A method for increasing fungal resistance in a plant, a plant part, or a plant cell wherein the method comprises the step of increasing the production and/or accumulation of scopoletin and/or a derivative thereof in the plant, plant part, or plant cell in comparison to a wild type plant, wild type plant part, or wild type plant cell.

Disclosed is a steviol glycoside referred to as rebaudioside D2. Rebaudioside D2 has five β-D-glucosyl units connected to the aglycone steviol. Also disclosed are methods for producing rebaudioside D2, a UDP-glycosyltransferase fusion enzyme, and methods for producing rebaudioside D and rebaudioside E.

The present invention discloses a mutant of cyclodextrin glycosyltransferase and belongs to the fields of gene engineering and enzyme engineering. According to the present invention, a mutant having higher disproportionation activity of cyclodextrin glycosyltransferase is obtained by mutating the cyclodextrin glycosyltransferase. The disproportionation activity of enzymes of mutants V6D, S90G, T168A, T171A, T383A, G608A, and V6D/S90G/T168A/T171A/T383A/G608A, is respectively 1.89 times, 1.21 times, 1.21 times, 1.22 times, 1.32 times, 2.03 times, and 3.16 times that of the wild type enzyme in shake flask fermentations.

The present invention relates to the field of modified proteins, immunogenic compositions and vaccines comprising the modified proteins, their manufacture and the use of such compositions in medicine. More particularly, it relates to a modified EPA (Exotoxin A of Pseudomonas aeruginosa) protein. The modified EPA can be used as a carrier protein for other antigens, particularly saccharide antigens or other antigens lacking T cell epitopes.

Disclosed herein are glucosyltransferases with modified amino acid sequences. Such engineered enzymes exhibit improved alpha-glucan product yields and/or lower leucrose yields, for example. Further disclosed are reactions and methods in which engineered glucosyltransferases are used to produce alpha-glucan.

The purpose of the present invention is to provide a steviol glycoside hexose transferase, and a method for producing a steviol glycoside that contains glucose and/or rhamnose using said enzyme. The present invention provides a steviol glycoside hexose transferase, and a method for producing a steviol glycoside that contains glucose and/or rhamnose using said enzyme. The present invention also provides a transformant into which a steviol glycoside hexose transferase gene has been introduced, and a method for preparing said transformant.

The present invention relates to a group of glycosyltransferase, and an application thereof. Specifically, provided is using glycosyltransferase GT29-32, GT29-33, GT29-34, GT29-4, GT29-5, GT29-7, GT29-9, GT29-11, GT29-13, GT29-17, GT29-18, GT29-19, GT29-20, GT29-21, GT29-22, GT29-23, GT29-24, GT29-25, GT29-36, GT29-37, GT29-42, GT29-43, GT29-45, GT29-46, PNUGT29-1, PNUGT29-2, PNUGT29-3, PNUGT29-4, PNUGT29-5, PNUGT29-6, PNUGT29-7, PNUGT29-8, PNUGT29-9, PNUGT29-14, and PNUGT29-15, as well as derived polypeptides thereof to catalyze the first glycosyl at position C-20, the first glycosyl at position C-6, and the first glycosyl at position C-3 of a tetracyclic triterpene compound substrate to elongate a carbohydrate chain, thereby obtaining a catalytic reaction of ginsenoside products such as ginsenoside Rg3, ginsenoside Rd, ginsenoside Rb1, ginsenoside Rb3, saponin DMGG, saponin DMGX, gypenoside LXXV, gypenoside XVII, gypenoside XIII, gypenoside IX, notoginsenoside U, and notoginsenoside R1, notoginsenoside R2, notoginsenoside R3, 3-O-β-(D-xylopyranosyl)-β-(D-glucopyranosyl)-PPD, 3-O-β-(D-xylopyranosyl)-β-(D-glucopyranosyl)-CK, 20-O-Glucosylginsenoside Rf, and Ginsenoside F3. Glycosyltransferase in the present invention can further be applied to construction of artificially synthesized ginsenoside, novel ginsenoside, and derivatives thereof.

Compositions comprising oxidized dextran compounds are disclosed herein. Oxidized dextran compounds are produced by contacting dextran under aqueous conditions with at least one N-oxoammonium salt, at least one periodate compound, and/or at least one peroxide compound.

This disclosure is in the technical field of synthetic biology and metabolic engineering. The disclosure provides engineered viable bacteria having a reduced or abolished synthesis of poly-N-acetyl-glucosamine (PNAG), Enterobacterial Common Antigen (ECA), cellulose, colanic acid, core oligosaccharides, Osmoregulated Periplasmic Glucans and Glucosylglycerol (O), glycan, and trebalose. The disclosure further provides methods for the production of bioproduct by the viable bacteria and uses thereof. Furthermore, the disclosure is in the technical field of fermentation of metabolically engineered microorganisms producing bioproduct.

The present disclosure provides mutated PglB oligosaccharyltransferase enzymes that have the ability to efficiently catalyze the transfer of a saccharide from a lipid carrier to an asparagine reissue in a glycosylation motif on a protein. Also provided are polynucleotides encoding the mutated PglB oligosaccharyltransferase enzymes, host cells capable of expressing the engineered PglB oligosaccharyltransferase enzymes, and methods of using the engineered PglB oligosaccharyltransferase enzymes to make N-glycosylated proteins. Also provided are N-glycosylated proteins that are made using the engineered PglB oligosaccharyltransferase enzymes.