Reconstitution of gene expression from a regulatory-protein-deficient hepatitis B virus genome by cell-permeable HBx protein.

Abstract

Various functions are ascribed to the HBx regulatory protein of the hepatitis B virus (HBV). Due to the low expression level of HBx, it has been difficult to correlate spatial and temporal HBx expression levels with specific functions. Based on a novel cell-permeable peptide, known as the translocation motif (TLM), cell-permeable HBx fusion proteins were generated. The TLM-HBx fusion protein is rapidly internalized from the medium into almost all cells, whereas no significant internalization was seen with wild-type HBx. The major fraction of internalized HBx protein moves from the cytoplasm to the nucleus. The cytosolic fraction, however, activates c-RAF1/extracellular-signal-related kinase 2 signalling and causes activation of activator protein 1 (AP1) and nuclear factor-kappaB. The TLM-HBx protein rescues HBV gene expression from an activator-deficient HBV genome. These results indicate that cell-permeable regulatory proteins provide a novel, efficient tool for a clearly defined, dose-dependent analysis of regulatory protein function, without affecting the integrity of the cell, and can be used for the safe reconstitution of virus production from a regulatory-protein-deficient virus genome.