Abstract: Disruption of a Lipid Droplet Regulatory—Tudor Domain Containing (LRT1) gene in plants leads to accumulation of storage lipids in cells of the plants. An increased amount of lipids storage in these plants offers new possibilities for developing crops with more energy dense biomass and increased seed oil content.

Abstract: The present disclosure relates to increasing oil content in plants through manipulating expression of proteins, namely At5g16550 proteins. At5g16550 proteins are lipid droplet proteins. Plants having reduced expression of At5g16550 proteins demonstrate cytoplasmic lipid droplets (LDs) that are increased in size, resulting in greater overall oil content in the plant cells.

Abstract: In some embodiments, the present invention provides a method of elevating lipid content in vegetative (non-seed) plant or algae cells, plant tissues, or whole plants by genetically modifying the plant or algae to express a lipid droplet-associated protein or polypeptide (such as fat-specific protein 27) of mammalian origin. Also provided are genetically-modified plant or algae cells, plant tissues, or whole plants with elevated cellular lipid content, expressing a lipid droplet-associated protein or polypeptide (such as fat-specific protein 27) of mammalian (e.g. human) origin.

Abstract: An identified 90 bp sequence insertion in the GB0331 genome disrupts the coding sequence of the FAD2-1D gene near the 3? end of the protein coding region. This sequence is not found in reference genomes of other Gossypium species. This DNA segment can be used to track the high oleic fad-2-1D mutant allele for introgression into cotton varieties such as Pima and upland cotton varieties. This enables a non-GMO strategy to elevate the oleic acid content of commercial cottonseed oil.

Abstract: An identified 90 bp sequence insertion in the GB0331 genome disrupts the coding sequence of the FAD2-1D gene near the 3? end of the protein coding region. This sequence is not found in reference genomes of other Gossypium species. This DNA segment can be used to track the high oleic fad-2-1D mutant allele for introgression into cotton varieties such as Pima and upland cotton varieties. This enables a non-GMO strategy to elevate the oleic acid content of commercial cottonseed oil.

Abstract: A method for enhancing amidohydrolase activity of Fatty Acid Amide Hydrolase (FAAH) is disclosed. The method comprising administering a phenoxyacyl-ethanolamide that causes the enhanced activity. The enhanced activity can have numerous effects on biological organisms including, for example, enhancing the growth of certain seedlings.

Abstract: The present disclosure relates to increasing oil content in plants through manipulating expression of proteins, namely At5g16550 proteins. At5g16550 proteins are lipid droplet proteins. Plants having reduced expression of At5g16550 proteins demonstrate cytoplasmic lipid droplets (LDs) that are increased in size, resulting in greater overall oil content in the plant cells.

Abstract: A method for enhancing amidohydrolase activity of Fatty Acid Amide Hydrolase (FAAH) is disclosed. The method comprising administering a phenoxyacyl-ethanolamide that causes the enhanced activity. The enhanced activity can have numerous effects on biological organisms including, for example, enhancing the growth of certain seedlings.

Abstract: A method for enhancing amidohydrolase activity of Fatty Acid Amide Hydrolase (FAAH) is disclosed. The method comprising administering a phenoxyacylethanolamide that causes the enhanced activity. The enhanced activity can have numerous effects on biological organisms including, for example, enhancing the growth of certain seedlings. The subject matter disclosed herein relates to enhancers of amidohydrolase activity.

Abstract: A method for enhancing amidohydrolase activity of Fatty Acid Amide Hydrolase (FAAH) is disclosed. The method comprising administering a phenoxyacylethanolamide that causes the enhanced activity. The enhanced activity can have numerous effects on biological organisms including, for example, enhancing the growth of certain seedlings. The subject matter disclosed herein relates to enhancers of amidohydrolase activity.

Abstract: In some embodiments, the present invention provides a method of elevating lipid content in vegetative (non-seed) plant or algal cells, plant tissues, or whole plants by genetically modifying the plant or algae to express a protein or polypeptide associated with lipid metabolism (such as fat-specific protein 27) of animal origin or plant origin. Also provided are genetically-modified plant or algal cells, plant tissues, or whole plants with elevated cellular lipid content, expressing a protein or polypeptide associated with lipid metabolism (such as fat-specific protein 27) of animal (e.g. human) origin or plant origin.

Abstract: In some embodiments, the present invention provides a method of elevating lipid content in vegetative (non-seed) plant or algae cells, plant tissues, or whole plants by genetically modifying the plant or algae to express a lipid droplet-associated protein or polypeptide (such as fat-specific protein 27) of mammalian origin. Also provided are genetically-modified plant or algae cells, plant tissues, or whole plants with elevated cellular lipid content, expressing a lipid droplet-associated protein or polypeptide (such as fat-specific protein 27) of mammalian (e.g. human) origin.

Abstract: Preferred embodiments of this invention relate to a method for increasing fiber yield in a cotton plant by regenerating a whole cotton plant from a plant cell that has been transformed with a dominant negative allele for an endoplasmic reticulum located gene. The expression of this gene results in suppression of oil and protein biosynthesis in the developing seed and increased production of fiber in the plant.

Abstract: The invention provides plant binding proteins of N-acylethanolamines. Also provided are constructs comprising coding sequences for the binding proteins, plants transformed therewith and methods of use thereof. The invention allows the modification of plant signaling by N-acylethanolamines. Such modification may be used to produce plants that are improved with respect to growth, seed germination, pathogen response and stress tolerance.

Abstract: The present invention includes compositions and methods for neuroprotection by modulating intracellular calcium concentrations by administering an effective amount of an N-acylethanolamine to a subject.

Abstract: The invention provides plant fatty acid amide hydrolase (FAAH) coding sequences. Also provided are constructs comprising these sequences, plants transformed therewith and methods of use thereof. The invention allows the modification of plants for FAAH activity and N-Acylethanolamine levels. Such modification may be used to produce plants that are improved with respect to growth, seed germination, pathogen response and stress tolerance.