Theoretical Study of Biological Form - Spherical Capsids
Marzec, Christopher J.   
State University of New York at Albany, Albany, NY, United States

This proposal aims at making improvements in the theory of spherical capsid structure commensurate with the recent explosion of low resolution structures as determined by cryo-electron microscopy. We now have no theoretical understanding of the assembly of closed shells and polymorphs, and since the thirty year old Quasi-Equivalence theory has met fatal counter-examples, we do not even understand why icosahedral symmetry is observed, instead of octahedral symmetry or random packing. The numerical """"""""Uniform Spacing"""""""" model was developed as a partial explanation of observed capsid patterns, and it successfully reproduces the surface morphologies of the capsids to which it has been applied. The proposed work consists of: 1) applying Uniform Spacing to additional empirical capsid patterns; 2) developing a comprehensive library of theoretical capsid morphologies; 3) simulating capsomeres self- organizing into icosahedral or other symmetry; 4) studying the stability of spherical and polyhedral shells and simulating the formation of closed capsid shells and polymorphic structures. The working hypothesis is that capsids self-assemble via long to intermediate-ranged, non-specific forces which mediate the inter-capsomere interactions and are tuned or switched by solvent conditions or specific external mechanisms. Low resolution capsids are modeled as 'generic' structures, chosen by specific mechanisms from a range of alternatives determined by non- specific interactions; the polymorphism observed for some capsid proteins suggests this viewpoint. The simulations will explore the roles of nucleating structures, solvent conditions, and the form of the inter- capsomere forces. The goal is to discover the principles guiding capsid assemble and morphology, and thus to further the determination and understanding of empirical capsid structures. A new method for representing the capsid has been developed and will be implemented. Both the two-dimensional Uniform Spacing model and the proposed three-dimensional shell stability and assemble model describe capsomeres and their interaction via Fourier series. Such representation allows easy reconfiguration of the capsomere shape and the inter- capsomere force laws, and easy calculation of the net capsomere interaction energy, which determines the fitness of a model capsid. Fourier representation is far more computationally tractable than the usual sort of representation in real space. It affords a natural way to describe non-specific forces, filtering out short-ranged details but retaining the global, form-generating interactions which govern self- assembly. The compact representation allows practical computation of extensive simulations of Euler-Langevin dynamics for systems of model capsomeres.