Cancer vaccine targeting CD4+ T cells

Cancer vaccine targeting CD4+ T cells is a type of vaccine used to treat existing cancer. Cancerous cells usually cannot be recognized by the human immune system, and therefore cannot be destroyed. Some researchers state that cancer can be treated by increasing the response of T cells, especially CD4+ T cells, to cancerous cells through cancer vaccine injection.

Mechanism

CD4+ T cells promote anti-tumor immunity through numerous mechanisms, including enhancing antigen presentation, co-stimulation, T cell homing, T cell activation, and effector function. These effects are mediated at sites of T cell priming and at the tumor microenvironment. Several cancer vaccine approaches induce durable CD4+ T cell responses and have promising clinical activity. This kind of vaccine can be realized by DNA recombinant fusion proteins expressed in E. coli. The protein MAGE-3 has already been used in lung cancer treatment and has received positive feedback.

Advantages

Recent studies show the crucial role of proliferating activated effector memory Th1 CD4+ T cells in effective anti-tumor immunity and reveal that CD4+ T cells induce more durable immune-mediated tumor control than CD8+ T cells. Even though CD4+ T cells are known to play a central role in regulating virtually all antigen-specific immune responses, the role they play in immune responses to tumor antigens has not been widely studied compared to that of CD8+ T cells. This is due to the fact that most tumors are positive for MHC class I but negative for MHC class II, and CD8+ cytotoxic T lymphocytes (CTLs) are able to induce tumor killing upon direct recognition of peptide antigens presented by the tumor's MHC class I molecules.

This preference has been bolstered by numerous adoptive transfer studies in which CD8+ T cell lines and CD8+ clones specific for tumor antigens (that have been stimulated in vitro) can mediate anti-tumor immunity when transferred back into tumor-bearing hosts;[1] furthermore, recent reports suggest that immunization (using either adjuvant or dendritic cells with pure tumor peptides) can result in productive anti-tumor immunity that is restricted by MHC class I.[2][3][4][5]

Finally, elimination of CD8+ T cells from mice at least partially abrogates anti-tumor immunity induced by most cancer vaccines.[6][7][8][9] Similarly, a critical role for CD4+ T cells in induced anti-tumor immunity has been consistently demonstrated in vaccine/challenge experiments employing antibody-mediated depletion of CD4+ T cells or using CD4-knockout mice. Abrogation of anti-tumor immunity in CD4-knockout mice or mice depleted of CD4+ T cells has been demonstrated in cases of cell-based vaccines, recombinant viral vaccines and recombinant bacterial vaccines. While most adoptive transfer experiments have been performed with tumor-specific CD8+ T cells, activated CD4+ T cell clones specific for the murine leukemia virus have been demonstrated to confer systemic anti-tumor immunity upon transfer into tumor-bearing hosts.[10]

Experiments

CD4+ T cells has already been successfully induced in non-small-cell lung carcinoma patients vaccinated with MAGE-3 recombinant protein. Two cohorts were analyzed: one receiving MAGE-3 protein alone, and one receiving MAGE-3 protein with adjuvant AS028. Of nine patients in the first cohort, three developed marginal antibody titers and another one had a CD8+ T cell response to HLA-A2-restricted peptide MAGE-3 271–279.

In contrast, of eight patients from the second cohort vaccinated with MAGE-3 protein and adjuvant, seven developed high-titered antibodies to MAGE-3, and four had a strong concomitant CD4+ T cell response to HLA-DP4-restricted peptide 243–258. One patient simultaneously developed CD8+ T cells to HLA-A1-restricted peptide 168–176. The novel monitoring methodology used in this MAGE-3 study established that protein vaccination induces clear CD4+ T cell responses for further evaluating integrated immune responses in vaccine settings and for optimizing these responses for clinical benefit.

Studies have indicated that CD4+ T cells in vivo have the capacity to enhance CD8+ T cell activity and, most importantly, help to maintain the immune response for sustained periods of time.[11] Therefore, it seems likely that optimal anti-tumor activity can only be achieved if both CD4+ and CD8+ tumor-specific T cells are induced.[12] The inclusion of CD4+ epitopes into MAGE-3 vaccination studies has recently been facilitated by the identification of several HLA-DR-restricted and one HLA-DP4-restricted epitope.

Clinical trials

Clinical vaccination studies using full-length recombinant proteins have the advantage that this form of antigen potentially includes the full range of epitopes for CD4+ and CD8+ T T cells. In addition, it is likely that protein vaccination leads to presentation of epitopes in the context of various HLA alleles, and therefore this type of vaccine should be applicable to any patient regardless of HLA restriction.

To date, only one clinical study using MAGE-3 protein as a vaccine has been reported.[13] Using a cloning approach, one patient was shown to have a CD4+ T cell response to HLA-DR1-restricted peptide 267–282.

Future work

At this point, not enough data has been collected from human trials. As a result, the side effects or the long-term results are still unknown. In addition, future work should further optimize vaccine adjuvants and combination therapies incorporating helper peptide vaccines.

See also

List of distinct cell types in the adult human body

References

  1. Riddell, S.R. and Greenberg, P.D., 1995. Principles for adoptive T cell therapy of human viral diseases. Annual review of immunology, 13(1), pp.545-586.doi:10.1146/annurev.iy.13.040195.002553
  2. Feltkamp, M.C., Smits, H.L., Vierboom, M.P., Minnaar, R.P., De Jongh, B.M., Drijfhout, J.W., Schegget, J.T., Melief, C.J. and Kast, W.M., 1993. Vaccination with cytotoxic T lymphocyte epitope‐containing peptide protects against a tumor induced by human papillomavirus type 16‐transformed cells. European journal of immunology, 23(9), pp.2242-2249.doi:10.1002/eji.1830230929
  3. Noguchi, Y., Richards, E.C., Chen, Y.T. and Old, L.J., 1995. Influence of interleukin 12 on p53 peptide vaccination against established Meth A sarcoma. Proceedings of the National Academy of Sciences, 92(6), pp.2219-2223.doi:10.1073/pnas.92.6.2219
  4. Mandelboim, O., Vadai, E., Fridkin, M., Katz-Hillel, A., Feldman, M., Berke, G. and Eisenbach, L., 1995. Regression of established murine carcinoma metastases following vaccination with tumour-associated antigen peptides. Nature medicine, 1(11), pp.1179-1183.doi:10.1038/nm1195-1179
  5. Mayordomo, J.I., Zorina, T., Storkus, W.J., Zitvogel, L., Celluzzi, C., Falo, L.D., Melief, C.J., Ildstad, S.T., Kast, W.M., Deleo, A. and Lotze, M.T., 1995. Bone marrow-derived dendritic cells pulsed with synthetic tumour peptides elicit protective and therapeutic antitumour immunity. Nature medicine, 1(12), p.1297.doi:10.1038/nm1295-1297
  6. Fearon, E.R., Pardoll, D.M., Itaya, T., Golumbek, P., Levitsky, H.I., Simons, J.W., Karasuyama, H., Vogelstein, B. and Frost, P., 1990. Interleukin-2 production by tumor cells bypasses T helper function in the generation of an antitumor response. Cell, 60(3), pp.397-403.doi:10.1016/0092-8674(90)90591-2
  7. Golumbek, P.T., Lazenby, A.J., Levitsky, H.I., Jaffee, L.M., Karasuyama, H., Baker, M. and Pardoll, D.M., 1991. Treatment of established renal cancer by tumor cells engineered to secrete interleukin-4. Science, 254(5032), pp.713-716.doi:10.1126/science.1948050
  8. Dranoff, G., Jaffee, E., Lazenby, A., Golumbek, P., Levitsky, H., Brose, K., Jackson, V., Hamada, H., Pardoll, D. and Mulligan, R.C., 1993. Vaccination with irradiated tumor cells engineered to secrete murine granulocyte-macrophage colony-stimulating factor stimulates potent, specific, and long-lasting anti-tumor immunity. Proceedings of the National Academy of Sciences, 90(8), pp.3539-3543.doi:10.1073/pnas.90.8.3539
  9. Pardoll, D.M. and Topalian, S.L., 1998. The role of CD4+ T cell responses in antitumor immunity. Current opinion in immunology, 10(5), pp.588-594.doi:10.1016/S0952-7915(98)80228-8
  10. Greenberg, P.D., Kern, D.E. and Cheever, M.A., 1985. Therapy of disseminated murine leukemia with cyclophosphamide and immune Lyt-1+, 2-T cells. Tumor eradication does not require participation of cytotoxic T cells. Journal of Experimental Medicine, 161(5), pp.1122-1134.doi:10.1084/jem.161.5.1122
  11. Husmann, L.A. and Bevan, M.J., 1988. Cooperation between helper T cells and cytotoxic T lymphocyte precursors. Annals of the New York Academy of Sciences, 532(1), pp.158-169.doi:10.1111/j.1749-6632.1988.tb36335.x
  12. Fischer, W.H., thor Straten, P., Terheyden, P. and Becker, J.C., 1999. Function and dysfunction of CD4+ T cells in the immune response to melanoma. Cancer Immunology, Immunotherapy, 48(7), pp.363-370.
  13. Marchand, M., Punt, C.J.A., Aamdal, S., Escudier, B., Kruit, W.H.J., Keilholz, U., Håkansson, L., Van Baren, N., Humblet, Y., Mulders, P. and Avril, M.F., 2003. Immunisation of metastatic cancer patients with MAGE-3 protein combined with adjuvant SBAS-2: a clinical report. European Journal of Cancer, 39(1), pp.70-77.doi:10.1016/S0959-8049(02)00479-3
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