Nowadays, chronic hepatitis B virus infection remains one of the most important infectious diseases for human. It is estimated 350 million people worldwide are chronically infected with HBV. Compared to healthy people, these patients have higher risks in developing progressed liver diseases. Current anti-HBV drugs, including alpha interferons and nucleoside / nucleotide analogues, can only achieve limited effects. Furthermore, durable therapeutic effects are hindered by unresponsiveness or emergence of drug-resistance mutants. Accordingly, requests of new anti-HBV agents continue. Accumulating studies showed that long-term suppression of HBV might be beneficial to chronic infected patients, by preventing liver pathologies. The major purpose of the present study is to develop gene therapy approach to introduce RNA interference as a new anti-HBV therapeutics strategy. RNA interference (RNAi) is a mechanism taking place in animal or plant cells which degrades mRNAs by introducing small RNA duplexes (< 30 bp) with complementary sequences. Besides in vitro cell culture systems, RNAi has been approved as effective in in vivo circumstances. Taking advantages of its high specificity and low toxicity, RNAi has been widely applied in numerous medical utilizations. We evaluated RNAi therapeutic effects on chronic HBV infections using an ICR/HBV transgenic mouse model, which carries 1.3-fold of HBV genome. Southern and Northern blot showed that these HBV transgenic mice continuously expressed profound HBV RNA and DNA in liver. Immunohistochemistry analysis showed that HBcAg expression was detected in nuclei of over than 90 % of mouse hepatocytes. High levels of HBV infectious particles, HBsAg and HBeAg were also detected in circulation. The serum HBV DNA titer (~ 1x 108 copies / ml) in this transgenic mouse line was comparable to that found in chronic infected patients. In order to achieve efficient and durable RNAi effects in ICR/HBV mice, novel recombinant adeno-associated viral vectors (AAV) containing double-stranded (ds) genome were used to deliver short hairpin RNA (shRNA). In the initial animal experiments, serotype 8 AAV was used because it was reported to mediate the highest liver infectivity among all known AAV serotypes. HBV titer- and age-matched male HBV transgenic mice were intrasplenically injected with 1 x 1012 vg of dsAAV8 encoding various shRNAs. Two weeks after injection, dsAAV8 expressing one of the HBV-specific shRNA reduced serum HBV titer by 1,000- to 10,000-fold. HBV DNA and RNA expression in mouse liver was almost completely eliminated. HBcAg expression in most hepatocytes in AAV-treated mice was reduced to undetectable level. In contrast, AAV vectors encoding non-specific shRNA and saline treatment resulted in no significant reduction of HBV in the ICR/HBV transgenic mice. Real-time RT-PCR measurement revealed that inflammatory factors including IFNs and TNF-α were not involved in the RNAi-mediated anti-HBV effects. Kinetic studies showed that HBV suppression peaked at two to three weeks after injection, and gradually decreased afterward. Four months after injection, about 10-fold decreased in HBV titer was still maintained. Interestingly, dsAAV8 vectors infused through tail vein resulted in more persistent RNAi effects than intrasplenic injection. ALT elevation between two to three weeks after intrasplenic injection of AAV vectors was consistently observed. Liver AAV genome DNA, as well as RNAi effects in mice treated with intrasplenic AAV vectors decreased faster than those by intravenous injection. It is speculated that AAV directly injected into spleen is likely to induce cytotoxic T cell responses which might destroy AAV-transduced hepatocytes. In contrast, systemic delivery of AAV vectors avoided these scenarios, and accordinly the anti-HBV RNAi effect could more stably sustain. Nevertheless, substantial decreases of RNAi effects were still observed, that reductions in HBV titers were reduced to 10-fold on 40 weeks after injection. In order to further extend anti-HBV effect, strategy of repetitive injection of AAV vectors was adopted. Besides serotypes 8, two recently identified serotypes AAV7 and AAV9 have also been illustrated as potent gene delivery vectors for liver. Therefore, dsAAV7, dsAAV8 and dsAAV9 vectors expressing HBV-specific shRNA were prepared and intravenously injected to HBV transgenic mice. Significant anti-HBV activities could be achieved by the three vectors, with dsAAV8 the strongest. Serotypes 7 and 9 induce substantial, but slightly lower silencing effects than AAV8. In vivo cross-administration experiments were conducted to verify that dsAAV7 and dsAAV9 transductions on mice pre-exposed to dsAAV8 were fully active. Finally, HBV transgenic mice which were initially injected with dsAAV8 expressing HBV-specific shRNA, with HBV titer returned to pre-treated levels (sixty to sixty-two weeks later), were re-injected with dsAAV9 vector encoding the same shRNA. Serum HBV titers revealed that RNAi effects were active on these mice and HBV suppressions could be further prolonged. Notably, higher proliferation rates and several pathologies were observed in liver of ICR/HBV. These mice ultimately developed liver tumors at the age of 18-month-old. Remarkably, HBV transgenic mice treated with RNAi gene therapy displaying HBV titer less than 1 x 107 copy / ml had significant lower tumor incidence or, if any, smaller tumor nodules. Increasing evidences have shown HBeAg and / or HBV DNA titers in patients’ sera were positively related to the risks of cirrhosis and hepatocellular carcinoma. Thus the ICR/HBV mouse represents an animal model which reproduces the clinical observations. Combination of RNAi and AAV vectors to reach long-term antiviral therapeutic effects might have great merits to impede progressive liver diseases.