Tissue distribution of a plasmid DNA encoding Hsp65 gene is dependent on the dose administered through intramuscular delivery

In order to assess a new strategy of DNA vaccine for a more complete understanding of its action in immune response, it is important to determine the in vivo biodistribution fate and antigen expression. In previous studies, our group focused on the prophylactic and therapeutic use of a plasmid DNA encoding the Mycobacterium leprae 65-kDa heat shock protein (Hsp65) and achieved an efficient immune response induction as well as protection against virulent M. tuberculosis challenge. In the present study, we examined in vivo tissue distribution of naked DNA-Hsp65 vaccine, the Hsp65 message, genome integration and methylation status of plasmid DNA. The DNA-Hsp65 was detectable in several tissue types, indicating that DNA-Hsp65 disseminates widely throughout the body. The biodistribution was dose-dependent. In contrast, RT-PCR detected the Hsp65 message for at least 15 days in muscle or liver tissue from immunized mice. We also analyzed the methylation status and integration of the injected plasmid DNA into the host cellular genome. The bacterial methylation pattern persisted for at least 6 months, indicating that the plasmid DNA-Hsp65 does not replicate in mammalian tissue, and Southern blot analysis showed that plasmid DNA was not integrated. These results have important implications for the use of DNA-Hsp65 vaccine in a clinical setting and open new perspectives for DNA vaccines and new considerations about the inoculation site and delivery system.     

Mechanism of enhancement of DNA expression consequent to cointernalization of a replication-deficient adenovirus and unmodified plasmid DNA.

Given the knowledge that replication-deficient adenoviruses can mediate the delivery of unlinked plasmid DNA into eukaryotic cells (K. Yoshimura, M. A. Rosenfeld, P. Seth, and R. G. Crystal, J. Biol. Chem. 268:2300-2303, 1993), this study focuses on the role of receptor-mediated endocytosis in this process. AdCFTR (an E1- E3- adenovirus type 5-based replication-deficient adenovirus containing the 4.5-kb human cystic fibrosis transmembrane conductance regulator cDNA) was added to Cos-7 cells together with plasmid pRSVL (containing the Rous sarcoma virus long terminal repeat promoter followed by the luciferase cDNA), and luciferase activity was quantified as a measure of the expression of the plasmid DNA. When AdCFTR was bound to Cos-7 cells at 4 degrees C and the cells were subsequently incubated at 37 degrees C in the presence of pRSVL, the expression of luciferase activity was increased in proportion to the amount of AdCFTR added, reaching > 10(4)-fold at 3,000 PFU per cell. AdCFTR-mediated increase in pRSVL was inhibited by addition of purified adenovirus fiber but not hexon, suggesting cell surface adenovirus receptors were involved in the cointernalization process. Cell lines with a high number of adenovirus receptors (Cos-7 and HeLa) showed significant AdCFTR-dependent pRSVL expression, while cell lines with low numbers of adenovirus receptors (NIH 3T3 and U-937) showed little. AdCFTR-mediated increase in the expression of pRSVL was prevented when AdCFTR was heat treated and exposed to antibody against adenovirus or when the cointernalization process was evaluated in the presence of chloroquine, conditions all known to prevent adenovirus-mediated disruption of endocytic vesicles. In contrast, the uptake of AdCFTR into Cos-7 cells was not affected by any of these conditions. When AdCFTR was exposed to UV light, its ability to grow in 293 cells was obviated, but AdCFTR-dependent increase in pRSVL expression was minimally reduced. Finally, empty capsids of AdCFTR were able to enhance the delivery and expression of plasmid pRSVL into Cos-7 cells, suggesting that the adenovirus genome is not required for AdCFTR-mediated plasmid cointernalization. Together, these observations suggest that the ability of a replication-deficient recombinantly adenovirus to mediate the cointernalization and expression of plasmids is mediated by the receptor-mediated endocytosis pathway.