Abstract: In various aspects and embodiments, the present disclosure provides methods for making glycosylated products, as well as bacterial cells and uridine diphosphate (UDP)-dependent glycosyltransferase (UGT) enzymes useful for the same. In other aspects and embodiments, the disclosure provides methods for high yield and/or high purity recovery of such glycoside products from microbial cultures or cell free reactions. In various aspects and embodiments, the disclosure provides for whole cell bioconversion processes involving the glycosylation of a desired substrate, and/or the recovery of the glycosylated product at high yield and/or high purity.

Abstract: The present invention in various aspects and embodiments provides engineered bacterial strains having a modified genome that provides advantages in maintenance and biosynthetic processes when cultured at large scale. The present invention further provides methods for large-scale fermentation using the bacterial strains. In various embodiments, the strain engineering yields a reduction in cellular responses to micro-environmental stimuli imposed in large scale bioreactors.

Abstract: In various aspects, the present invention provides uridine diphosphate-dependent glycosyltransferase (UGT) enzymes capable of catalyzing the transfer of a monosaccharide moiety from a NDP-sugar to the 3? carbon of a sugar moiety of a substrate, such as a terpenoid glycan, thereby functioning as a “1-3 UGT.” In other aspects, the invention provides polynucleotides encoding the 1-3 UGT, and host cells comprising the same. In still other aspects, the invention provides methods for preparing glycosylated substrates, including steviol glycosides, using the enzyme and host cells of this disclosure.

Abstract: The present disclosure provides methods and compositions for producing artemisinic acid, dihydroartemisinic acid or artemisinin. In various aspects, the present disclosure provides enzymes, polynucleotides encoding said enzymes, and recombinant microbial host cells (or microbial host strains) for the production of artemisinic acid, dihydroartemisinic acid or artemisinin. The present disclosure further provides methods of making pharmaceutical products containing artemisinic acid, dihydroartemisinic acid or artemisinin.

Abstract: The present disclosure provides methods and compositions for producing rotundone. In various aspects, the present disclosure provides enzymes, polynucleotides encoding said enzymes, and recombinant microbial host cells (or microbial host strains) for the production of rotundone. In some embodiments, the present disclosure provides microbial host cells for producing rotundone at high purity and/or yield, from either enzymatic transformation of ?-guaiene, or from sugar or other carbon source. The present disclosure further provides methods of making products containing rotundone, including flavor or fragrance products, among others.

Abstract: The present invention provides engineered cells and methods for making high purity steviol glycosides, including RebM. In some aspects, the present invention provides host cells, such as bacterial cells (including but not limited to E. coli), that are engineered to overexpress and/or delete or inactivate one or more steviol glycoside transport proteins. The bacterial cells selectively export RebM, or other specific combination of steviol glycosides, out of the cell to increase productivity and reduce production costs associated with downstream purification. Non-target steviol glycosides are not transported to the extracellular medium in significant amounts.

Abstract: The present disclosure provides methods and compositions for producing rotundone. In various aspects, the present disclosure provides enzymes, polynucleotides encoding said enzymes, and recombinant microbial host cells (or microbial host strains) for the production of rotundone. In some embodiments, the present disclosure provides microbial host cells for producing rotundone at high purity and/or yield, from either enzymatic transformation of ?-guaiene, or from sugar or other carbon source. The present disclosure further provides methods of making products containing rotundone, including flavor or fragrance products, among others.

Abstract: The present invention provides host cells and methods for making mogrol glycosides, including Mogroside V (Mog.V), Mogroside VI (Mog.VI), Iso-Mogroside V (Isomog.V), siamenoside, and glycosylation products that are minor products in Siraitia grosvenorii. The invention provides engineered enzymes and engineered host cells for producing mogrol glycosylation products, such as Mog.V, Mog.VI, and Isomog.V, at high purity and/or yield. The present technology further provides methods of making products containing mogrol glycosides, such as Mog.V, Mog.VI, and Isomog.V, including food products, beverages, oral care products, sweeteners, and flavoring products.

Abstract: In various aspects and embodiments, the invention relates to bacterial strains and methods for making terpene and terpenoid products. The invention provides bacterial strains with improved carbon flux through the MEP pathway, to thereby increase terpene and/or terpenoid product yield by fermentation with carbon sources such as glucose.

Abstract: The invention relates to methods and bacterial strains for making terpene and terpenoid products, the bacterial strains having improved carbon pull through the MEP pathway and to a downstream recombinant synthesis pathway.

Abstract: The invention relates to methods and bacterial strains for making terpene and terpenoid products, the bacterial strains having improved carbon pull through the MEP pathway and to a downstream recombinant synthesis pathway.

Abstract: In various aspects and embodiments, the invention provides microbial cells and methods for producing advanced glycosylation products from lower glycosylated intermediates. The microbial cell expresses one or more UDP-dependent glycosyl transferase enzymes in the cytoplasm, for glycosylation of the intermediates. When incubating the microbial strain with a plant extract or fraction thereof comprising the intermediates, these glycosylated intermediates are available for further glycosylation by the cell, and the advanced glycosylation products can be recovered from the media and/or microbial cells.

Abstract: In various aspects and embodiments, the invention relates to bacterial strains and methods for making terpene and terpenoid products. The invention provides bacterial strains with improved carbon flux through the MEP pathway, to thereby increase terpene and/or terpenoid product yield by fermentation with carbon sources such as glucose.

Abstract: In various aspects, the present invention provides uridine diphosphate-dependent glycosyltransferase (UGT) enzymes capable of catalyzing the transfer of a monosaccharide moiety from a NDP-sugar to the 3? carbon of a sugar moiety of a substrate, such as a terpenoid glycan, thereby functioning as a “1-3 UGT.” In other aspects, the invention provides polynucleotides encoding the 1-3 UGT, and host cells comprising the same. In still other aspects, the invention provides methods for preparing glycosylated substrates, including steviol glycosides, using the enzyme and host cells of this disclosure.

Abstract: In various aspects and embodiments, the invention provides microbial cells and methods for producing advanced glycosylation products from lower glycosylated intermediates. The microbial cell expresses one or more UDP-dependent glycosyl transferase enzymes in the cytoplasm, for glycosylation of the intermediates. When incubating the microbial strain with a plant extract or fraction thereof comprising the intermediates, these glycosylated intermediates are available for further glycosylation by the cell, and the advanced glycosylation products can be recovered from the media and/or microbial cells.

Abstract: Enzymes involved in cannabinoid biosynthesis are recombinantly expressed in a host cell. The host cell may be a prokaryote (e.g. Escherichia coli) or a eukaryote (e.g. Yarrowia lipolytica). The enzymes include a heterologous cannabigerolic acid synthase as well as additional enzymes involved in the biosynthesis of cannabinoid precursors such as geranyl diphosphate, olivetol, olivetolic acid, divarin and/or divarinic acid. Methods are provided for producing C5-cannabinoids and/or C3-cannabinoids by fermentation of the recombinant host cell. Alternatively, cannabinoids can be produced by biotransformation of cannabinoid precursors in recombinant cells or by disrupted recombinant cells.

Abstract: In various aspects, the present invention provides uridine diphosphate-dependent glycosyltransferase (UGT) enzymes capable of catalyzing the transfer of a monosaccharide moiety from a NDP-sugar to the 3? carbon of a sugar moiety of a substrate, such as a terpenoid glycan, thereby functioning as a “1-3 UGT.” In other aspects, the invention provides polynucleotides encoding the 1-3 UGT, and host cells comprising the same. In still other aspects, the invention provides methods for preparing glycosylated substrates, including steviol glycosides, using the enzyme and host cells of this disclosure.

Abstract: The present invention is related to enzymatic pathways for production of carminic acid, host cells capable of production of carminic acid, and methods for the production of carminic acid and related compounds.

Abstract: The present disclosure provides methods and compositions for producing rotundone. In various aspects, the present disclosure provides enzymes, polynucleotides encoding said enzymes, and recombinant microbial host cells (or microbial host strains) for the production of rotundone. In some embodiments, the present disclosure provides microbial host cells for producing rotundone at high purity and/or yield, from either enzymatic transformation of ?-guaiene, or from sugar or other carbon source. The present disclosure further provides methods of making products containing rotundone, including flavor or fragrance products, among others.

Abstract: Aspects of the invention provide methods for producing one or more secondary metabolites from microbial culture. In various embodiments, the method comprises culturing a microbial cell producing a secondary metabolite for recovery from a bioreactor medium, the medium comprising an aqueous phase and an extraction phase. The composition of the extraction phase, and the relevant amount with respect to the aqueous phase, enhances production of the secondary metabolite from microbial cells and/or enhances extracellular transfer of the metabolite.