I am a developmental cell biologist and molecular geneticist focusing on mechanisms controlling cell proliferation and modelling the development of cancer in the vinegar fly, Drosophila.
Next-generation Sequencing Of Candidate Ovarian Tumour Suppressor Genes
Funder
National Health and Medical Research Council
Funding Amount
$101,899.00
Summary
In Australia in 2001 there were approximately 1300 new cases of ovarian cancer. Survival of ovarian cancer is very poor and current treatments inadequate. To develop more effective treatments we need to understand the molecular events that cause ovarian cancer. Some genes are inactivated by loss of a copy or mutation. We aim to find these genes using new DNA sequencing techniques.
Control Of Salvador-Warts-Hippo Pathway Activity In Drosophila And Mammals
Funder
National Health and Medical Research Council
Funding Amount
$514,048.00
Summary
The primary function of the Salvador-Warts-Hippo (SWH) pathway is to dictate the appropriate size of organs in developing animals. Deregulation of this pathway results in vastly overgrown organs and can lead to the formation of cancer in humans. Our study will provide important insights into how the size of organs are controlled during development by identifying new SWH pathway components. We will also increase understanding of diseases that arise due to aberrant tissue growth, such as cancer.
Examination Of The Mechanism By Which The Salvador/warts/hippo Complex Restricts Cell Growth And Number
Funder
National Health and Medical Research Council
Funding Amount
$283,767.00
Summary
Cancer is a disease that results from the generation of surplus cells. These extra unwanted cells are produced as a result of excess cell proliferation and impaired programmed cell death. These important processes can be deregulated in cancers as a result of mutations in many different genes. Many genetic lesions have been reported in different types of cancers but many of the genes that are mutated in these diseases have yet to be identified. To isolate new genes involved in cancer we created r ....Cancer is a disease that results from the generation of surplus cells. These extra unwanted cells are produced as a result of excess cell proliferation and impaired programmed cell death. These important processes can be deregulated in cancers as a result of mutations in many different genes. Many genetic lesions have been reported in different types of cancers but many of the genes that are mutated in these diseases have yet to be identified. To isolate new genes involved in cancer we created random mutations in the vinegar fly, Drosophila, and tested their ability to cause solid cancers. Drosophila is an excellent model organism for this study because many of the pathways that are often perturbed in cancer are conserved between humans and flies. Using this approach we identified several known and novel genes that cause cancerous growths. By studying the human counterparts of these novel genes we identified a potential role for some of these genes in the generation of human cancer. Three of these genes, hippo, salvador and warts, appear to act in concert to restrict cell number. In this study we aim to understand the mechanism by which these genes restrict cell number. To do this we will analyze how the activity of this pathway is controlled and in what tissues it functions. We also plan to discover other key components of this pathway that function downstream of hippo, salvador and warts. To perform these experiments we will use a variety in vitro biochemical techniques as well as experiments in tissue culture cells. We will then verify the results of these experiments in the context of a whole animal. By performing these experiments we hope to gain greater insight into the genesis of cancer.Read moreRead less
An understanding of the way cells control their complex internal circuitry is relevant to diseases like cancer and leukemia. The main focus of this project is a cellular regulator we identified several years ago called BORIS. Normally dormant in all cells outside the male reproductive organs, BORIS is reactivated in many cancers. We will study the network of factors perturbed when BORIS becomes inappropriately active in cancer cells. Ultimately this project may lead to new treatments for cancer.
Identifying Long-range Regulatory Elements Of The Breast Cancer Susceptibility Gene, BRCA1
Funder
National Health and Medical Research Council
Funding Amount
$612,842.00
Summary
BRCA1 is a breast cancer susceptibility gene implicated in both familial and sporadic breast cancers. The mechanisms controlling BRCA1 expression are poorly understood. We will identify DNA sequences critical for regulation of the BRCA1 gene. We hypothesise that these regions are mutational hot spots conferring an increased breast cancer risk. A better understanding of the pathways responsible for promoting BRCA1-associated breast cancer will provide important diagnostic and treatment targets.
Function Of FOR Gene Products In Normal And Cancer Cells
Funder
National Health and Medical Research Council
Funding Amount
$521,310.00
Summary
Cancer cells usually exhibit the loss of control of normal cell functions. This involves the increase of proteins which promote growth and cell division and the decrease in proteins which inhibit growth and cell division. Loss of function may also occur in proteins that are normally involved in killing the cell when growth becomes uncontrolled. Many of these proteins interact with one another and in so doing establish pathways and networks of control which must be perturbed and overridden in the ....Cancer cells usually exhibit the loss of control of normal cell functions. This involves the increase of proteins which promote growth and cell division and the decrease in proteins which inhibit growth and cell division. Loss of function may also occur in proteins that are normally involved in killing the cell when growth becomes uncontrolled. Many of these proteins interact with one another and in so doing establish pathways and networks of control which must be perturbed and overridden in the cancer cell. Sometimes this is because the role of the protein is altered in the cancer cell compared to what it normally is in a normal cell. The main aim of this study is to understand the role that is played by a set of proteins that are coded by a single gene. This gene (which we refer to as the FOR gene) spans a region of the human genome which is sensitive to a particular type of mutation. This mutation takes place early in tumour development and therefore we believe that it has important role to play in determining the fate of the cell - helping to cause it to become a tumour cell. We will find out which other proteins in the cell the FOR proteins interact with. Where these proteins are known then this will help determine the pathways in the cell in which the FOR proteins participate. In another approach we will establish animal models (in mice and flies) of mutations in the FOR genes of these species. The transgenic mice will help us find out whether the mutations that we have observed in the FOR gene in various human cancers cause increased sensitivity to mutagens and in so doing aid in transforming normal cells into cancer cells. The transgenic flies will help us identify the metabolic pathways in which the FOR proteins participate. These studies will help understand the roles of the FOR proteins and their significance in cancer.Read moreRead less
Inhibition Of Retinoblastoma Protein Degradation By Interaction With The Serpin PAI-2 Via A Novel Consensus Motif
Funder
National Health and Medical Research Council
Funding Amount
$463,500.00
Summary
Plasminogen activator inhibitor-2 (PAI-2) has previously been shown to inhibit the activity of enzymes outside the cell that are involved in blood clotting and cell migration. We have discovered that this activity is probably not the major role of PAI-2. PAI-2 also has a function inside cells that protect and increases the activity of an important tumour suppressor protein called the retinoblastoma tumour suppressor protein (Rb). Rb is involved in many cellular functions such as, cell death, cel ....Plasminogen activator inhibitor-2 (PAI-2) has previously been shown to inhibit the activity of enzymes outside the cell that are involved in blood clotting and cell migration. We have discovered that this activity is probably not the major role of PAI-2. PAI-2 also has a function inside cells that protect and increases the activity of an important tumour suppressor protein called the retinoblastoma tumour suppressor protein (Rb). Rb is involved in many cellular functions such as, cell death, cell differentiation, cell growth, and most importantly prevention of cancer development. Rb is attacked and destroyed by several viruses which causes cells to become cancerous. This grant seeks to fully understand how PAI-2 protects and interacts with Rb. We have already found a new site on Rb to which PAI-2 binds. This site is also used by other proteins in the cell as well as disease causing virus proteins. Examples of these proteins are BRCA1, a protein involved in breast cancer development, and EBNA6, a protein from Epstein Barr virus that causes glandular fever and tumours. We have also found, and seek to explore further, how PAI-2 reverses the activities of the cervical cancer causing proteins of the human papilloma virus. Although at an early stage, these studies may lead to the development of new therapeutic drugs based on PAI-2 for the treatment of various types cancers or warts caused by HPV. Analysing the activity of PAI-2 inside cells will have implications for understanding much of the confusing scientific literature on PAI-2 and will provide a better comprehension of the role of PAI-2 in inflammation, cell differentiation, wound healing and cancer. For example it has long been known that the presence of PAI-2 in cancerous tumours is linked with a better prognosis, an activity that can now be understood in terms of the PAI-2 interaction with Rb. This new understanding may lead to the development of PAI-2 based prognostic assays for cancer.Read moreRead less
Porphyromonas Gingivalis Cysteine Proteinases In Modulation Of Cell-mediated Immune Response In Periodontitis
Funder
National Health and Medical Research Council
Funding Amount
$228,000.00
Summary
Chronic inflammatory diseases of the tissues supporting the teeth comprise some of the most widespread and common diseases to affect mankind. Recent research has indicated the major contributor to the most common form of destructive periodontal disease is the bacterium Porphyromonas gingivalis. This organism produces powerful enzymes which overcome the body's attempts to neutralise them. It is also known that the destructive phase of the disease is characterised by a change in the behaviour of t ....Chronic inflammatory diseases of the tissues supporting the teeth comprise some of the most widespread and common diseases to affect mankind. Recent research has indicated the major contributor to the most common form of destructive periodontal disease is the bacterium Porphyromonas gingivalis. This organism produces powerful enzymes which overcome the body's attempts to neutralise them. It is also known that the destructive phase of the disease is characterised by a change in the behaviour of the immune system cells which accumulate in the diseased tissues. This is manifest as a loss of protective immunity and replacement by ineffective or even tissue damaging responses. Critical in directing the pattern of behaviour of the immune system cells are the potent messenger molecules or cytokines which pass between cells. We have demonstrated that the bacterial proteinases can destroy a critical messenger molecule that instructs the defensive phagocytic cells to attack bacteria. These cells in return normally send a powerful signal back to the controlling T lymphocyte to amplify the protective signals. Associated bacterial molecules stimulate more secretion of messenger molecules which are paradoxically destroyed by the bacterial enzymes. This could cause chaos in the local tissue environment. Further, the bacterial proteinases can also eliminate some important surface molecules of T lymphocyte that are important in the activation process. The effect of this could produce impairment of T lymphocyte at periodontal sites. The planned research will define how the proteinases modulate T lymphocyte immune response. Further, the relation between the capacity of the bacterial enzymes to disrupt the vascular cells and the progression of periodontitis will also be determined.Read moreRead less