Smuggling on the Nanoscale—Fusogenic Liposomes Enable Efficient RNA-Transfer with Negligible Immune Response In Vitro and In Vivo
Abstract
:1. Introduction
2. Material and Methods
2.1. Cell Culture
2.2. Ethics Statement for Neuron Isolation
2.3. Preparation of Fusion- and Lipofection-Based Reagents
2.4. Fluorescence Microscopy
2.5. Flow Cytometry
2.6. Live/Dead Stain Assay
2.7. RNA Isolation and cDNA Synthesis for In Vitro and In Vivo Studies
2.8. qRT-PCR Assays for In Vitro and In Vivo Studies
2.9. Inhibition of Endocytosis
2.10. Live Cell Calcium Imaging
2.11. Neuronal Meshwork Synchronization Analysis
2.12. In Vivo Experiments with Zebrafish
2.12.1. Ethics Statement
2.12.2. Fish and Transgenic Lines
2.12.3. Injection into the Adult Zebrafish Brain
2.12.4. Injection into the Zebrafish Embryo
2.12.5. Immunohistochemistry of Fish Brains
2.12.6. Fluorescence Microscopy of Zebrafish
2.12.7. Quantification of eGFP-Positive Cells in Zebrafish Telencephalon-Slices
2.13. Statistical Analysis
3. Results
3.1. Quantity of Transferred Nucleic Acids and Transfer Mechanism Determine Biocompatibility in Neuronal Cells
3.2. The Reduced Influence of Endosomal Uptake Mechanisms for Fusion-Based RNA Transfer Allows High Biocompatibility and Low Cytokine Responses
3.3. Endocytosis-Dependent RNA Transfer Blocks Functionality of Neuronal Networks
3.4. Inflammatory Responses Are Also Initiated In Vivo by Endosomal Transfer Mechanisms of Nucleic Acids
3.5. Endosome-Independent Transfer Mechanisms Are Highly Efficient without Detectable Teratological Effects in Early Embryogenesis
4. Discussion
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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CHOK1 | nHEK | Neuronal-Like PC-12 | Primary Embryonic Cortical Neurons | |
---|---|---|---|---|
Medium | DMEM F12 Glutmax (Gibco, USA), 1× PenStrep (Gibco, USA), 10% FBS (Superior, Biochrom) | Dermalife K (CellSystems, Germany) without EGF | RPMI 1640 (Gibco, USA), 1× PenStrep (Gibco, USA), 10% FBS (Superior, Biochrom) | 50 mL Gibco Neurobasal Medium + 1 mL B-27 Supplement (Thermo Scientific, USA), 2.5 mg Gentamicin Reagent Solution (Sigma, USA), 125 µL GlutaMax (Thermo Scientific, USA) |
Lipofectamine® 2000 standard protocol (LSP 1) | 2 µL reagent in 25 µL OptiMEM + 1 µg eGFP mRNA in 25 µL OptiMEM/complexed mRNA + reagent (50 µL) add 500 µL media/incubation over night | |||
Lipofectamine® 2000 reduced uptake protocol (RU 2) by reduced incubation time (LRT 3) | Lipoplex prepared as in L SP add 500 µL OptiMEM/incubation for 40 min (min) | / | ||
Lipofectamine® 2000 reduced uptake protocol (RU 2) by LRT and PBS washing (LRT + PBS 4) | Lipoplex prepared as in L SP add 500 µL OptiMEM/incubation for 40 min/wash cells 3× with 1× PBS, pH 7.2, room temperature (RT) | / | ||
Lipofectamine® 2000 reduced uptake protocol (RU 2) by LRT and PBS-H washing (LRT + PBSH 5) | Lipoplex prepared as in L SP add 500 µL OptiMEM/incubation for 40 min/wash cells 3× with 1× PBS-Heparin (20 U/mL Heparin-Natrium-25.000 (i.v./s.c.) ratiopharm GmbH), pH 7.2, RT | / | ||
Fuse-It-mRNA standard protocol (F SP 6) | 2 µL neutralization buffer (NB) + 1 µg eGFP mRNA 10 min RT/add 2.5 µL fusogenic solution (FS) | |||
10 min fusion in 250 µL PBS | 8 min fusion in 250 µL PBS | 10 min fusion in 250 µL PBS | 10 min fusion in 250 µL PBS | |
Fuse-It-mRNA reduced uptake protocol (RU 2) by PBS washing after fusion (F SP + PBS 7) | after incubation at 37 °C washed 3× with 1× PBS, pH 7.2, RT | / | ||
Fuse-It-mRNA reduced uptake protocol (RU 2) by PBS-H washing after fusion (FSP + PBSH 8) | after incubation at 37 °C washed 3× with 1× PBS-Heparin (20 U/mL Heparin-Natrium-25.000 (i.v./s.c.) ratiopharm GmbH), pH 7.2, RT |
CHOK1 | nHEK | Neuronal-Like PC-12 | Primary Embryonic Cortical Neurons | |
---|---|---|---|---|
endogenous control | GAPDH chinese hamster (Thermo Scientific; Cg04424039-gh GAPDH FAM) | GAPDH homo sapiens (Thermo Scientific; HS02786624-g1 GAPDH) | GAPDH rattus norvegius (Thermo Scientific; Rn01775763_g1) | |
eGFP | eGFP mr Enhance (Thermo Scientific; Mr04097229_mr eGFP) | |||
IL-6 | / | IL-6 Fam homo sapiens (Thermo Scientific; HS00174131_m1 IL-6) | IL-6 Fam rattus norvegius (Thermo Scientific; Rn01410330_m1) | |
TNF-α | / | TNF-α homo sapiens (Thermo Scientific; HS00174128_m1 TNF-α) | / | / |
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Hoffmann, M.; Gerlach, S.; Takamiya, M.; Tarazi, S.; Hersch, N.; Csiszár, A.; Springer, R.; Dreissen, G.; Scharr, H.; Rastegar, S.; et al. Smuggling on the Nanoscale—Fusogenic Liposomes Enable Efficient RNA-Transfer with Negligible Immune Response In Vitro and In Vivo. Pharmaceutics 2023, 15, 1210. https://doi.org/10.3390/pharmaceutics15041210
Hoffmann M, Gerlach S, Takamiya M, Tarazi S, Hersch N, Csiszár A, Springer R, Dreissen G, Scharr H, Rastegar S, et al. Smuggling on the Nanoscale—Fusogenic Liposomes Enable Efficient RNA-Transfer with Negligible Immune Response In Vitro and In Vivo. Pharmaceutics. 2023; 15(4):1210. https://doi.org/10.3390/pharmaceutics15041210
Chicago/Turabian StyleHoffmann, Marco, Sven Gerlach, Masanari Takamiya, Samar Tarazi, Nils Hersch, Agnes Csiszár, Ronald Springer, Georg Dreissen, Hanno Scharr, Sepand Rastegar, and et al. 2023. "Smuggling on the Nanoscale—Fusogenic Liposomes Enable Efficient RNA-Transfer with Negligible Immune Response In Vitro and In Vivo" Pharmaceutics 15, no. 4: 1210. https://doi.org/10.3390/pharmaceutics15041210
APA StyleHoffmann, M., Gerlach, S., Takamiya, M., Tarazi, S., Hersch, N., Csiszár, A., Springer, R., Dreissen, G., Scharr, H., Rastegar, S., Beil, T., Strähle, U., Merkel, R., & Hoffmann, B. (2023). Smuggling on the Nanoscale—Fusogenic Liposomes Enable Efficient RNA-Transfer with Negligible Immune Response In Vitro and In Vivo. Pharmaceutics, 15(4), 1210. https://doi.org/10.3390/pharmaceutics15041210