The present invention relates to a recombinant microorganism comprising one or more nucleotide sequence(s) encoding: a polypeptide having ent-copalyl pyrophosphate synthase activity; a polypeptide having ent-Kaurene synthase activity; a polypeptide having ent-Kaurene oxidase activity; and a polypeptide having kaurenoic acid 13-hydroxylase activity, whereby expression of the nucleotide sequence(s) confer(s) on the microorganism the ability to produce at least steviol.

Methods and materials for genetically engineering methylotrophic yeast are provided.

Methods and materials for genetically engineering methylotrophic yeast are provided.

The invention relates to a mutant of Saccharomyces eubayanus that is able to ferment maltotriose, and to the use of this mutant for producing hybrid yeast and the resulting hybrid yeast. The invention relates to methods of producing a fermented beer product by employing said mutant and/or said hybrid yeast.

Acetate is a potent microbial inhibitor which can affect the performance of yeast in ethanolic fermentation. The present disclosure provides a recombinant microbial host cell having (i) a first genetic modification for increasing the activity of one or more proteins that function in a first metabolic pathway to convert acetate into an alcohol in the microbial host cell; (ii) a second genetic modification for increasing the activity of one or more proteins that function in a second metabolic pathway to import glycerol in the recombinant microbial host cell (iii) a third genetic modification for increasing the activity of one or more proteins that function in a third metabolic pathway to convert a C5 carbohydrate into ethanol in the microbial host cell. The recombinant microbial host cell comprises and natively expresses native proteins that function in a fourth native metabolic pathway to produce glycerol in the microbial host cell.

Less-than-diploid I. orientalis cells are produced. The cells have at least one unpaired chromosome and may be haploid, i.e., are missing one member of each pair of chromosomes that are present in the wild-type strains. The less-than-diploid cells are useful fermentation strains, performing similarly to diploid strains that are otherwise similarly engineered. The less-than-diploid strains can be mated to produce diploids, which themselves are useful fermentation strains. The less-than-diploid strains are also useful as host strains for producing further genetically modified strains that can be less-than-diploid or mated to produce diploids.

Less-than-diploid I. orientalis cells are produced. The cells have at least one unpaired chromosome and may be haploid, i.e., are missing one member of each pair of chromosomes that are present in the wild-type strains. The less-than-diploid cells are useful fermentation strains, performing similarly to diploid strains that are otherwise similarly engineered. The less-than-diploid strains can be mated to produce diploids, which themselves are useful fermentation strains. The less-than-diploid strains are also useful as host strains for producing further genetically modified strains that can be less-than-diploid or mated to produce diploids.

The present disclosure relates to intercellular signaling between genetically-engineered cells and, more specifically, to a scalable peptide-GPCR intercellular signaling system. The present disclosure provides an intercellular signaling system that includes at least two cells that have been genetically-engineered to communicate with each other, methods of use and kits thereof.

The present disclosure relates to intercellular signaling between genetically-engineered cells and, more specifically, to a scalable peptide-GPCR intercellular signaling system. The present disclosure provides an intercellular signaling system that includes at least two cells that have been genetically-engineered to communicate with each other, methods of use and kits thereof.

This invention is intended to improve the ethanol fermentation ability of a yeast strain having xylose-metabolizing ability with the use of a mutant gene encoding a mutant protein comprising a consensus sequence comprising a substitution of amino acid in the 30th position in SEQ ID NO: 1, amino acid in the 43rd position in SEQ ID NO: 4, and amino acid in the 31st position in SEQ ID NO: 7 with other amino acid residues.