A method for producing a polypeptide, includes at least one native ligation step using a peptide functionalized with a selenium group. The selenium peptides and compounds are also described.

The present invention provides a method for making uncapped cysteine protein preparations, including uncapped engineered cysteine antibody preparations. The methods include, inter alia, contacting a reducing agent with engineered cysteine antibody molecules, each of the antibody molecules having at least one capped engineered cysteine residue and at least one interchain disulfide bond and reacting the reducing agent with the antibody molecules under conditions sufficient to uncap engineered cysteine residues and form cap byproducts. The method also includes removing the cap byproduct during the reduction reaction. Substantially all of the interchain disulfide bonds present in the antibody molecules prior to reduction are retained following reduction. Antibody conjugates and methods for preparing antibody conjugates using uncapped antibody preparations are also described.

The present invention relates to a liquid (or solution)-phase manufacturing process for preparing the decapeptide Degarelix, its protected precursor, and other useful intermediates. The invention further relates to polypeptides useful in the solution-phase manufacturing process and to the purification of Degarelix itself. Degarelix can be obtained by subjecting a Degarelix precursor according to formula II: (P.sub.1)AA.sub.1-AA.sub.2-AA.sub.3-AA.sub.4(P.sub.4)-AA.sub.5-AA.sub.6(P.sub.6)-AA.sub.7-AA.sub.8(P.sub.8)-AA.sub.9-AA.sub.10-NH.sub.2 (II) or a salt or solvate thereof, to a treatment with a cleaving agent in an organic solvent, wherein P.sub.1 is an amino protecting groups; preferably acetyl; P.sub.4 is hydrogen or a hydroxyl protecting group, preferably a hydroxyl protecting group; P.sub.6 is hydrogen or an amino protecting groups; preferably an amino protecting groups; and P.sub.8 is an amino protecting group.

The present invention relates to a liquid (or solution)-phase manufacturing process for preparing the decapeptide Degarelix, its protected precursor, and other useful intermediates. The invention further relates to polypeptides useful in the solution-phase manufacturing process and to the purification of Degarelix itself. Degarelix can be obtained by subjecting a Degarelix precursor according to formula II: (P.sub.1)AA.sub.1-AA.sub.2-AA.sub.3-AA.sub.4(P.sub.4)-AA.sub.5-AA.sub.6(P.sub.6)-AA.sub.7-AA.sub.8(P.sub.8)-AA.sub.9-AA.sub.10-NH.sub.2 (II) or a salt or solvate thereof, to a treatment with a cleaving agent in an organic solvent, wherein P.sub.1 is an amino protecting groups; preferably acetyl; P.sub.4 is hydrogen or a hydroxyl protecting group, preferably a hydroxyl protecting group; P.sub.6 is hydrogen or an amino protecting groups; preferably an amino protecting groups; and P.sub.8 is an amino protecting group.

The present disclosure relates to site-selective labeling compounds, and methods of using such compounds.

The present disclosure provides a method of solid-phase peptide synthesis from the N terminus to C terminus without detectable epimerization of the C-terminal amino acid. The method includes using derivatized amino acids comprising a diamino-aryl group.

The present invention relates to the field of medicinal synthesis, and discloses a method for synthesizing degarelix. The method of the present invention as a whole divides the synthesis of degarelix into two parts from amino acids at positions 5 and 6, employs proper protective groups in part of the protected amino acids therein, and finally uses in association with a specific acidolysis agent to complete the whole synthesis process. In the present invention, a proper synthesizing scheme is selected, and adaptive protective group and acidolysis agent are selected, so that the overall synthesis process is optimized, the purity of degarelix is significantly improved with a higer total yield, and the production of the toxic hydantoin degradation product is avoided.

The present disclosure provides methods and reagents useful for analyzing protein-protein interfaces such as interfaces between a presenter protein (e.g., a member of the FKBP family, a member of the cyclophilin family, or PIN1) and a target protein. In some embodiments, the target and/or presenter proteins are intracellular proteins. In some embodiments, the target and/or presenter proteins are mammalian proteins.

The invention provides a method for producing a peptide which includes a step of reacting a peptide in which a C-terminal carboxy group is activated which is obtained by reacting an N-protected peptide represented by the formula (I):

P-AA.sub.1-OH  (I)

a tertiary amine represented by the formula (II):

##STR00001##

and an acid halide in a flow reactor, with a silylated amino acid or peptide obtained by reacting an amino acid or peptide represented by the formula (III):

H-AA.sub.2-OH  (III)

with a silylating agent, in a flow reactor, wherein, in the formulae (I) to (III), AA.sub.1, AA.sub.2, P, R.sup.1, R.sup.2 and R.sup.3 are as defined herein.

The present invention is to provide a method for producing a peptide containing an N-alkylamino acid, which comprises the following Steps (1) to (3). Step (1): a step of mixing an N-terminal protected amino acid or an N-terminal protected peptide with a carboxylic acid halide or a halogenated alkyl formate; Step (2): a step of mixing an amino acid or a peptide in which the N-terminal and the C-terminal are not protected with a trialkylsilylating agent; and Step (3): a step of mixing the product obtained in Step (1) with the product obtained in Step (2).