Recombinant microorganisms are disclosed that produce steviol glycosides and have altered expression of one or more endogenous transporter or transcription factor genes, or that overexpress one or more heterologous transporters, leading to increased excretion of steviol glycosides of interest.

The present invention provides antibodies that bind to the IL-3 receptor alpha subunit alpha (Il3Rα) chain, and compositions comprising such antibodies. The present invention provides methods for inhibiting or reducing an IL3Rα-expressing cell population, the methods comprising contacting a population of IL3Rα-expressing cells (e.g., cancer cells and/or cancer stem cells) with an antibody that binds to IL3Rα. The present invention also provides antibody conjugates comprising an antibody that binds to an IL3Rα chain linked to a cytotoxic agent or anticellular agent and compositions comprising such conjugates. The present invention also provides methods for preventing, treating and/or managing a disorder associated with IL3Rα-expressing cells (e.g., a hematological cancer), the methods comprising administering to a subject in need thereof an antibody that binds to IL3Rα.

The present invention relates to microbial host cells that have been engineered for increased tolerance to temperature shifts, for increased performance at temperatures different from the microorganism's optimal temperature and/or for changing at least one of the microorganism's cardinal temperatures by replacing an endogenous NAD.sup.+ biosynthesis gene by a heterologous gene encoding a corresponding enzyme with another temperature profile and/or from a microorganism with a different optimum growth temperature. The invention further relates to processes wherein the engineered microbial host cells are used for producing a fermentation product, and to the use nucleotide sequences encoding NAD.sup.+ biosynthesis gene for changing at least one of a microorganism's cardinal temperatures and/or for improving a microorganism's tolerance to temperature shifts.

The current inventive technology includes novel systems, methods and compositions for the in vivo production, modification and isolation of terpene compounds from Cannabis or other plants. In particular, the invention provides systems and methods for high level in vivo biosynthesis of water-soluble terpene compounds. In one preferred embodiment, the present invention generally relates to the conversion of Cannabis sativa or hemp derived terpenes into water-soluble terpene compounds, such as terpene glycosides, glycosylated-xylosylated terpenes, and an acetylated glycoside terpenes. In one preferred aspect, the invention may include system for producing water-soluble terpene compounds in yeast and tobacco cell suspension cultures, as well as an in planta system using transgenic Cannabis or hemp plants.

Bacillus agaradhaerens strain WDG185 expresses an inulosucrase that efficiently synthesizes a broad range of IOS with a GF range of GF3-GF30. The isolated and/or purified inulosucrase, recombinantly engineered variants thereof, active fragments thereof, synthetic nucleic acids encoding the inulosucrase, its variants, or its active fragments, host cells comprising the synthetic nucleic acids, and compositions comprising the inulosucrase are provided. Methods of using the compositions include the manufacture of inulooligosaccharides.

A vaccine comprising a polypeptide comprising an amino acid sequence of at least 9 contiguous amino acids from the N-terminal region of MAP P900, or a polynucleotide encoding said polypeptide, for use in a method of treating or preventing MAP infection or a condition or symptom associated with MAP infection in a subject.

A genetically reprogrammed, biologically active and metabolically active cell, tissue, and/or an organ comprising live cells that vascularize after xenotransplantation, wherein the genetically reprogrammed, biologically active and metabolically active cell, tissue, and/or an organ has been obtained from a non-wild type, biologically engineered porcine comprising a nuclear genome that has been reprogrammed to replace a plurality of nucleotides in a plurality of exon regions of a major histocompatibility complex of a wild-type porcine with a plurality of synthesized nucleotides from a human captured reference sequence, wherein the nuclear genome has wild-type porcine intron regions from a wild-type porcine and has been reprogrammed at exon regions.

The invention refers to a composition comprising inactivated cells deficient in LPS from the genus Acinetobacter and/or outer membrane vesicles form the same and their use for the manufacture of a medicament, preferably a vaccine, for the prevention of diseases produced by organisms of the genus Acinetobacter.

The present application relates to Leishmania cells genetically engineered such that the formation of an O-linked GlcNAc on a polypeptide in the Leishmania cell is reduced or eliminated. The formation of the O-linked GlcNAc may be catalyzed in the Leishmania cell prior to said genetic engineering by at least one N-acetylglucosamine (GlcNAc)-transferase. Also provided herein are methods of making a polypeptide using a Leishmania cell described herein and polypeptides produced by the methods provided herein.

The disclosure is in the technical field of synthetic biology and metabolic engineering. More particularly, the disclosure is in the technical field of cultivation or fermentation of metabolically engineered cells. The disclosure describes a method for the production of a di- or oligosaccharide with an N-acetylglucosamine at the reducing end by a cell as well as the purification of the di- or oligosaccharide from the cultivation. Furthermore, the disclosure provides a cell metabolically engineered for production of a di- or oligosaccharide with an N-acetylglucosamine at the reducing end.