Abstract

It has become increasingly clear that NK cells can promote DC activation and polarization of the subsequent immune response. This project will evaluate, in transplantable and spontaneous murine tumor models, the significance of NK-DC interactions for the generation and function of anti-tumor CTLs and will improve antitumor activity against established MHC+/MHC- tumors by controlling/manipulating these interactions. We hypothesize that activated NK (A-NK) cells, delivered to tumor sites, will kill tumor cells and thereby liberate both mediators of acute inflammation (such as HSP and HMGB1) and antigens which can be taken up by DCs. In addition, contact- and cytokine-dependent cross-talk between DCs and NK cells will further activate both cell types, leading to the generation of polarized DCs with enhanced capability of stimulating Th1-anti tumor responses. This will be evaluated in three animal models: 1) a model tumor antigen expressing system (the MO-5, ovalbumin transfected B16 melanoma). Effective NK /DC interactions will, in this model be evaluated by measuring the number of adoptively transferred ova-specific OT-I (CDS) and OT-II (CD4) cells in tumors, lymph nodes, blood and spleen; 2) The wild-type B16 model and; 3) in the p16INK4a-/-KO model of spontaneous melanoma. Following systemic or local delivery of A-NK cells and DCs, we will vary the cytokine profile in the tumor microenvironment. To achieve this, DCs and NK cells will be transduced with cytokine gene-containing viral vectors to produce various pro-NK and pro-DC cytokines, e.g., IL2, IL18, IFN-alpha and GM-CSF. In addition, the ability of multiple NK/DC injections to ensure continuous stimulation of the afferent limb (and thereby resultant CTL generation) as well as local CTL effector function, will be tested.
Three Specific Aims will be conducted to explore these issues:
Aim 1. Define the in vivo survival of NK cells and DCs as well as their traffic to tumors and lymph nodes following injection different NK/DC ratios into tumor-bearing animals via different routes.
Aim 2. Demonstrate that intratumoral delivery of NK cells and DCs promotes CTL generation and function in transplantable and spontaneous tumor models.;
Aim 3. Enhance NK/DC function in tumors by forced cytokine-gene transduction of NK cells and DCs.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Program Projects (P01)
Project #
5P01CA101944-02
Application #
7311209
Study Section
Subcommittee G - Education (NCI)
Project Start
Project End
Budget Start
2006-07-01
Budget End
2007-06-30
Support Year
2
Fiscal Year
2006
Total Cost
$180,035
Indirect Cost

  Institution

Name
University of Pittsburgh
Department
Type
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213

  Publications

Radomski, Michal; Zeh, Herbert J; Edington, Howard D et al. (2016) Prolonged intralymphatic delivery of dendritic cells through implantable lymphatic ports in patients with advanced cancer. J Immunother Cancer 4:24
Kang, R; Tang, D; Schapiro, N E et al. (2014) The HMGB1/RAGE inflammatory pathway promotes pancreatic tumor growth by regulating mitochondrial bioenergetics. Oncogene 33:567-77
Kaufmann, Stefan H E; Lange, Christoph; Rao, Martin et al. (2014) Progress in tuberculosis vaccine development and host-directed therapies--a state of the art review. Lancet Respir Med 2:301-20
Wong, Jeffrey L; Berk, Erik; Edwards, Robert P et al. (2013) IL-18-primed helper NK cells collaborate with dendritic cells to promote recruitment of effector CD8+ T cells to the tumor microenvironment. Cancer Res 73:4653-62
Wong, Jeffrey L; Muthuswamy, Ravikumar; Bartlett, David L et al. (2013) IL-18-based combinatorial adjuvants promote the intranodal production of CCL19 by NK cells and dendritic cells of cancer patients. Oncoimmunology 2:e26245
Vernon, Philip J; Loux, Tara J; Schapiro, Nicole E et al. (2013) The receptor for advanced glycation end products promotes pancreatic carcinogenesis and accumulation of myeloid-derived suppressor cells. J Immunol 190:1372-9
Kang, Rui; Tang, Daolin; Lotze, Michael T et al. (2013) Autophagy is required for IL-2-mediated fibroblast growth. Exp Cell Res 319:556-65
Livesey, Kristen M; Kang, Rui; Zeh 3rd, Herbert J et al. (2012) Direct molecular interactions between HMGB1 and TP53 in colorectal cancer. Autophagy 8:846-8
Liang, Xiaoyan; De Vera, Michael E; Buchser, William J et al. (2012) Inhibiting systemic autophagy during interleukin 2 immunotherapy promotes long-term tumor regression. Cancer Res 72:2791-801
Livesey, Kristen M; Kang, Rui; Vernon, Philip et al. (2012) p53/HMGB1 complexes regulate autophagy and apoptosis. Cancer Res 72:1996-2005

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