Catalytic assembly of symmetric diblock copolymers in a thin film: a dissipative particle dynamics simulation study.

Obtaining a thin block copolymer film with a perfect structure by self-assembly is difficult because the system is, in general, trapped in a metastable state. We used dissipative particle dynamics (DPD) to investigate the self-assembly of AB symmetric diblock copolymers in a thin film. We discovered that addition of a small molecule (molecule C) as the third composition could help the system evade the metastable state. Therefore, imperfect structures could be corrected, and ordered structures formed. Analogous to the performance of a catalyst in catalytic chemistry, molecule C could promote assembly into an ordered structure, but was less involved within the polymer phase. Moreover, simulation results showed that the content of molecule C and its repulsive interactions with blocks A and B were quite important for promoting assembly into ordered structures effectively.

Theoretical Insights into the Interactions between Star-Shaped Antimicrobial Polypeptides and Bacterial Membranes.

A structurally nanoengineered antimicrobial polypeptide consisting of lysine and valine residues is a new class of antimicrobial agent with superior antibacterial activity against multidrug-resistant bacteria and low toxicity toward mammalian cells. Utilizing coarse-grained models, we studied the interactions of microbial cytoplasmic membranes with polypeptides of either (K2V1)5 (star-KV) or CM15 (star-CM15). Our computational results verify the low toxicity of polypeptides of (K2V1)5 toward the dipalmitoyl phosphatidylcholine bilayer. This low toxicity is demonstrated to originate from weakened hydrophobicity combined with its random coil conformation for (K2V1)5 because of the highly abundant valine residues, compared with the typical antimicrobial peptides, such as CM15. In the interactions with a palmitoyl-oleoyl-phosphatidylethanolamine/palmitoyl-oleoyl-phosphatidylglycerol bilayer, star-KV has greater ability in phase separation and generation of phase boundary defects not only in lipid redistribution but also in lateral dynamic movements, although both star-KV and star-CM15 can extract the phosphatidylglycerol lipids and purify the phosphatidylethanolamine lipids into continuum domains. We suggest that the polypeptide of (K2V1)5 can nondisruptively kill bacteria by hampering bacterial metabolism through reorganizing lipid domain distribution and simultaneously "freezing" lipid movement.

Curvature-Mediated Pair Interactions of Soft Nanoparticles Adhered to a Cell Membrane.

The curvature-mediated interactions by cell membranes are crucial in many biological processes. We systematically studied the curvature-mediated wrapping of soft nanoparticles (NPs) by a tensionless membrane and the underlying pair interactions between NPs in determining it. We found that there are three types of wrapping pathways, namely, independence, cooperation, and tubulation. The particle size, adhesion strength, and softness are found to be strongly related with the wrapping mechanism. Reducing the adhesion strength transforms the wrapping pathway from cooperation to independence, while enhancing the NP softness requires a stronger adhesion to achieve the cooperative wrapping. This transformation of the wrapping pathway is controlled by the curvature-mediated interactions between NPs. For either soft or rigid NPs, the pair interactions are repulsive at short-ranged distances between NPs, while at long-ranged distances, a larger adhesion between NPs and a membrane is needed to generate attraction between NPs. Moreover, an enhancement of NP softness weakens the repulsion between NPs. These distinct behaviors of soft NPs are ascribed to the gentler deformation of the membrane at the face-to-face region between NPs due to the flattening and spreading of soft NPs along the membrane, requiring a reduced energy cost for soft NPs to approach each other. Our results provide a mechanistic understanding in detail about the membrane-mediated interactions between NPs and their interactions with cell membranes, which is helpful to understand the curvature-mediated assemblies of adhesive proteins or NPs on membranes, and offer novel possibilities for designing an effective NP-based vehicle for controlled drug delivery.

Morphological and mechanical determinants of cellular uptake of deformable nanoparticles.

Understanding the interactions of nanoparticles (NPs) with cell membranes and regulating their cellular uptake processes are of fundamental importance to the design of drug delivery systems with minimum toxicity, high efficiency and long circulation time. Employing the procedure of coarse-graining, we built an elastically deformable NP model with tunable morphological and mechanical properties. We found that the cellular uptake of deformable NPs depends on their shape: an increase in the particle elasticity significantly slows the uptake rate of spherical NPs, slightly retards that of prolate NPs, and promotes the uptake of oblate NPs. The intrinsic mechanisms have been carefully investigated through analysis of the endocytic mechanisms and free energy calculations. These findings provide unique insights into how deformable NPs penetrate across cell membranes and offer novel possibilities for designing effective NP-based carriers for drug delivery.