The present invention relates to a secretagogue compound derived from oxalate degrading bacteria, for use in the treatment of an oxalate related disease and/or oxalate related imbalance in a subject, wherein the administration of the secretagogue results in a reduction of urinary oxalate and/or plasma oxalate in the subject. The invention further relates to a pharmaceutical composition comprising such a secretagogue compound, a method for treating a subject suffering from an oxalate related disease, and to a method for preparing a secretagogue.

A method is described for producing L-methionine by fermentation using a bacterium which has been modified to overexpress a 1st gene and a 2nd gene, such as genes having the nucleotide sequences shown in SEQ ID NOs: 1 and 3.

The present invention describes an approach to produce or increase hypotaurine or taurine production in unicellular organisms. More particularly, the invention relates to genetic modification of unicellular organisms that include bacteria, algal, microalgal, diatoms, yeast, or fungi. The invention relates to methods to increase taurine levels in the cells by binding taurine or decreasing taurine degradation. The invention can be used in organisms that contain native or heterologous (transgenic) taurine biosynthetic pathways or cells that have taurine by enrichment. The invention also relates to methods to increase taurine levels in the cells and to use the said cells or extracts or purifications from the cells that contain the invention to produce plant growth enhancers, food, animal feed, aquafeed, food or drink supplements, animal-feed supplements, dietary supplements, health supplements or taurine.

The present invention describes methods to produce a synthetic or semi-synthetic cysteine synthase/PLP-dependent decarboxylase (sCs/PLP-DC). More particularly, the invention relates to genetic modification of organisms including eukaryotes and prokaryotes to express a functional sCs/PLP-DC. The invention includes methods to produce taurine in organisms that contain native or heterologous (transgenic) taurine biosynthetic pathways or cells that have taurine by enrichment. The invention also relates to methods to increase taurine levels in the cells and to use the said cells or extracts or purifications from the cells that contain the invention to produce plant growth enhancers, food, animal feed, aquafeed, food or drink supplements, animal-feed supplements, dietary supplements, health supplements or taurine.

The present invention relates to an L-cysteine-producing mutant microorganism having introduced therein genes encoding enzymes which are involved in the L-cysteine metabolic pathway, and more particularly to an L-cysteine-producing mutant microorganism having introduced therein cysE, cysK and cysR, which are genes encoding enzymes which are involved in the L-cysteine metabolic pathway, and to a method of producing L-cysteine using the mutant microorganism. According to the present invention, L-cysteine can be produced with high efficiency as a result of regulating metabolic fluxes associated with the L-cysteine metabolic pathway of the mutant microorganism and regulating a system for supplying a sulfur source essential for synthesis of L-cysteine.

Provided is a process for synthesizing a functionalized cyclic dithiocarbamate.

Metal bioremediation and metal mining strategies can include compositions and methods.

A method of reducing an amount of a sulfur-containing compound in a reservoir fluid includes contacting a treatment fluid comprising an aqueous medium and an enzymatic scavenger with a precipitating fluid to precipitate the enzymatic scavenger; contacting the precipitated enzymatic scavenger with the reservoir fluid comprising the sulfur-containing compound; and reducing a number of the sulfur-containing compound in the reservoir fluid.

The present disclosure relates to erythroid cells that have been engineered to express a homocysteine reducing polypeptide, or a variant thereof, or a homocysteine degrading polypeptide, or a variant thereof. The engineered erythroid cells may further comprise an amino acid transporter, for example a homocysteine transporter or a serine transporter, or a cystathionine degrading polypeptide. The engineered erythroid cells of the present disclosure are useful in reducing the level of homocysteine in a subject. The engineered erythroid cells of the present disclosure are further useful in methods of treating homocystinuria.

A method of reducing an amount of a sulfur-containing compound in a reservoir fluid includes contacting a treatment fluid comprising an aqueous medium and an enzymatic scavenger with a precipitating fluid to precipitate the enzymatic scavenger; contacting the precipitated enzymatic scavenger with the reservoir fluid comprising the sulfur-containing compound; and reducing a number of the sulfur-containing compound in the reservoir fluid.