The ability to generate, maintain and target clinically-important anti-tumor immunity is critically dependent upon the appropriate presentation of tumor antigenic epitopes to T cells in lymphoid organs, as well as, the tumor itself. Recent evidence from a number of laboratories, including our own, suggests that vaccines may be most effective when they promote a phenomenon termed """"""""epitope spreading"""""""" which involves T cell stimulations in both the vaccine-draining lymph nodes and tumor-draining lymph nodes. Hence, both vaccine site and tumor-associated antigen presenting cells play major roles in the magnitude and effectiveness of such immune responses. The biasing of the type of DC accessed by a vaccine and the number and type of DC infiltrating the tumor lesion, one may theoretically augment """"""""epitope spreading and promote tumor regression and urable anti-tumor immunity. We have recently determined that one may mobilize predominantly lymphoid (CD 11c+/CD1lb-/CD 8a+) or myeloid (CD 11c+CD 1lb+/CD8a-) DC subsets based on the type or combination of mobilizing agents selected. Furthermore, in preliminary experiments we have determined that freshly-prepared lymphoid DC are the predominant producers of IL-12 in the mouse. These lymphoid DC when pulsed with tumor peptide antigens and injected into tumor bearing mice as a vaccine, far outperform myeloid DC in promoting anti-tumor immunity and tumor regression. In the current proposal, we will evaluate the """"""""clinical effects"""""""" of manipulating vaccine-associated and tumor-associated DC subsets on the ability of vaccines to promote efficacious """"""""tumorepitope spreading"""""""" within the CD4+ and CD8+ T cell compartments of tumor-bearing mice. This will be accomplished by application of both in vivo and ex vivo DC-Based Therapeutic Approaches.
Our Specific aims are: (1) Analyze the impact of mobilization and systemic maturation on murine DC subset numbers, phenotype, function, tissue localization, and established tumor growth; (2) Determine the clinical efficacy and mechanism of action of DC subset mobilization on the efficacy of tumor-antigen-based vaccines (peptides, proteins, irradiated tumor cells);(3) Determine the clinical efficacy and mechanism of action of ex vivo purified DC subset therapies in mice bearing tumors; (4) Evaluate the process of """"""""epitope spreading"""""""" in tumor-bearing mice that are mobilized, mobilized and vaccinated, or that receive DC based therapies.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
2R01CA063350-06
Application #
6365041
Study Section
Experimental Therapeutics Subcommittee 1 (ET)
Program Officer
Yovandich, Jason L
Project Start
1996-04-09
Project End
2006-04-30
Budget Start
2001-05-01
Budget End
2002-04-30
Support Year
6
Fiscal Year
2001
Total Cost
$240,192
Indirect Cost
Name
University of Pittsburgh
Department
Dermatology
Type
Schools of Medicine
DUNS #
053785812
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213
Sasaki, Kotaro; Pardee, Angela D; Qu, Yanyan et al. (2009) IL-4 suppresses very late antigen-4 expression which is required for therapeutic Th1 T-cell trafficking into tumors. J Immunother 32:793-802
Sasaki, Kotaro; Zhao, Xi; Pardee, Angela D et al. (2008) Stat6 signaling suppresses VLA-4 expression by CD8+ T cells and limits their ability to infiltrate tumor lesions in vivo. J Immunol 181:104-8
Sasaki, Kotaro; Pardee, Angela D; Okada, Hideho et al. (2008) IL-4 inhibits VLA-4 expression on Tc1 cells resulting in poor tumor infiltration and reduced therapy benefit. Eur J Immunol 38:2865-73
Berhanu, Aklile; Huang, Jian; Watkins, Simon C et al. (2007) Treatment-enhanced CD4+Foxp3+ glucocorticoid-induced TNF receptor family related high regulatory tumor-infiltrating T cells limit the effectiveness of cytokine-based immunotherapy. J Immunol 178:3400-8
Berhanu, Aklile; Huang, Jian; Alber, Sean M et al. (2006) Combinational FLt3 ligand and granulocyte macrophage colony-stimulating factor treatment promotes enhanced tumor infiltration by dendritic cells and antitumor CD8(+) T-cell cross-priming but is ineffective as a therapy. Cancer Res 66:4895-903
Bjorck, P; Coates, P T H; Wang, Z et al. (2005) Promotion of long-term heart allograft survival by combination of mobilized donor plasmacytoid dendritic cells and anti-CD154 monoclonal antibody. J Heart Lung Transplant 24:1118-20
Huang, Jian; Tatsumi, Tomohide; Pizzoferrato, Eva et al. (2005) Nitric oxide sensitizes tumor cells to dendritic cell-mediated apoptosis, uptake, and cross-presentation. Cancer Res 65:8461-70
Bjorck, Pia (2004) Dendritic cells exposed to herpes simplex virus in vivo do not produce IFN-alpha after rechallenge with virus in vitro and exhibit decreased T cell alloreactivity. J Immunol 172:5396-404
Tatsumi, Tomohide; Huang, Jian; Gooding, William E et al. (2003) Intratumoral delivery of dendritic cells engineered to secrete both interleukin (IL)-12 and IL-18 effectively treats local and distant disease in association with broadly reactive Tc1-type immunity. Cancer Res 63:6378-86
Tatsumi, Tomohide; Gambotto, Andrea; Robbins, Paul D et al. (2002) Interleukin 18 gene transfer expands the repertoire of antitumor Th1-type immunity elicited by dendritic cell-based vaccines in association with enhanced therapeutic efficacy. Cancer Res 62:5853-8

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