Publication date: Feb 10, 2025
Nanobodies are single domain antibody variants proving themselves to be compelling tools for research, disease diagnostics, and as therapeutics targeting a myriad of disease agents. However, despite this potential, their mechanisms of paratope presentation and structural stabilization have not been fully explored. Here, we show that unlike monoclonal antibodies, a nanobody repertoire maximizes sampling of an antigen surface by binding a single antigen in at least three different orientations, which are correlated with their paratope composition. Structure-guided reengineering of several nanobodies reveals that a single point mutation within the paratope or a highly conserved region of a nanobody’s framework 3 (FR3) can markedly improve antigen affinity, nanobody stability, or both. Conversely, we show the negative impact on antigen affinity when “over-stabilizing” nanobodies. Collectively our results provide a universal strategy to tune a nanobody’s affinity by modifying specific residues that can readily be applied to guide nanobody optimization and functionalization.
| Concepts | Keywords |
|---|---|
| Antibodies | antibody |
| Nanobodies | green fluorescent protein |
| Reengineering | nanobody |
| Therapeutics | nanobody engineering |
| Tune | nanobody optimization |
| SARS-CoV-2 nanobodies | |
| V(H)H |
Semantics
| Type | Source | Name |
|---|---|---|
| disease | MESH | point mutation |
| disease | IDO | protein |