The present invention provides recombinant host cells that produce proteins or therapeutic proteins, and nucleic acid constructs for producing the cells. The cells have nucleic acid constructs that encode a heterologous protein, for example an antibody. The nucleic acid constructs also can have a functional signal sequence that directs the secretion of the protein from the cell. The signal sequence can be any functional signal sequence, and various signal sequences are disclosed herein. The invention also provides methods of producing the proteins.

The present invention provides recombinant host cells that produce proteins or therapeutic proteins, and nucleic acid constructs for producing the cells. The cells have nucleic acid constructs that encode a heterologous protein, for example an antibody. The nucleic acid constructs also can have a functional signal sequence that directs the secretion of the protein from the cell. The signal sequence can be any functional signal sequence, and various signal sequences are disclosed herein. The invention also provides methods of producing the proteins.

This invention is in the field of micro-organism and algal cell processing. The invention relates to a method of maximizing migration of micro-organism and/or algal cells to a solvent fraction while simultaneously displacing water in a separate fraction and subsequent extraction of hydrophobic products from the organisms. The invention further relates to a method of sequestration of protein from an aqueous phase to an organic solvent.

This invention is in the field of micro-organism and algal cell processing. The invention relates to a method of maximizing migration of micro-organism and/or algal cells to a solvent fraction while simultaneously displacing water in a separate fraction and subsequent extraction of hydrophobic products from the organisms. The invention further relates to a method of sequestration of protein from an aqueous phase to an organic solvent.

The disclosure generally relates to methods and materials for modulating cell productivity. In particular, the present disclosure provides polynucleotides encoding transcription factor proteins that when overexpressed in microorganisms result in increased in productivity, such as increased biomass productivity. Also disclosed are methods of using the genetically engineered host strains to modulate or increase productivity of host cells such as, for example, algal or heterokont cells. Genetically engineered host cells, such as algal and heterokont cells having increased biomass productivity and bioproducts derived from such host cells are also disclosed.

The disclosure generally relates to methods and materials for modulating cell productivity. In particular, the present disclosure provides polynucleotides encoding transcription factor proteins that when overexpressed in microorganisms result in increased in productivity, such as increased biomass productivity. Also disclosed are methods of using the genetically engineered host strains to modulate or increase productivity of host cells such as, for example, algal or heterokont cells. Genetically engineered host cells, such as algal and heterokont cells having increased biomass productivity and bioproducts derived from such host cells are also disclosed.

A method for improving a cell biomass includes de-ashing the cell biomass by applying pulsed electric field (PEF)- or constant electric field (CEF)-treatment to the cell biomass in a solvent, optionally under pressure higher than the ambient pressure, to thereby extract an ash fraction from the cell biomass into the solvent.

A method for improving a cell biomass includes de-ashing the cell biomass by applying pulsed electric field (PEF)- or constant electric field (CEF)-treatment to the cell biomass in a solvent, optionally under pressure higher than the ambient pressure, to thereby extract an ash fraction from the cell biomass into the solvent.

Methods and expression systems are described herein that are useful for production of terpenes and terpenoids.

Mutant photosynthetic organisms having reduced chlorophyll and increased photosynthetic efficiency are provided. The mutant strains have mutated or attenuated: chloroplastic SRP54 gene and SGI1 gene; chloroplastic SRP54 gene and SGI2 gene; chloroplastic SRP54 gene, SGI1, and SGI2 genes are disclosed. The mutant photosynthetic organisms exhibit increased productivity with respect to wild-type strains. Also provided are mutant photosynthetic organisms having mutated or attenuated cytosolic SRP54 genes. Provided herein are methods of producing biomass and other products such as lipids using strains having mutations in an SRP54 gene, SGI1, SGI2 genes, a combination of SGI1/SRP54, and a combination of SGI2 and SRP54 genes. Also included are constructs and methods for attenuating or disrupting SRP54, SGI1, and SGI2 genes.