The natural history of human cancers is characterized by the progressive selection and outgrowth of cells that possess increasingly aggressive properties. This process ultimately leads to resistance to therapeutic agents, distant metastasis, and tumor recurrence. Together, these three manifestations of tumor progression are responsible for the vast majority of cancer deaths. Indeed, metastasis is the proximate cause of death for most of the 282,000 people each year in the United States who succumb to cancers of the breast, lung, prostate, and colon. Nevertheless, while tumor progression constitutes a problem of unrivaled clinical importance, the mechanisms underlying it are largely unknown. As such, elucidating the molecular, cellular, and pathophysiological events that contribute to this process is a critical priority in cancer research. The principal goal of this proposal is to develop new conceptual and technical approaches for understanding the mechanisms of tumor progression and metastasis. To accomplish this, the proposed program will employ a broad array of state-of-the-art cellular and molecular in vivo imaging approaches to analyze several genetically engineered mouse models for breast cancer progression developed by the investigators of this program, including a series of inducible transgenic models that permits the ordered, temporal dissection of each of the stages of mammary tumorigenesis and tumor progression as driven by defined oncogenic pathways. This proposal represents a highly integrated translational effort to image and understand tumor progression, tumor metastasis, and tumor response to therapy by using computed tomography (CT), magnetic resonance imaging (MRI), magnetic resonance spectroscopy (MRS), positron emission tomography (PET), single photon emission computed tomography (SPECT), ultrasound (US), bioluminescence imaging, and optical methods for measuring gene expression and mitochondrial redox potential. Specific goals of this program include development of the technology required to visualize and follow a tumor cell in vivo from its origins through its progression to distant metastasis, the ability to assess tumor response to therapy over time and predict clinical outcome, and the development of novel platforms for imaging the activity of molecular pathways relevant to human cancers. Finally, while this proposal is focused on breast cancer, the mechanisms, processes, approaches, and findings from the proposed studies will undoubtedly be applicable to most solid tumors. Without question, the biological and technical challenges to studying tumor progression and metastasis are considerable, likely explaining why this field has been termed """"""""one of the last great frontiers of cancer biology"""""""". The group of 25 investigators from 6 institutions assembled for this project provides the necessary breadth and depth required for this challenge. We believe that combining state-of-the-art mouse modeling approaches with genomics, histopathology, and a comprehensive set of non-invasive imaging methods has the power and promise to revolutionize our understanding of cancer etiology, progression, metastasis, recurrence, and response to therapy.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project--Cooperative Agreements (U01)
Project #
5U01CA105490-05
Application #
7448491
Study Section
Special Emphasis Panel (ZCA1-SRRB-U (J1))
Program Officer
Marks, Cheryl L
Project Start
2004-09-27
Project End
2009-09-10
Budget Start
2008-07-14
Budget End
2009-09-10
Support Year
5
Fiscal Year
2008
Total Cost
$544,744
Indirect Cost
Name
University of Pennsylvania
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
042250712
City
Philadelphia
State
PA
Country
United States
Zip Code
19104
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Engelberg, Jesse A; Retallack, Hanna; Balassanian, Ronald et al. (2015) ""Score the Core"" Web-based pathologist training tool improves the accuracy of breast cancer IHC4 scoring. Hum Pathol 46:1694-704
Mori, Hidetoshi; Soonsawad, Pan; Schuetter, Louis et al. (2015) Introduction of Zinc-salt Fixation for Effective Detection of Immune Cell-related Markers by Immunohistochemistry. Toxicol Pathol 43:883-9
Cardiff, Robert D; Miller, Claramae H; Munn, Robert J (2014) Analysis of mouse model pathology: a primer for studying the anatomic pathology of genetically engineered mice. Cold Spring Harb Protoc 2014:561-80
Feng, Yi; Pan, Tien-Chi; Pant, Dhruv K et al. (2014) SPSB1 promotes breast cancer recurrence by potentiating c-MET signaling. Cancer Discov 4:790-803
Alvarez, James V; Belka, George K; Pan, Tien-Chi et al. (2014) Oncogene pathway activation in mammary tumors dictates FDG-PET uptake. Cancer Res 74:7583-98
Payne, Ania W; Pant, Dhruv K; Pan, Tien-Chi et al. (2014) Ceramide kinase promotes tumor cell survival and mammary tumor recurrence. Cancer Res 74:6352-63
Engelberg, Jesse A; Giberson, Richard T; Young, Lawrence J T et al. (2014) The use of mouse models of breast cancer and quantitative image analysis to evaluate hormone receptor antigenicity after microwave-assisted formalin fixation. J Histochem Cytochem 62:319-34
Thiel, Austin T; Feng, Zijie; Pant, Dhruv K et al. (2013) The trithorax protein partner menin acts in tandem with EZH2 to suppress C/EBP? and differentiation in MLL-AF9 leukemia. Haematologica 98:918-27
Cardiff, Robert D; Hubbard, Neil E; Engelberg, Jesse A et al. (2013) Quantitation of fixative-induced morphologic and antigenic variation in mouse and human breast cancers. Lab Invest 93:480-97

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