Abstract

Immunotoxins (IT) are experimental pharmacologic agents that are made by linking antibodies or cytokines that specifically bind to cancer cells to potent catalytic toxins of which a single molecule can kill a cell. The major purpose is to deliver therapy selectively to cancer cells instead of nontarget organs as does conventional chemotherapy. Although these agents selectively bind and kill cancer cells, clinically they have been limited by their 1) failure to penetrate and localize in adequate concentrations in cancer target tissue 2) localization in nontarget organs limiting the tolerated dose and collapsing the therapeutic window. In this application, the applicant will explore a solution to this problem. Cells of the immune system such as T cells are the most prominent cell types that penetrate, attack, and destroy cancer cells and are naturally suited for the expression and production of cytokines in response to antigenic challenge. Therefore, he proposes using T cells to deliver retroviral IT (retIT) consisting of IL-4 spliced to genetically modified diphtheria toxin at the site of the leukemia cells. He has established a model of retIT therapy that he will use as a foundation for future attempts to modify and improve retIT. He will test the usefulness of retIT for therapy of myeloid leukemia, the most common adult form of leukemia. In this model, the applicant has produced an antigen specific CTL cell line called T15 by hyperimmunization with irradiated murine myeloid leukemia C1498. When T15 is transduced with retrovirus encoding IL-4 spliced to truncated DT, T15 cells have been shown to express and secrete IL-4 retIT which specifically kills IL-4R+ C1498 cells, but not IL-4R- cells in vitro. More importantly, mice given C1498 tumors show significantly enhanced anti-C1498 effects when treated with transduced T15 cells as compared to controls. In this application in the first aim, the applicant intends to use this model first to answer important questions regarding the role of IL-4 IT and T15 CTL in the first retroviral model. Is secretion of IL-4 IT necessary and how much must be secreted to get an anti-cancer effect? Does the amount of secreted retIT correlate with the magnitude of the anti-cancer effect? What is the role of the CTL vehicle in the retIT response? Can we enhance secretion and CTL delivery of retIT? In the second aim, he will determine if retIT administration has advantages over conventional IT administration particularly regarding their toxic effects on non-target organ systems and effects on the immune response. With the anti-C1498 effects that he has already established as a baseline, in the last aim he will ask whether or not important genetic modifications can improve retIT.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA082154-02
Application #
6377288
Study Section
Special Emphasis Panel (ZRG1-ET-2 (01))
Program Officer
Yovandich, Jason L
Project Start
2000-04-01
Project End
2003-03-31
Budget Start
2001-04-01
Budget End
2002-03-31
Support Year
2
Fiscal Year
2001
Total Cost
$264,245
Indirect Cost

  Institution

Name
University of Minnesota Twin Cities
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
168559177
City
Minneapolis
State
MN
Country
United States
Zip Code
55455

  Publications

Tsai, Alexander K; Oh, Seunguk; Chen, Hua et al. (2011) A novel bispecific ligand-directed toxin designed to simultaneously target EGFR on human glioblastoma cells and uPAR on tumor neovasculature. J Neurooncol 103:255-66
Oh, Seunguk; Tsai, Alexander K; Ohlfest, John R et al. (2011) Evaluation of a bispecific biological drug designed to simultaneously target glioblastoma and its neovasculature in the brain. J Neurosurg 114:1662-71
Vallera, Daniel A; Oh, Seunguk; Chen, Hua et al. (2010) Bioengineering a unique deimmunized bispecific targeted toxin that simultaneously recognizes human CD22 and CD19 receptors in a mouse model of B-cell metastases. Mol Cancer Ther 9:1872-83
Oh, Seunguk; Stish, Brad J; Vickers, Selwyn M et al. (2010) A new drug delivery method of bispecific ligand-directed toxins, which reduces toxicity and promotes efficacy in a model of orthotopic pancreatic cancer. Pancreas 39:913-22
Stish, B J; Oh, S; Chen, H et al. (2009) Design and modification of EGF4KDEL 7Mut, a novel bispecific ligand-directed toxin, with decreased immunogenicity and potent anti-mesothelioma activity. Br J Cancer 101:1114-23
Oh, Seunguk; Stish, Brad J; Sachdev, Deepali et al. (2009) A novel reduced immunogenicity bispecific targeted toxin simultaneously recognizing human epidermal growth factor and interleukin-4 receptors in a mouse model of metastatic breast carcinoma. Clin Cancer Res 15:6137-47
Vallera, Daniel A; Chen, Hua; Sicheneder, Andrew R et al. (2009) Genetic alteration of a bispecific ligand-directed toxin targeting human CD19 and CD22 receptors resulting in improved efficacy against systemic B cell malignancy. Leuk Res 33:1233-42
Vallera, D A; Stish, B J; Shu, Y et al. (2008) Genetically designing a more potent antipancreatic cancer agent by simultaneously co-targeting human IL13 and EGF receptors in a mouse xenograft model. Gut 57:634-41
Stish, Brad J; Oh, Seunguk; Vallera, Daniel A (2008) Anti-glioblastoma effect of a recombinant bispecific cytotoxin cotargeting human IL-13 and EGF receptors in a mouse xenograft model. J Neurooncol 87:51-61
Stish, Brad J; Chen, Hua; Shu, Yanqun et al. (2007) Increasing anticarcinoma activity of an anti-erbB2 recombinant immunotoxin by the addition of an anti-EpCAM sFv. Clin Cancer Res 13:3058-67

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