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Utilization of cell-penetrating peptide adaptors to enhance delivery of variably charged protein cargos.

Created on 11 Jul 2026

Authors

Daniel P Morris, Nathaniel I Turner, Jojo J Croffie, Jonathan L McMurry

Published in

PloS one. Volume 21. Issue 7. Pages e0345530. Epub Jul 10, 2026.

Abstract

Cell-penetrating peptides (CPPs) can deliver biomacromolecular cargos into cells, potentially enabling a new mode of intracellular drug delivery. However, a major problem with CPP-mediated delivery is entrapment of CPPs within endosomes as covalent linkages ensure CPPs and cargos share common fates. We previously developed a CPP-adaptor system based on reversible, calcium-dependent cargo binding that produces cargo release from adaptors as complexes dissociate following internalization and Ca2+ efflux from early endosomes. Having employed CPP-adaptors with an array of protein cargos of differing charges, it became apparent that positively charged cargos often appeared to dominate internalization and that association with the adaptor had little effect. To systematically address the effects of cargo charge and CPP function, we tested the ability of several adaptors to increase internalization of a set of adaptor binding GFP cargos having charges of +9, + 15, + 20, + 25 and +36. Intrinsic internalization of these cargos reproduced reported patterns showing that positive charge increases internalization. Interestingly, labeling these cargos with a chemical fluorophore revealed that GFP fluorescence grossly underestimated total internalization as shown by the fluor. Internalization was charge and concentration dependent with more positive cargos showing apparent saturation of internalization at 100-400 nM, well below the concentrations at which covalently linked CPP-cargos are commonly dosed. We tested the ability of 5 adaptors to internalize these cargos. Our prototype adaptor, TAT-CaM, was completely ineffective with the + 9 cargo, but internalized moderately charged cargos extremely efficiently at concentrations far below the µM range. A derivative adaptor, TAT-LAH4-CaM, was highly effective with all cargos and produced similar maximal internalization at 100-400 nM. However, two adaptors specifically designed with increased positive charge inhibited internalization of the most positive cargos. One of these, GFP-CaM, based on the supercharged GFP with net charge of +36, did increase internalization of the least positive cargos, demonstrating an adaptor with high affinity for the cell surface can increase internalization of a neutral cargo at very low concentration. The common maximal level of intrinsic GFP cargo internalization correlated with surface loading of these cargos, suggesting a limit to the beneficial effects of increased plasma membrane association. However, TAT-CaM further increased internalization above intrinsic levels via an apparently distinct mechanism. In this limited study of the interaction of cargo charge and adaptor efficacy, we found diverse behaviors that hint at the power and flexibility possible with adaptor/cargo internalization.

PMID:
42430400
Bibliographic data and abstract were imported from PubMed on 11 Jul 2026.

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