Immunization with a lymphocytic choriomeningitis virus peptide mixed with heat shock protein 70 results in protective antiviral immunity and specific cytotoxic T lymphocytes.

Heat shock proteins (hsp's) isolated from murine cancer cells can elicit protective immunity and specific cytotoxic T lymphocytes (CTLs) by channeling tumor-derived peptides bound to hsp's to the major histocompatibility class I antigen presentation pathway. Here we have investigated if hsp70 can be used in a novel peptide vaccine for the induction of protective antiviral immunity and memory CTLs. A CTL epitope from the well-defined lymphocytic choriomeningitis virus (LCMV) system was mixed with recombinant hsp70 in vitro under conditions that optimize peptide binding to hsp70. Mice were immunized with the hsp70-peptide mixture and challenged with LCMV. Virus titers were reduced 10-100-fold in these mice compared to control mice. Immunization with the hsp70-peptide mixture resulted in the development of CTL memory cells that could be reactivated during LCMV infection, and that in a 51Cr-release assay could lyse cells pulsed with the same peptide, but not cells pulsed with another LCMV peptide. These results show that hsp70 can be used with CTL epitopes to induce efficient protective antiviral immunity and the generation of peptide-specific CTLs. The results also demonstrate the usefulness of hsp70 as an alternative to adjuvants and DNA vectors for the delivery of CTL epitopes to antigen-presenting cells.

Human heat shock protein 70 peptide complexes specifically activate antimelanoma T cells.

Members of the heat shock protein 70 (HSP70) family display a broad cellular localization and thus bind a repertoire of chaperoned peptides potentially derived from proteins of different cellular compartments. In this report, we show that HSP70 purified from human melanoma can activate T cells recognizing melanoma differentiation antigens in an antigen- and HLA class I-dependent fashion. HLA class I-restricted anti-melanoma T cells were susceptible to MHC-restricted, HSP70-dependent stimulation, indicating that HSP70 complexed peptides were able to gain access to the class I HLA presentation pathway. In addition, MHC matching between the melanoma cells used as a source of HSP and the responding T cells were not required, indicating that HSP70 activation may occur across MHC barriers. Besides the MHC-restricted and peptide-dependent activation pathway, HSP70 with no endogenous complexed peptides or HSP70 purified from antigen-negative cells was also able to induce IFN-gamma release by antimelanoma T cells by a MHC-independent mechanism. In this case, however, higher doses of HSP70 were required. The capacity to activate class I-restricted, antitumor T cells as well as antigen-presenting cells, together with the finding that the HSP70 chaperoned peptide repertoire includes melanoma-shared epitopes, holds promise for a HSP70-based cancer vaccine.

Methylcholanthrene-induced mouse sarcomas express individually distinct major histocompatibility complex class I-associated peptides recognized by specific CD8+ T-cell lines.

Mouse sarcomas induced by methylcholanthrene (MC) are immunologically distinct even if they are induced in the same strain of mice. T-cell lines were derived from mice immunized against a series of syngeneic MC sarcomas on B6 background, known to carry unique tumor-specific transplantation antigens. Tumor necrosis factor-alpha (TNF-alpha) release assays concurred with the in vivo rejection tests. The strongest response in the TNF-alpha release was always obtained with the corresponding tumor, with very limited cross-reactivity against five other MC tumors or two virally induced B6 lymphomas. The specific TNF-alpha release from the anti-MC tumor CTL lines was mainly mediated by CD8+ cells. T-cell lines from intact and CD4-/- mice gave a similarly specific pattern. In contrast, T-cell lines derived from CD8-/- mice cross-reacted with several other MC-induced tumors. Peptides eluted from MC sarcomas under mild acid conditions were fractionated by reverse-phase high performance liquid chromatography and tested for their ability to sensitize the processing- and presentation-defective mutant RMA-S line. Only one high performance liquid chromatographic fraction from each of the three different tumor-derived peptide eluates capacitated RMA-S to induce TNF-alpha release and sensitized the cell to the cytotoxic effect of the corresponding tumor-specific T-cell line. A different Kb-restricted peptide fraction was active for each of the three MC sarcomas tested, indicating that they all expressed individually distinct peptide epitopes.

A long-term memory obtained by genetic immunization results in full protection from a mammary adenocarcinoma expressing an EBV gene.

We have tested the capability of a plasmid DNA (pDNA) expressing the EBV nuclear Ag-4 (EBNA-4) to evoke a T cell response-associated protective immune response against a tumor expressing this gene. We have found that ACA mice immunized with EBNA-4-expressing plasmid were partially protected against syngeneic mammary carcinoma line (S6C) expressing EBNA-4 (S6C-E4). This protection was enhanced by coimmunizing mice with EBNA-4- and GM-CSF-expressing plasmids, and a full protection was achieved by coimmunizing mice with EBNA-4- and IFN-gamma-expressing plasmids. Furthermore, mice that have rejected the EBNA-4-positive tumor were also resistant against a subsequent challenge with the original nontransfected tumor line. We then checked for the ability of pDNA immunization to provide a protective long-term memory response. We indeed found that even after 3 mo from the last immunization, full protection was obtained by this method, as compared with full tumor outgrowth in the control-immunized group. These findings support the concept that a nonviral, pDNA-based vaccination strategy is useful to fully protect from the outgrowth of tumors expressing this EBV gene.