Malignant transformation of the breast and other organs is associated with dramatic changes in the microenvironment surrounding neoplastic cells, including a reactive fibrotic stroma characterized by increased production of inflammatory cytokines, excessive accumulation of extracellular matrix (ECM), and an increase in tissue stiffness. Contractile myofibroblasts are key mediators of the biochemical and biophysical properties of the fibrotic tumor microenvironment. Additionally, the transdifferentiation of myofibroblasts from tissue cells and their subsequent activation is controlled by a combination of soluble factors and contractile tension. The increased tissue stiffness associated with fibrosis may thereby generate a positive feedback loop to facilitate tumor progression and metastatic invasion; delineating the microenvironmental effects and effectors will require sophisticated, tractable model systems. Here we describe the development of an experimental model that can define how alterations of biochemical and biophysical cellular microenvironment can stimulate myofibroblast development and activation, and how formation and activation of myofibroblasts in tissue structures affects progression to malignancy.
In Specific Aim 1, we will determine the biochemical and biomechanical requirements of the substratum microenvironment for the transdifferentiation process.
In Specific Aim 2, we will use a novel three- dimensional microlithography-based organotypic culture mimetic of the mammary epithelial ductal network to determine how myofibroblast transdifferentiation affects the microenvironment of the duct at the biochemical, mechanical, and cell population levels. Given that the presence of fibrotic foci in breast tumors correlates with metastasis and negative prognosis, and might hinder the efficacy of tumor therapies, the new physiologically relevant models developed in this work will have significant impact for discovery and evaluation of novel therapeutic targets to combat fibrosis genesis and tumor progression. PROJECT

Public Health Relevance

Repair of tissue damage involves the generation of specialized fibrous tissues that assist in tissue remodeling; deregulation or inappropriate activation of these repair processes can lead to fibrosis. Increasing evidence suggests that tissue fibrosis is a significant risk factor for development of cancer of the breast, lung, and many other organs. We present here a three-dimensional, microlithography-based model that can be used to break down the key steps involved in the earliest stages of fibrosis genesis. ? ? ?

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Exploratory/Developmental Grants (R21)
Project #
5R21CA128660-02
Application #
7460779
Study Section
Tumor Microenvironment Study Section (TME)
Program Officer
Mohla, Suresh
Project Start
2007-09-01
Project End
2010-08-31
Budget Start
2008-09-01
Budget End
2010-08-31
Support Year
2
Fiscal Year
2008
Total Cost
$146,380
Indirect Cost
Name
Princeton University
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
002484665
City
Princeton
State
NJ
Country
United States
Zip Code
08544
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Gjorevski, Nikolce; Nelson, Celeste M (2012) Mapping of mechanical strains and stresses around quiescent engineered three-dimensional epithelial tissues. Biophys J 103:152-62
Manivannan, Sriram; Gleghorn, Jason P; Nelson, Celeste M (2012) Engineered tissues to quantify collective cell migration during morphogenesis. Methods Mol Biol 886:173-82
Boghaert, Eline; Gleghorn, Jason P; Lee, KangAe et al. (2012) Host epithelial geometry regulates breast cancer cell invasiveness. Proc Natl Acad Sci U S A 109:19632-7
Lui, Cecillia; Lee, KangAe; Nelson, Celeste M (2012) Matrix compliance and RhoA direct the differentiation of mammary progenitor cells. Biomech Model Mechanobiol 11:1241-9

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