A process comprising (i) providing a gaseous stream including greater than 1% by volume carbon dioxide; (ii) providing water; (iii) converting the carbon dioxide and the water to an organic intermediate and oxygen gas in the presence of light; (iv) separating the oxygen gas from the organic intermediate; and (v) converting the organic intermediate to ethylene and carbon dioxide after said step of separating the oxygen gas from the organic intermediate.

The present disclosure relates to biomanufacturing systems for producing an organic product. The present disclosure relates to recombinant microorganisms having an improved organic substrate producing ability, and to recombinant microorganisms having an improved organic product producing ability. A benefit of the systems and recombinant microorganisms disclosed herein can include an ability to separately produce an organic product and an organic substrate that generates a culture impurity during its production. The present disclosure relates to methods of producing an organic product using biomanufacturing systems and recombinant microorganisms disclosed herein.

The present invention relates to a sucrose phosphorylase variant comprising or consisting of an amino acid sequence with at least 75% homologous and/or identical to an amino acid sequence of wild type sucrose phosphorylase, preferably wherein the sucrose phosphorylase is characterized by different structural and functional features. The invention also relates to method for preparing aG1P and a co-product, wherein the method comprises reacting a sucrose phosphorylase with a glucoside substrate, wherein the sucrose phosphorylase is a sucrose phosphorylase as defined in the context of the present invention.

The present invention relates to a sucrose phosphorylase variant comprising or consisting of an amino acid sequence with at least 75% homologous and/or identical to an amino acid sequence of wild type sucrose phosphorylase, preferably wherein the sucrose phosphorylase is characterized by different structural and functional features. The invention also relates to method for preparing aG1P and a co-product, wherein the method comprises reacting a sucrose phosphorylase with a glucoside substrate, wherein the sucrose phosphorylase is a sucrose phosphorylase as defined in the context of the present invention.

The present invention relates to a method for producing 2-O-a-D-glucopyranosyl-L-ascorbic acid (AA-2G) under acidic conditions from a glucosyl donor and a glucosyl acceptor and the use of a sucrose phosphorylase.

A method for producing glucose and derivatives thereof by means of biotransformation with a recombinant yeast, which belongs to the technical field of synthetic biology. A construction method comprises any one of the following steps: i, knocking out metabolic pathway-related enzymes of glucose and derivatives thereof in a yeast strain; ii, enhancing or using an activity of synthetic pathway-related enzymes of glucose and derivatives thereof in the yeast strain; and iii, enhancing or using a capability of glucose and derivatives thereof in the yeast strain to enter and exit the yeast. Further provided are a recombinant yeast strain capable of producing glucose or derivatives thereof at a high yield and the use thereof in the conversion of a non-grain low-carbon carbon source. The low-carbon non-grain carbon source synthesized by means of using photoelectrocatalysis or traditional chemical industry is used as a substrate, and rapid preparation of food product raw materials glucose and derivatives thereof from the non-grain carbon source is realized by means of recombinant yeast cells.