A novel alga mutant having improved pigment productivity is provided. The mutant can be used to produce carotenoid-based pigments, particularly, xanthophyll by using a small amount of energy, and thus can effectively produce pigment on an industrial level. In addition, the mutant can be used as a source for foods, health functional foods, and medications which contain a pigment. Further, when account is taken of the physiological characteristics of the euryhaline microalgae Dunaliella and the geological characteristics of Korean, the three sides of which are in contact with the sea, sea-water can be used as a culture medium, with the expectation of reducing the cost and leading to the development of related industries.

Provided herein are methods for obtaining purified recombinant osteopontin (rOPN) from cultures of transgenic microalgae, as well as nutritional supplements from such cultures.

The present disclosure provides a resource-circulation-type and eco-friendly livestock manure treatment method, and a system for producing algal biomass used therein, the method being capable of: preventing water pollution while allowing livestock liquid fertilizer to be treated on the basis of a biological process; producing algal biomass; and supplying the produced algal biomass to livestock feed and farms.

The invention provides a recombinant algal organism that has been genetically modified in a gene encoding a protein kinase-like protein. The recombinant organism exhibits higher biomass productivity and higher lipid productivity versus a corresponding control algal organism not having the genetic modification. The recombinant organism is therefore useful in applications requiring biomass and/or lipid productivity, e.g. in the production of biofuels or other lipidic matter. Methods of using the organism and biomass containing or produced by the organism are also provided.

The invention provides recombinant algal mutants that have a genetic modification to a gene or nucleic acid sequence encoding a WD40 repeat containing protein or domain. The genetic modification of one or more nucleic acid sequences encoding a WD40 repeat containing protein or domain results in a mutant organism with increased lipid productivity and/or higher biomass productivity (as measured by total organic carbon). The genetic modification can be a gene attenuation or functional deletion. The lipid products of these mutants can be utilized as biofuels or for other specialty chemical products. Methods of making and using the recombinant algal mutants and methods of producing lipids are also disclosed.

The present invention is directed to isolated thraustochytrid microorganisms as well as strains and mutants thereof. The invention is further directed to biomasses, microbial oils, compositions, cultures, methods of producing microbial oils, and methods of using the isolated thraustochytrids, biomasses, and microbial oils.

Provided are compositions containing extracellular vesicles from microalgae (MEVs) that are exogenously loaded with bioactive cargo or other cargo of interest, such as for therapeutic, industrial, diagnostic, and cosmetic uses. The MEVs have a variety of applications as therapeutics, including as vaccines, as anti-cancer therapeutics, as diagnostics, and other such uses.

In ethyl alcohol production using the self-fermentation of a microalga, a step of concentrating or collecting an algal body by centrifugal treatment, filtering treatment or the like is made unnecessary or simple to save labor for effort and equipment therefor is saved. The microalga belongs to Chlamydomonas sp., and is a variant strain which has an ability to produce ethyl alcohol under dark and anaerobic conditions and has acquired an ability to proliferate while aggregating. The microalga is proliferated and maintained under dark and anaerobic conditions to generate ethyl alcohol in this method for producing ethyl alcohol.

A microbial oil includes a triglyceride. Sn-2 fatty acids of the triglyceride in the microbial oil contain 23% or more by weight of DHA. The microbial oil is prepared by fermentation using a Schizochytrium strain, where the Schizochytrium strain is Schizochytrium sp. with an accession number of GDMCC No. 60733. A food including the microbial oil is also provided.

The invention relates to the novel use of photosynthetic microorganisms to allow for the generation of micron-scale optical output mechanical sensors. In one preferred embodiment, the invention includes systems, methods and compositions for the use of photosynthetic microbes as biologically-based micron-scale tunable, light/chemical-mechanical energy transducers, sensors, and/or actuators.