Provided herein are a glucan kinase polypeptide, an isolated polynucleotide, and a method for processing starch. The glucan kinase polypeptide comprises an isolated polypeptide including a sequence selected from the group consisting of SEQ ID NO: 2, SEQ ID NO:22, fragments thereof, variants thereof, and combinations thereof. The isolated polynucleotide comprises a nucleotide sequence selected from the group consisting of SEQ ID NO: 1, SEQ ID NO: 21, a fragment thereof, a variant thereof, and a combination thereof. The method for processing starch comprises providing a glucan dikinase; exposing a starch to the glucan dikinase; and collecting the starch that has been exposed to the glucan dikinase.

The invention discloses a genetically engineered bacterium and its application in the preparation of sialyllactose. The genetically engineered bacterium has an N-acetylneuraminic acid biosynthesis pathway, includes multiple copies of a gene neuB for encoding sialic acid synthase, and the gene neuB is initiated for expression by a strong promoter. Using the genetically engineered bacteria of the invention to produce sialyllactose has the advantages of high yield and low overall cost.

Provided are a recombinant microorganism including a genetic modification that increases a pyruvate, phosphate dikinase activity, a method of producing cellulose using the same, and a method of producing a microorganism having enhanced cellulose productivity.

Disclosed herein are improved methods for production of 2-phenylethanol by microbial fermentation of substrates comprising carbon monoxide and/or carbon dioxide and further disclosed are genetically modified microorganisms for use in such methods that alleviate dependence on natural and petrochemical processes.

The invention provides compounds, compositions, non-naturally occurring organisms, and methods useful for production of 5-hydroxytryptophan (5-HTP) in a microbial cell. A microbial system which includes at least one microbial cell, such as a bacterial cell or a yeast cell, is genetically engineered to express all or a portion of non-naturally occurring biosynthetic pathway that catalyzes the conversion of a simple carbon source, such as glucose, to 5-HTP. The invention can result in improved titers of 5-HTP and permits low-cost, large scale production. Methods of making and using the genetically engineered cells are also included in the invention.

Genetically engineered plants expressing altered Glucan Water Dikinase and having elevated levels of starch are provided. Methods of genetically engineering plants to express altered Glucan Water Dikinase, and genetic constructs are provided. Methods of breeding genetically engineered plants homozygous for a mutated gene encoding an altered Glucan Water Dikinase are described. Methods of agricultural processing and animal feed using the genetically engineered plants are also provided.

Genetically engineered plants having altered levels of one or more starch regulation enzymes and a polysaccharide degrading enzyme are provided. Methods of genetically engineering plants to express products altering expression of one or more starch regulation enzymes and polysaccharide degrading enzymes, and genetic constructs are provided. Methods of agricultural processing and animal feed using the genetically engineered plants are described.

Presented herein are biocatalysts and methods for converting C1-containing materials to organic acids such as muconic acid or adipic acid.

Disclosed herein are transgenic plants and plant cells having increased photosynthetic rate, increased biomass production, and/or improved cold tolerance compared to control plants (such as non-transgenic plants of the same species as the transgenic plants). In some examples, the transgenic plants/plant cells contain a plant transformation vector including a nucleic acid encoding a pyruvate orthophosphate dikinase (PPDK) polypeptide. Also disclosed herein are methods for making the transgenic plants, for instance by introducing into progenitor cells of the plant a plant transformation vector including a nucleic acid that encodes a PPDK polypeptide, and growing the transformed progenitor cells to produce a transgenic plant, in which the PPDK nucleic acid is expressed. Further disclosed herein are PPDK-encoding nucleic acids, PPDK polypeptides, and plant transformation vectors of use in producing the transgenic plants or plant cells.

Disclosed is a method for forming selenoneine or analogs thereof. The method may include phosphorylating sodium selenide to a selenophosphate, using adenosine triphosphate (ATP) and at least a first protein, generating a selenosugar by converting the selenophosphate using at least a second protein in the presence of a common sugar donor, and forming selenoneine or an analog thereof by combining the selenosugar with N,N,N-trimethyl-L-histidine or analogs thereof using at least a third protein. The method may include combining SenA, SenB, and SenC in an aqueous buffer at neutral pH and ambient temperature, and allowing SenA, SenB, and SenC to form selenoneine or an analog thereof in the presence of ATP, a common sugar donor, and sodium selenide.