Shuenn-Jue Wu

Role of Dendritic Cells in Antibody-Dependent Enhancement of Dengue Virus Infection

ABSTRACT Dengue viruses (DV), composed of four distinct serotypes (DV1 to DV4), cause 50 to 100 million infections annually. Durable homotypic immunity follows infection but may predispose to severe subsequent heterotypic infections, a risk conferred in part by the immune response itself. Antibody-dependent enhancement (ADE), a process best described in vitro, is epidemiologically linked to complicated DV infections, especially in Southeast Asia. Here we report for the first time the ADE phenomenon in primary human dendritic cells (DC), early targets of DV infection, and human cell lines bearing Fc receptors. We show that ADE is inversely correlated with surface expression of DC-SIGN (DC-specific intercellular adhesion molecule-3-grabbing nonintegrin) and requires Fc gamma receptor IIa (FcγRIIa). Mature DC exhibited ADE, whereas immature DC, expressing higher levels of DC-SIGN and similar FcγRIIa levels, did not undergo ADE. ADE results in increased intracellular de novo DV protein synthesis, increased viral RNA production and release, and increased infectivity of the supernatants in mature DC. Interestingly, tumor necrosis factor alpha and interleukin-6 (IL-6), but not IL-10 and gamma interferon, were released in the presence of dengue patient sera but generally only at enhancement titers, suggesting a signaling component of ADE. FcγRIIa inhibition with monoclonal antibodies abrogated ADE and associated downstream consequences. DV versatility in entry routes (FcγRIIa or DC-SIGN) in mature DC broadens target options and suggests additional ways for DC to contribute to the pathogenesis of severe DV infection. Studying the cellular targets of DV infection and their susceptibility to ADE will aid our understanding of complex disease and contribute to the field of vaccine development.

Inoculation of plasmids expressing the dengue-2 envelope gene elicit neutralizing antibodies in mice.

To develop a nucleic acid vaccine against dengue type-2 virus, the PreM and 92% of the envelope (E) genes were cloned into different eukaryotic plasmid expression vectors (pkCMVint Polyli and pVR1012). The resultant plasmid constructs (pD2ME and P1012D2ME) properly expressed the truncated E protein in vitro as evidenced by the expected protein size on SDS-PAGE and the ability of the protein to be recognized by monoclonal antibodies directed against conformational epitopes. Three-week-old BALB/c mice were given intradermal inoculations of each construct. Plasmid expression vectors without dengue genes were used as controls. One hundred percent of the mice that received the pD2ME and p1012D2ME constructs developed anti-dengue antibodies. These antibodies were shown to neutralize dengue type-2 virus in vitro. This is the first demonstration of the use of nucleic acid inoculation in the development of potential dengue virus. vaccines.

Evaluation of a prototype dengue-1 DNA vaccine in a Phase 1 clinical trial.

Candidate dengue DNA vaccine constructs for each dengue serotype were developed by incorporating pre-membrane and envelope genes into a plasmid vector. A Phase 1 clinical trial was performed using the dengue virus serotype-1 (DENV-1) vaccine construct (D1ME(100)). The study was an open-label, dose-escalation, safety and immunogenicity trial involving 22 healthy flavivirus-naïve adults assigned to one of two groups. Each group received three intramuscular injections (0, 1, and 5 months) of either a high dose (5.0mg, n=12) or a low dose (1.0mg, n=10) DNA vaccine using the needle-free Biojector(®) 2000. The most commonly reported solicited signs and symptoms were local mild pain or tenderness (10/22, 45%), local mild swelling (6/22, 27%), muscle pain (6/22, 27%) and fatigue (6/22, 27%). Five subjects (41.6%) in the high dose group and none in the low dose group developed detectable anti-dengue neutralizing antibodies. T-cell IFN gamma responses were detected in 50% (4/8) and 83.3% (10/12) of subjects in the low and high dose groups, respectively. The safety profile of the DENV-1 DNA vaccine is acceptable at both doses administered in the study. These results demonstrate a favorable reactogenicity and safety profile of the first in human evaluation of a DENV-1 DNA vaccine.

Immunogenicity and protective efficacy of a vaxfectin-adjuvanted tetravalent dengue DNA vaccine.

A prototype dengue-1 DNA vaccine was shown to be safe and immunogenic in a previous Phase 1 clinical trial. Anti-dengue-1 neutralizing antibody responses were detectable only in the group of volunteers receiving the high dose of nonadjuvanted vaccine and the antibody titers were low. Vaxfectin(®), a lipid-based adjuvant, enhances the immunogenicity of DNA vaccines. We conducted a nonhuman primate study to evaluate the effect of Vaxfectin(®) on the immunogenicity of a tetravalent dengue DNA vaccine. Animals were immunized on days 0, 28 and 84, with each immunization consisting of 3mg of Vaxfectin(®)-adjuvanted tetravalent dengue DNA vaccine. The use of Vaxfectin(®) resulted in a significant increase in anti-dengue neutralizing antibody responses against dengue-1, -3 and -4. There was little to no effect on T cell responses as measured by interferon gamma ELISPOT assay. Animals immunized with the Vaxfectin(®)-formulated tetravalent DNA vaccine showed significant protection against live dengue-2 virus challenge compared to control animals (0.75 mean days of viremia vs 3.3 days). Animals vaccinated with nonadjuvanted DNA had a mean 2.0 days of viremia. These results support further evaluation of the Vaxfectin(®)-adjuvanted tetravalent dengue DNA vaccine in a Phase 1 clinical trial.

Infection and activation of human peripheral blood monocytes by dengue viruses through the mechanism of antibody-dependent enhancement ☆ , ☆☆ , ★, ★★

Human monocytes are susceptible to dengue virus (DV) infection through an FcR-dependent pathway known as antibody-dependent enhancement (ADE). In this study, infection enhancement was observed when purified monocytes were infected with DV serotypes in the presence of serially diluted immune serum antibodies. Analyzing binding of the DV-antibody immune complexes to monocytes by quantifying the amount of viruses attached to monocytes, we found that binding did not correlate with the input amount of antibodies; rather, it peaked at suboptimal antibody concentrations, correlating with the observed infection enhancement. These results suggested that immune complexes are involved in hindering DV from binding to FcR-bearing cells; when such a protective feature is weakened, enhancement of viral attachment and ADE are observed. Further, increased cytokine production (TNF-alpha and IFN-alpha), and costimulatory marker expression (CD86 and CD40), were found to be associated with infection enhancement, suggesting a pathological role of ADE-affected monocytes in dengue hemorrhagic diseases.