The invention relates to a genetically engineered thermophilic bacterial cell that is facultative anaerobic comprising: a) inactivation or deletion of the endogenous (S)-lactate dehydrogenase gene; b) introduction of a (R)-lactate dehydrogenase gene; c) inactivation or deletion of the endogenous pyruvate formate lyase A and/or B gene.

The present disclosure relates to various different types of variants in E. coli coding and noncoding regions leading to enhanced lysine production for, e.g., supplements and nutraceuticals.

The present disclosure relates to various different types of variants in E. coli coding and noncoding regions leading to enhanced lysine production for, e.g., supplements and nutraceuticals.

The present invention relates to genetically modified microorganisms comprising one or more heterologous nucleic acid molecules together encoding at least three different proteins, each protein comprising an enzymatic domain and a bacterial microcompartment-targeting signal polypeptide, wherein said enzymatic domains each catalyse a different substrate to product conversion in the same metabolic pathway, and wherein said microorganisms are essentially free of bacterial microcompartments (BMCs); and to cell free systems comprising aggregates comprising at least three different proteins, each protein comprising an enzymatic domain and a bacterial microcompartment-targeting signal polypeptide, wherein said enzymatic domains each catalyse a different substrate to product conversion in the same metabolic pathway, and wherein said system does not comprise bacterial microcompartments; and to methods for the production of said microorganisms and cell free systems and their use in methods of producing a product of interest.

The present disclosure relates to various different types of variants in E. coli coding and noncoding regions leading to enhanced lysine production for, e.g., supplements and nutraceuticals.

The present invention relates to new methylglyoxal reductase (MGR) enzymes which are useful for efficiently converting methylglyoxal into hydroxyacetone. The invention more particularly relates to a method for efficiently converting methylglyoxal into hydroxyacetone using said enzymes, to a method for producing 1,2-propanediol using a microorganism overexpressing said enzymes, and to said microorganism.

The present disclosure relates to various different types of variants in E. coli coding and noncoding regions leading to enhanced lysine production for, e.g., supplements and nutraceuticals.

Provided are a microorganism for producing a pantoic acid, and a construction method therefor and an application thereof. The microorganism for producing the pantoic acid is obtained by knocking out a gene in Escherichia coli and introducing an exogenous gene. The obtained microorganism is Escherichia coli that is registered in the China General Microbiological Culture Collection Center with an accession number of CGMCC No. 21699. A pantoic acid synthesis pathway has been opened up, and accumulation of the pantoic acid can be achieved in a fermentation process.

The present invention relates to new lactaldehyde reductase (LAR) enzymes useful for the production of 1,2-propanediol and to microorganisms overexpressing said enzymes. The invention also relates to a method for producing 1,2-propanediol by converting lactaldehyde into 1,2-propanediol with said enzymes.

The invention relates to a genetically engineered thermophilic bacterial cell that is facultative anaerobic comprising: a) inactivation or deletion of the endogenous (S)-lactate dehydrogenase gene; b) introduction of a (R)-lactate dehydrogenase gene; c) inactivation or deletion of the endogenous pyruvate formate lyase A and/or B gene.