Intracellular release of endocytosed nanoparticles upon a change of ligand-receptor interaction.

During passive endocytosis, nanosized particles are initially encapsulated by a membrane separating it from the cytosol. Yet, in many applications the nanoparticles need to be in direct contact with the cytosol in order to be active. We report a simulation study that elucidates the physical mechanisms by which such nanoparticles can shed their bilayer coating. We find that nanoparticle release can be readily achieved by a pH-induced lowering of the attraction between nanoparticle and membrane only if the nanoparticle is either very small or nonspherical. Interestingly, we find that in the case of large spherical nanoparticles, the reduction of attraction needs to be accompanied by exerting an additional tension on the membrane (e.g., via nanoparticle expansion) to achieve release. We expect these findings will contribute to the rational design of drug delivery strategies via nanoparticles.

[1]  Grace Brannigan,et al.  Flexible lipid bilayers in implicit solvent. , 2005, Physical review. E, Statistical, nonlinear, and soft matter physics.

[2]  R. M. Owen,et al.  Selective tumor cell targeting using low-affinity, multivalent interactions. , 2007, ACS chemical biology.

[3]  John F. Nagle,et al.  Structure of Fully Hydrated Fluid Phase Lipid Bilayers with Monounsaturated Chains , 2006, The Journal of Membrane Biology.

[4]  Fabian Kiessling,et al.  Theranostic nanomedicine. , 2020, Accounts of chemical research.

[5]  Daniel S. D. Larsson,et al.  Virus Capsid Dissolution Studied by Microsecond Molecular Dynamics Simulations , 2012, PLoS Comput. Biol..

[6]  D Needham,et al.  Elastic deformation and failure of lipid bilayer membranes containing cholesterol. , 1990, Biophysical journal.

[7]  Wataru Shinoda,et al.  Free energy analysis of vesicle-to-bicelle transformation , 2011 .

[8]  M. Kozlov,et al.  The gaussian curvature elastic modulus of N-monomethylated dioleoylphosphatidylethanolamine: relevance to membrane fusion and lipid phase behavior. , 2004, Biophysical journal.

[9]  Charles H. Bennett,et al.  Efficient estimation of free energy differences from Monte Carlo data , 1976 .

[10]  K. Kremer,et al.  Tunable generic model for fluid bilayer membranes. , 2005, Physical review. E, Statistical, nonlinear, and soft matter physics.

[11]  Evans,et al.  Entropy-driven tension and bending elasticity in condensed-fluid membranes. , 1990, Physical review letters.

[12]  D. Siegel The Gaussian curvature elastic energy of intermediates in membrane fusion. , 2008, Biophysical journal.

[13]  J. Nagle,et al.  Temperature dependence of structure, bending rigidity, and bilayer interactions of dioleoylphosphatidylcholine bilayers. , 2008, Biophysical journal.

[14]  Adam P. Silverman,et al.  Developing therapeutic proteins by engineering ligand-receptor interactions. , 2008, Trends in biotechnology.

[15]  D. Davis,et al.  Membrane nanotubes: dynamic long-distance connections between animal cells , 2008, Nature Reviews Molecular Cell Biology.

[16]  K. Kremer,et al.  Aggregation and vesiculation of membrane proteins by curvature-mediated interactions , 2007, Nature.

[17]  Solvent-free model for self-assembling fluid bilayer membranes: stabilization of the fluid phase based on broad attractive tail potentials. , 2005, The Journal of chemical physics.

[18]  Evan Evans,et al.  Physical properties of surfactant bilayer membranes: thermal transitions, elasticity, rigidity, cohesion and colloidal interactions , 1987 .

[19]  Mark E. Davis,et al.  Clinical Developments in Nanotechnology for Cancer Therapy , 2011, Pharmaceutical Research.

[20]  Hugues Talbot,et al.  Cryo-electron tomography of nanoparticle transmigration into liposome. , 2009, Journal of structural biology.

[21]  John E. Johnson,et al.  Structures of the native and swollen forms of cowpea chlorotic mottle virus determined by X-ray crystallography and cryo-electron microscopy. , 1995, Structure.

[22]  Hans-Jörg Limbach,et al.  ESPResSo - an extensible simulation package for research on soft matter systems , 2006, Comput. Phys. Commun..

[23]  Markus Deserno,et al.  Mesoscopic membrane physics: concepts, simulations, and selected applications. , 2009, Macromolecular rapid communications.

[24]  Ernst Wagner,et al.  Polymers for siRNA delivery: inspired by viruses to be targeted, dynamic, and precise. , 2012, Accounts of chemical research.

[25]  Olivier Sandre,et al.  Cascades of transient pores in giant vesicles: line tension and transport. , 2003, Biophysical journal.

[26]  E. Evans,et al.  Effect of chain length and unsaturation on elasticity of lipid bilayers. , 2000, Biophysical journal.

[27]  Frank Caruso,et al.  Engineering particles for therapeutic delivery: prospects and challenges. , 2012, ACS nano.

[28]  D. Zhelev,et al.  Tension-stabilized pores in giant vesicles: determination of pore size and pore line tension. , 1993, Biochimica et biophysica acta.

[29]  Daan Frenkel,et al.  Receptor-mediated endocytosis of nanoparticles of various shapes. , 2011, Nano letters.

[30]  C Sauterey,et al.  Osmotic pressure induced pores in phospholipid vesicles. , 1975, Biochemistry.

[31]  D. Frenkel,et al.  Designing super selectivity in multivalent nano-particle binding , 2011, Proceedings of the National Academy of Sciences.

[32]  Hiroshi Noguchi,et al.  Dynamics of vesicle self-assembly and dissolution. , 2006, The Journal of chemical physics.