The present invention relates to methods and formulations useful for reducing the reconstitution time of lyophilized polypeptides.

The present invention relates to methods and formulations useful for reducing the reconstitution time of lyophilized polypeptides.

The present invention provides for a one-pot enzymatic approach which does not require removal of the enzyme and purification of the intermediate after deglycosylation step, and the Endo-S treatment is able to do both deglycosylation and transglycosylation. The one-pot strategy of the present invention enables chemoenzymatic synthesis of an azido-tagged N-glycoform of monocloncal antibodies which could be further modified through orthogonal chemical ligation for various applications.

The present invention provides for a one-pot enzymatic approach which does not require removal of the enzyme and purification of the intermediate after deglycosylation step, and the Endo-S treatment is able to do both deglycosylation and transglycosylation. The one-pot strategy of the present invention enables chemoenzymatic synthesis of an azido-tagged N-glycoform of monocloncal antibodies which could be further modified through orthogonal chemical ligation for various applications.

The present invention has an object of shortening the process time and reducing use of a poor solvent for solidifying a carrier (Tag)-peptide component, by removing impurities without conducting solid-liquid separation (condensation, solid-liquid separation and drying operation) of a Tag-peptide component, in an Fmoc method using a Tag for liquid phase peptide synthesis. Provided is the peptide synthesis method that includes the following steps a-d: step a: a carrier-protected amino acid, carrier-protected peptide, or a carrier-protected amino acid amide, and an N-Fmoc-protected amino acid or an N-Fmoc-protected peptide are condensed in an organic solvent or a mixed solution of organic solvents, to obtain an N-Fmoc-carrier-protected peptide, step b: a water-soluble amine is added to the reaction solution after the condensation reaction, step c: the Fmoc group is deprotected from the protected amino group in the presence of a water-soluble amine, and step d: the reaction solution is neutralized by adding an acid, and further, by adding and washing with an acidic aqueous solution, then, by liquid-liquid separation an aqueous layer is removed to obtain an organic layer.

The present invention has an object of shortening the process time and reducing use of a poor solvent for solidifying a carrier (Tag)-peptide component, by removing impurities without conducting solid-liquid separation (condensation, solid-liquid separation and drying operation) of a Tag-peptide component, in an Fmoc method using a Tag for liquid phase peptide synthesis. Provided is the peptide synthesis method that includes the following steps a-d: step a: a carrier-protected amino acid, carrier-protected peptide, or a carrier-protected amino acid amide, and an N-Fmoc-protected amino acid or an N-Fmoc-protected peptide are condensed in an organic solvent or a mixed solution of organic solvents, to obtain an N-Fmoc-carrier-protected peptide, step b: a water-soluble amine is added to the reaction solution after the condensation reaction, step c: the Fmoc group is deprotected from the protected amino group in the presence of a water-soluble amine, and step d: the reaction solution is neutralized by adding an acid, and further, by adding and washing with an acidic aqueous solution, then, by liquid-liquid separation an aqueous layer is removed to obtain an organic layer.

This method for producing a protein crystal includes: a step (a) for adding, to a protein synthesis system, a nucleic acid that encodes crystalline protein; and a step (b) for incubating the protein synthesis system during the predetermined time until the crystalline protein encoded by the added nucleic acid is expressed and the expressed crystalline protein completes the formation of crystals, wherein the protein synthesis system is a cell-free protein synthesis system.

This method for producing a protein crystal includes: a step (a) for adding, to a protein synthesis system, a nucleic acid that encodes crystalline protein; and a step (b) for incubating the protein synthesis system during the predetermined time until the crystalline protein encoded by the added nucleic acid is expressed and the expressed crystalline protein completes the formation of crystals, wherein the protein synthesis system is a cell-free protein synthesis system.

The present disclosure relates to atypical split N- and C-inteins and variants thereof. This disclosure also relates to complexes comprising the split N- or C-inteins of this disclosure and a compound of interest and compositions comprising said complexes. In addition, this disclosure relates to methods of using the atypical split N- and C-inteins.

A method for preparing peptides is disclosed, the method comprising a step of forming a peptide bond wherein the carboxyl group of a first amino acid or first peptide is activated and an amino group of the first activated amino acid or first peptide is protected by a protecting group having a water-solubility enhancing group and the activated carboxyl group of the first amino acid or first peptide is reacted with an amino group of a second amino acid or second peptide wherein said carboxyl group of the first amino acid or first peptide is activated in the absence of the second amino acid or second peptide. Peptides comprising a protecting group having a water-solubility enhancing group being bound to the amino group and an activated or free carboxyl group are also disclosed.