The novel immunogenic chimeric peptide vaccine to elicit potent cellular and mucosal immune responses against HTLV-1.

This study reports on the immunogenicity assessment of a novel chimeric peptide vaccine including Tax, gp21, gp46, and gag immunodominant epitopes of human T-cell lymphotropic virus type 1 (HTLV-1) to induce immunity against HTLV-1 after subcutaneous (SC) or intranasal administration in a mice model. Additionally, to elevate the efficacy of the HTLV-1 vaccine, the chimera was physically mixed with monophosphoryl lipid A (MPLA) or ISCOMATRIX (IMX) adjuvants. For this purpose, the ISCOMATRIX with a size range of 40-60 nm were prepared using lipid film hydration method. Our investigation revealed that the mixture of IMX and chimera could significantly increase antibody titers containing IgG2a, and mucosal IgA, as well as IFN-γ and IL-10 cytokines and decrease the level of TGF-ß1, compared to other vaccine formulations. The intranasal delivery of chimera vaccine in the absence or presence adjuvants stimulated potent mucosal sIgA titer relative to subcutaneous immunization. Furthermore, the SC or nasal delivery of various vaccine formulations could shift the immunity toward cell-mediated responses, as evident by higher IgG2a and IFN-γ, as well as suppressed TGF-ß1 level. Our findings suggest that proper design, construction, and immunization of multi-epitope vaccine are essential for developing an effective HTLV-1 vaccine.

Expansion of human T-cell leukemia virus type 1 (HTLV-1) reservoir in orally infected rats: inverse correlation with HTLV-1-specific cellular immune response.

Adult T-cell leukemia (ATL) occurs in a small population of human T-cell leukemia virus type 1 (HTLV-1)-infected individuals. Although the critical risk factor for ATL development is not clear, it has been noted that ATL is incidentally associated with mother-to-child infection, elevated proviral loads, and weakness in HTLV-1-specific T-cell immune responses. In the present study, using a rat system, we investigated the relationships among the following conditions: primary HTLV-1 infection, a persistent HTLV-1 load, and host HTLV-1-specific immunity. We found that the persistent HTLV-1 load in orally infected rats was significantly greater than that in intraperitoneally infected rats. Even after inoculation with only 50 infected cells, a persistent viral load built up to considerable levels in some orally infected rats but not in intraperitoneally infected rats. In contrast, HTLV-1-specific cellular immune responses were markedly impaired in orally infected rats. As a result, a persistent viral load was inversely correlated with levels of virus-specific T-cell responses in these rats. Otherwise very weak HTLV-1-specific cellular immune responses in orally infected rats were markedly augmented after subcutaneous reimmunization with infected syngeneic rat cells. These findings suggest that HTLV-1-specific immune unresponsiveness associated with oral HTLV-1 infection may be a potential risk factor for development of ATL, allowing expansion of the infected cell reservoir in vivo, but could be overcome with immunological strategies.

Immunodominant sites of human T cell lymphotropic virus type 1 envelope protein for murine helper T cells.

HTLV-I (human T cell lymphotropic virus type 1) is the retrovirus causally related to adult T cell leukemia/lymphoma and is also associated with a neurological disorder, tropical spastic paraparesis, or HTLV-I-associated myelopathy. The development of these two different diseases among HTLV-I-infected individuals may depend in part on differences in their T cell immunity associated with a difference of HLA phenotype. Peptides corresponding to 17 sites in the HTLV-I envelope protein were tested for their antigenicity for lymph node cells from B10.BR, B10.D2, B10.A(5R), and B10.HTT congenic mice, representing four independent MHC haplotypes, immunized with the native envelope protein. Ten of the 17 tested sites were predicted to be amphipathic alpha-helical sites and all of them were found to be antigenic for at least one of the four MHC congenic strains of mice. Three of the 17 sites were amphipathic 3(10)-helical sites and four sites were predicted to be non-helical sites: none of the 3(10)-helical sites were antigenic and only one of four non-predicted sites was found to be immunodominant. Furthermore, three potent immunodominant peptides, V1E1 (342-363), V1E8/SP4a (191-209), and V1E10 (141-156) were also shown to be immunogenic; i.e., these peptides could be used to immunize mice to elicit proliferative responses of lymph node cells to the native HTLV-I envelope protein. Furthermore, these three peptides were able to prime animals for an enhanced antibody response to the native protein. Because this priming followed the same Ir gene control as the proliferative response, it probably reflects the ability of these peptides to prime helper T cells. The localization of immunodominant sites in HTLV-I envelope protein in mice may be useful for finding antigenic and immunogenic sites in humans, for developing a peptide vaccine for the virus, and possibly for aiding in prognosis for the development of different disease manifestations of HTLV-I infection.