Doxycycline-regulated lentiviral vector system with a novel reverse transactivator rtTA2S-M2 shows a tight control of gene expression in vitro and in vivo.

Regulated expression of therapeutic genes is required for long-term gene therapy applications for many disorders. Here we describe a doxycycline (dox)-regulated lentiviral vector system consisting of two HIV-1-based self-inactivating viruses. One of the vectors is constitutively expressing a novel improved version of the tetracycline reverse transactivator rtTA2(S)-M2 and the other has a rtTA responsive promoter driving the expression of beta-galactosidase gene (lacZ). The rtTA2(S)-M2 has highly improved properties with respect to specificity, stability and inducibility. Functionality of the system by dox was confirmed after in vitro cotransduction of Chinese hamster ovary and human endothelial hybridoma (EAhy926) cells. Regulation of the system showed tight control of the gene expression. Dose dependence for dox was seen with concentrations that can be obtained in vivo with doses normally used in clinical practice. LacZ expression could be switched on/off during long-term (3 months) culturing of cotransduced cells. The system was next tested in vivo after cotransduction into rat brain and studying expression of the lacZ gene in dox-treated and control rats. Nested RT-PCR confirmed that the tight control of the gene expression was achieved in vivo. Also, X-gal staining showed positive cells in the dox-treated rats, but not in the controls 10 days after cotransduction with 4 days preceding treatment with dox. It is concluded that our doxycycline-regulated vector system shows significant potential for long-term gene therapy treatments.

Baculoviruses exhibit restricted cell type specificity in rat brain: a comparison of baculovirus- and adenovirus-mediated intracerebral gene transfer in vivo.

Baculoviruses have recently been shown to be effective gene transfer vectors in mammalian cells. However, very little information is available about their target cell tropism in the central nervous system. We studied transduction efficiency, tropism and biodistribution of baculoviruses after local delivery to rat brain and compared their properties to adenoviruses. It was found that baculoviruses specifically transduced cuboid epithelium of the choroid plexus in ventricles and that the transduction efficiency was as high as 76+/-14%, whereas adenoviruses showed preference to corpus callosum glial cells and ventricular ependymal lining. Only a modest microglia response was seen after the baculovirus transduction whereas the adenovirus gene transfer led to a strong microglia response. Sensitive nested RT-PCR revealed transgene expression in the hindbrain and in ectopic organs including spleen, heart and lung, which indicates that some escape of both vectors occurs to ectopic organs after local gene transfer to the brain. We conclude that both baculovirus and adenovirus vectors can be used for local intracerebral gene therapy. The knowledge of the cell type specificity of the vectors may offer a possibility to achieve targeted gene delivery to distinct brain areas. Baculoviruses seem to be especially useful for the targeting of choroid plexus cells.