Dual Constant Domain-Fab: A novel strategy to improve half-life and potency of a Met therapeutic antibody

6533b853fe1ef96bd12ac19f

RESEARCH PRODUCT

Dual Constant Domain-Fab: A novel strategy to improve half-life and potency of a Met therapeutic antibody

Elisa Vigna Chiara Modica Cristina Chiriaco Paola Milla Lara Fontani Simona Cignetto Paolo Michieli Paolo M. Comoglio

subject

0301 basic medicine Cancer Research Mice SCID Cancer targeted therapy 0302 clinical medicine Mice Inbred NOD Epidermal growth factor receptor Phosphorylation biology Chemistry Immunoglobulin Fab Fragments Antibodies Monoclonal General Medicine Articles Proto-Oncogene Proteins c-met Half-life Cell biology Oncology 030220 oncology & carcinogenesis Colonic Neoplasms Met Molecular Medicine Female medicine.symptom Signal transduction Antibody Signal Transduction medicine.drug_class Colon Antibody; Cancer targeted therapy; Fab; Half-life; Met; Protein engineering; Cancer Research; Genetics; Molecular Medicine Antineoplastic Agents Monoclonal antibody 03 medical and health sciences Immunoglobulin Fab Fragments Protein Domains Cell Line Tumor medicine Genetics Animals Humans Fab Antibody Cell growth Molecular biology 030104 developmental biology HEK293 Cells Mechanism of action Hepatocyte Growth Factor Receptor A549 Cells biology.protein Protein engineering

description

The kinase receptor encoded by the Met oncogene is a sensible target for cancer therapy. The chimeric monovalent Fab fragment of the DN30 monoclonal antibody (MvDN30) has an odd mechanism of action, based on cell surface removal of Met via activation of specific plasma membrane proteases. However, the short half-life of the Fab, due to its low molecular weight, is a severe limitation for the deployment in therapy. This issue was addressed by increasing the Fab molecular weight above the glomerular filtration threshold through the duplication of the constant domains, in tandem (DCD-1) or reciprocally swapped (DCD-2). The two newly engineered molecules showed biochemical properties comparable to the original MvDN30 in vitro, acting as full Met antagonists, impairing Met phosphorylation and activation of downstream signaling pathways. As a consequence, Met-mediated biological responses were inhibited, including anchorage-dependent and -independent cell growth. In vivo DCD-1 and DCD-2 showed a pharmacokinetic profile significantly improved over the original MvDN30, doubling the circulating half-life and reducing the clearance. In pre-clinical models of cancer, generated by injection of tumor cells or implant of patient-derived samples, systemic administration of the engineered molecules inhibited the growth of Met-addicted tumors.

year	journal	country	edition	language
2016-03-28

10.1016/j.molonc.2016.03.004 http://hdl.handle.net/2318/1633002