Development of mirror-image monobodies targeting the oncogenic BCR::ABL1 kinase

Development of mirror-image monobodies targeting the oncogenic BCR::ABL1 kinase

Abstract Mirror-image proteins, composed of d-amino acids, are an attractive therapeutic modality, as they exhibit high metabolic stability and lack immunogenicity. Development of mirror-image binding proteins is achieved through chemical synthesis of d-target proteins, phage display library selecti...

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Main Authors: Nina Schmidt, Amit Kumar, Lukas Korf, Adrian Valentin Dinh-Fricke, Frank Abendroth, Akiko Koide, Uwe Linne, Magdalena Rakwalska-Bange, Shohei Koide, Lars-Oliver Essen, Olalla Vázquez, Oliver Hantschel
Format: Article
Language:English
Published: Nature Portfolio 2024-12-01
Series:Nature Communications
Online Access:https://doi.org/10.1038/s41467-024-54901-y
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Summary:Abstract Mirror-image proteins, composed of d-amino acids, are an attractive therapeutic modality, as they exhibit high metabolic stability and lack immunogenicity. Development of mirror-image binding proteins is achieved through chemical synthesis of d-target proteins, phage display library selection of l-binders and chemical synthesis of (mirror-image) d-binders that consequently bind the physiological l-targets. Monobodies are well-established synthetic (l-)binding proteins and their small size (~90 residues) and lack of endogenous cysteine residues make them particularly accessible to chemical synthesis. Here, we develop monobodies with nanomolar binding affinities against the d-SH2 domain of the leukemic tyrosine kinase BCR::ABL1. Two crystal structures of heterochiral monobody-SH2 complexes reveal targeting of the pY binding pocket by an unconventional binding mode. We then prepare potent d-monobodies by either ligating two chemically synthesized d-peptides or by self-assembly without ligation. Their proper folding and stability are determined and high-affinity binding to the l-target is shown. d-monobodies are protease-resistant, show long-term plasma stability, inhibit BCR::ABL1 kinase activity and bind BCR::ABL1 in cell lysates and permeabilized cells. Hence, we demonstrate that functional d-monobodies can be developed readily. Our work represents an important step towards possible future therapeutic use of d-monobodies when combined with emerging methods to enable cytoplasmic delivery of monobodies.
ISSN:2041-1723

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