Targeting Transcriptional Addiction For Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$128,224.00
Summary
.Tumours driven by the oncogene “Myc” are difficult to treat and an effective means to directly target Myc using small molecules has proven elusive. We have discovered that Myc-dependent tumours are dependent on their ability to globally amplify gene expression through a mechanism that involves the CDK9 enzyme and possibly other related enzymes. I will test the effectiveness of targeting CDK9 in a range of tumours with a Myc dependency, both alone and in combination with other small molecules.
Role Of Cyclin E2 In Hormone-responsive Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$328,194.00
Summary
The female hormone estrogen stimulates the growth of breast cancers by promoting cell reproduction. We have found that cyclin E2, which is part of the machinery that controls cell reproduction, responds to estrogen. Since abnormally high levels of cyclin E2 are linked with earlier relapse in breast cancer, we wish to understand what role it plays in estrogen action and in breast cancer, how its levels are controlled, and whether too much cyclin E2 interferes with drugs that block estrogen action
Characterization Of Novel Inhibitors Of G1-S Phase Progression In Drosophila
Funder
National Health and Medical Research Council
Funding Amount
$456,000.00
Summary
Cancer is a disease that affects 1-3 people and therefore, understanding the mechanisms by which cancer arises is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation, cell death or cell movement. Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell p ....Cancer is a disease that affects 1-3 people and therefore, understanding the mechanisms by which cancer arises is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation, cell death or cell movement. Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell proliferation, and have been studying this in the genetically amenable animal model system, the vinegar fly, Drosophila. A key regulator of cell proliferation in all multicellular organisms is Cyclin E, which is required to drive cells from the G1 (resting state) into S phase (where DNA replication occurs). Correct control of Cyclin E is important in limiting cell proliferation and many cancer-causing mutations result in up-regulation of this critical cell cycle regulator. We have used a genetic approach to identify novel negative regulators of Cyclin E. This proposal seeks to further clarify the mechanism by which the identified Cyclin E interactors regulate cell cycle progression. In addition, this proposal seeks to identify the genes encoding other cyclin E interactors, expected to be novel tumor suppressors. The expected outcome of this project is to elucidate novel genes and mechanisms that control cell proliferation in the context of a whole organism. Due to the conservation of cell proliferation and signalling proteins, this proposal is relevant to understanding human cancer.Read moreRead less
Cyclin Dependent Kinases As Drug-Targets To Reduce Renal Cyst Formation And Scarring In Polycystic Kidney Disease
Funder
National Health and Medical Research Council
Funding Amount
$319,446.00
Summary
Polcystic kidney disease (PKD) is one of the most common genetic diseases in humans. The most common type (autosomal dominant-PKD) affects approximately 1:400 to 1:1000 individuals worldwide. Kidney failure is the most debilitating and serious complication of PKD, and it accounts for approximately 10% of the cases of end-stage kidney requiring artificial kidney treatment (dialysis) or transplantation. Over the last decade, major advances have been made in preventing kidney failure due to diabeti ....Polcystic kidney disease (PKD) is one of the most common genetic diseases in humans. The most common type (autosomal dominant-PKD) affects approximately 1:400 to 1:1000 individuals worldwide. Kidney failure is the most debilitating and serious complication of PKD, and it accounts for approximately 10% of the cases of end-stage kidney requiring artificial kidney treatment (dialysis) or transplantation. Over the last decade, major advances have been made in preventing kidney failure due to diabetic kidney disease, but these are ineffective for PKD. As such, currently, there is no treatment to prevent kidney failure due to PKD, and new therapies are needed. PKD is characterised by the development of multiple cysts in the kidney, which enlarge and destroy normal kidney tissue. The growth of the cysts is due to uncontrolled growth (cell division) of the cells of the kidney (epithelial cells), which causes cyst formation. In recent years, gene mutations in proteins called polcysytins are thought to be responsible for the cause of the disease. However, the genetic mutations in PKD are complex (>30 types for autosomal dominant PKD alone), and it is unlikely that gene therapy will be possible with current technology in the near future. A simpler approach is to develop 'drugs' that target the consequences of the mutation. This project will investigate the role of a group proteins, called cyclin-dependent kinases (CDKs) in PKD. CDKs which are enzymes that are critical in promoting cell division. Our preliminary data shows that CDKs are upregulated in PKD. The aim of this project is to establish the importance of CDKs in PKD, and examine the effect of new drugs (CDK inhibitors) in maintaining in preventing cyst growth and kidney scarring in PKD. CDK inhibitors are currently being tested in phase 1 and 2 clinical trials in patients with cancer, and this will facilitate the translation of the findings of this project to humans with PKD.Read moreRead less
ALCOHOL AND IMPAIRED LIVER REGENERATION: EFFECTS ON MITOGENIC SIGNALING PATHWAYS
Funder
National Health and Medical Research Council
Funding Amount
$365,295.00
Summary
Patients who regularly consume alcohol are slow to recover from liver injury because alcohol poisons the liver's capacity to regenerate itself (grow back). Hence patients with alcohol-induced liver disease have a high mortality and prolonged hospital stays. The applicants have been supported by NHMRC to study how alcohol impairs liver regeneration. They found that the effect is at the level of cell surface receptors for the growth factors that control liver regeneration. Alcohol alters the funct ....Patients who regularly consume alcohol are slow to recover from liver injury because alcohol poisons the liver's capacity to regenerate itself (grow back). Hence patients with alcohol-induced liver disease have a high mortality and prolonged hospital stays. The applicants have been supported by NHMRC to study how alcohol impairs liver regeneration. They found that the effect is at the level of cell surface receptors for the growth factors that control liver regeneration. Alcohol alters the function of these receptors. One major discovery has been that it damages the capacity to generate a rise in calcium within the cell, something that is fundamentally required for any cell to divide and reproduce itself. Thus when a rise in calcium was produced artificially (with chemicals to unlock the internal calcium stores), liver cells from alcohol-fed rats once more responded normally under the influence of growth factors and replicated themselves. The present work isdesigned to find out where this effect of calcium is exerted. The investigators believe that it is related to how other types of signals work, the so-called protein kinase pathways. These are cascades of one protein turning on (activating) the next down the line to ultimately switch on the genes that control cell growth. They will manipulate liver cells from alcohol-fed rats in culture to establish which of these pathways is most affected, and which is the most critical for the control of cell division genes. These studies will greatly advance our understanding about how alcohol impairs liver regeneration. They will give new insight into the control of liver cell growth and division that is such a crucial response of the liver to injury, vital for survival of the liver. This kind of knowledge will open the door for new treatments to be designed that can control liver growth - turn it back on when it has been poisoned, or turn it off when it is inappropriately vigorous and predisposing to liver cancer.Read moreRead less