HBV persistence and transmission require HBV replication, which depends on the assembly of a core particle composed of capsid protein (Cp), polymerase, and pregenomic RNA. Reverse transcription to produce infectious DNA-containing particles occurs solely within the core residing in the cytoplasm (9, 10). Thus, core assembly is likely to be a high value target for therapeutics (11).The capsid, the protein shell of the core, is built of 120 Cp dimers arranged with T ϭ 4 symmetry (12, 13). The dimer interfaces are evident as spikes (14-16) that are the major epitope of the capsid (17). Cp in low ionic strength solution is dimeric (18). We have studied ionic strength-dependent capsid assembly extensively in vitro by using the Cp assembly domain (Cp149) (residues 1-149) lacking the 34-residue C-terminal RNA-binding domain (19)(20)(21). Assembly is nucleated by a trimer of Cp dimers and proceeds without accumulating observable populations of intermediates (22). Interactions between dimers are weak but sum to give a globally stable capsid (23). These capsids persist, even under conditions where they are not thermodynamically favored, because of hysteresis to dissociation (24). Some Cp mutations lead to faster assembly and greater stability (25), indicating that wild-type Cp is suboptimal for assembly and suggesting that assembly is regulated in vivo, possibly by conformational change. In support of this assertion, we found that Zn 2ϩ alters the conformation of Cp dimers and enhances the rate of assembly, suggesting that capsid assembly is allosterically regulated (26).Recently, it was discovered that heteroaryldihydropyrimidines (HAPs) (Fig. 1) affect the accumulation of HBV capsids (27,28). HAP drugs decreased the yield of assembled core and HBV genomes from cells that constitutively produce HBV. Electron microscopy showed that Cp assembled in vitro in the presence of HAP drugs led to polymers that had abnormal morphology (29). Similarly, small molecules such as bis ANS {5,5-bis[8-(phenylamino)-1-naphthalenesulfonate]} alter Cp assembly in vitro (30). Recent reports suggest that other small molecules also inhibit normal HBV capsid assembly (31-33).Here, we describe the mechanism of a representative HAP compound, HAP-1 [methyl 4-(2-chloro-4-f luorophenyl)-6-methyl-2-(pyridin-2-yl)-1,4-dihydropyrimidine-5-carboxylate] (Fig. 1). In vitro, low concentrations of HAP-1 enhance both the rate and extent of assembly by favoring an assembly-active state; thus, HAP-1 acts like an allosteric effector. At higher concentrations, HAP-1 led to aberrant noncapsid polymers in vitro, even at the expense of preexisting capsids. We propose that both of these effects on assembly contribute to reducing HBV virion production.
Materials and MethodsSynthesis of HAP-1. Preparation of racemic HAP-1 (Fig. 1) was adapted from the patent literature (27,28,34). Condensation of a pyridylamidine with a substituted ␣-carboxymethyl enone gave a 30% yield of Ͼ97% pure HAP-1 after chromatographic purification. HAP-1 was characterized by 1 H, 13 C, and 19 ...
