Nanobody-Mediated Cellular Uptake Maximizes the Potency of Polylysine Dendrimers While Preserving Solid Tumor Penetration
- Author(s)
- Yuen, D; Feeney, OM; Noi, L; Shengule, S; McLeod, VM; Reitano, P; Tsegay, S; Hufton, R; Houston, ZH; Fletcher, NL; Humphries, J; Thurecht, KJ; Cullinane, C; Owen, DJ; Porter, CJH; Johnston, APR;
- Journal Title
- ACS Nano
- Publication Type
- Online publication before print
- Abstract
- Dendrimers are branched macromolecular structures that are useful nanocarriers for small-molecule drugs, such as cancer therapeutics. Their small size permits penetration into solid tumors, coupled with functionalization with a low-fouling PEG coating that minimizes transient cellular interactions and enhances plasma circulation time. While PEGylated dendrimers show significant promise as anticancer therapeutics, there is potential to increase tumor cell specificity and drive uptake of drugs into cells by conjugating cell-targeting ligands onto the dendrimers. To achieve this, we used an expanded genetic code and bio-orthogonal click chemistry to functionalize monomethyl auristatin E (MMAE)-loaded PEGylated dendrimers with a single tumor cell-targeting nanobody per dendrimer. The uniform addition of a single nanobody ligand facilitated greater intracellular uptake of the drug payload into HER2-positive target cells, while preserving the desirable circulatory characteristics of dendrimers. While the nanobody-dendrimer conjugates show similar levels of tumor infiltration over 24 h compared to unmodified dendrimers, the targeted dendrimers had significantly greater inhibition of tumor growth and long-term retention in the tumors. Our results highlight that biodistribution studies alone are poor predictors of therapeutic performance. The controlled conjugation strategy presented here preserves the size advantage and tissue penetration of dendrimers while maximizing targeted cellular uptake and potency in difficult-to-access solid tumor tissue.
- Keywords
- Click chemistry; antibody-drug conjugate; dendrimer; drug delivery; nanomedicine; tumor penetration; unnatural amino acids
- Department(s)
- Laboratory Research
- Publisher's Version
- https://doi.org/10.1021/acsnano.4c10851
- Terms of Use/Rights Notice
- Refer to copyright notice on published article.
Creation Date: 2025-02-11 06:48:58
Last Modified: 2025-02-11 06:50:53