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Discovery and optimization of a novel anti-GUCY2c x CD3 bispecific antibody for the treatment of solid tumors.

Adam R RootGurkan GuntasMadan KatragaddaJames R ApgarJatin NarulaChew Shun ChangSara HanscomMatthew McKennaJason WadeCaryl MeadeWeijun MaYongjing GuoYan LiuWeili DuanClaire HendershotAmy C KingYan ZhangEric SousaAmy TamSusan BenardHan YangKerry KelleherFang JinNicole M Piche-NicholasSinead E KeatingFernando NarciandiRosemary Lawrence-HendersonMaya AraiWayne R StochajKristine SvensonLidia MosyakKhetemcnee LamChristopher FrancisKimberly MarquetteLiliana WroblewskaH Lily ZhuAlfredo Darmanin SheehanEdward R LaVallieAaron M D'AntonaAlison BettsLindsay KingEdward RosfjordOrla CunninghamLaura LinPuja SapraLioudmila TchistiakovaDivya MathurLaird Bloom
Published in: mAbs (2021)
We report here the discovery and optimization of a novel T cell retargeting anti-GUCY2C x anti-CD3ε bispecific antibody for the treatment of solid tumors. Using a combination of hybridoma, phage display and rational design protein engineering, we have developed a fully humanized and manufacturable CD3 bispecific antibody that demonstrates favorable pharmacokinetic properties and potent in vivo efficacy. Anti-GUCY2C and anti-CD3ε antibodies derived from mouse hybridomas were first humanized into well-behaved human variable region frameworks with full retention of binding and T-cell mediated cytotoxic activity. To address potential manufacturability concerns, multiple approaches were taken in parallel to optimize and de-risk the two antibody variable regions. These approaches included structure-guided rational mutagenesis and phage display-based optimization, focusing on improving stability, reducing polyreactivity and self-association potential, removing chemical liabilities and proteolytic cleavage sites, and de-risking immunogenicity. Employing rapid library construction methods as well as automated phage display and high-throughput protein production workflows enabled efficient generation of an optimized bispecific antibody with desirable manufacturability properties, high stability, and low nonspecific binding. Proteolytic cleavage and deamidation in complementarity-determining regions were also successfully addressed. Collectively, these improvements translated to a molecule with potent single-agent in vivo efficacy in a tumor cell line adoptive transfer model and a cynomolgus monkey pharmacokinetic profile (half-life>4.5 days) suitable for clinical development. Clinical evaluation of PF-07062119 is ongoing.
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