Advanced Anti-cancer Activities With Therapeutic Agents That Induce Tumor Cell Apoptosis And Antitumor Immune Responses.
Funder
National Health and Medical Research Council
Funding Amount
$85,701.00
Summary
The aim is to perform pre-clinical studies to identify new therapies for blood cancers. We will utilise three new anti-cancer agents that kill tumor cells and genetically engineered mice that develop cancer. We will determine if these three new agents kill the mouse tumor cells and activate anti-tumor immunity. The combined effect of killing blood cancer cells using new therapeutics, coupled with enhancing the anti-cancer immune response may hold the key to developing new treatments.
Analysis Of The Apoptotic And Therapeutic Effects Of Histone Deacetylase Inhibitors On Multiple Myeloma
Funder
National Health and Medical Research Council
Funding Amount
$287,321.00
Summary
Multiple myeloma (MM) is an incurable progressive cancer of plasma cells within blood. It is the second most common blood cancer and represents 2% of all cancer-related deaths. Statistics show increasing incidence and decreasing age of onset. The cause and progression of MM is poorly understood and current treatments are frequently followed by relapse. This project will assess exciting new therapies against the survival of MM cells leading to more effective treatments in the future.
Investigating Tumour Biology Using Regulated RNAi In Cells And Mice
Funder
National Health and Medical Research Council
Funding Amount
$305,915.00
Summary
Inhibiting gene expression using the recently discovered process known as RNA interference (RNAi) can be used as an experimental tool to analyse specific genes, in cells and genetically engineered animal models of human disease. I propose to use RNAi to mimic human cancer gene mutations in mouse cancer models, and aim to discover novel tumour suppressor genes. A further aim is to validate potential drug targets in cancer by using RNAi to inhibit specific genes in established mouse tumours.
I am a cancer cell biologist investigating molecular mechanisms of leukaemia cell resistance to chemotherapeutic drugs, and novel strategies for the management of high risk or relapsed disease. For these purposes I have developed orthotopic xenograft mode
Colorectal Cancer - Molecular Basis To Targeted Therapeutics.
Funder
National Health and Medical Research Council
Funding Amount
$19,818,386.00
Summary
Cancer of the colon and rectum is the most common form of cancer in Australia. Over 12,000 people are diagnosed each year with colorectal cancer (CRC) and more than one third of people will die of their disease. CRC is caused by mistakes in production of colon cells. Our research aims to discover new ways to detect CRC, develop smart drugs and nanoparticle delivery systems for destroying all types of CRC cells. We will then test our new anti-cancer drugs in clinical trials with CRC patients.
Development Of Anti-metastatic And Tumour Targeting Reagents By Design Of Inhibitors To Specific Eph/ephrin Cell-cell
Funder
National Health and Medical Research Council
Funding Amount
$200,000.00
Summary
Metastatic disease, malignant melanoma in particular, is a health issue of considerable global importance with 1,000 fatal melanoma cases- year in Australia alone. While progress has been made on prevention and early diagnosis, no curative treatment exists for stage IV melanoma. Tumour progression and the acquisition of metastatic competence primarily reflect dysregulation of cell adhesion and cell motility rather than proliferation and survival. In this context, Eph receptor tyrosine kinases (E ....Metastatic disease, malignant melanoma in particular, is a health issue of considerable global importance with 1,000 fatal melanoma cases- year in Australia alone. While progress has been made on prevention and early diagnosis, no curative treatment exists for stage IV melanoma. Tumour progression and the acquisition of metastatic competence primarily reflect dysregulation of cell adhesion and cell motility rather than proliferation and survival. In this context, Eph receptor tyrosine kinases (Ephs) and their membrane-bound ephrin ligands are crucial mediators of cell adhesion and motility and are notably overexpressed in metastatic tumours rather than primary (benign) lesions5. Our laboratories were the first to identify EphA3 7, and one of the first to isolate its ligand, ephrin-A5. EphA3 was isolated from acute lymphoblastoid leukemia and malignant melanoma patients, where increasing expression levels correlate with metastatic progression. Soluble, non-clustered forms of Ephs and ephrins are effective inhibitors of Eph activity 3 and provide opportunities to generate specific drugs for cancer therapy. We now propose a research and development program for the development of EphA3-specific drugs and their production for pre-clinical and clinical evaluation for placement onto a national and international market.Read moreRead less
Stage II In The Development Of Eph/ephrin Based Tumor Targeting Reagents: Optimisation Of Drug Efficacy And Delivery
Funder
National Health and Medical Research Council
Funding Amount
$204,125.00
Summary
In the final stage of cancer, including melanoma, tumor cells gain the ability to spread, a process called metastasis. Altered communication between cancer and normal cells is one of the causes of this invasive characteristic. We have started the development of novel agents that target and modulate proteins on the cell surface that control these properties and are found in metastatic tumors. We propose to refine the targeting and killing properties of these agents for early clinical testing.
One of the hallmarks of cancer cells is their ability to divide and multiply in an uncontrolled manner. Specific proteins that make up the skeleton of cells (cytoskeleton) play an important part in the cell division process and as such make extremely important targets for anticancer therapy. Our research is developing ways to best target cell division proteins so that we can make drug resistant cancer cells sensitive to chemotherapy.
The 3-dimensional Structure Of Anticancer Drug-DNA Complexes Determined By X-ray Crystallography
Funder
National Health and Medical Research Council
Funding Amount
$264,358.00
Summary
Our main objective is to discover the molecular details of how cancer drugs interact with DNA and how these interactions differ from those of inactive chemically related compounds. We propose to use X-ray crystallography together with the successful methods we have developed for determining the 3-dimensional structures of the DNA complexes of a class of antitumour active drugs to study the complexes of other clinically or scientifically important DNA intercalating anticancer drugs. These agents ....Our main objective is to discover the molecular details of how cancer drugs interact with DNA and how these interactions differ from those of inactive chemically related compounds. We propose to use X-ray crystallography together with the successful methods we have developed for determining the 3-dimensional structures of the DNA complexes of a class of antitumour active drugs to study the complexes of other clinically or scientifically important DNA intercalating anticancer drugs. These agents act by poisoning the DNA binding enzyme topoisomerase. Crystallographic analysis will give us unequivocal answers at the atomic level as to the exact way in which the drug binds to DNA and how this binding differs between antitumour active and inactive compounds. We believe that a knowledge of the DNA binding mode of a class of intercalating anticancer drugs at the atomic level is valuable in guiding drug design within that class.Read moreRead less
Targeting MYC-driven Cancers By Inhibition Of The MTOR Pathway
Funder
National Health and Medical Research Council
Funding Amount
$547,970.00
Summary
This proposal will evaluate a new strategy for treating cancers associated with the cancer causing gene MYC. Globally there are more than 1 million cases of MYC-associated cancers diagnosed per year. Based on encouraging early results we will test if turning off the proteins associated with mTOR will be an effective strategy for treating MYC cancers using state-of-the-art cancer models and investigate why these cancers respond.