Immunization with a vaccine that combines the expression of MUC1 and B7 co-stimulatory molecules prolongs the survival of mice and delays the appearance of mouse mammary tumors.

Human epithelial mucin (MUC1) is expressed by many carcinomas, including breast cancer cells. This breast cancer-associated antigen has been widely used for immunotherapy, despite the fact that cellular immune responses to MUC1 are impaired in breast cancer patients and MUC1 transgenic animals. Previously, we found that immunogenicity to MUC1 was also impaired in BALB/c mice injected with a mammary tumor cell line (410.4) expressing human MUC1. We suggested that one reason for its weak immunogenicity was the lack of expression of B7 molecules by 410.4 cells. Recognition of antigenic epitopes in conjunction with MHCI/II by the T-cell receptor without co-stimulation by B7/CD28 association resulted in T-cell anergy. Therefore, we attempted to enhance protective anti-MUC1-specific immunity in mice using B7 co-stimulatory molecules as a component of the MUC1 vaccine. We also compared cell-based with DNA-based vaccination strategies. One group of mice was vaccinated with an irradiated, 410.4 syngeneic mammary tumor cell line co-expressing human MUC1 and CD80 or CD86 co-stimulatory molecules, and a second group of mice was vaccinated with plasmids encoding MUC1 and CD80 or CD86. These mice along with appropriate controls were challenged with mammary tumor cell line 4T1, which expresses MUC1. There were significant inhibition on rates of tumor growth and survival in mice vaccinated with irradiated 410.4/MUC1 cells co-expressing either CD80 or CD86 molecules, compared to non-vaccinated animals. In addition, there were also significant delays in the appearance of measurable tumors and their growth in mice vaccinated by gene-gun immunization with plasmids encoding MUC1 and CD80 or CD86.

Adjuvant-dependent modulation of Th1 and Th2 responses to immunization with beta-amyloid.

The role of adjuvant on the T(h)1 and T(h)2 immune responses to Abeta-immunotherapy (Abeta(42 )peptide) was examined in wild-type mice. Fine epitope analysis with overlapping oligomers of the Abeta(42) sequence identified the 1-15 region as a dominant B cell epitope. The 6-20 peptide was recognized only weakly by antisera from mice administrated with Abeta(42) peptide formulated in complete Freund's adjuvant (CFA), alum or TiterMax Gold (TMG). However, mice immunized with Abeta(42) mixed with QS21 induced a significant antibody response to the 6-20 peptide. The only T cell epitope found was within the 6-28 sequence of Abeta(42). QS21 and CFA induced the strongest humoral response to Abeta, alum was intermediate, and TMG the weakest adjuvant. Analysis of antibody isotypes specific for Abeta indicates that alum induces primarily T(h)2-type immune response, whereas TMG, CFA and QS21 shift the immune responses toward a T(h)1 phenotype. Stimulation of splenocytes from Abeta-immunized mice with Abeta(40) peptide induced strikingly different cytokine expression profiles. QS21 and CFA induced significant IFN-gamma, IL-4 and tumor necrosis factor-alpha expression, whereas alum induced primarily IL-4 production. As T(h)1-type immune responses have been implicated in many autoimmune disorders, whereas T(h)2-type responses have been shown to inhibit autoimmune disease, the choice of adjuvant may be critical for the design of a safe and effective immunotherapy for Alzheimer's disease.