Quantum dots (QDs) and nanoplatelets (NPLs) are two types of nanoparticles used as scaffolds for enzymes operating in enzymatic cascades. Combinations of QDs and NPLs were surprisingly found to operate synergistically to create a greater enhancement than either alone when operating as scaffolds for enzymatic cascade reactions. A process involves providing an enzymatic cascade including a cluster of nanoparticles including both QDs and NPLs and having a plurality of enzymes bound thereto, the enzymes configured as an enzymatic cascade, such that the product of a first enzyme is a substrate of a second enzyme; contacting the cascade cluster with a substrate of the first enzyme; and allowing a reaction to proceed so that each of the plurality of enzymes acts in succession to produce an end product. The enzymes are bound to the nanoparticles via metal affinity coordination between histidine tags on the enzymes and zinc-containing surfaces of the nanoparticles.

Disclosed are an engineered yeast for efficient and rapid synthesis of erythritol and a construction method thereof. Yarrowia lipolytica is used as a synthetic chassis for genetic improvement. A method for synthesizing erythritol is as follows: using glucose as a carbon source, and a nitrogen source and an inorganic salt as raw materials, sterilizing a medium, cooling the sterilized medium before inoculating yeast Yarrowia lipolytica, performing continuous fermentation or fed-batch fermentation under the condition of oxygen supply, and purifying erythritol from a fermentation broth. Under the condition of continuous feeding, the yield of erythritol is more than 350 g/L, and the production efficiency is more than 4.5 g/L.Math.h, nearly 100% higher than that of a comparative strain.

The invention relates to a lactose-positive, galactose-negative, Streptococcus thermophilus strain carrying a mutation in 2 or 3 genes selected from the group consisting of 1) a gene encoding a protein of the mannose-glucose-specific PTS and a glcK gene, 2) a gene encoding a protein of the mannose-glucose-specific PTS and a ccpA gene, and 3) a gene encoding a protein of the mannose-glucose-specific PTS, a glcK gene and a ccpA gene, wherein said strain, when used to ferment milk, provides a low lactose fermented milk and/or a fermented milk not undergoing acidification when stored at fermentation temperature.

The present disclosure relates to a combination therapy comprising a first AAV vector genome comprising an insulin expression cassette; and a second AAV vector genome comprising a glucokinase expression cassette; wherein the first AAV vector genome and the second AAV vector genome are in a ratio selected from the group consisting of 1:0.25-0.75, 1:1.75-2.25, and 1:3.75-4.25, and methods for using the same for treating diabetes.

This disclosure provides methods and genetically engineered strains of Vibrio natriegens, specifically developed for the bio-based production of succinate. Capitalizing on the rapid growth kinetics and highly efficient carbon metabolism of V. natriegens, this disclosure provides an environmentally friendly, scalable, and cost-effective alternative to traditional petrochemical methods for succinate production.

The invention relates to a composition for producing a fermented milk product comprising: (i) a starter culture comprising a glucose-fermenting Streptococcus thermophilus (St) strain and a glucose-fermenting Lactobacillus delbrueckii subsp. bulgaricus (Lb) strain; and (ii) a glucose-deficient Streptococcus thermophilus (St) strain, wherein said St strain is galactose-fermenting and carries a mutation in the DNA sequence of the glcK gene encoding a glucokinase protein, which mutation inactivates the glucokinase protein or has a negative effect on expression of the gene.

The present specification relates to a microorganism into which a GPD gene, a GPP gene, and dhaB, gdrAB, aldH and/or yqhD genes are introduced, and/or use thereof, the microorganism being capable of simultaneously producing 1,3-PDO and 3-HP.

The present invention relates to new improved methods for expressing native lactases in their native hosts. Methods for homologous as well as heterologous expression of lactase in lactic acid bacteria with altered expression dynamics are comprised by present invention.

The present disclosure relates to microorganisms useful in the biosynthesis of psicose. Also provided are methods of producing the disclosed microorganism and methods of producing psicose.