Abstract: 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.

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 taurine or increase hypotaurine or taurine production in prokaryotes or eukaryotes. More particularly, the invention relates to genetic transformation of organisms with algal, microalgal or fungal genes that encode proteins that pool catalyze the conversion of sulfur-containing compounds such as sulfate or cysteine to taurine. The invention describes methods for the use of polynucleotides for cysteine dioxygenase-like (CDOL), sulfinoalanine decarboxylase-like (SADL), cysteine sulfate/decarboxylase or a portion of the cysteine synthetase/PLP decarboxylase (partCS/PLP-DC) polypeptide in bacteria, alga, yeast, or plants to produce taurine or increase hypotaurine or taurine. The preferred embodiment of the invention is in plants but other organisms may be used.

Abstract: The present invention provides formulations using combinations of protein alpha-amino acids, non-protein alpha-amino acids, beta-amino acids, gamma-amino acids, methyl-amino acids, polyamines or sulfonic acids, to increase plant growth or improve agronomic quality. The present invention provides for use of the formulations as a foliar spray, soil additive, or plant-organ or seed treatment. The present invention provides applications of the formulation to plants, plant organs or seeds to enhance plant performance, especially with regard to promotion of germination, growth, yield or increased sugar content or total sugar production.

Abstract: The present invention describes a non-transgenic approach to produce truncated glutamate decarboxylase (GAD) genes and the corresponding truncated gene product in plants. More particularly, the invention relates to the removal of the calcium-calmodulin binding domain (CaM-BD) from plant GADs using site-directed mutagenesis or gene-editing techniques. The removal of the CaM-BD from plant GADS results in an active GAD enzyme that is not regulated by the CaM-BD, which increases gamma aminobutyric acid (GABA) production in plant cells, organs or whole plants. Non-transgenic plants with truncated GAD have agronomic benefits, including increased GABA, biomass, yield, sugar, and tolerance to abiotic and biotic stressors. In addition, GABA from plants could be used as nutraceutical, pharmaceutical, or therapeutic compounds or as a supplement in animal feed or for animal feed or as an enhancer for plant growth or yield.

Abstract: The present invention describes an approach to increase taurine or hypotaurine production in prokaryotes. More particularly, the invention relates to genetic transformation of organisms with genes that encode proteins that catalyze the conversion of cysteine to taurine, methionine to taurine, cysteamine to taurine, or alanine to taurine. The invention describes methods for the use of polynucleotides that encode cysteine dioxygenase (CDO) and sulfinoalanine decarboxylase (SAD) polypeptides in prokaryotes to increase taurine, hypotaurine or taurine precursor production. The preferred embodiment of the invention is in plants but other organisms may be used. Increased taurine production in prokaryotes could be used as nutraceutical, pharmaceutical, or therapeutic compounds or as a supplement in animal feed.

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 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.

Abstract: The present invention describes an approach to produce taurine or increase hypotaurine or taurine production in prokaryotes or eukaryotes. More particularly, the invention relates to genetic transformation of organisms with algal, microalgal or fungal genes that encode proteins that pool catalyze the conversion of sulfur-containing compounds such as sulfate or cysteine to taurine. The invention describes methods for the use of polynucleotides for cysteine dioxygenase-like (CDOL), sulfmoalanine decarboxylase-like (SADL), cysteine sulfate/decarboxylase or a portion of the cysteine synthetase/PLP decarboxylase (partCS/PLP-DC) polypeptide in bacteria, alga, yeast, or plants to produce taurine or increase hypotaurine or taurine. The preferred embodiment of the invention is in plants but other organisms may be used.

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 increase taurine or hypotaurine production in prokaryotes. More particularly, the invention relates to genetic transformation of organisms with genes that encode proteins that catalyze the conversion of cysteine to taurine, methionine to taurine, cysteamine to taurine, or alanine to taurine. The invention describes methods for the use of polynucleotides that encode cysteine dioxygenase (CDO) and sulfinoalanine decarboxylase (SAD) polypeptides in prokaryotes to increase taurine, hypotaurine or taurine precursor production. The preferred embodiment of the invention is in plants but other organisms may be used. Increased taurine production in prokaryotes could be used as nutraceutical, pharmaceutical, or therapeutic compounds or as a supplement in animal feed.

Abstract: The present invention provides metabolic regulators, which are proteins (such as fusion proteins, truncated proteins or full-length proteins) that bind to specific metabolites and which can be used to control the availability of the metabolites in cells, particularly plant cells. Proteins of the invention include one or more metabolic regulator proteins, can be truncated or full length, can further comprise a transmembrane domain or lipoylation site or can further comprise a transit peptide. Metabolic regulators of the invention can be soluble, e.g., cytosolic soluble, can be anchored to a biological membrane or can be organelle targeted or apoplastic targeted. The present invention also provides nucleic acid molecules encoding the metabolic regulators, methods of making the nucleic acid molecules, methods for making transformed organisms, including plants, photosynthetic organisms, microbes, invertebrates, and vertebrates, and methods for controlling availability of metabolites to a host cell.

Abstract: The present invention describes an approach to increase taurine or hypotaurine production in prokaryotes. More particularly, the invention relates to genetic transformation of organisms with genes that encode proteins that catalyze the conversion of cysteine to taurine, methionine to taurine, cysteamine to taurine, or alanine to taurine. The invention describes methods for the use of polynucleotides that encode cysteine dioxygenase (CDO) and sulfinoalanine decarboxylase (SAD) polypeptides in prokaryotes to increase taurine, hypotaurine or taurine precursor production. The preferred embodiment of the invention is in plants but other organisms may be used. Increased taurine production in prokaryotes could be used as nutraceutical, pharmaceutical, or therapeutic compounds or as a supplement in animal feed.

Abstract: The present invention describes an approach to increase taurine or hypotaurine production in prokaryotes. More particularly, the invention relates to genetic transformation of organisms with genes that encode proteins that catalyze the conversion of cysteine to taurine, methionine to taurine, cysteamine to taurine, or alanine to taurine. The invention describes methods for the use of polynucleotides that encode cysteine dioxygenase (CDO) and sulfinoalanine decarboxylase (SAD) polypeptides in prokaryotes to increase taurine, hypotaurine or taurine precursor production. The preferred embodiment of the invention is in plants but other organisms may be used. Increased taurine production in prokaryotes could be used as nutraceutical, pharmaceutical, or therapeutic compounds or as a supplement in animal feed.

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 discloses regulatory sequences, promoters and terminators, and their use in plants. The regulatory sequences can be used to make gene constructs that include a gene not natively associated with the regulatory sequences. Methods to use the regulatory sequences with antisense constructs or functional RNAs are disclosed. Methods to use the regulatory sequences, promoter or terminator, independently of each other are also disclosed. Methods to use the regulatory sequences to improve plant growth and production such as increased biomass, increased yield and increased tolerance to abiotic or biotic stresses are also disclosed.

Abstract: The present invention describes an approach to increase taurine or hypotaurine production in prokaryotes. More particularly, the invention relates to genetic transformation of organisms with genes that encode proteins that catalyze the conversion of cysteine to taurine, methionine to taurine, cysteamine to taurine, or alanine to taurine. The invention describes methods for the use of polynucleotides that encode cysteine dioxygenase (CDO) and sulfinoalanine decarboxylase (SAD) polypeptides in prokaryotes to increase taurine, hypotaurine or taurine precursor production. The preferred embodiment of the invention is in plants but other organisms may be used. Increased taurine production in prokaryotes could be used as nutraceutical, pharmaceutical, or therapeutic compounds or as a supplement in animal feed.

Abstract: The present invention describes an approach to increase taurine or hypotaurine production in prokaryotes or eukaryotes. More particularly, the invention relates to genetic transformation of organisms with genes that encode proteins that catalyze the conversion of cysteine to taurine, methionine to taurine, cysteamine to taurine, or alanine to taurine. The invention describes methods for the use of polynucleotides that encode functional cysteine dioxygenase (CDO), cysteine dioxygenase (CDO) and sulfinoalanine decarboxylase (SAD) or glutamate decarboxylase (GAD), cysteamine dioxygenase (ADO), taurine-pyruvate aminotransferase (TPAT), TPAT and sulfoacetaldehyde acetyltransferase (SA), taurine dioxygenase (TDO) or the small (ssTDeHase) and large subunits of taurine dehydrogenase (lsTDeHase) polypeptides in plants to increase taurine, hypotaurine or taurine precursor production. The preferred embodiment of the invention is in plants but other organisms may be used.

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.