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1. Hierarchical assembly is more robust than egalitarian assembly in synthetic capsids

   https://doi.org/10.1073/pnas.2312775121  

   Wei, Wei-Shao; Trubiano, Anthony; Sigl, Christian; Paquay, Stefan; Dietz, Hendrik; Hagan, Michael F.; Fraden, Seth (February 2024, Proceedings of the National Academy of Sciences)

   Self-assembly of complex and functional materials remains a grand challenge in soft material science. Efficient assembly depends on a delicate balance between thermodynamic and kinetic effects, requiring fine-tuning affinities and concentrations of subunits. By contrast, we introduce an assembly paradigm that allows large error-tolerance in the subunit affinity and helps avoid kinetic traps. Our combined experimental and computational approach uses a model system of triangular subunits programmed to assemble intoT= 3 icosahedral capsids comprising 60 units. The experimental platform uses DNA origami to create monodisperse colloids whose three-dimensional geometry is controlled to nanometer precision, with two distinct bonds whose affinities are controlled tok_BTprecision, quantified in situ by static light scattering. The computational model uses a coarse-grained representation of subunits, short-ranged potentials, and Langevin dynamics. Experimental observations and modeling reveal that when the bond affinities are unequal, two distincthierarchicalassembly pathways occur, in which the subunits first form dimers in one case and pentamers in another. These hierarchical pathways produce complete capsids faster and are more robust against affinity variation than egalitarian pathways, in which all binding sites have equal strengths. This finding suggests that hierarchical assembly may be a general engineering principle for optimizing self-assembly of complex target structures. 

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2. From Disorder to Icosahedral Symmetry: How Conformation-Switching Subunits Enable RNA Virus Assembly

   Li, S; Tresset, G; Zandi, R (August 2025, Science advances)

   Icosahedral capsids are ubiquitous among spherical viruses, yet their assem- bly pathways and governing interactions remain elusive. We present a molecular dynamics model that incorporates essential physical and biological interactions, including protein diffusion, genome flexibility, and a conformational switch that mimics allostery and activates the elastic properties of proteins upon binding. This switch makes the simulations computationally feasible and enables the assembly of icosahedral capsids around a flexible genome—overcoming long-standing lim- itations in previous models. Using this framework, we successfully reproduce the self-assembly of subunits around a flexible genome into icosahedral shells with numbers greater than one – most notably 3, the most common structure in na- ture – a feat that rigid-body models have so far failed to achieve. We systematically explore the range of morphologies formed with different genome architectures, in line with in vitro experiments using cowpea chlorotic mottle virus capsid proteins: viral RNAs with more complex structure form more complete and stable capsids than linear ones. These results provide a predictive framework for genome-guided assembly and capsid design. 

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3. Particle Deformability Enables Control of Interactions between Membrane-Anchored Nanoparticles

   https://doi.org/10.1021/acs.jctc.3c00687  

   Nambiar, Nikhil; Loyd, Zachary A; Abel, Steven M (October 2023, Journal of Chemical Theory and Computation)

   Nanoparticles adsorbed on a membrane can induce deformations of the membrane that give rise to effective interactions between the particles. Previous studies have focused primarily on rigid nanoparticles with fixed shapes. However, DNA origami technology has enabled the creation of deformable nanostructures with controllable shapes and mechanical properties, presenting new opportunities to modulate interactions between particles adsorbed on deformable surfaces. Here we use coarse-grained molecular dynamics simulations to investigate deformable, hinge-like nanostructures anchored to lipid membranes via cholesterol anchors. We characterize deformations of the particles and membrane as a function of the hinge stiffness. Flexible particles adopt open configurations to conform to a flat membrane, whereas stiffer particles induce deformations of the membrane. We further show that particles spontaneously aggregate and that cooperative effects lead to changes in their shape when they are close together. Using umbrella sampling methods, we quantify the effective interaction between two particles and show that stiffer hinge-like particles experience stronger and longer-ranged attraction. Our results demonstrate that interactions between deformable, membrane-anchored nanoparticles can be controlled by modifying mechanical properties of the particles, suggesting new ways to modulate the self-assembly of particles on deformable surfaces. 

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4. Molecular Geometry‐Directed Self‐Recognition in the Self‐Assembly of Giant Amphiphiles

   https://doi.org/10.1002/marc.202200216  

   Zhou, Yifan; Luo, Jiancheng; Liu, Tong; Wen, Tao; Williams‐Pavlantos, Kayla; Wesdemiotis, Chrys; Cheng, Stephen Z. D.; Liu, Tianbo (May 2022, Macromolecular Rapid Communications)

   Abstract Three sets of polyoxometalate (POM)‐based amphiphilic hybrid macromolecules with different rigidity in their organic tails are used as models to understand the effect of molecular rigidity on their possible self‐recognition feature during self‐assembly processes. Self‐recognition is achieved in the mixed solution of two structurally similar, sphere‐rigid T‐shape‐linked oligofluorene(TOF₄) rod amphiphiles, with the hydrophilic clusters being Anderson (Anderson‐TOF₄) and Dawson (Dawson‐TOF₄), respectively. Anderson‐TOF₄is observed to self‐assemble into onion‐like multilayer structures and Dawson‐TOF₄forms multilayer vesicles. The self‐assembly is controlled by the interdigitation of hydrophobic rods and the counterion‐mediated attraction among charged hydrophilic inorganic clusters. When the hydrophobic blocks are less rigid, e.g., partially rigid polystyrene and fully flexible alkyl chains, self‐recognition is not observed, attributing to the flexible conformation of hydrophobic molecules in the solvophobic domain. This study reveals that the self‐recognition among amphiphiles can be achieved by the geometrical limitation of the supramolecular structure due to the rigidity of solvophobic domains. 

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5. Coarse-Grained Modeling of Coronavirus Spike Proteins and ACE2 Receptors

   https://doi.org/10.3389/fphy.2021.680983  

   Leong, Timothy; Voleti, Chandhana; Peng, Zhangli (June 2021, Frontiers in Physics)

   null (Ed.)

   We developed coarse-grained models of spike proteins in SARS-CoV-2 coronavirus and angiotensin-converting enzyme 2 (ACE2) receptor proteins to study the endocytosis of a whole coronavirus under physiologically relevant spatial and temporal scales. We first conducted all-atom explicit-solvent molecular dynamics simulations of the recently characterized structures of spike and ACE2 proteins. We then established coarse-grained models using the shape-based coarse-graining approach based on the protein crystal structures and extracted the force field parameters from the all-atom simulation trajectories. To further analyze the coarse-grained models, we carried out normal mode analysis of the coarse-grained models to refine the force field parameters by matching the fluctuations of the internal coordinates with the original all-atom simulations. Finally, we demonstrated the capability of these coarse-grained models by simulating the endocytosis of a whole coronavirus through the host cell membrane. We embedded the coarse-grained models of spikes on the surface of the virus envelope and anchored ACE2 receptors on the host cell membrane, which is modeled using a one-particle-thick lipid bilayer model. The coarse-grained simulations show the spike proteins adopt bent configurations due to their unique flexibility during their interaction with the ACE2 receptors, which makes it easier for them to attach to the host cell membrane than rigid spikes. 

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