The invention relates to the use of, and methods of use employing, certain glycolipid compounds as defined in detail below and having preservative or antimicrobial properties, novel compounds of the glycolipid class, and related invention embodiments. The compounds have the formula I ##STR00001##
wherein m is 3 to 5, n is 2 to 5, o is 0 or 1 and p is 3 to 17, with the proviso that the sum m+n+o+p is not less than 14; and
R is a carbohydrate moiety bound via one of its carbon atoms to the binding oxygen,
and/or a physiologically, especially pharmaceutically or nutraceutically or cosmetically, acceptable salt thereof, or an ester thereof,
as such or in the form of a composition,
where the compound may be present in open chain form and/or in the form of a lactone (FIG. 1).

Provided is a group of new uridine diphosphate (UDP)-glycosyltransferases, which are carbon glycoside glycosyltransferases, wherein the glycosyltransferases can specifically and efficiently catalyze the carbon glycoside glucosylation of a dihydrochalcone(s) compound or a 2-hydroxyflavanone(s) compound, thereby producing a carbon glycoside dihydrochalcone(s) compound or a carbon glycoside-2-hydroxyflavanone(s) compound; and a flavonoid carbon glycoside(s) compound is formed from a carbon glycoside-2-hydroxyflavanone(s) compound by means of a further dehydration reaction. Further provided is the use of said new UDP glycosyltransferases in artificially constructed recombinant expression systems to produce a carbon glycoside dihydrochalcone(s) compound or a flavonoid carbon glycoside(s) compound by means of fermentation engineering.

Provided is a group of new uridine diphosphate (UDP)-glycosyltransferases, which are carbon glycoside glycosyltransferases, wherein the glycosyltransferases can specifically and efficiently catalyze the carbon glycoside glucosylation of a dihydrochalcone(s) compound or a 2-hydroxyflavanone(s) compound, thereby producing a carbon glycoside dihydrochalcone(s) compound or a carbon glycoside-2-hydroxyflavanone(s) compound; and a flavonoid carbon glycoside(s) compound is formed from a carbon glycoside-2-hydroxyflavanone(s) compound by means of a further dehydration reaction. Further provided is the use of said new UDP glycosyltransferases in artificially constructed recombinant expression systems to produce a carbon glycoside dihydrochalcone(s) compound or a flavonoid carbon glycoside(s) compound by means of fermentation engineering.

The invention provides a method of producing a host cell, plant cell or plant with increased trilobatin content or increased N 4′-O-glycosyltransferase activity, the method comprising transformation of the host cell or plant cell with a polynucleotide encoding a polypeptide with 4′-O-glycosyltransferase activity. The invention also provides host cells, plant cells and plants, genetically modified to contain and or express the polynucleotides.

The subject invention provides microbe-based products, as well as their use to improve oil production and refining efficiency by, for example, remediating the disposable layers in oil tanks and other oil storage units. In preferred embodiments, the microbe-based products comprise biochemical-producing yeast and growth by-products thereof, such as, e.g., biosurfactants. The subject invention can be used to remediate rag layer and/or other dissolved solid layers that form in water-oil emulsions. Furthermore, the subject invention can be used for remediating solid impurities, such as sand, scale, rust and clay, in produced water, flow-back, brine, and/or fracking fluids.

The subject invention provides microbe-based products, as well as their use to improve oil production and refining efficiency by, for example, remediating the disposable layers in oil tanks and other oil storage units. In preferred embodiments, the microbe-based products comprise biochemical-producing yeast and growth by-products thereof, such as, e.g., biosurfactants. The subject invention can be used to remediate rag layer and/or other dissolved solid layers that form in water-oil emulsions. Furthermore, the subject invention can be used for remediating solid impurities, such as sand, scale, rust and clay, in produced water, flow-back, brine, and/or fracking fluids.

The invention relates to cells which make rhamnolipids and are genetically modified such that they have a decreased activity, compared to the wild type thereof, of a glucose dehydrogenase and to a method for producing rhamnolipids using the cells according to the invention.

The invention relates to cells which make rhamnolipids and are genetically modified such that they have a decreased activity, compared to the wild type thereof, of a glucose dehydrogenase and to a method for producing rhamnolipids using the cells according to the invention.

Etoposide glycosides and methods of making etoposide glycosides are disclosed. Glycosyl transferases catalyze addition of one or more monosaccharides to etoposide to yield etoposide glycosides. Suitable monosaccharides can be in the L- or D-configuration and typically have 5, 6, or 7 carbons. Suitable monosaccharides include allose, apiose, arabinose, fructose, fucitol, fucose, galactose, glucose, glucuronic acid, mannose, A-acetylglucosamine, rhamnose, or xylose. Uridine diphosphate glycosyl transferases can catalyze formation of either an alpha or beta glycosidic bond.

Enasidenib glycosides and methods of making enasidenib glycosides are disclosed. Glycosyl transferases catalyze addition of one or more monosaccharides to enasidenib to yield enasidenib glycosides. Suitable monosaccharides can be in the L- or D-configuration and typically have 5, 6, or 7 carbons. Suitable monosaccharides include allose, apiose, arabinose, fructose, fucitol, fucose, galactose, galacturonate, glucose, glucuronic acid, mannose, N-acetylglucosamine, rhamnose, or xylose. Uridine diphosphate glycosyl transferases can catalyze formation of either an alpha or beta glycosidic bond.