The Importance Of VEGF-D, An Angiogenic Protein, For Lymphangiogenesis, Tumor Growth And Metastasis.
Funder
National Health and Medical Research Council
Funding Amount
$227,036.00
Summary
Tumors attract blood vessels to obtain the nutrients for growth. Furthermore, the presence of blood vessels in a tumor enables tumor cells to enter the bloodstream and spread to distant parts of the body - a process known as metastatis that is the major cause of death in cancer patients. The growth of blood vessels - angiogenesis - is the mechanism by which tumors attract the vasculature. The capacity to block tumor angiogenesis would be of great benefit in the clinic as it would restrict both t ....Tumors attract blood vessels to obtain the nutrients for growth. Furthermore, the presence of blood vessels in a tumor enables tumor cells to enter the bloodstream and spread to distant parts of the body - a process known as metastatis that is the major cause of death in cancer patients. The growth of blood vessels - angiogenesis - is the mechanism by which tumors attract the vasculature. The capacity to block tumor angiogenesis would be of great benefit in the clinic as it would restrict both the growth and spread of tumors. Tumor cells attract blood vessels by secreting angiogenic growth factors that stimulate the proliferation of endothelial cells - the cells that form the inner lining of blood vessels. These Vascular Endothelial Growth Factors (VEGFs) are proteins. One VEGF, namely VEGF-D, was discovered in our laboratory at the Melbourne Branch of the Ludwig Institute for Cancer Research. VEGF-D stimulates the growth of blood vessels and possibly lymphatic vessels and is present in the most common human cancers including malignant melanoma and cancer of the breast and lung. We hypothesize that angiogenesis in some tumors is dependent on VEGF-D. Moreover, VEGF-D secreted by tumor cells may stimulate growth of lymphatic vessels - lymphangiogenesis. As metastatic spread often occurs via the lymphatic vessels, tumor lymphangiogenesis induced by VEGF-D may contribute to metastasis. The purpose of the research project is to determine the role of VEGF-D in tumor angiogenesis and lymphangiogenesis. Firstly we will thoroughly characterize the localization of VEGF-D in human cancer. Secondly, we will test VEGF-D for lymphangiogenic activity. Thirdly, the growth and metastatic spread in mice of tumors overexpressing VEGF-D will be analysed. Finally, aspects of VEGF-D biochemistry and gene regulation will be studied to develop strategies for inhibition of VEGF-D action in cancer.Read moreRead less
Acute myeloid leukaemia (AML) is a major health problem with only about one third of patients being cured. In addition therapies have changed little over the last 20 years. However there is optimism that with greater knowledge of the biochemical changes in AML that are caused by genetic mutations, more effective treatments will be developed. This project therefore aims to increase understanding of the biochemical interplay between two proteins called c-Cbl and Flt3 that are altered in AML.
Role Of A Novel Tks5-Nck Signaling Pathway In Cancer Invasion
Funder
National Health and Medical Research Council
Funding Amount
$560,434.00
Summary
Invasion and metastasis are major causes of death in cancer patients. Our research has uncovered a pathway that increases the invasive potential of tumour cells in vitro. We now aim to determine if the pathway is relevant in invasion and metastasis in clinically relevant models; how a drug targeting the pathway affects invasion and; the extent to which the pathway is active in human tumours. These studies may identify a new molecular target for anti-invasive drugs.
Regulation Of Mitogenic Signalling Via The Gab2 Docking Protein
Funder
National Health and Medical Research Council
Funding Amount
$141,750.00
Summary
Cell proliferation is regulated by growth factors which bind to specific receptors on the cell surface. These receptors then transmit a signal to the interior of the cell instructing it to divide. Inside the cell, the signal is transmitted by signalling proteins. Importantly, aberrant signalling by growth factor receptors or intracellular signalling molecules can contribute to cancer. We have recently demonstrated that the signalling protein Gab2 is overexpressed in a subset of breast cancers. F ....Cell proliferation is regulated by growth factors which bind to specific receptors on the cell surface. These receptors then transmit a signal to the interior of the cell instructing it to divide. Inside the cell, the signal is transmitted by signalling proteins. Importantly, aberrant signalling by growth factor receptors or intracellular signalling molecules can contribute to cancer. We have recently demonstrated that the signalling protein Gab2 is overexpressed in a subset of breast cancers. Furthermore, we have identified that another protein, termed PKB, can 'switch off' signalling by Gab2, and that deregulated signalling by Gab2 can make cells cancerous. The aim of this project is to characterize how PKB regulates Gab2, and to investigate whether this mechanism is impaired in human cancers, leading to enhanced Gab2 signalling. The research will provide important information regarding how growth factor signals are transmitted inside cells, and may identify a new cancer-causing gene.Read moreRead less
Development And Evaluation Of Biological Reagents Targeting And Inhibiting Function Of The EphA3 Receptor On Tumor Cells
Funder
National Health and Medical Research Council
Funding Amount
$490,500.00
Summary
Eph receptors and their ligands regulate morphogenesis in the embryo; they direct migration and positioning of cells during the formation of tissue layers and organ systems. There is little evidence for a function of Ephs in adult tissues. However, their abundant, un-scheduled occurrence in various malignant tumours, indicates a role in cancer. Human EphA3, the principle subject of this proposal, is not found in adult tissue but is present at high levels in lung, kidney and brain tumours, leukem ....Eph receptors and their ligands regulate morphogenesis in the embryo; they direct migration and positioning of cells during the formation of tissue layers and organ systems. There is little evidence for a function of Ephs in adult tissues. However, their abundant, un-scheduled occurrence in various malignant tumours, indicates a role in cancer. Human EphA3, the principle subject of this proposal, is not found in adult tissue but is present at high levels in lung, kidney and brain tumours, leukemia and malignant melanoma. High levels of EphA3 and corresponding ligands correlate with melanoma progression, and EphA3 stimulation triggers repulsion and detachment of melanoma cells. It is likely that Eph A3 is involved in release and spreading of tumour cells during melanoma progression. We have characterised reagents, the soluble EphA3 ligand and a monoclonal anti-EphA3 antibody, which bind EphA3 with high affinity and specificity. We will use these two proteins, or modified forms containing attached radiochemicals or cytotoxins, to target human tumours that were implanted into into immuno-deficient mice as animal model system. Our studies will determine if the specificity of our reagents, suggested from previous in-vitro studies, will allow imaging of EphA3 containing tumours, and effect their targeted killing. We will also use a tissue culture model, containing artificial epidermal and dermal layers of skin cells, to study if an inhibitory form of the EphA3 ligand will affect the invasiveness of EphA3 positive, metastatic melanoma cells. Furthermore, we will identify essential parts of this ligand to develop inhibitors with improved pharmacological properties. Together, our studies will establish the role for EphA3 in cancer progression and to assess the efficacy of EphA3 targeting for tumor killing and prevention of metastasis. We envision that this will provide the groundwork for Eph-specific reagents with anti-metastatic action in cancer therapy.Read moreRead less