Genetically altering the thermodynamics and kinetics of hepatitis B virus capsid assembly has profound effects on virus replication in cell culture.

Capsid (core) assembly is essential for hepatitis B virus (HBV) replication. We hypothesize that assembly kinetics and stability are tuned for optimal viral replication, not maximal assembly. Assembly effectors (AEfs) are small molecules proposed to disrupt this balance by inappropriately enhancing core assembly. Guided by the structure of an AEf-bound core, we designed a structural mimic of AEf-bound core protein, the V124W mutant. In biochemical studies, the V124W mutant recapitulated the effects of AEfs, with fast assembly kinetics and a strong protein-protein association energy. Also, the mutant was resistant to exogenous AEfs. In cell culture, the V124W mutant behaved like a potent AEf: expression of HBV carrying the V124W mutant was defective for genome replication. Critically, the V124W mutant interfered with replication of wild-type HBV in a dose-dependent manner, mimicking AEf activity. In addition, the V124W mutant was shown to adopt a more compact conformation than that of the wild type, confirming the allosteric regulation in capsid assembly. These studies show that the heteroaryldihydropyrimidine (HAP) binding pocket is a promiscuous target for inducing assembly. Suppression of viral replication by the V124W mutant suggests that mutations that fill the HAP site are not a path for HBV to escape from AEfs.