The vectorial orientation of human monoamine oxidase in the mitochondrial outer membrane

Summary C‐Glycosides are characterized by their C–C bonds in which the anomeric carbon of the sugar moieties is directly bound to the carbon atom of aglycon. C‐Glycosides are remarkably stable, as their C–C bonds are resistant to glycosidase or acid hydrolysis. A variety of plant species are known to accumulate C‐glycosylflavonoids; however, the genes encoding for enzymes that catalyze C‐glycosylation of flavonoids have been identified only from Oryza sativa (rice) and Zea mays (maize), and have not been identified from dicot plants. In this study, we identified the C‐glucosyltransferase gene from the dicot plant Fagopyrum esculentum M. (buckwheat). We purified two isozymes from buckwheat seedlings that catalyze C‐glucosylation of 2‐hydroxyflavanones, which are expressed specifically in the cotyledon during seed germination. Following purification we isolated the cDNA corresponding to each isozyme [FeCGTa (UGT708C1) and FeCGTb (UGT708C2)]. When expressed in Escherichia coli, both proteins demonstrated C‐glucosylation activity towards 2‐hydroxyflavanones, dihydrochalcone, trihydroxyacetophenones and other related compounds with chemical structures similar to 2′,4′,6′‐trihydroxyacetophenone. Molecular phylogenetic analysis of plant glycosyltransferases shows that flavonoid C‐glycosyltransferases form a different clade with other functionally analyzed plant glycosyltransferases.

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C‐Glycosyltransferases catalyzing the formation of di‐C‐glucosyl flavonoids in citrus plants

Ito

Fujimoto

Suito

et al. 2017

The Plant Journal

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Citrus plants accumulate many kinds of flavonoids, including di-C-glucosyl flavonoids, which have attracted considerable attention due to their health benefits. However, the biosynthesis of di-C-glucosyl flavonoids has not been elucidated at the molecular level. Here, we identified the C-glycosyltransferases (CGTs) FcCGT (UGT708G1) and CuCGT (UGT708G2) as the primary enzymes involved in the biosynthesis of di-C-glucosyl flavonoids in the citrus plants kumquat (Fortunella crassifolia) and satsuma mandarin (Citrus unshiu), respectively. The amino acid sequences of these CGTs were 98% identical, indicating that CGT genes are highly conserved in the citrus family. The recombinant enzymes FcCGT and CuCGT utilized 2-hydroxyflavanones, dihydrochalcone, and their mono-C-glucosides as sugar acceptors and produced corresponding di-C-glucosides. The K and k values of FcCGT toward phloretin were <0.5 μm and 12.0 sec , and those toward nothofagin (3'-C-glucosylphloretin) were 14.4 μm and 5.3 sec , respectively; these values are comparable with those of other glycosyltransferases reported to date. Transcripts of both CGT genes were found to concentrate in various plant organs, and particularly in leaves. Our results suggest that di-C-glucosyl flavonoid biosynthesis proceeds via a single enzyme using either 2-hydroxyflavanones or phloretin as a substrate in citrus plants. In addition, Escherichia coli cells expressing CGT genes were found to be capable of producing di-C-glucosyl flavonoids, which is promising for commercial production of these valuable compounds.

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Production of C-glucosides of flavonoids and related compounds by Escherichia coli expressing buckwheat C-glucosyltransferase

Ito

Fujimoto

Shimosaka

et al. 2014

Plant Biotechnology

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C-Glucosides are glucose-containing glycosides that have carbon-carbon bonds between the anomeric carbon of the sugar moieties and aglycon, rendering the molecules remarkably stable against hydrolysis by enzymes or acids. In this work, we showed the production of C-glucosides of flavonoids and related compounds (i.e., 2-hydroxyflavanone, dihydrochalcone, and trihydroxyacetophenone) by Escherichia coli expressing buckwheat C-glucosyltransferase. The substrates in their respective cultures were taken up by the cells and C-glucosylated, and the products were released into the culture media. The bioconversion process was completed in 1-2 h, but products were already observed immediately after addition of the substrates (200 µM). The conversion rates of these substrates reached 80-95%. Without addition of glucose to the conversion media, almost no C-glucosides were produced. Although the amounts of the substrates fed to their respective cultures were limited by their solubility in water, repeated addition of the substrate to the culture at regular time intervals effectively increased the total amount of product obtained.

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Takamitsu Ito

Purification, molecular cloning and functional characterization of flavonoid C‐glucosyltransferases from Fagopyrum esculentum M. (buckwheat) cotyledon

C‐Glycosyltransferases catalyzing the formation of di‐C‐glucosyl flavonoids in citrus plants

Production of <i>C</i>-glucosides of flavonoids and related compounds by <i>Escherichia coli</i> expressing buckwheat <i>C</i>-glucosyltransferase

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