Hepatitis B virus (HBV) infection is a major public health problem throughout the world. HBV infection causes acute or chronic hepatitis which may cause liver cirrhosis or hepatocellular carcinoma (HCC). Although effective HBV vaccine are available to prevent HBV infection, some individual can’t produce antibody against HBV and existing vaccine has no therapeutic effect on the chronically infected populations. The first-line antiviral HBV therapy reagents include type I interferon and nucleotide analogs but both have limited efficacy; severe side effects and drug resistance were found in many cases. Furthermore, current therapeutic methods such as viral entry inhibitors and capsid assembly inhibitors cannot eradicate HBV because viral cccDNAs still exist in hepatocytes. Chronic HBV infection still influences 350 million people worldwide and estimated 786,000 people die every year due to complications of HBV-related liver cirrhosis and HCC. Exploration of more effective therapeutic strategies for HBV infection is extremely urgent. micro-RNAs (miRNAs) are small, non-coding RNAs that can regulate gene expression at post-transcriptional level through translational repression or degradation of targeted mRNAs. So far, several studies have implicated that miRNAs influence the virus and host interaction and affect the virus life cycle. Recently, some miRNAs have been found to directly or indirectly regulate HBV replication by targeting cellular protein or HBV transcript. Previously, our laboratory found that miR-130a inhibited HBV replication by targeting two HBV transcriptional factor/coactivator: PGC1a and PPARg, thereby inhibits viral mRNA transcription and thus influence viral protein expression and virus replication. In this study, we create the miR-130a knockout (KO) mice by TALEN approach to dissect the relationship between HBV and miR-130a in vivo. After HBV plasmids tail-vein hydrodynamic injection, these miR-130a KO mice can promote the HBV replication due to higher expression levels of PGC1a and PPARg. In addition, the I.V. injection of miR-130a-expressing adenovirus in miR-130a KO mice, which replenishes the miR-130a expression, would inhibit the HBV replication reversely. Taken together, we validate that miR-130a have an inhibitory effect on HBV replication in vivo and increase miR-130a might be an effective strategy to limit HBV replication.