Comparison of ionizable lipids for lipid nanoparticle mediated DNA delivery.

Lipid nanoparticles (LNPs) are successfully used for RNA-based gene delivery. In the context of gene replacement therapies, however, delivery of DNA expression plasmids using LNPs as a non-viral vector could be a promising strategy for the induction of longer-lasting effects. Therefore, DNA expression plasmids (3 to 4 kbp) coding for fluorescent markers or luciferase were combined with LNPs. Different clinically used ionizable lipids (DLin-MC3-DMA, SM-102, and ALC-0315) were tested to compare their influence on DNA plasmid delivery. DNA-LNPs were characterized with respect to their colloidal properties (size, polydispersity, ζ-potential, morphology), in vitro performance (cellular uptake, DNA delivery, and gene expression), and in vivo characteristics (biodistribution and luciferase gene expression). At an optimized N/P ratio of 6, spherical, small and monodisperse particles with anionic ζ-potential were obtained. Efficient transgene expression was achieved with a minimum amount of 1 pg DNA per initially plated cells. Zebrafish studies allowed selection of DNA-LNPs, which demonstrated prolonged blood circulation, avoidance of macrophage clearance, and vascular extravasation. Our comparative study demonstrates a high impact of the ionizable lipid type on DNA-LNP performance. Superior transfection efficiency of DNA-LNPs containing the ionizable lipid ALC-0315 was confirmed in wildtype mice.

High efficiency preparation of monodisperse plasma membrane derived extracellular vesicles for therapeutic applications.

Extracellular vesicles (EVs) are highly interesting for the design of next-generation therapeutics. However, their preparation methods face challenges in standardization, yield, and reproducibility. Here, we describe a highly efficient and reproducible EV preparation method for monodisperse nano plasma membrane vesicles (nPMVs), which yields 10 to 100 times more particles per cell and hour than conventional EV preparation methods. nPMVs are produced by homogenizing giant plasma membrane vesicles following cell membrane blebbing and apoptotic body secretion induced by chemical stressors. nPMVs showed no significant differences compared to native EVs from the same cell line in cryo-TEM analysis, in vitro cellular interactions, and in vivo biodistribution studies in zebrafish larvae. Proteomics and lipidomics, on the other hand, suggested substantial differences consistent with the divergent origin of these two EV types and indicated that nPMVs primarily derive from apoptotic extracellular vesicles. nPMVs may provide an attractive source for developing EV-based pharmaceutical therapeutics.

Incorporation of phosphatidylserine improves efficiency of lipid based gene delivery systems.

The essential homeostatic process of dead cell clearance (efferocytosis) is used by viruses in an act of apoptotic mimicry. Among others, virions leverage phosphatidylserine (PS) as an essential "eat me" signal in viral envelopes to increase their infectivity. In a virus-inspired biomimetic approach, we demonstrate that PS can be incorporated into non-viral lipid nanoparticle (LNP) pDNA/mRNA constructs to enhance cellular transfection. The inclusion of the bioactive PS leads to an increased ability of LNPs to deliver nucleic acids in vitro to cultured HuH-7 hepatocellular carcinoma cells resulting in a 6-fold enhanced expression of a transgene. Optimal PS concentrations are in the range of 2.5 to 5% of total lipids. PS-decorated mRNA-LNPs show a 5.2-fold enhancement of in vivo transfection efficiency as compared to mRNA-LNPs devoid of PS. Effects were less pronounced for PS-decorated pDNA-LNPs (3.2-fold increase). Incorporation of small, defined amounts of PS into gene delivery vectors opens new avenues for efficient gene therapy and can be easily extended to other therapeutic systems.

Magnesium sensing via LFA-1 regulates CD8+ T cell effector function.

The relevance of extracellular magnesium in cellular immunity remains largely unknown. Here, we show that the co-stimulatory cell-surface molecule LFA-1 requires magnesium to adopt its active conformation on CD8+ T cells, thereby augmenting calcium flux, signal transduction, metabolic reprogramming, immune synapse formation, and, as a consequence, specific cytotoxicity. Accordingly, magnesium-sufficiency sensed via LFA-1 translated to the superior performance of pathogen- and tumor-specific T cells, enhanced effectiveness of bi-specific T cell engaging antibodies, and improved CAR T cell function. Clinically, low serum magnesium levels were associated with more rapid disease progression and shorter overall survival in CAR T cell and immune checkpoint antibody-treated patients. LFA-1 thus directly incorporates information on the composition of the microenvironment as a determinant of outside-in signaling activity. These findings conceptually link co-stimulation and nutrient sensing and point to the magnesium-LFA-1 axis as a therapeutically amenable biologic system.