Abstract

The limitation of present assessment of response to therapy is that patients are treated for 2 months before tumor volumes are measured to reassess effectiveness of the drug. The goal of this research is to develop systems for the rapid assessment of cancer responsiveness and susceptibility to tyrosine kinase inhibitors (TKIs) by use of recombinant peptides that bind to responding cells.
These aims will test the central hypothesis that non-invasive imaging of cancer response can be achieved by use of recombinant peptides selected from a phage-displayed libraries that bind within tumor blood vessels following treatment with TKIs and cytotoxic therapy. PET, SPECT and gamma camera imaging will be used to rapidly monitor the response of cancer to TKIs. One model includes VEGF receptor TKIs that enhance the cytotoxic effects of radiation in the tumor microvasculature. This results in apoptosis of the tumor endothelium and subsequent activation of inflammation and thrombotic cascades. Our preliminary data indicates that VEGF receptor TKIs enhance the effects of radiation within tumor microvasculature resulting in improved tumor control. Cancer susceptibility to TKIs has been evaluated primarily by tumor tissue sectioning and staining. This pharmacodynamic approach is not entirely feasible in patients with brain tumors and lung cancer primaries. For that reason, we have developed the hypotheses that recombinant peptides from phage-displayed peptide libraries can be selected that bind to apoptotic endothelium and to receptors activated in response to therapy. These peptides in turn can be labeled with internal emitters to provide a means of non-invasive monitoring of responsiveness to therapy. The physiologic response to therapy is seen within 24 hours of therapy, which provides a rapid assessment using non-invasive means. We utilized phage displayed peptide libraries to select peptides that bind within treated tumor blood vessels. We will study these peptides with the intention of monitoring tumor blood vessel response during therapy with RTK inhibitors and radiation. We hypothesize that recombinant peptides will bind to cells undergoing apoptosis and provide a means to non-invasively assess cancer response to TKI therapy. The studies of the RGD peptide pneumatic imaging of tumor vasculature response has shown that this simple amino acid sequence binds to activated receptor that is non-specific and achieves binding to other tissues in addition to tumor [Hallahan, 2001]. For that reason, we have developed recombinant peptide that binds more specifically to irradiated tumor blood vessels. In the present investigation, we will test the hypothesis that these recombinant peptides bind selectively to microvasculature of treated tumors.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA112385-03
Application #
7174304
Study Section
Developmental Therapeutics Study Section (DT)
Program Officer
Bernhard, Eric J
Project Start
2005-02-23
Project End
2010-01-31
Budget Start
2007-02-01
Budget End
2008-01-31
Support Year
3
Fiscal Year
2007
Total Cost
$258,357
Indirect Cost

  Institution

Name
Vanderbilt University Medical Center
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
004413456
City
Nashville
State
TN
Country
United States
Zip Code
37212

  Publications

Kapoor, Vaishali; Dadey, David Y A; Nguyen, Kim et al. (2016) Tumor-Specific Binding of Radiolabeled PEGylated GIRLRG Peptide: A Novel Agent for Targeting Cancers. J Nucl Med 57:1991-1997
Thotala, Dinesh; Karvas, Rowan M; Engelbach, John A et al. (2015) Valproic acid enhances the efficacy of radiation therapy by protecting normal hippocampal neurons and sensitizing malignant glioblastoma cells. Oncotarget 6:35004-22
Wang, H; Han, M; Whetsell Jr, W et al. (2014) Tax-interacting protein 1 coordinates the spatiotemporal activation of Rho GTPases and regulates the infiltrative growth of human glioblastoma. Oncogene 33:1558-69
Bhave, Sandeep R; Dadey, David Y A; Karvas, Rowan M et al. (2013) Autotaxin Inhibition with PF-8380 Enhances the Radiosensitivity of Human and Murine Glioblastoma Cell Lines. Front Oncol 3:236
Laszlo, Andrei; Thotala, Dinesh; Hallahan, Dennis E (2013) Membrane phospholipids, EML4-ALK, and Hsp90 as novel targets in lung cancer treatment. Cancer J 19:238-46
Thotala, D K; Hallahan, D E; Yazlovitskaya, E M (2012) Glycogen synthase kinase 3? inhibitors protect hippocampal neurons from radiation-induced apoptosis by regulating MDM2-p53 pathway. Cell Death Differ 19:387-96
Jarboe, John S; Jaboin, Jerry J; Anderson, Joshua C et al. (2012) Kinomic profiling approach identifies Trk as a novel radiation modulator. Radiother Oncol 103:380-7
Schleicher, Stephen M; Thotala, Dinesh K; Linkous, Amanda G et al. (2011) Autotaxin and LPA receptors represent potential molecular targets for the radiosensitization of murine glioma through effects on tumor vasculature. PLoS One 6:e22182
Hariri, Ghazal; Wellons, Matthew S; Morris 3rd, William H et al. (2011) Multifunctional FePt nanoparticles for radiation-guided targeting and imaging of cancer. Ann Biomed Eng 39:946-52
Schulte, Rachael R; Linkous, Amanda G; Hallahan, Dennis E et al. (2011) Cytosolic phospholipase A2 as a molecular target for the radiosensitization of ovarian cancer. Cancer Lett 304:137-43

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