A mutant algal strain showing upregulation of mRNA transcripts encoding urea carboxylase, Δ-15-ω3-desaturase and downregulation of mRNA transcripts of gene encoding triacylglycerol lipase is provided herein. The mutant algal strain of the present disclosure is tolerant to low temperature and thus can be grown over a wide temperature range. The strain shows enhanced biomass and fatty acid production and enhanced growth rate and nitrogen metabolism over a wide temperature range of about 10° C. to about 37° C., wherein the enhancement is in comparison to the wild type algal strain. A method of obtaining the mutant algal strain and a method of producing industrially relevant products such as fatty acids from the mutant algal strain also are provided herein.

The present invention provides for a mechanism to reduce glycerol production and increase nitrogen utilization and ethanol production of recombinant microorganisms. One aspect of this invention relates to strains of S. cerevisiae with reduced glycerol productivity that get a kinetic benefit from higher nitrogen concentration without sacrificing ethanol yield. A second aspect of the invention relates to metabolic modifications resulting in altered transport and/or intracellular metabolism of nitrogen sources present in corn mash.

The present invention provides for a mechanism to reduce glycerol production and increase nitrogen utilization and ethanol production of recombinant microorganisms. One aspect of this invention relates to strains of S. cerevisiae with reduced glycerol productivity that get a kinetic benefit from higher nitrogen concentration without sacrificing ethanol yield. A second aspect of the invention relates to metabolic modifications resulting in altered transport and/or intracellular metabolism of nitrogen sources present in corn mash.

The present disclosure relates to a mutant algal strain, wherein said mutant algal strain shows upregulation of mRNA transcripts encoding urea carboxylase, -15-3-desaturase and down-regulation of mRNA transcripts of gene encoding triacylglycerol lipase. Said mutant algal strain of the present disclosure is tolerant to low temperature and thus can be grown over a wide temperature range. The strain shows enhanced biomass and fatty acid production and enhanced growth rate and nitrogen metabolism over a wide temperature range of about 10 C. to about 37 C., wherein said enhancement is in comparison to the wild type algal strain. The present disclosure further provides a method of obtaining said mutant algal strain and method of producing industrially relevant products such as fatty acids from said mutant algal strain.

The present invention provides for a mechanism to reduce glycerol production and increase nitrogen utilization and ethanol production of recombinant microorganisms. One aspect of this invention relates to strains of S. cerevisiae with reduced glycerol productivity that get a kinetic benefit from higher nitrogen concentration without sacrificing ethanol yield. A second aspect of the invention relates to metabolic modifications resulting in altered transport and/or intracellular metabolism of nitrogen sources present in corn mash.

The present invention provides for a mechanism to reduce glycerol production and increase nitrogen utilization and ethanol production of recombinant microorganisms. One aspect of this invention relates to strains of S. cerevisiae with reduced glycerol productivity that get a kinetic benefit from higher nitrogen concentration without sacrificing ethanol yield. A second aspect of the invention relates to metabolic modifications resulting in altered transport and/or intracellular metabolism of nitrogen sources present in com mash.

The present invention provides for a mechanism to reduce glycerol production and increase nitrogen utilization and ethanol production of recombinant microorganisms. One aspect of this invention relates to strains of S. cerevisiae with reduced glycerol productivity that get a kinetic benefit from higher nitrogen concentration without sacrificing ethanol yield. A second aspect of the invention relates to metabolic modifications resulting in altered transport and/or intracellular metabolism of nitrogen sources present in corn mash.

The present invention provides for a mechanism to reduce glycerol production and increase nitrogen utilization and ethanol production of recombinant microorganisms. One aspect of this invention relates to strains of S. cerevisiae with reduced glycerol productivity that get a kinetic benefit from higher nitrogen concentration without sacrificing ethanol yield. A second aspect of the invention relates tometabolic modifications resulting in altered transport and/or intracellular metabolism of nitrogen sources present in corn mash.

The present invention provides for a genetically modified host cell comprising a first polypeptide capable of active transport of urea into the host cell and/or a second polypeptide capable of degrading urea into ammonia and carbon dioxide, wherein the genetically modified host cell is capable of degrading urea into ammonia and carbon dioxide. The genetically modified host cell in a medium comprising urea, a calcium salt or calcium ion, and a phosphate is capable of producing calcium phosphate.