The present disclosure provides methods for identifying anthocyanins with improved stability, color, or hue using a screening method, and producing anthocyanins with improved stability, color, or hue in, for example, host cells comprising one or more heterologous glycosyltransferase nucleic acid molecules and one or more heterologous acyltransferase nucleic acid molecules.

The present invention relates to a method for selectively producing compound K and compound Y, which are originally present in ginseng in a trace amount, from saponins of ginseng, and more specifically to a method capable of obtaining desired target compounds, that is, compound K and compound Y, in high yields, by treating saponins, obtained from ginseng, with particular enzymes to structurally convert the saponins.

The present invention provides steviol glycosyltransferase and a method for producing a steviol glycoside using this enzyme. The present invention provides a transformant transformed with a gene for steviol glycosyltransferase and a method for preparing such a transformant.

The invention provides a method for producing steviol glycosides. The invention provides a transformant having introduced therein the steviol glucosyltransferase and a method for producing steviol glycosides using the transformant.

The invention provides a method for producing steviol glycosides. The invention provides a transformant having introduced therein the steviol glucosyltransferase and a method for producing steviol glycosides using the transformant.

The present invention relates to a method for selectively producing ginsenoside F2, compound Mc or compound O, which is originally present in ginseng in a trace amount, from a saponin of ginseng, and more specifically to a method capable of obtaining desired target compounds, that is, ginsenoside F2, compound Mc and compound O, in high yields, by treating saponins, obtained from ginseng, with particular enzymes to structurally convert the saponins.

Embodiments of the disclosure provide for unique lipooligosaccharide/lipid A-based mimetics for use as adjuvants. Methods of generating lipooligosaccharide/lipid A-based mimetics are provided that utilize recombinantly engineered bacteria to produce the mimetics, including, for example, addition of one or more particular enzymes such as acyltransferases, deacylases, phosphatases, or glycosyltransferases.

Embodiments of the disclosure provide for unique lipooligosaccharide/lipid A-based mimetics for use as adjuvants. Methods of generating lipooligosaccharide/lipid A-based mimetics are provided that utilize recombinantly engineered bacteria to produce the mimetics, including, for example, addition of one or more particular enzymes such as acyltransferases, deacylases, phosphatases, or glycosyltransferases.

The present invention relates to a process for fermenting Yarrowia in a bioreactor, comprising cultivating Yarrowia in a medium, and adding a feed comprising formic acid and a sugar to the medium in a molar ratio of formic acid to sugar of 1 to 13 mol formic acid/mol monosaccharide.

The present invention relates to the field of microbial production of novel biosurfactants. More specifically, the present invention discloses the usage of a fungal strain such as the yeast Starmerella bombicola having a dysfunctional CYP52M1 cytochrome P450 monooxygenase and a dysfunctional FAO1 fatty alcohol oxidase for producing high amounts of so-called symmetrical bolaform sophorosides where both sophorose moieties are attached through a terminal glycosidic linkage to the hydrophobic linker. In addition, the present invention further discloses that the latter yeast can also be used to produce alkyl sophorosides and symmetrical bolaform glucosides.