This is an application to investigate the mechanisms of microvesicle biogenesis in invasive tumor cells. It builds on exciting findings generated with previous NIH funding on a unique population of vesicles, called microvesicles that contain functionally active proteases and are released by tumor cells as they acquire invasive potential. The release of protease-loaded microvesicles may serve as a mechanism to bring about matrix degradation and perhaps even deposit paracrine information at distal locations, thus creating paths of """"""""least resistance"""""""" as tumor cells invade and migrate through surrounding tissue. This is distinct from pericellular proteolysis at invadopodia, which enables localized matrix degradation juxtaposed to the leading edge. Discovering that there may exist more than one mode of proteolytic invasion, limits the effectiveness of any invasion-targeted therapeutic strategy that does not include both focal and distal proteolysis. While a significant amount of research has been directed to the understanding mechanisms of invadopodia formation and function at sites of cell invasion, microvesicles biogenesis and function remains a relatively understudied area of tumor biology. However, recent accruing evidence demonstrating the bona fide presence of microvesicles in body fluids (blood, urine and ascites), and their potential to serve as indicators of disease, has extended interest and intensified research efforts in microvesicle biology and function. The overarching objective of this application is to define molecular mechanisms of microvesicle formation. The project focuses on the central hypothesis that specific ARF and Rab proteins direct membrane type proteases and other proteins to sites of microvesicle biogenesis and that tight interchanges between RhoA and Rac1 signaling governs the plasticity required for switching between microvesicle and invadopodia-mediated proteolytic invasion. We will address two specific aims. In the first aim, we will define endocytic recycling pathways that direct cargo to sites of microvesicle biogenesis as well as examine how recruitment of specific Rab effectors regulate actomyosin-based contraction required for microvesicle biogenesis. In the second aim, we will examine the spatial activation of RhoA and Rac1 in invasive tumor cells. We will also investigate potential mechanisms that regulate Rac1 down regulation during microvesicle formation and how Rho signaling facilitates the process. Given recent heightened interest in the biology and clinical promise of microvesicles, these investigations are highly current. They will advance present understanding of microvesicle biogenesis and have potential to provide targets for diagnostic as well as therapeutic application.

Public Health Relevance

Cell invasion is an essential element of tumor metastasis, the most common life-threatening complication of cancer, and occurs as cells detach from the primary tumor to 'invade'tissues at distal locations. The goal of this research is to better understand the mechanisms that confer invasive capacity to tumor cells by investigating small membrane particles shed by tumor cells that promote disease progression. We envision that the findings resulting from our proposed investigations will generate new and timely approaches to control tumor invasion as well as diagnose cancer. Thus these investigations will not only provide new information on the biology of disease but could also be vital for generating clinically applicable strategies for therapeutic intervention.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA115316-06
Application #
8710021
Study Section
Intercellular Interactions Study Section (ICI)
Program Officer
Ault, Grace S
Project Start
2007-09-25
Project End
2016-07-31
Budget Start
2014-08-01
Budget End
2015-07-31
Support Year
6
Fiscal Year
2014
Total Cost
Indirect Cost
Name
University of Notre Dame
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
City
Notre Dame
State
IN
Country
United States
Zip Code
46556
D'Souza-Schorey, Crislyn; Schorey, Jeffrey S (2018) Regulation and mechanisms of extracellular vesicle biogenesis and secretion. Essays Biochem 62:125-133
Clancy, James W; Sheehan, Colin S; Tricarico, Christopher J et al. (2018) Aberrant endocytosis leads to the loss of normal mitotic spindle orientation during epithelial glandular morphogenesis. J Biol Chem 293:12095-12104
Clancy, James W; Sedgwick, Alanna; Rosse, Carine et al. (2015) Regulated delivery of molecular cargo to invasive tumour-derived microvesicles. Nat Commun 6:6919
Sedgwick, Alanna E; Clancy, James W; Olivia Balmert, M et al. (2015) Extracellular microvesicles and invadopodia mediate non-overlapping modes of tumor cell invasion. Sci Rep 5:14748
D'Souza-Schorey, Crislyn; Di Vizio, Dolores (2014) Biology and proteomics of extracellular vesicles: harnessing their clinical potential. Expert Rev Proteomics 11:251-3
Grossmann, Allie H; Yoo, Jae Hyuk; Clancy, James et al. (2013) The small GTPase ARF6 stimulates ?-catenin transcriptional activity during WNT5A-mediated melanoma invasion and metastasis. Sci Signal 6:ra14
Pellon-Cardenas, Oscar; Clancy, James; Uwimpuhwe, Henriette et al. (2013) ARF6-regulated endocytosis of growth factor receptors links cadherin-based adhesion to canonical Wnt signaling in epithelia. Mol Cell Biol 33:2963-75
Monteleon, Christine L; Sedgwick, Alanna; Hartsell, Alyssa et al. (2012) Establishing epithelial glandular polarity: interlinked roles for ARF6, Rac1, and the matrix microenvironment. Mol Biol Cell 23:4495-505
D'Souza-Schorey, Crislyn; Clancy, James W (2012) Tumor-derived microvesicles: shedding light on novel microenvironment modulators and prospective cancer biomarkers. Genes Dev 26:1287-99
Di Vizio, Dolores; Morello, Matteo; Dudley, Andrew C et al. (2012) Large oncosomes in human prostate cancer tissues and in the circulation of mice with metastatic disease. Am J Pathol 181:1573-84

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