A DNA vaccine based on a shuffled E7 oncogene of the human papillomavirus type 16 (HPV 16) induces E7-specific cytotoxic T cells but lacks transforming activity.

Vaccination with oncogene-derived DNA for anti-cancer treatment carries a risk of de-novo tumor induction triggered by the persisting recombinant DNA. We hypothesized that an oncoprotein whose primary sequence has been rearranged ('shuffled') to maintain all possible T cell epitopes still induces cytotoxic T cells against the authentic protein but is devoid of transforming properties. As a model antigen, we used the E7 oncoprotein of the human papillomavirus (HPV) type 16, the major cause of cervical cancer. We have generated an artificial E7 molecule in which four domains were rearranged and, in order to maintain all possible T cell epitopes, certain sequences were duplicated. Upon transfection of this shuffled E7 gene (E7SH) into RMA cells, presentation of an E7 Db-restricted T cell epitope was shown by an E7-specific CTL line in vitro. Immunization of C57BL/6 mice with E7SH DNA induced E7-specific CTL and also conveyed protection against E7-positive syngeneic tumor cells. No transforming activity of E7SH DNA in NIH3T3 cells was detected, as determined by focus formation, induction of S-phase under conditions of serum deprivation and degradation of endogenous pRB. Our results suggest that DNA shuffling may become a promising concept for DNA-based anti-cancer vaccines.

Chimeric virus-like particles of the human papillomavirus type 16 (HPV 16) as a prophylactic and therapeutic vaccine.

Infection by certain human papillomaviruses (HPV), most notably HPV types 16 and 18, is the major risk factor for cervical cancer. Worldwide, this disease represents the second most frequent malignant tumor in women; thus, there is urgent need for efficient therapy and prevention. The natural history of cervical cancer and its precursors (cervical intraepithelial neoplasias), as well as animal experiments, strongly suggest that the immune system controls both the primary infection (by neutralizing antibodies directed against the major structural protein L1) and the progression of the disease (via cytotoxic T cells specific for the viral oncoproteins expressed in transformed cells, e.g., E7). By the expression of an HPV 16 L1E7 fusion protein, we have generated chimeric virus-like particles (CVLP). Immunization of mice with CVLPs induces neutralizing antibodies directed against L1 virus-like particles (devoid of the E7 portion) and E7-specific T cells as measured in vitro. Vaccinated animals are protected against tumor growth following inoculation of syngeneic HPV 16-transformed cells. In addition, we observed a therapeutic effect of vaccination on pre-existing tumors. This data allowed us to conclude that CVLPs are suitable for prevention and therapy of HPV infection. A vaccine based on HPV 16 L1E7 CVLPs is currently under development.

Immune response to human papillomavirus 16 L1E7 chimeric virus-like particles: induction of cytotoxic T cells and specific tumor protection.

Expression of human papillomavirus type 16 (HPV 16) fusion proteins LI deltaCE7(1-55) and LI deltaCE7(1-60) (carboxy-terminal deletion of LI replaced by 55 or 60 amino-terminal amino acids of E7) leads to formation of chimeric papillomavirus-like particles (CVLPs). After "infection" of cells by CVLPs, the chimeric proteins can be detected in the cytosol and the endoplasmic reticulum (ER), suggesting that they are intracellularly processed via the MHC class I pathway and, therefore, able to activate cytotoxic T lymphocytes (CTLs). To investigate the cytotoxic immune response against HPV 16 LI deltaCE7(1-60) and LI deltaCE7(1-55) CVLPs, we immunized C57Bl/6 mice with various CVLP doses without adjuvant. Two weeks after immunization, spleen cells were prepared and stimulated in vitro using HPV 16 E7-expressing transfectants of the tumor cell line RMA. In 51Cr-release cytotoxicity assays, spleen cells of mice vaccinated with LI deltaCE7(1-60) CVLPs specifically lysed the RMA-E7 transfectants as well as RMA cells loaded with the peptide E7(49-57), which represents an H2-Db-restricted CTL epitope. This demonstrates that CVLPs induce an E7-specific CTL response in mice in the absence of an adjuvant. Furthermore, immunization with CVLPs prevented outgrowth of E7-expressing tumor cells even if inoculation of cells was performed 2 weeks before vaccination. We conclude from our data that CVLPs show promise for therapy of HPV-associated lesions.

Priming of cytotoxic T lymphocytes by five heat-aggregated antigens in vivo: conditions, efficiency, and relation to antibody responses.

Mice were immunized i.p. with soluble or heat-denatured protein antigens [ovalbumin, beta-galactosidase, or recombinant E7 protein of human papilloma virus type 16 (HBV)]. Heat-denatured (100 degrees C) preparations of these proteins were able to induce cytotoxic T lymphocytes (CTL) that recognize cells expressing the respective genes, whereas native protein was either inefficient or required up to 30-fold higher doses. If the heat-treated proteins were separated into aggregated and soluble fractions by ultracentrifugation, only the aggregated fractions were able to induce specific CTL; this is probably because of the easier access to one of the major histocompatibility complex class I loading pathways for exogenous antigen. Addition of the adjuvant aluminium hydroxide (alum) to aggregated proteins abolished their ability to induce CTL; thus, a condition leading to a strong antibody response appeared to inhibit CTL induction. Interestingly, immunization with heat-denatured ovalbumin plus alum increased the IgM/IgG1 ratio compared to immunization with native ovalbumin and alum. Immunization of B6 mice transgenic for an HLA-A2/H-2K(b) hybrid gene with heat-denatured, recombinant HPV 16-E7 protein induced D(b)-restricted CTL specific for the peptide 49-57 of E7, indicating that this epitope is immunodominant over any A2-restricted E7 epitope in these mice. A whole influenza virus preparation heated to 100 degrees C or even autoclaved was still able to induce virus-specific CTL and BALB/c spleen cells heated to 100 degrees C could still cross-prime minor H-specific CTL in B6 mice, although with lower efficiency than fresh spleen cells. Thus, aggregated proteins can be considered as components for future vaccines.

Influences of transporter associated with antigen processing (TAP) on the repertoire of peptides associated with the endoplasmic reticulum-resident stress protein gp96.

The endoplasmic reticulum (ER)-resident stress protein gp96 induces protective immunity and specific cytotoxic T lymphocyte (CTL) responses against antigens expressed in those cells it has been isolated from. This ability is based on peptides associated with gp96. Because gp96 is located inside the ER, our experiments address the question whether or not the repertoire of peptides associated with gp96 is influenced by the transporter associated with antigen processing (TAP). For this purpose, gp96 was isolated from cells with and without a TAP defect and used for immunization of mice. We found that for some antigens the association of peptides with gp96 required functional TAP molecules, whereas the association of peptides from other antigens was TAP independent. In the case of a TAP-dependent association of peptides with gp96, our results prove that peptide binding by gp96 in vivo occurs inside the ER and is not an artifact induced by cell lysis during the gp96 purification. The finding that some antigens can also associate with gp96 in the absence of functional TAP molecules indicates that the repertoire of peptides bound by gp96 truly reflects the entire repertoire of peptides present inside the ER and not only those peptides transported by TAP. These results, together with the earlier finding that the gp96 peptide repertoire is independent of the major histocompatibility complex molecules expressed by the cell gp96 is isolated from, give the theoretical foundation for the ability of gp96 to induce CTL responses against all kinds of intracellular antigens.

Cross-priming of minor histocompatibility antigen-specific cytotoxic T cells upon immunization with the heat shock protein gp96.

Vaccination of mice with heat shock proteins isolated from tumor cells induces immunity to subsequent challenge with those tumor cells the heat shock protein was isolated from but not with other tumor cells (Udono, H., and P.K. Srivastava. 1994. J. Immunol. 152:5398-5403). The specificity of this immune response is caused by tumor-derived peptides bound to the heat shock proteins (Udono., H., and P.K. Srivastava. 1993. J. Exp. Med. 178:1391-1396). Our experiments show that a single immunization with the heat shock protein gp96 isolated from beta-galactosidase (beta-gal) expressing P815 cells (of DBA/2 origin) induces cytotoxic T lymphocytes (CTLs) specific for beta-gal, in addition to minor H antigens expressed by these cells. CTLs can be induced in mice that are major histocompatibility complex (MHC) identical to the gp96 donor cells (H-2d) as well as in mice with a different MHC (H-2b). Thus gp96 is able to induce "cross priming" (Matzinger, P., and M.J. Bevan. 1977. Cell. Immunol. 33:92-100), indicating that gp96-associated peptides are not limited to the MHC class I ligands of the gp96 donor cell. Our data confirm the notion that samples of all cellular antigens presentable by MHC class I molecules are represented by peptides associated with gp96 molecules of that cell, even if the fitting MHC molecule is not expressed. In addition, we extend previous reports on the in vivo immunogenicity of peptides associated gp96 molecules to two new groups of antigens, minor H antigens, and proteins expressed in the cytosol.

MHC/peptide binding studies indicate hierarchy of anchor residues.

MHC class I molecules present octa- or nonapeptides derived from cellular proteins. Such peptides adhere to strict rules, which are individual to each MHC allele. Synthetic peptides conforming to these rules or peptides being at variance at critical residues were assayed for binding to MHC class I molecules. The binding assay employed the peptide-induced stabilization of MHC molecules of RMA-S cells. The data indicate that most proline-free peptides conforming to the allele-specific motifs of Kb or Db bind to the respective molecules, whereas peptides missing only one of the two allele-specific anchor residues lost their capacity to stabilize class I molecules on RMA-S cells. The residues allowed at anchor positions of the Kb motif are not equal in their binding efficiency and can be ordered in a hierarchic row. Residues at nonanchor positions may also influence efficiency of peptide binding or may require deviations from the standard peptide length.

Both human and mouse cells expressing H-2Kb and ovalbumin process the same peptide, SIINFEKL.

HeLa cells, derived from a human cervix carcinoma line, were transfected with a mouse MHC class I gene, H-2Kb, and chicken ovalbumin. H-2Kb-restricted cytotoxic mouse T cells specific for ovalbumin recognized the double-transfected human cells with similar efficiency as ovalbumin-transfected EL4 mouse thymoma cells (H-2b). The naturally processed ovalbumin T cell epitope was eluted from H-2Kb molecules from double-transfected HeLa cells and was biochemically compared to a synthetic peptide, SIINFEKL, known to be the natural Kb ligand of ovalbumin-transfected H-2b mouse cells. The results indicate that the ovalbumin-derived Kb-ligand of double-transfected HeLa cells is also SIINFEKL. Thus, both human cervix carcinoma cells and mouse thymoma cells expressing Kb and ovalbumin process the same octapeptide. Together with previous data, derived by comparing Kb ligands of unknown sequences from both human and mouse cells expressing Kb, it can be concluded that both mouse and human cells are capable of processing the same ligands for mouse MHC class I molecules. Hence, the general specificity of the peptide-generating mechanism for class I ligands is apparently conserved between evolutionary distant species.

Identification and quantification of a naturally presented peptide as recognized by cytotoxic T lymphocytes specific for an immunogenic tumor variant.

The target antigen recognized by H-2Kd-restricted cytotoxic T lymphocytes (CTLs) specific for a mutagen-induced antigen on DBA/2-derived tumor P815 was identified as the product of a normal cellular gene encompassing a point mutation. Using synthetic peptides, the epitope recognized by these CTLs was narrowed down to be contained within the undecamer KYQAVTTTLEE, incorporating the point mutation. The allele-specific peptide motif for H-2Kd molecules allowed us to predict the peptide naturally presented by the tumor cells to be the nonamer KYQAVTTTL. Isolation of the natural tum(-)-specific peptide from P198.3 tumor cells and biochemical comparison with the synthetic nonamer confirmed the prediction. This natural nonapeptide is represented by approximately 100 copies per tumor cell.

On the nature of peptides involved in T cell alloreactivity.

The strong reaction of T cells against foreign major histocompatibility complex (MHC) antigens, commonly termed "alloreactivity", is not only a nuisance for clinical organ transplantation; it also remains a puzzling question for immunologists. By making use of recent technical developments, alloreactive T cells nominally directed against a mutation in a single MHC class I molecule were found to fall into several major categories. One is recognizing peptides whose occurrence is dependent on one particular MHC allele, another is recognizing peptides supported by several MHC alleles, and a third is recognizing peptides occurring independently of MHC alleles. In a fourth category, the binding to MHC of any of a broad range of peptides appears sufficient. In addition, there are T cells for which no peptide involvement could be detected at all. Even within these categories, the heterogeneity of T cells is considerable: among 16 Kb-reactive T cells analyzed, 15 different modes of reactions were found.

Characterization of naturally occurring minor histocompatibility peptides including H-4 and H-Y.

Minor histocompatibility (H) antigens can be peptides derived from cellular proteins that are presented on the cell surface by major histocompatibility complex (MHC) class I molecules. This is similar to viral antigens, because in both cases cytotoxic T lymphocytes (CTLs) recognize artificially produced peptides loaded on target cells. Naturally processed minor H peptides were found to be similar to those artificial CTL-epitopes, as far as size and hydrophobicity is concerned. The peptides studied were isolated from a transfectant that expressed a model CTL-defined antigen, beta-galactosidase, from male cells that express H-Y, which has been known operationally since 1955, and from cells that express H-4, known since 1961.