THE ROLE OF NOVEL TUMOUR SUPPRESSORS DURING DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$200,880.00
Summary
Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). 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 intereste ....Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). 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, Drosophila. Central to the control of cell proliferation in all organisms are the Cyclin dependent protein kinases. Cyclin E-dependent protein kinase 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 and premature entry into the cell cycle. We have used a genetic approach using a weak mutation in Drosophila Cyclin E to isolate mutations in other important regulators of the G1 to S phase transition. We have identified a number of genes that act to negatively regulate the cell cycle, 2 of which have characteristics typical of tumour suppressors. We have identified candidate genes for 3 of these mutations, all of which encode novel proteins related to mammalian proteins involved in negative regulation of cell proliferation or tumour suppressors. In this proposal we seek to determine the way in which these proteins function to control cell proliferation in Drosophila. Due to the remarkable conservation of genes involved in cell proliferation control through evolution, this study is likely to be highly relevant to the control of cell proliferation and the development of cancer in humans.Read moreRead less
Dominant Repeat Expansion Diseases - A Common RNA Mediated Pathogenic Pathway?
Funder
National Health and Medical Research Council
Funding Amount
$281,118.00
Summary
There are fourteen human genetic diseases that are caused by a similar mutation mechanism and have similar clinical outcomes - the loss of function, degeneration and eventual death of nerve cells. This group of diseases includes Huntington's Disease. They are transmitted from parent to offspring such that each child of an affected parent has 50% risk of inheriting the affected gene and therefore developing the disease. The symptoms of these diseases typically develop later in life - between the ....There are fourteen human genetic diseases that are caused by a similar mutation mechanism and have similar clinical outcomes - the loss of function, degeneration and eventual death of nerve cells. This group of diseases includes Huntington's Disease. They are transmitted from parent to offspring such that each child of an affected parent has 50% risk of inheriting the affected gene and therefore developing the disease. The symptoms of these diseases typically develop later in life - between the ages of 35 and 50 years. While the different genes for these diseases have been identified the pathways that lead from their similar form of mutation to their similar clinical outcomes are not yet understood. Some evidence suggests that certain of these diseases have a common toxic component but this component is not shared by all of the disease genes and so an additional agent that they have in common is being sought. This research will use a genetic model organism - the vinegar fly, Drosophila melanogaster, to test the identity of a good candidate (RNA) for a common toxic agent and to provide information about the pathway by which RNA leads to nerve cell degeneration and death. Accurate and complete knowledge of the identity and composition of the pathways that lead from the mutation to the disease are crucial for correct target identification in the development of drug leads.Read moreRead less
Discovery Of Novel Oncogenes And Tumour Suppressor Genes Via Genetic Interactions With Drosophila Cbl.
Funder
National Health and Medical Research Council
Funding Amount
$396,760.00
Summary
Cancer is a complex genetic disease resulting from an accumulation of mutations that allow a cell to escape its normal growth controls. The cell can then multiply indefinitely to produce a tumour. We still only know the nature of some of these mutations, and the genes that they affect. Recently the fruitfly, Drosophila, has gained increasing importance in the discovery of new cancer genes and understanding how they function. The long history of genetic studies with this organism, and the recent ....Cancer is a complex genetic disease resulting from an accumulation of mutations that allow a cell to escape its normal growth controls. The cell can then multiply indefinitely to produce a tumour. We still only know the nature of some of these mutations, and the genes that they affect. Recently the fruitfly, Drosophila, has gained increasing importance in the discovery of new cancer genes and understanding how they function. The long history of genetic studies with this organism, and the recent completion of the DNA sequence of the entire genetic code of the fruitfly allows a wealth of experiments to be conducted on how mutations affect growth and development. We have used the fruitfly to investigate how a particular cancer gene, v-cbl, causes cells to lose growth control and are now using this organism in a systematic way to discover new cancer genes. We will then map these genes onto the human genome to determine if these genes are also responsible for human cancers.Read moreRead less
Investigating Tumour Development And Metastasis Using A Novel Drosophila Cancer Model.
Funder
National Health and Medical Research Council
Funding Amount
$505,500.00
Summary
The majority of cancers are derived from epithelial cells. The primary cause of cancer related deaths is due to the ability of these epithelial cancer cells to migrate and invade other tissues within the body away from their primary tissue of origin (metastasise). This proposal seeks to understand the pathways that are important in regulating the processes of epithelial cell migration and invasion that are instrumental in promoting the metastatic spread of tumour cells. As controls usually opera ....The majority of cancers are derived from epithelial cells. The primary cause of cancer related deaths is due to the ability of these epithelial cancer cells to migrate and invade other tissues within the body away from their primary tissue of origin (metastasise). This proposal seeks to understand the pathways that are important in regulating the processes of epithelial cell migration and invasion that are instrumental in promoting the metastatic spread of tumour cells. As controls usually operate to induce cell death in any cell that attempts to break away and invade other tissues, this proposal also seeks to understand some of the pathways that are responsible for causing these cells to die. To carry out these investigations we have developed a novel Drosophila model of epithelial cancer development. We use this model because of the ease with which it is possible to carry out complex genetic analyses and so dissect the roles of the many different signalling pathways involved in these processes. The strength of the model is that it is dependent upon genetic alterations that are also implicated in the development and metastatic spread of many mammalian cancers, namely activating mutations in two genes, Ras and Notch. It is expected, therefore, to offer considerable insight into why these activated genes also cause the spread of cancer cells in humans.Read moreRead less
Molecular Genetic Analysis Of BRCT Domain Function And RhoGEF Signalling In DNA-damage Response And Apoptosis.
Funder
National Health and Medical Research Council
Funding Amount
$195,691.00
Summary
Cancers arise as a consequence of a series of genetic changes, usually by mutation of DNA. DNA is consistently exposed to an array of damaging agents, but the majority of mutations are corrected by cellular repair mechanisms. We now know that if these mechanisms work normally, too few mutations persist for cancer to result. However if these DNA damage repair mechanisms are themselves faulty, a high mutation rate occurs and a high risk of cancer results. DNA damage has another outcome. If the dam ....Cancers arise as a consequence of a series of genetic changes, usually by mutation of DNA. DNA is consistently exposed to an array of damaging agents, but the majority of mutations are corrected by cellular repair mechanisms. We now know that if these mechanisms work normally, too few mutations persist for cancer to result. However if these DNA damage repair mechanisms are themselves faulty, a high mutation rate occurs and a high risk of cancer results. DNA damage has another outcome. If the damage is too extensive, the cell commits suicide, not because it cannot function, but because it senses the DNA damage and chooses to die. One poorly understood aspect of the response to DNA damage is how the cell senses the damage and activates the suicide process. We have discovered a novel gene that appears to play a role in this sensing and suicide signalling process. The mouse version of this gene can itself act as a cancer-causing gene. We propose, however, to study the equivalent gene in Drosophila melanogaster, a more powerful experimental system, to characterise in detail its role in these processes. In this way we hope to generate a much more detailed understanding of the way that cells deal with DNA damage and choose suicide when the damage is too severe.Read moreRead less
Regulation Of Epithelial Migration By Scribble In Development And Wound Repair
Funder
National Health and Medical Research Council
Funding Amount
$516,078.00
Summary
The movement of epithelial cells within our body (the cells that form the thin protective layer on exposed bodily surfaces such as skin and the lining of internal cavities, ducts, and organs) is essential for our normal embryonic development as well as for healing of wounds following injury. Understanding how this movement is regulated is therefore a fundamental area of medical biology. Although much is known about the mechanics of how a cell moves, the signals used to coordinate this movement s ....The movement of epithelial cells within our body (the cells that form the thin protective layer on exposed bodily surfaces such as skin and the lining of internal cavities, ducts, and organs) is essential for our normal embryonic development as well as for healing of wounds following injury. Understanding how this movement is regulated is therefore a fundamental area of medical biology. Although much is known about the mechanics of how a cell moves, the signals used to coordinate this movement so as to ensure that each cell migrates to the right place during embryonic development or in response to a wound is not well understood. A number of lines of evidence suggest that proteins required for the correct orientation of cells within our body (a property of cells known as polarity) may be essential for this process. Mutation of the polarity protein Scribble in the fly, zebrafish and mouse causes a disorganization of epithelial tissues during embryonic development. We have now shown that Scribble is required for cells to orientate correctly so as to be able to move in response to a wound in tissue culture and also during embryonic development and wound healing in the mouse. It is currently unknown how Scribble regulates migration. Here we propose to identify the molecules that Scribble regulates to coordinate cell movement during development and tissue repair. These studies will provide new insights into the fundamental process of how cell movement is coordinated and could lead to novel strategies for improved treatment of tissue injuries.Read moreRead less
THE ROLE OF A NOVEL NEGATIVE CELL CYCLE REGULATORY PATHWAY DURING ANIMAL DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$406,980.00
Summary
Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). 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 intereste ....Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). 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, Drosophila. Central to the control of cell proliferation in all organisms are the Cyclin dependent protein kinases. Cyclin E-dependent protein kinase 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 and premature entry into the cell cycle. We have used a genetic approach using a weak mutation in Drosophila Cyclin E to isolate mutations in other important regulators of the G1 to S phase transition. This proposal focuses on one of these regulators, Phyl, and the proteins that function with it, Sina and Ebi, which act to target and lead to the degradation of key proteins that negatively regulate differentiation and that promote cell proliferation. In this proposal we seek to understand how the Ebi-Phyl-SIna protein complex functions to control cell proliferation in Drosophila. In addition, we will examine whether the Sina complex also acts to inhibit cell proliferation in the mouse. Due to the remarkable conservation of genes involved in cell proliferation control through evolution, this study is directly relevant to the control of cell proliferation and the development of cancer in humans.Read moreRead less