose, through a two-stage protocol. ,, For example, when fructose is used as a substrate, sorbitol is first dehydrogenated and subsequently dehydrated to yield sorbose . Biological strains, such as Gluconobacter and Acetobacter , are shown to be promising in sorbitol production . Despite several improvements made to the biological process systems, such as the supplementation of fermentation inducers (e.g., casamino acid) to increase sorbose productivity, a yield of less than 36% is reported after prolonged incubation (>48 h). , Notwithstanding, biological processing is challenging due to difficult microbe recycling, downstream product processing, and enzyme activity loss. ,, These factors can significantly affect the economics of sorbose production, thereby limiting its application as a regular sugar substitute.…”

Section: Introductionmentioning

confidence: 99%

“…Biological strains, such as Gluconobacter and Acetobacter , are shown to be promising in sorbitol production . Despite several improvements made to the biological process systems, such as the supplementation of fermentation inducers (e.g., casamino acid) to increase sorbose productivity, a yield of less than 36% is reported after prolonged incubation (>48 h). , Notwithstanding, biological processing is challenging due to difficult microbe recycling, downstream product processing, and enzyme activity loss. ,, These factors can significantly affect the economics of sorbose production, thereby limiting its application as a regular sugar substitute. From the literature, it is chemically producible via a single-step conversion using glucose.…”

Section: Introductionmentioning

confidence: 99%

“…16 Biological strains, such as Gluconobacter and Acetobacter, are shown to be promising in sorbitol production. 17 Despite several improvements made to the biological process systems, such as the supplementation of fermentation inducers (e.g., casamino acid) 18 to increase sorbose productivity, a yield of less than 36% is reported after prolonged incubation (>48 h). 14,17 Notwithstanding, biological processing is challenging due to difficult microbe recycling, downstream product processing, and enzyme activity loss.…”

Section: ■ Introductionmentioning

confidence: 99%

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Fructose Epimerization to l-Sorbose in Water over Molybdenum Oxide: Reaction Kinetics and Mechanism Insights

Devi

Arumugam²,

Mahala

et al. 2023

Ind. Eng. Chem. Res.

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Herein, we report the significant production of l-sorbose via a chemical catalysis method over molybdenum oxide (MoO3) using fructose in a water medium. The heterogeneous catalytic setup could produce 32% l-sorbose and 55% selectivity via C5-fructose epimerization. However, the synthesis was accompanied by a minor formation of tagatose (∼4%) and allulose (∼1%) side products via 1,3-hydride shift and 1,2-hydride shift mechanisms, respectively, using the single fructose source. Moreover, the interconversion reaction (fructose–sorbose) exhibited temperature-dependent characteristics, with an activation barrier of 68.2 kJ/mol. Based on the kinetics, fructose is shown to have a preference for reaching equilibrium with sorbose, which forms through a single 1,4-hydride shift. Due to this, a delayed formation of side products was observed, which follows a series of hydride shifts between the intermediates. From the results, the catalyst is versatile for various epimerization reactions. Selective extraction of fructose from the postreaction medium for product enrichment via naphthalene-2-boronic acid liquid–liquid, however, resulted in the recovery of both fructose and sorbose (ketoses) because of identical characteristics. Thus, the catalytic setup represents an environmentally friendly and sustainable method for upscaling based on the process’s green matrices.

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Enhanced production of l-sorbose by systematic engineering of dehydrogenases in Gluconobacter oxydans

Cited by 10 publications

References 45 publications

Rare sugar l-sorbose exerts antitumor activity by impairing glucose metabolism

Rare sugar l-sorbose exerts antitumor activity by impairing glucose metabolism

Molybdenum sulfide-2D nanosheets offering multiple metallic sites enable different sugar epimerization reactions to rare sugars in water

Fructose Epimerization to l-Sorbose in Water over Molybdenum Oxide: Reaction Kinetics and Mechanism Insights

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