The mechanism of hepatitis B virus (HBV) persistence following its exposure has long been an unresolved question. Using a hydrodynamics-based mouse model for HBV persistence, we have previously found that HBV core protein (HBc) was the major determinant viral factor for HBV clearance. Therefore, my thesis aimed to further explore the underlying mechanisms. First, we determined the region of HBc protein that is crucial for HBV clearance in mice by using a series of HBcAg deletion mutants. Interestingly, the very C-terminal 10-residue region HBc176-185 of HBc protein, which does not appear to contain a major epitope of T and B cells, contributed to HBV clearance. A deletion of this region prolonged HBV persistence in mice while the viral replication, transcription and translation within hepatocytes remained unaffected. Besides, this particular HBV mutant failed to induce robust humoral and cellular immunity against HBV. Moreover, using an assembly-defective HBV mutant, HBcY132A pAAV/HBV1.2, we revealed the requirement of nucleocapsid structure for inducing effective immunity that leads to HBV clearance in mice. Viral or cellular RNAs, but not DNAs, within the capsid particle were essential for the nucleocapsid to trigger antiviral responses. Finally, these findings prompted us to hypothesize that the HBV nucleocapsid functions as a novel viral pathogen-associated molecular pattern (PAMP) that promotes the viral clearance. This is a burgeoning and exciting research area and may open a new field for future study.