Engineering Agonistic Bispecifics to Investigate the Influence of Distance on Surface-Mediated Complement Activation

Engineering Agonistic Bispecifics to Investigate the Influence of Distance on Surface-Mediated Complement Activation

The development of agonists capable of activating the human complement system by binding to the C1 complex presents a novel approach for targeted cell killing. Bispecific nanobodies and Abs can successfully use C1 for this purpose; however, efficacy varies significantly between epitopes, Ab type, an...

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Veröffentlicht in:The Journal of immunology (1950) 2024-07, Vol.213 (2), p.235-243
Hauptverfasser: Hamers, Sebastiaan M W R, Boyle, Aimee L, Sharp, Thomas H
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Sprache:eng
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Antibodies, Bispecific - immunology
Antibodies, Bispecific - pharmacology
Complement Activation - immunology
Complement C1 - immunology
Complement C4b - immunology
Epitopes - immunology
Humans
Molecular and Structural Immunology
Protein Binding
Protein Engineering
Single-Domain Antibodies - immunology
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container_issue 2
container_start_page 235
container_title The Journal of immunology (1950)
container_volume 213
creator Hamers, Sebastiaan M W R
Boyle, Aimee L
Sharp, Thomas H
description The development of agonists capable of activating the human complement system by binding to the C1 complex presents a novel approach for targeted cell killing. Bispecific nanobodies and Abs can successfully use C1 for this purpose; however, efficacy varies significantly between epitopes, Ab type, and bispecific design. To address this variability, we investigated monomeric agonists of C1 in the form of bispecific nanobodies, which lack Fc domains that lead to oligomerization in Abs. These therefore offer an ideal opportunity to explore the geometric parameters crucial for C1 activation. In this study, we explored the impact of linker length as a metric for Ag and epitope location. DNA nanotechnology and protein engineering allowed us to design linkers with controlled lengths and flexibilities, revealing a critical range of end-to-end distances for optimal complement activation. We discovered that differences in complement activation were not caused by differential C1 activation or subsequent cleavage of C4, but instead impacted C4b deposition and downstream membrane lysis. Considering the importance of Ab class and subclass, this study provides insights into the structural requirements of C1 binding and activation, highlighting linker and hinge engineering as a potential strategy to enhance potency over specific cellular targets. Additionally, using DNA nanotechnology to modify geometric parameters demonstrated the potential for synthetic biology in complement activation. Overall, this research offers valuable insights into the design and optimization of agonists for targeted cell killing through complement activation.
doi_str_mv 10.4049/jimmunol.2400091
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subjects Antibodies, Bispecific - immunology
Antibodies, Bispecific - pharmacology
Complement Activation - immunology
Complement C1 - immunology
Complement C4b - immunology
Epitopes - immunology
Humans
Molecular and Structural Immunology
Protein Binding
Protein Engineering
Single-Domain Antibodies - immunology
title Engineering Agonistic Bispecifics to Investigate the Influence of Distance on Surface-Mediated Complement Activation
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