Understanding Lymphatic And Vascular Biology For Application To Human Disease
Funder
National Health and Medical Research Council
Funding Amount
$697,209.00
Summary
This research is designed to provide further understanding of the role that the blood and lymphatic vessels plays in human disease. The proposal will use advanced molecular and cell biological approaches to define new diagnostic and therapeutic targets for human disease.
In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, ....In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, to investigate the role of Siah in the hypoxia signalling cascade. How cells sense and react to low oxygen levels is complex and involves several proteins. A key protein is called Hypoxia induced factor, Hif-1. It accumulates under hypoxia and is responsible for the expression of genes enabling the cell to tolerate and function under hypoxic conditions. tolerate and function under hypoxic conditions, which is involved in new blood vessel formation. PHD protein directs the degradation of Hif1, while Siah directs the degradation of PHD, when oxygen is limiting. Loss of Siah proteins (eg in our knockout models) leads to an increase in PHD proteins under hypoxia thus no stabilisation of Hif-1 and impaired response to hypoxia. Thus, sitting on the top of a cascade, which controls the trashing of proteins in the cell (focus of this year's Nobel price for medicine), Siah has primary control on the response to oxygen deprivation. The relative immunity of multicellular organisms to acquired defects is through redundancy. Oxygen is a unique case, for which organisms can not bypass the defect via redundancy, making it an attractive target for future therapy. Therefore, understanding the molecular and cellular response to hypoxia may allow us to identify key molecules which could be targeted for the development of novel anti inflammatory and cancer drugs. The scope of this study is to understand the key role of Siah utilising our knockout mice in models of inflammation and cancer.Read moreRead less
I am a molecular biologist determining the mechanisms that promote the spread of cancer via blood vessels and lymphatic vessels, with the aim of developing novel anti-cancer therapeutics to block these processes. My approach is to target protein growth fa
Definition Of The Role Of Senescence In Tumour-associated Endothelial Cells.
Funder
National Health and Medical Research Council
Funding Amount
$583,081.00
Summary
'Cellular senescence' is a mechanism to stop cells growing, and it may protect against tumour growth. However, it may also induce changes in cells leading to 'pro-tumour' effects. We have identified a gene - which we have called SEN1 - which induces senescence in the blood vessels of tumours. This gene may cause alterations in the blood supply to the tumour allowing it to grow and to resist chemotherapy. Understanding this gene may allow us to treat cancer by shutting off its blood supply.
The Function Of Histidine-rich Glycoprotein In Inflammation And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$455,670.00
Summary
This research proposal investiagtes the role of a molecule known as histidine-rich glycoprotein (HRG) in the important diseases of cancer and inflammation. Inflammatory diseases can occur when the the normal checks on the immune system breakdown resulting in attacks on the body leading to tissue damage (e.g rheumatoid arthritis) and are significant contributors to morbidity and health costs in Australia. Cancer is the leading cause of death in Australia (28.4% of deaths in 2003). HRG has been im ....This research proposal investiagtes the role of a molecule known as histidine-rich glycoprotein (HRG) in the important diseases of cancer and inflammation. Inflammatory diseases can occur when the the normal checks on the immune system breakdown resulting in attacks on the body leading to tissue damage (e.g rheumatoid arthritis) and are significant contributors to morbidity and health costs in Australia. Cancer is the leading cause of death in Australia (28.4% of deaths in 2003). HRG has been implicated in controlling important aspects of inflammatory and cancer disease progression. Namely, HRG appears to regulate the formation and clearance of substances known as immune complexes - the primary cause of tissue damage in this disease. Furthermore, HRG may also control the process of cell invasion which is crucial for the migration of white blood cells of the immune system (leukocytes) to sites of inflammation to combat infections, and is also an important mechanism by which malignant tumour cells escape from primary tumour sites and spread throughout the circulation to other sites in the body. It is this process that makes cancer such a deadly disease. This study aims to define how HRG contributes to these important processes. This information may allow the development of new therapeutic approaches for the treatment of inflammatory diseases and cancer.Read moreRead less
Receptor Tyrosine Kinase Function As Molecular Target In Cancer.
Funder
National Health and Medical Research Council
Funding Amount
$415,788.00
Summary
As molecular cell biologist and protein chemist my motivation for research is to tackle metastatic cancer, one of the principle health burdens of the 21 century. Over the next five years I will lead R&D programs with national and international collaborators that will generate new diagnostic approaches and insights in basic and translational research. These will allow us to develop anti-cancer drugs, which target several of the mechanisms that are active in metastatic cancers.
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
Sympathetic Nervous System Regulation Of The Tumour Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$396,212.00
Summary
Metastasis is the major cause of morbidity and mortality in breast cancer. These studies will evaluate the translational opportunity of targeting the sympathetic nervous system as a common regulator of cancer progression pathways. By exploiting sensitive imaging technology for non-invasive, real-time assessment of stress biology, these studies will define the neuroendocrine mechanisms that operate in the tumour microenvironment to support dissemination and arrest of cancer cells in target organs ....Metastasis is the major cause of morbidity and mortality in breast cancer. These studies will evaluate the translational opportunity of targeting the sympathetic nervous system as a common regulator of cancer progression pathways. By exploiting sensitive imaging technology for non-invasive, real-time assessment of stress biology, these studies will define the neuroendocrine mechanisms that operate in the tumour microenvironment to support dissemination and arrest of cancer cells in target organs.Read moreRead less