The present invention relates to the combination of spirulina and palmitoylethanolamide (PEA) and/or pharmaceutically acceptable derivates or salts thereof, pharmaceutical formulations comprising the combination of spirulina and PEA and/or pharmaceutically acceptable derivates or salts thereof, optionally together with at least one physiologically acceptable excipient, and the use of the combination of spirulina and PEA and/or pharmaceutically acceptable derivates or salts thereof and formulations which include the said combination, for use in the prevention and/or treatment of tissue hyperactivation states, in the prevention and/or treatment of inflammatory pathologies, in the prevention and/or treatment of alterations in cardiac and/or coronary tissue, in the prevention and/or treatment of alterations in the vascular tissue, in the prevention and/or treatment of ophthalmic pathologies, preferably in the prevention and/or treatment of macular degeneration pathologies and glaucoma, in the prevention and/or treatment of dyslipidemia, in the prevention and/or treatment of alterations in pulmonary tissue, in the prevention and/or treatment of alterations in pelvic tissues, in the prevention and/or treatment of cellular alterations due to carcinogenesis, and/or in the prevention and/or treatment of dermatological alterations.

Methods for improving the ability of a population of biological agents to compete and survive in a field setting are provided. The modified population of agents is able to grow, compete with other microbial strains and fungi, and provide protection for plants from pathogens. Modified biological agents and modified populations of such agents that are herbicide tolerant or resistant are selected or engineered. In this manner, the protection from disease-causing agents is enhanced. Such modified populations can be added to soils to prevent fungal pathogens and associated diseases, promoting plant growth. The present invention is useful for enhancing the competitiveness of modified biological agents particularly over other microbial agents which are not herbicide resistant. Compositions include selected or engineered herbicide resistant biological agents and modified populations of biocontrol agents. These modified biological agents can be used as an inoculant or as a seed coating for plants and seeds.

Methods for improving the ability of a population of biological agents to compete and survive in a field setting are provided. The modified population of agents is able to grow, compete with other microbial strains and fungi, and provide protection for plants from pathogens. Modified biological agents and modified populations of such agents that are herbicide tolerant or resistant are selected or engineered. In this manner, the protection from disease-causing agents is enhanced. Such modified populations can be added to soils to prevent fungal pathogens and associated diseases, promoting plant growth. The present invention is useful for enhancing the competitiveness of modified biological agents particularly over other microbial agents which are not herbicide resistant. Compositions include selected or engineered herbicide resistant biological agents and modified populations of biocontrol agents. These modified biological agents can be used as an inoculant or as a seed coating for plants and seeds.

The present disclosure provides an iPSC cell derived from a somatic cell comprising a Cbx family gene and the applications thereof. Also provided are methods for generating the somatic cells that have potential to become induced pluripotent stem (iPS) cells (iPS cells) without oncogenic properties, and methods for generating iPS cells from the population of cells, which may then be used for transplantation and for cellular differentiation and interaction.

The present invention relates to novel mixtures comprising, as active components, at least one isolated bacterial strain, which is a member of the genus Paenibacillus, or a cell-free extract thereof or at least one metabolite thereof, and at least one other biopesticide. The present invention also relates to compositions comprising at least one of such bacterial strains, whole culture broth or a cell-free extract or a fraction thereof or at least one metabolite thereof, and at least one other biopesticide. The present invention also relates to a method of controlling or suppressing plant pathogens or preventing plant pathogen infections by applying such composition. The present invention also relates to mixtures of fusaricidins which are pesticidal metabolites produced by the abovementioned strains, and other biopesticides.

Provided herein are methods for using RNAi molecules targeting an Inhibitor of Apoptosis (IAP) gene for controlling Coleopteran insects, methods for producing RNAi molecules targeting IAP, and compositions comprising RNAi molecules targeting IAP.

Provided herein are methods for using RNAi molecules targeting an Inhibitor of Apoptosis (IAP) gene for controlling Coleopteran insects, methods for producing RNAi molecules targeting IAP, and compositions comprising RNAi molecules targeting IAP.

The present invention relates to methods of scalably producing microorganisms by propagating them within plant tissues and introducing them into agricultural seeds to improve their shelf-life during long-term storage, to produce substances of interest, and to create libraries of microbes.

The present invention relates to methods of scalably producing microorganisms by propagating them within plant tissues and introducing them into agricultural seeds to improve their shelf-life during long-term storage, to produce substances of interest, and to create libraries of microbes.

Disclosed herein are microbial consortia and compositions including microbes, for example, for use in agricultural or biodegradation applications. In some embodiments, soil, plants, and/or plant parts (such as seeds, seedlings, shoots, roots, leaves, fruit, stems, or branches) are contacted with a disclosed microbial consortia or composition including microbes. The microbial consortia or microbe-containing compositions may be applied to soil, plant, and/or plant parts alone or in combination with additional components (such as chitin, chitosan, glucosamine, amino acids, and/or liquid fertilizer). In additional embodiments, the disclosed microbial consortia or compositions including microbes are used in methods of degrading biological materials, such as chitin-containing biological materials.