Provided is a method of producing and isolating a diamine produced by microbial fermentation that minimizes undesirable salt formation to provide a lower cost process.

Provided is a method of producing and isolating a diamine produced by microbial fermentation that minimizes undesirable salt formation to provide a lower cost process.

Signal sequences useful for targeting proteins and peptides to the surface of endospores produced by Paenibacillus family members and methods of using the same are provided. The display of heterologous molecules, such as peptides, polypeptides and other recombinant constructs, on the spore surface of Paenibacillus family members, using particular N-terminal targeting sequences and derivatives of the same, are also provided.

Signal sequences useful for targeting proteins and peptides to the surface of endospores produced by Paenibacillus family members and methods of using the same are provided. The display of heterologous molecules, such as peptides, polypeptides and other recombinant constructs, on the spore surface of Paenibacillus family members, using particular N-terminal targeting sequences and derivatives of the same, are also provided.

Compositions and methods are provided for genetically modifying cells to guide in situ chemical synthesis of electroactive, conductive, or insulating polymers on plasma membranes, organelle membranes, or subcellular surfaces of cells. In particular, compositions and methods are provided for genetically modifying excitable cells such as neurons, muscle cells, and endocrine cells to guide in situ chemical synthesis of polymers on the extracellular side of the plasma membrane. The subject methods can be used in various applications, for example, to assemble polymers in vivo at targeted locations to modulate electrical conduction and create new electrical conduction pathways, allow cell-type-specific neuromodulation, provide a conductive structure on cells for connection to electrodes, sensors, or other external electronic and electrochemical devices, and create a durable structure to replace damaged tissue for use in regenerative medicine.

The present invention provides methods for the cultivation of the Methylobacterium genus of bacteria. In particular the method provides methods for the efficient and inexpensive cultivation of these bacteria. Additionally, the invention provides methods for the utilization of these bacterial cultures to improve plant agriculture.

The present invention provides methods for the cultivation of the Methylobacterium genus of bacteria. In particular the method provides methods for the efficient and inexpensive cultivation of these bacteria. Additionally, the invention provides methods for the utilization of these bacterial cultures to improve plant agriculture.

Compositions comprising (i) lactate oxidase (LOX) and Catalase (CAT), preferably in a 1:1 molar ratio; or (ii) a fusion polypeptide comprising both LOX and CAT, e.g., LOXCAT, and methods of use thereof for reducing blood lactate levels, increasing blood pyruvate levels, and/or decreasing blood lactate/pyruvate ratio in a subject.

Compositions comprising (i) lactate oxidase (LOX) and Catalase (CAT), preferably in a 1:1 molar ratio; or (ii) a fusion polypeptide comprising both LOX and CAT, e.g., LOXCAT, and methods of use thereof for reducing blood lactate levels, increasing blood pyruvate levels, and/or decreasing blood lactate/pyruvate ratio in a subject.

The present disclosure relates to compositions of immobilized enzymes on the surface of achromosomal and/or anucleate cells and uses thereof. In particular, the present disclosure provides genetically engineered minicells with enzymes self-assembled on their surface. The immobilized enzymes on the surface of achromosomal and/or anucleate minicells, has agricultural, industrial, and environmental applications due to their improved stability durability and, reusability. Also, provided are methods for producing and purifying enzyme-immobilized minicells.