The present invention provided the techniques and recipes for enhancing recombinant peptide production in microorganism like E. coli, Saccharomyces cerevisiae, Pichia pastoris and Bacillus subtilis. The designs of fusion protein with a polypeptide and high cell density fermentation process to over express the peptides are given. Methods for separation of polypeptides from fusion protein and methods for isolation and purification of peptides are mentioned. This invention also provides an uncomplicated and unique purification processes for manufacturing of Teriparatide, Liraglutide precursor and Semaglutide precursor with purifies of >98%.

A method for self-assembly of a protein in a three-dimensional honeycomb structure, comprising the following consecutive steps: providing a solution comprising a solvent and a protein, the protein comprising a sequence of amino acids corresponding to an oligomerisation domain of a LEAFY protein, for example to the oligomerisation domain of Ginkgo biloba, in fusion with a tag, placing the solution in contact with a substrate, evaporating the solvent in order to crystallise the protein, the oligomerisation domain crystallising in the form of a primary helix, each primary helix interacting with six other primary helixes, whereby a three-dimensional honeycomb protein structure is obtained perpendicular to the substrate, the protein structure being attached to the substrate by the tag.

A method is provided for extraction of fine silk fibroin powder from Bombyx mori silk cocoons. The conventional method of silk processing includes dissolution of the degummed silk fibers in some strong salt solutions followed by a dialysis step. The earlier reported strong salt solutions have either associated environment issues or lower dissolution ability for silk. However, the provided method includes degumming silk cocoons, drying and cutting the degummed silk fibers, mixing the fibers with an ionic liquid, stirring the mixture, regeneration of silk from the mixture with the help of an anti-solvent followed by centrifugation, drying the precipitated silk and finally obtaining a fine powder of silk.

The present invention relates to a method and a system of extracting a protein with high yield from a protein-comprising precipitate, in particular immunoglobulin, from human or non-human origins, such as blood plasma.

The present invention relates to a method and a system of extracting a protein with high yield from a protein-comprising precipitate, in particular immunoglobulin, from human or non-human origins, such as blood plasma.

Described herein are isolated cell culture components such as, e.g., biologics and/or lipids, and methods for isolating cell culture components from a liquid cell culture medium. Methods of the present invention may include contacting a dehydration composition and a liquid cell culture medium comprising a target component to form a mixture; forming an at least partially dehydrated component in the mixture; and separating the at least partially dehydrated component from the mixture, thereby providing an isolated component. In some embodiments, the isolated component comprises the at least partially dehydrated component. In some embodiments, the isolated component is present in a composition (e.g., liquid phase) separated from the at least partially dehydrated component.

A balanced-lattice-ledge nucleant having ledge inducing local densification of proteins and a balanced-lattice inducing self-organized crystal packing. Using this balanced-lattice-ledge nucleant enhances nucleation of protein crystals.

The present invention describes the integration of preparative crystallization, crystal separation, crystal washing and freeze-drying processes of insulin and insulin analogues into single continuous process using pressure filtration. The process facilitates time reduction and outlines the novel design of using multiple organic solvent washes and nitrogen gas purging for the removal of imbibed water and achieve final drug substance that meets the quality specifications.

A crystallization method for making high-quality molecular crystals containing complexes of diacylglycerol (DAG)-effector proteins and ligands thereof. For example, some of such crystals are of a quality sufficient for crystal-structure determination by X-ray crystallography with a spatial resolution of at least 3.0 Å or, in some cases, of about 1 Å. At least some embodiments of the crystallization method and of the molecular crystals produced thereby can beneficially be used, e.g., to provide high-resolution guides for the design and development of exogenous agonists of DAG-effector proteins of therapeutic interest.

Provided herein are methods for producing a mung bean protein isolate having high functionality for a broad range of food applications. In some embodiments, the methods for producing the isolate comprise one or more steps selected from: (a) extracting one or more mung bean proteins from a mung bean protein source in an aqueous solution, for example, at a pH between about 6.5-10.0; (b) purifying protein from the extract using at least one of two methods: (i) precipitating protein from the extract at a pH near the isoelectric point of a globulin-rich fraction, for example a pH between about 5.0-6.0; and/or (ii) fractionating and concentrating protein from the extract using filtration such as microfiltration, ultrafiltration or ion-exchange chromatography; and (c) recovering purified protein isolate.