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Biofluid specific protein coronas affect lipid nanoparticle behavior in vitro

Demian van Straten, Helena Sork, Luuk van de Schepop, Rowan Frunt, Kariem Ezzat, Raymond M. Schiffelers

2024Journal of Controlled Release36 citationsDOIOpen Access PDF

Abstract

Lipid nanoparticles (LNPs) have successfully entered the clinic for the delivery of mRNA- and siRNA-based therapeutics, most recently as vaccines for COVID-19. Nevertheless, there is a lack of understanding regarding their in vivo behavior, in particular cell targeting. Part of this LNP tropism is based on the adherence of endogenous protein to the particle surface. This protein forms a so-called corona that can change, amongst other things, the circulation time, biodistribution and cellular uptake of these particles. The formation of this protein corona, in turn, is dependent on the nanoparticle properties (e.g., size, charge, surface chemistry and hydrophobicity) as well as the biological environment from which it is derived. With the potential of gene therapy to target virtually any disease, administration sites other than intravenous route are considered, resulting in tissue specific protein coronas. For neurological diseases, intracranial administration of LNPs results in a cerebral spinal fluid derived protein corona, possibly changing the properties of the lipid nanoparticle compared to intravenous administration. Here, the differences between plasma and CSF derived protein coronas on a clinically relevant LNP formulation were studied in vitro. Protein analysis showed that LNPs incubated in human CSF (C-LNPs) developed a protein corona composition that differed from that of LNPs incubated in plasma (P-LNPs). Lipoproteins as a whole, but in particular apolipoprotein E, represented a higher percentage of the total protein corona on C-LNPs than on P-LNPs. This resulted in improved cellular uptake of C-LNPs compared to P-LNPs, regardless of cell origin. Importantly, the higher LNP uptake did not directly translate into more efficient cargo delivery, underlining that further assessment of such mechanisms is necessary. These findings show that biofluid specific protein coronas alter LNP functionality, suggesting that the site of administration could affect LNP efficacy in vivo and needs to be considered during the development of the formulation. Schematic representation of the protein corona formation, isolation and characterization protocol. • Unique protein coronas develop on the surface of lipid nanoparticles after exposure to human plasma or cerebrospinal fluid. • Biofluid specific protein coronas affect lipid nanoparticle performance and influence their uptake by cells in vitro in time . • Biofluid specific protein coronas affect lipid nanoparticle delivery efficiency of cargo siRNA to cells in vitro. • Lipid nanoparticle uptake is not a predictor for siRNA transfection efficiency in vitro • Difference in Apolipoprotein content in cerebrospinal fluid and plasma could affect lipid nanoparticle performance in vitro.

Topics & Concepts

ChemistryBiodistributionBiophysicsProtein aggregationIn vitroNanoparticleIn vivoCell biologyNanotechnologyBiochemistryBiologyMaterials scienceBiotechnologyRNA Interference and Gene DeliveryLipid Membrane Structure and BehaviorExtracellular vesicles in disease