Abstract: 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.

Abstract: 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.

Abstract: 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.

Abstract: The present invention describes an alternative approach to increase Taurine (Tau) or methionine (Met) production in eukaryotes, namely by the insertion of components of a sulfur-metabolic pathway and Tau- or Met-binding proteins in organisms where the peptides do not exist or have not clearly been identified. The invention describes methods for the use of polynucleotides that encode functional cysteine dioxygenase (CDO) alone, sulfinoalanine decarboxylase (SAD) alone or CDO and SAD polypeptides in combination with functional Tau- or Met-binding proteins in plants to increase Tau or Met production. The preferred embodiment of the invention is in plants but other organisms may be used. Increased Tau or Met availability will improve nutritional value of the crop.

Abstract: The present invention describes an alternative approach to increase methionine (Met) production in eukaryotes, namely by the insertion of components of a sulfur-metabolic pathway in organisms where the pathway does not exist or has not clearly been identified. The invention describes methods for the use of polynucleotides that encode functional cysteine dioxygenase (CDO) alone or CDO and sulfinoalanine decarboxylase (SAD) polypeptides in plants to increase Met production. The preferred embodiment of the invention is in plants but other organisms may be used. Changes in Met availability will improve nutritional value of the crop.

Abstract: The present invention describes an alternative approach to increase methionine (Met) production in eukaryotes, namely by the insertion of components of a sulfur-metabolic pathway in organisms where the pathway does not exist or has not clearly been identified. The invention describes methods for the use of polynucleotides that encode functional cysteine dioxygenase (CDO) alone or CDO and sulfinoalanine decarboxylase (SAD) polypeptides in plants to increase Met production. The preferred embodiment of the invention is in plants but other organisms may be used. Changes in Met availability will improve nutritional value of the crop.