Abstract
Disruption of virus capsid assembly has compelling antiviral potential that has been applied to hepatitis B virus (HBV). HBV core protein assembly can be modulated by heteroaryldihydropyrimidines (HAPs), and such molecules are collectively termed core protein allosteric modulators (CpAMs). Although the antiviral effects of CpAMs are acknowledged, the mechanism of action remains an open question. Challenging aspects of characterizing misdirected assembly are the large size and nonuniform nature of the final particles. In this study of HBV assembly, we observed a competition between normative and CpAM-induced aberrant assembly with electron microscopy and resistive-pulse sensing on nanofluidic devices. This competition was a function of the strength of the association energy between individual core proteins, which is proportional to ionic strength. At strong association energy, assembly reactions primarily yielded morphologically normal HBV capsids, despite the presence of HAP-TAMRA. At weak association energy, HAP-TAMRA led to increased assembly product size and disrupted morphology. The smallest particles were T = 4 icosahedra, whereas the larger particles were defective spheres, ellipsoids, and bacilliform cylinders, with regions of T = 4 geometry interspersed with flat regions. Deviation from spherical geometry progressively increased with particle size, which is consistent with the interpretation of a competition between two alternative assembly pathways.