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Efficient Gene Delivery of Tailored Amphiphilic Polypeptides by Polyplex Surfing

Paul Klemm, Jana I. Solomun, Marko Rodewald, Maren T. Kuchenbrod, Veit G. Hänsch, Friederike Richter, Jürgen Popp, Christian Hertweck, Stephanie Hoeppener, Colin Bonduelle, Sébastien Lecommandoux, Anja Traeger, Stephanie Schubert

2022Biomacromolecules17 citationsDOIOpen Access PDF

Abstract

Within this study, an amphiphilic and potentially biodegradable polypeptide library based on poly[(4-aminobutyl)-l-glutamine-stat-hexyl-l-glutamine] [P(AB-l-Gln-stat-Hex-l-Gln)] was investigated for gene delivery. The influence of varying proportions of aliphatic and cationic side chains affecting the physicochemical properties of the polypeptides on transfection efficiency was investigated. A composition of 40 mol% Hex-l-Gln and 60 mol % AB-l-Gln (P3) was identified as best performer over polypeptides with higher proportions of protonatable monomers. Detailed studies of the transfection mechanism revealed the strongest interaction of P3 with cell membranes, promoting efficient endocytic cell uptake and high endosomal release. Spectrally, time-, and z-resolved fluorescence microscopy further revealed the crucial role of filopodia surfing in polyplex–cell interaction and particle internalization in lamellipodia regions, followed by rapid particle transport into cells. This study demonstrates the great potential of polypeptides for gene delivery. The amphiphilic character improves performance over cationic homopolypeptides, and the potential biodegradability is advantageous toward other synthetic polymeric delivery systems.

Topics & Concepts

AmphiphileGene deliveryChemistryTransfectionBiochemistryGeneBiophysicsComputational biologyNanotechnologyBiologyPolymerMaterials scienceOrganic chemistryCopolymerRNA Interference and Gene DeliverySilk-based biomaterials and applicationsAdvanced biosensing and bioanalysis techniques
Efficient Gene Delivery of Tailored Amphiphilic Polypeptides by Polyplex Surfing | Litcius