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Cancer Immunology, Immunotherapy
Published in: Cancer Immunology, Immunotherapy 8/2005

01-08-2005 | Review

Tumor antigen-specific T helper cells in cancer immunity and immunotherapy

Authors: K. L. Knutson, M. L. Disis

Published in: Cancer Immunology, Immunotherapy | Issue 8/2005

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Abstract

Historically, cancer-directed immune-based therapies have focused on eliciting a cytotoxic T cell (CTL) response, primarily due to the fact that CTL can directly kill tumors. In addition, many putative tumor antigens are intracellular proteins, and CTL respond to peptides presented in the context of MHC class I which are most often derived from intracellular proteins. Recently, increasing importance is being given to the stimulation of a CD4+ T helper cell (Th) response in cancer immunotherapy. Th cells are central to the development of an immune response by activating antigen-specific effector cells and recruiting cells of the innate immune system such as macrophages and mast cells. Two predominant Th cell subtypes exist, Th1 and Th2. Th1 cells, characterized by secretion of IFN-γ and TNF-α, are primarily responsible for activating and regulating the development and persistence of CTL. In addition, Th1 cells activate antigen-presenting cells (APC) and induce limited production of the type of antibodies that can enhance the uptake of infected cells or tumor cells into APC. Th2 cells favor a predominantly humoral response. Particularly important during Th differentiation is the cytokine environment at the site of antigen deposition or in the local lymph node. Th1 commitment relies on the local production of IL-12, and Th2 development is promoted by IL-4 in the absence of IL-12. Specifically modulating the Th1 cell response against a tumor antigen may lead to effective immune-based therapies. Th1 cells are already widely implicated in the tissue-specific destruction that occurs during the pathogenesis of autoimmune diseases, such as diabetes mellitus and multiple sclerosis. Th1 cells directly kill tumor cells via release of cytokines that activate death receptors on the tumor cell surface. We now know that cross-priming of the tumor-specific response by potent APC is a major mechanism of the developing endogenous immune response; therefore, even intracellular proteins can be presented in the context of MHC class II. Indeed, recent studies demonstrate the importance of cross-priming in eliciting CTL. Many vaccine strategies aim to stimulate the Th response specific for a tumor antigen. Early clinical trials have shown that focus on the Th effector arm of the immune system can result in significant levels of both antigen-specific Th cells and CTL, the generation of long lasting immunity, and a Th1 phenotype resulting in the development of epitope spreading.
Literature
1.
Surman DR, Dudley ME, Overwijk WW, Restifo NP (2000) Cutting edge: CD4+ T cell control of CD8+ T cell reactivity to a model tumor antigen. J Immunol 164:562–565
2.
Cohen PA, Peng L, Plautz GE, Kim JA, Weng DE, Shu S (2000) CD4+ T cells in adoptive immunotherapy and the indirect mechanism of tumor rejection. Crit Rev Immunol 20:17–56PubMed
3.
Kalams SA, Walker BD (1998) The critical need for CD4 help in maintaining effective cytotoxic T lymphocyte responses. J Exp Med 188:2199–2204CrossRef
4.
Ossendorp F, Toes RE, Offringa R, van der Burg SH, Melief CJ (2000) Importance of CD4(+) T helper cell responses in tumor immunity. Immunol Lett 74:75–79CrossRef
5.
Nishimura T, Iwakabe K, Sekimoto M, Ohmi Y, Yahata T, Nakui M, Sato T, Habu S, Tashiro H, Sato M, Ohta A (1999) Distinct role of antigen-specific T helper type 1 (Th1) and Th2 cells in tumor eradication in vivo. J Exp Med 190:617–627CrossRefPubMed
6.
Hung K, Hayashi R, Lafond-Walker A, Lowenstein C, Pardoll D, Levitsky H (1998) The central role of CD4(+) T cells in the antitumor immune response. J Exp Med 188:2357–2368CrossRefPubMed
7.
Fallarino F, Grohmann U, Bianchi R, Vacca C, Fioretti MC, and Puccetti P (2000) Th1 and Th2 cell clones to a poorly immunogenic tumor antigen initiate CD8+ T cell-dependent tumor eradication in vivo. J Immunol 165:5495–5501
8.
Lespagnard L, Gancberg D, Rouas G, Leclercq G, de Saint-Aubain Somerhausen N, Di Leo A, Piccart M, Verhest A, Larsimont D (1999) Tumor-infiltrating dendritic cells in adenocarcinomas of the breast: a study of 143 neoplasms with a correlation to usual prognostic factors and to clinical outcome. Int J Cancer 84:309–314
9.
Altomonte M, Fonsatti E, Visintin A, Maio M (2003) Targeted therapy of solid malignancies via HLA class II antigens: a new biotherapeutic approach?. Oncogene 22:6564–6569CrossRef
10.
Yazawa T, Kamma H, Fujiwara M, Matsui M, Horiguchi H, Satoh H, Fujimoto M, Yokoyama K, Ogata T (1999) Lack of class II transactivator causes severe deficiency of HLA-DR expression in small cell lung cancer. J Pathol 187:191–199CrossRef
11.
Zuk JA, Walker RA (1988) HLA class II sublocus expression in benign and malignant breast epithelium. J Pathol 155:301–309
12.
Lucin K, Iternicka Z, Jonjic N (1994) Prognostic significance of T-cell infiltrates, expression of beta 2-microglobulin and HLA-DR antigens in breast carcinoma. Pathol Res Pract 190:1134–1140
13.
Concha A, Ruiz-Cabello F, Cabrera T, Nogales F, Collado A, Garrido F (1995) Different patterns of HLA-DR antigen expression in normal epithelium, hyperplastic and neoplastic malignant lesions of the breast. Eur J Immunogenet 22:299–310
14.
Trieb K, Lechleitner T, Lang S, Windhager R, Kotz R, Dirnhofer S (1998) Evaluation of HLA-DR expression and T-lymphocyte infiltration in osteosarcoma. Pathol Res Pract 194:679–684
15.
Wroblewski JM, Bixby DL, Borowski C, Yannelli JR (2001) Characterization of human non-small cell lung cancer (NSCLC) cell lines for expression of MHC, co-stimulatory molecules and tumor-associated antigens. Lung Cancer 33:181–194CrossRef
16.
Nistico P, Tecce R, Giacomini P, Cavallari A, D’Agnano I, Fisher PB, Natali PG (1990) Effect of recombinant human leukocyte, fibroblast, and immune interferons on expression of class I and II major histocompatibility complex and invariant chain in early passage human melanoma cells. Cancer Res 50:7422–7429
17.
Giuntoli RL, Lu J II, Kobayashi H, Kennedy R, Celis E (2002) Direct costimulation of tumor-reactive CTL by helper T cells potentiate their proliferation, survival, and effector function. Clin Cancer Res 8:922–931
18.
Cheever MA, Chen W (1997) Therapy with cultured T cells: principles revisited. Immunol Rev 157:177–194
19.
Fruh K, Yang Y (1999) Antigen presentation by MHC class I and its regulation by interferon gamma. Curr Opin Immunol 11:76–81CrossRefPubMed
20.
Gao FG, Khammanivong V, Liu WJ, Leggatt GR, Frazer IH, Fernando GJ (2002) Antigen-specific CD4+ T-cell help is required to activate a memory CD8+ T cell to a fully functional tumor killer cell. Cancer Res 62:6438–6441
21.
Topalian SL, Rivoltini L, Mancini M, Ng J, Hartzman RJ, Rosenberg SA (1994) Melanoma-specific CD4+ T lymphocytes recognize human melanoma antigens processed and presented by Epstein-Barr virus-transformed B cells. Int J Cancer 58:69–79
22.
Perez SA, Sotiropoulou PA, Sotiriadou NN, Mamalaki A, Gritzapis AD, Echner H, Voelter W, Pawelec G, Papamichail M, and Baxevanis CN (2002) HER-2/neu-derived peptide 884–899 is expressed by human breast, colorectal and pancreatic adenocarcinomas and is recognized by in-vitro-induced specific CD4(+) T cell clones. Cancer Immunol Immunother 50:615–624CrossRef
23.
Schattner EJ, Mascarenhas J, Bishop J, Yoo DH, Chadburn A, Crow MK, Friedman SM (1996) CD4+ T-cell induction of Fas-mediated apoptosis in Burkitt’s lymphoma B cells. Blood 88:1375–1382
24.
Thomas WD, Hersey P (1998) TNF-related apoptosis-inducing ligand (TRAIL) induces apoptosis in Fas ligand-resistant melanoma cells and mediates CD4 T cell killing of target cells. J Immunol 161:2195–2200
25.
Echchakir H, Bagot M, Dorothee G, Martinvalet D, Le Gouvello S, Boumsell L, Chouaib S, Bensussan A, Mami-Chouaib F (2000) Cutaneous T cell lymphoma reactive CD4+ cytotoxic T lymphocyte clones display a Th1 cytokine profile and use a fas-independent pathway for specific tumor cell lysis. J Invest Dermatol 115:74–80CrossRef
26.
Dranoff G, Jaffee E, Lazenby A, Golumbek P, Levitsky H, Brose K, Jackson V, Hamada H, Pardoll D, Mulligan RC (1993) Vaccination with irradiated tumor cells engineered to secrete murine granulocyte-macrophage colony-stimulating factor stimulates potent, specific, and long-lasting anti-tumor immunity. Proc Natl Acad Sci USA 90:3539–3543
27.
Tsung K, Dolan JP, Tsung YL, Norton JA (2002) Macrophages as effector cells in interleukin 12-induced T cell-dependent tumor rejection. Cancer Res 62:5069–5075PubMed
28.
Jonuleit H, Schmitt E, Kakirman H, Stassen M, Knop J, Enk AH (2002) Infectious tolerance: human CD25(+) regulatory T cells convey suppressor activity to conventional CD4(+) T helper cells. J Exp Med 196:255–260CrossRef
29.
Brown JH, Jardetzky TS, Gorga JC, Stern LJ, Urban RG, Strominger JL, Wiley DC (1993) Three-dimensional structure of the human class II histocompatibility antigen HLA-DR1. Nature 364:33–39CrossRefPubMed
30.
Stern LJ, Brown JH, Jardetzky TS, Gorga JC, Urban RG, Strominger JL, Wiley DC (1994) Crystal structure of the human class II MHC protein HLA-DR1 complexed with an influenza virus peptide. Nature 368:215–221CrossRefPubMed
31.
Chicz RM, Urban RG, Gorga JC, Vignali DA, Lane WS, Strominger JL (1993) Specificity and promiscuity among naturally processed peptides bound to HLA-DR alleles. J Exp Med 178:27–47CrossRef
32.
Reece JC, Geysen HM, Rodda SJ (1993) Mapping the major human T helper epitopes of tetanus toxin. The emerging picture. J Immunol 151:6175–6184
33.
Bian H, Reidhaar-Olson JF, Hammer J (2003) The use of bioinformatics for identifying class II-restricted T-cell epitopes. Methods 29:299–309CrossRef
34.
Rammensee H, Bachmann J, Emmerich NP, Bachor OA, Stevanovic S (1999) SYFPEITHI: database for MHC ligands and peptide motifs. Immunogenetics 50:213–219CrossRefPubMed
35.
Feller DC, de la Cruz VF (1991) Identifying antigenic T-cell sites. Nature 349:720–721CrossRef
36.
Disis ML, Cheever MA (1998) HER-2/neu oncogenic protein: issues in vaccine development. Crit Rev Immunol 18:37–45
37.
Disis ML, Gooley TA, Rinn K, Davis D, Piepkorn M, Cheever MA, Knutson KL, Schiffman K (2002) Generation of T-cell immunity to the HER-2/neu protein after active immunization with HER-2/neu Peptide-based vaccines. J Clin Oncol 20:2624–2632CrossRefPubMed
38.
Knutson KL, Schiffman K, Disis ML (2001) Immunization with a HER-2/neu helper peptide vaccine generates HER- 2/neu CD8 T-cell immunity in cancer patients. J Clin Invest 107:477–484
39.
Southwood S, Sidney J, Kondo A, del Guercio MF, Appella E, Hoffman S, Kubo RT, Chesnut RW, Grey HM, Sette A (1998) Several common HLA-DR types share largely overlapping peptide binding repertoires. J Immunol 160:3363–3373
40.
Honeyman MC, Brusic V, Stone NL, Harrison LC (1998) Neural network-based prediction of candidate T-cell epitopes. Nat Biotechnol 16:966–969
41.
Schroers R, Shen L, Rollins L, Xiao Z, Sonderstrup G, Slawin K, Huang XF, Chen SY (2003) Identification of MHC class II-restricted T-cell epitopes in prostate-specific membrane antigen. Clin Cancer Res 9:3260–3271
42.
Schroers R, Shen L, Rollins L, Rooney CM, Slawin K, Sonderstrup G, Huang XF, Chen SY (2003) Human telomerase reverse transcriptase-specific T-helper responses induced by promiscuous major histocompatibility complex class II-restricted epitopes. Clin Cancer Res 9:4743–4755PubMed
43.
Consogno G, Manici S, Facchinetti V, Bachi A, Hammer J, Conti-Fine BM, Rugarli C, Traversari C, Protti MP (2003) Identification of immunodominant regions among promiscuous HLA-DR-restricted CD4+ T-cell epitopes on the tumor antigen MAGE-3. Blood 101:1038–1044CrossRefPubMed
44.
Hammer J, Bono E, Gallazzi F, Belunis C, Nagy Z, Sinigaglia F (1994) Precise prediction of major histocompatibility complex class II-peptide interaction based on peptide side chain scanning. J Exp Med 180:2353–2358CrossRef
45.
Mallios RR (2003) A consensus strategy for combining HLA-DR binding algorithms. Hum Immunol 64:852–856CrossRef
46.
Salazar LG, Fikes J, Southwood S, Ishioka G, Knutson KL, Gooley TA, Schiffman K, Disis ML (2003) Immunization of cancer patients with HER-2/neu-derived peptides demonstrating high-affinity binding to multiple class II alleles. Clin Cancer Res 9:5559–5565
47.
Gross DA, Graff-Dubois S, Opolon P, Cornet S, Alves P, Bennaceur-Griscelli A, Faure O, Guillaume P, Firat H, Chouaib S, Lemonnier FA, Davoust J, Miconnet I, Vonderheide RH, Kosmatopoulos K (2004) High vaccination efficiency of low-affinity epitopes in antitumor immunotherapy. J Clin Invest 113:425–433CrossRefPubMed
48.
Campi G, Crosti M, Consogno G, Facchinetti V, Conti-Fine BM, Longhi R, Casorati G, Dellabona P, Protti MP (2003) CD4(+) T cells from healthy subjects and colon cancer patients recognize a carcinoembryonic antigen-specific immunodominant epitope. Cancer Res 63:8481–8486PubMed
49.
Gnjatic S, Atanackovic D, Jager E, Matsuo M, Selvakumar A, Altorki NK, Maki RG, Dupont B, Ritter G, Chen YT, Knuth A, Old LJ (2003) Survey of naturally occurring CD4+ T cell responses against NY-ESO-1 in cancer patients: correlation with antibody responses. Proc Natl Acad Sci USA 100:8862–8867CrossRef
50.
Mandic M, Almunia C, Vicel S, Gillet D, Janjic B, Coval K, Maillere B, Kirkwood JM, Zarour HM (2003) The alternative open reading frame of LAGE-1 gives rise to multiple promiscuous HLA-DR-restricted epitopes recognized by T-helper 1-type tumor-reactive CD4+ T cells. Cancer Res 63:6506–6515PubMed
51.
Kobayashi H, Wood M, Song Y, Appella E, Celis E (2000) Defining promiscuous MHC class II helper T-cell epitopes for the HER2/neu tumor antigen. Cancer Res 60:5228–5236PubMed
52.
Knutson KL, Schiffman K, Cheever MA, Disis ML (2002) Immunization of cancer patients with a HER-2/neu, HLA-A2 peptide, p369–377, results in short-lived peptide-specific immunity. Clin Cancer Res 8:1014–1018
53.
Zeng G, Li Y, El-Gamil M, Sidney J, Sette A, Wang RF, Rosenberg SA, Robbins PF (2002) Generation of NY-ESO-1-specific CD4+ and CD8+ T cells by a single peptide with dual MHC class I and class II specificities: a new strategy for vaccine design. Cancer Res 62:3630–3635
54.
Gillogly ME, Kallinteris NL, Xu M, Gulfo JV, Humphreys RE, Murray JL (2004) Ii-Key/HER-2/neu MHC class-II antigenic epitope vaccine peptide for breast cancer. Cancer Immunol Immunother 53:490–496CrossRef
55.
Lu J, Wettstein PJ, Higashimoto Y, Appella E, Celis E (2001) TAP-independent presentation of CTL epitopes by Trojan antigens. J Immunol 166:7063–7071
56.
Sercarz EE, Lehmann PV, Ametani A, Benichou G, Miller A, and Moudgil K (1993) Dominance and crypticity of T cell antigenic determinants. Annu Rev Immunol 11:729–766CrossRef
57.
Nanda NK and Sercarz EE (1995) Induction of anti-self-immunity to cure cancer. Cell 82:13–17CrossRef
58.
Vanderlugt CL and Miller SD (2002) Epitope spreading in immune-mediated diseases: implications for immunotherapy. Nat Rev Immunol 2:85–95CrossRef
59.
Sercarz EE (2000) Driver clones and determinant spreading. J Autoimmun 14:275–277CrossRef
60.
Disis ML, Goodell V, Schiffman K, Knutson KL (2004) Humoral epitope spreading following immunization with a HER-2/neu peptide based vaccine in cancer patients. J Clin Immunol 24(5):571–578CrossRef
61.
Hueber W, Utz PJ, Steinman L, Robinson WH (2002) Autoantibody profiling for the study and treatment of autoimmune disease. Arthritis Res 4:290–295CrossRef
62.
Butterfield LH, Ribas A, Dissette VB, Amarnani SN, Vu HT, Oseguera D, Wang HJ, Elashoff RM, McBride WH, Mukherji B, Cochran AJ, Glaspy JA, Economou JS (2003) Determinant spreading associated with clinical response in dendritic cell-based immunotherapy for malignant melanoma. Clin Cancer Res 9:998–1008PubMed
Metadata
Title
Tumor antigen-specific T helper cells in cancer immunity and immunotherapy
Authors
K. L. Knutson
M. L. Disis
Publication date
01-08-2005
Publisher
Springer-Verlag
Published in
Cancer Immunology, Immunotherapy / Issue 8/2005
Print ISSN: 0340-7004
Electronic ISSN: 1432-0851
DOI
https://doi.org/10.1007/s00262-004-0653-2

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