Construction of arginine-rich peptide displaying bionanocapsules.

Bionanocapsule (BNC) is a hollow nanoparticle composed of L-protein of the hepatitis B virus surface antigen. BNC can deliver genes or drugs into specific human hepatocytes, but delivery is limited to hepatocytes. In this study, we attempted to alter the specificity of BNCs by genetically introducing cell-penetrating peptides (CPPs), such as arginine-rich peptides, into BNCs. The CPP-fused BNC was efficiently internalized into various cell lines in a short period without significant cytotoxicity. These results show that CPP-BNC could be applied as an efficient carrier for gene and drug delivery.

Expression of squamous cell carcinoma antigen-1 in liver enhances the uptake of hepatitis B virus envelope-derived bio-nanocapsules in transgenic rats.

We previously developed the bio-nanocapsule, which consists of hepatitis B virus envelope L proteins. The bio-nanocapsule can be used to deliver genes and drugs specifically to the human liver-derived tissues in xenograft models, presumably by utilizing the human liver-specific mechanism of hepatitis B virus infection. The hepatitis B virus tropism is highly restricted to humans and higher primates. Thus, to evaluate the in vivo therapeutic effects of forthcoming bio-nanocapsule-based medicines, it will be crucial to develop an animal model whose liver is susceptible to both bio-nanocapsule and hepatitis B virus. In the present study, we aimed to establish a bio-nanocapsule-susceptible animal model using transgenic rats expressing squamous cell carcinoma antigen-1 (SCCA1), which has been proposed to be a receptor for hepatitis B virus, interacting with the hepatitis B virus envelope protein and enhancing the cellular uptake of hepatitis B virus. We show that the recombinant SCCA1 protein interacts directly with bio-nanocapsule and inhibits its attachment to the cultured human liver-derived cells. Furthermore, we have established a transgenic rat that specifically expresses SCCA1 in the liver and also demonstrate that the amount of bio-nanocapsule accumulated in the liver is significantly increased by the SCCA1 expression. Histological analysis suggests that bio-nanocapsule is preferentially incorporated into the SCCA1-expressing hepatocytes but not into macrophages, such as Küppfer cells, nor into endothelial cells. Therefore, this animal model is expected to be useful for the development of bio-nanocapsule-based medicines.