Abstract

The long-term objective of our work is to determine how the heparan sulfate/heparanase axis regulates tumor behavior and to use this knowledge to develop new therapies for cancer. We have demonstrated that the heparan sulfate proteoglycan syndecan-1 and heparanase work synergistically to condition the tumor microenvironment thereby promoting an aggressive tumor phenotype in myeloma and breast cancer - two devastating cancers that home to and degrade bone. Our goal now is to determine the mechanism of heparanase activity in tumors and to target heparanase therapeutically using novel drugs. Although work in the field suggests that heparanase functions to degrade extracellular matrix and thereby promote tumor metastasis, based on our new discoveries we hypothesize that heparanase expression and activity initiates broad downstream effects that dramatically alter the tumor microenvironment to stimulate growth, angiogenesis, metastasis and osteolysis of bone-homing tumors. Data from in vivo models indicates that these events occur largely via heparanase-mediated upregulation of syndecan-1 shedding, enhanced MMP-9 expression and activated destruction of bone. The following specific aims will define the function and mechanism of action of heparanase in myeloma and breast cancer and test novel anti-heparanase drugs with the aim of eradicating these cancers.
Aim 1 will determine the functional link between heparanase, syndecan-1 and MMP-9;
Aim 2 will determine how heparanase enhances osteolysis;
Aim 3 will test the anti-tumor efficacy and mechanism of action of a new class of heparin-based inhibitors of heparanase against breast cancer. These studies will utilize well-developed in vitro and in vivo models including the SCID-hu model in which human tumor cells are grown within human bone. This work will generate novel insight into heparanase function and mechanism of action and provide pre-clinical data necessary to drive new heparanase inhibitors toward clinical trials.

Public Health Relevance

Heparanase is a protein made by cancer cells that plays a major role in helping them grow and spread throughout the body. This project is designed to provide a new understanding about how heparanase works in multiple myeloma and breast cancer and to test new anti-heparanase drugs to block cancer growth.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA135075-03
Application #
7903967
Study Section
Tumor Microenvironment Study Section (TME)
Program Officer
Forry, Suzanne L
Project Start
2008-09-05
Project End
2013-07-31
Budget Start
2010-08-01
Budget End
2011-07-31
Support Year
3
Fiscal Year
2010
Total Cost
$300,212
Indirect Cost

  Institution

Name
University of Alabama Birmingham
Department
Pathology
Type
Schools of Medicine
DUNS #
063690705
City
Birmingham
State
AL
Country
United States
Zip Code
35294

  Publications

Beauvais, DeannaLee M; Jung, Oisun; Yang, Yang et al. (2016) Syndecan-1 (CD138) Suppresses Apoptosis in Multiple Myeloma by Activating IGF1 Receptor: Prevention by SynstatinIGF1R Inhibits Tumor Growth. Cancer Res 76:4981-93
Jung, O; Trapp-Stamborski, V; Purushothaman, A et al. (2016) Heparanase-induced shedding of syndecan-1/CD138 in myeloma and endothelial cells activates VEGFR2 and an invasive phenotype: prevention by novel synstatins. Oncogenesis 5:e202
Stewart, Mark D; Ramani, Vishnu C; Sanderson, Ralph D (2015) Shed syndecan-1 translocates to the nucleus of cells delivering growth factors and inhibiting histone acetylation: a novel mechanism of tumor-host cross-talk. J Biol Chem 290:941-9
Ramani, Vishnu C; Sanderson, Ralph D (2014) Chemotherapy stimulates syndecan-1 shedding: a potentially negative effect of treatment that may promote tumor relapse. Matrix Biol 35:215-22
Stewart, Mark D; Sanderson, Ralph D (2014) Heparan sulfate in the nucleus and its control of cellular functions. Matrix Biol 35:56-9
Ruan, Jian; Trotter, Timothy N; Nan, Li et al. (2013) Heparanase inhibits osteoblastogenesis and shifts bone marrow progenitor cell fate in myeloma bone disease. Bone 57:10-7
Ramani, Vishnu C; Purushothaman, Anurag; Stewart, Mark D et al. (2013) The heparanase/syndecan-1 axis in cancer: mechanisms and therapies. FEBS J 280:2294-306
Vlodavsky, Israel; Blich, Miry; Li, Jin-Ping et al. (2013) Involvement of heparanase in atherosclerosis and other vessel wall pathologies. Matrix Biol 32:241-51
Thompson, Camilla A; Purushothaman, Anurag; Ramani, Vishnu C et al. (2013) Heparanase regulates secretion, composition, and function of tumor cell-derived exosomes. J Biol Chem 288:10093-9
Vlodavsky, Israel; Iozzo, Renato V; Sanderson, Ralph D (2013) Heparanase: multiple functions in inflammation, diabetes and atherosclerosis. Matrix Biol 32:220-2

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