TLR9 re-expression in cancer cells extends the S-phase and stabilizes p16(INK4a) protein expression.

Toll-like receptor 9 (TLR9) recognizes bacterial, viral or cell damage-associated DNA, which initiates innate immune responses. We have previously shown that TLR9 expression is downregulated in several viral induced cancers including HPV16-induced cervical neoplasia. Findings supported that downregulation of TLR9 expression is involved in loss of anti-viral innate immunity allowing an efficient viral replication. Here we investigated the role of TLR9 in altering the growth of transformed epithelial cells. Re-introducing TLR9 under the control of an exogenous promoter in cervical or head and neck cancer patient-derived cells reduced cell proliferation, colony formation and prevented independent growth of cells under soft agar. Neither TLR3, 7, nor the TLR adapter protein MyD88 expression had any effect on cell proliferation, indicating that TLR9 has a unique role in controlling cell growth. The reduction of cell growth was not due to apoptosis or necrosis, yet we observed that cells expressing TLR9 were slower in entering the S-phase of the cell cycle. Microarray-based gene expression profiling analysis highlighted a strong interferon (IFN) signature in TLR9-expressing head and neck cancer cells, with an increase in IFN-type I and IL-29 expression (IFN-type III), yet neither IFN-type I nor IL-29 production was responsible for the block in cell growth. We observed that the protein half-life of p16(INK4a) was increased in TLR9-expressing cells. Taken together, these data show for the first time that TLR9 affects the cell cycle by regulating p16(INK4a) post-translational modifications and highlights the role of TLR9 in the events that lead to carcinogenesis.

Immunization with a DNA vaccine expressing a truncated form of varicella zoster virus glycoprotein E.

The gE glycoprotein of varicella zoster virus (VZV) is involved with cell entry and it is the most abundant glycoprotein produced in VZV-infected cells. It is also the first glycoprotein to be recognized by the immune system and induces neutralizing antibodies and cellular immunity. We have shown previously that immunization with a DNA vaccine encoding full length gE induces high antibody titres in BALB/c mice. In this study, we engineered a truncated form of gE to facilitate secretion of the glycoprotein, which is thought to increase the quantity of antigen available for B cells to mount an immune response. This hypothesis was tested by using inverse PCR mutagenesis (IPCRM) to engineer a mutated form of gE that was secreted from the cell. This construct was then evaluated as a potential DNA vaccine. Following immunization studies, the magnitude of the immune response induced with the mutant form of gE was found to be similar to that induced by membrane bound protein. This finding suggests that, in the case of VZV, a DNA vaccine expressing a secreted protein has no advantage over one expressing a membrane bound protein. However, mice immunized with the truncated form of gE (gED) displayed responses favouring IgG1 (Th2) in comparison with mice immunized with the full length gE construct, which generated an IgG2a (Th1) response. This observation indicates that immunization with a truncated form of a gene may induce immune modulation, a phenomenon that should be taken into account for the design of vaccines.

Immunization with a DNA expression vector encoding the varicella zoster virus glycoprotein E (gE) gene via intramuscular and subcutaneous routes.

In this study we constructed a plasmid containing the gene encoding varicella-zoster virus transmembrane glycoprotein gE (VZV gE) and evaluated its utility for DNA immunization in mice. Our initial work demonstrates that intramuscular and subcutaneous injection of VZV gE DNA, without the use of costimulatory molecules or other adjuvant materials, results in the generation of antigen-specific antibodies of primarily the IgG2a subclass, indicating that this vaccine can stimulate Th1 type immunity. This is the first report of a prototype DNA vaccine for varicella-zoster virus.

Nucleic acid immunization: concepts and techniques associated with third generation vaccines.

A radical change in vaccine methodology arrived nine years ago with the advent of nucleic acid immunization. Aspects such as plasmid design, gene selection, the use of immunostimulatory complexes and clinical trials are discussed in this review. Furthermore, concepts and protocols involved in the construction, evaluation and immunization of a DNA vaccine have been examined as new strategies to enhance this technology continues to grow.