The disclosure relates to methods and compositions for the production of fructans using sucrose:sucrose 1-fructosyl-transferase (1-SST), fructan:fructan 1-fructosyltransferase (1-FFT), and/or sucrose fructan-6-fructosyltransferase (6-SFT) enzymes.

Genetic constructs capable of manipulating fructan biosynthesis in photosynthetic cells of a plant, said genetic constructs include a promoter operatively linked to a nucleic acid encoding a bacterial FT enzyme. These constructs can be used in modification of fructan biosynthesis in plants and, more particularly, for manipulating fructan biosynthesis in photosynthetic cells. The constructs can also be used for increasing plant biomass and, more particularly, for enhancing biomass yield and/or yield stability, including shoot and/or root growth in a plant, and for enhancing the productivity of biochemical pathways.

The present disclosure provides solutions to various challenges in health, including health challenges related to high consumption of carbohydrate and/or low consumption of soluble fiber. The present disclosure provides, among other things, bacteria engineered for expression of a fiber-synthesizing enzyme, e.g., for expression of the enzyme in the gut (e.g., in the intestine). In particular embodiments, the present disclosure provides bacteria engineered for expression of a fiber-synthesizing enzyme that consumes carbohydrate in the process of synthesizing fiber, e.g., in the gut. The present disclosure further includes formulations of isolated fiber-synthesizing enzymes for administration to subjects.

It is an object of the present invention to provide a bacterial strain that can decrease the amount of an intermediate Compound P converted into Metabolite M and efficiently accumulate Compound P in a medium that is not supplemented with Metabolite M or the final product generated from Metabolite M. The present invention provides a prokaryotic organism having all features (a) to (d) as defined in the specification so as to accumulate Compound P by regulating expression level of Enzyme X that converts Compound P as an intermediate metabolite into Metabolite M in a biosynthetic pathway in which Metabolite M indispensable for the growth is produced from a carbon source.

The instant disclosure provides a genetically modified bacterial cell, i.e., modified Agrobacterium strain, which expresses a levansucrase and has reduced expression of endogenous CysK. As a result, the growth of the modified bacterial cell on medium or tissue culture with sucrose and deficient in cysteine is inhibited. The two-action growth control of the modified Agrobacterium strain can overcome the unmet issue of Agrobacterium overgrowth during plant transformation, and therefore increase the efficiency of plant transformation.

The present invention relates to a recombinant microorganism for producing 2,3-butanediol, in which, in a microorganism having the 2,3-butanediol biosynthetic pathway, at least one selected from a group consisting of a pathway for converting glutamic acid into polyglutamic acid, a pathway for converting sucrose into levan, a pathway for converting pyruvate into lactate, and a pathway for converting glycerophosphate into glycerol is inhibited. The present invention also relates to a method for producing 2,3-butanediol by using the recombinant microorganism for producing 2,3-butanediol.

It is an object of the present invention to provide a bacterial strain that can decrease the amount of an intermediate Compound P converted into Metabolite M and efficiently accumulate Compound P in a medium that is not supplemented with Metabolite M or the final product generated from Metabolite M. The present invention provides a prokaryotic organism having all features (a) to (d) as defined in the specification so as to accumulate Compound P by regulating expression level of Enzyme X that converts Compound P as an intermediate metabolite into Metabolite M in a biosynthetic pathway in which Metabolite M indispensable for the growth is produced from a carbon source.

It is an object of the present invention to provide a bacterial strain that can decrease the amount of an intermediate Compound P converted into Metabolite M and efficiently accumulate Compound P in a medium that is not supplemented with Metabolite M or the final product generated from Metabolite M. The present invention provides a prokaryotic organism having all features (a) to (d) as defined in the specification so as to accumulate Compound P by regulating expression level of Enzyme X that converts Compound P as an intermediate metabolite into Metabolite M in a biosynthetic pathway in which Metabolite M indispensable for the growth is produced from a carbon source.

The present invention provides a bio-fuel, wood or other product, such as a paper, textile or yarn product. The product can contain material from a transgenic plant over-expressing a nucleic acid molecule encoding an enzyme that causes the plant cell wall to be more water soluble than the wild type.

The invention provides an oligosaccharide debranching enzyme mutant and use thereof in a glucose mother liquor. The mutant is obtained by mutating valine at position 219 in SEQ ID NO: 1 into alanine. According to oligosaccharide debranching enzyme mutant V219A, a primary mother liquor, a secondary mother liquor, or a tail liquid after chromatographic separation is used as a substrate, the percentage contents of glucose in the products are 99.21% (primary mother liquor), 98.89% (secondary mother liquor) and 97.97% (tail liquid after chromatographic separation) respectively, which are 2.86%, 8.64%, and 28.67% higher than that of glucose obtained with the wild-type oligosaccharide debranching enzyme. Therefore, the mutant V219A obviously improves the percentage content of glucose in the glucose mother liquor, and the scope of application of the mother liquor can be expanded by the high product purity and substrate conversion rate, so the mutant V219A has higher industrial application value.