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
RNA Binding Protein Musashi: Role In Folliculogenesis And Oocyte Development
Funder
National Health and Medical Research Council
Funding Amount
$419,223.00
Summary
Women in Australian have opted for social and economic reasons to delay both marriage and childbirth. Both infertility and congenital abnormality is associated with advancing maternal age as the ovarian pool of oocytes declines in number and quality. In this project we aim to gain an understanding of the molecular mechanisms underpinning healthy oocyte development. Insights gained have the potential to alleviate miscarriage, infertility and congenital abnormalities in Australian families.
High Resolution Genome-wide Genomic Analysis Of DCIS To Identify Genes Involved In Disease Initiation And Progression
Funder
National Health and Medical Research Council
Funding Amount
$543,370.00
Summary
DCIS is the most common type of noninvasive breast cancer and in some women may progress to malignant disease but little in know about how it develops. We will bring to bear our experience with cutting edge technology and access to extensive clinical resources to the analysis of a large series of pure DCIS with the aim of identifying previously unknown cancer causing genes. This data will lead to the identification of novel breast cancer genes that will assist clinical management.
Xenobiotics - Oxidative Stress In The Mammalian Ovary
Funder
National Health and Medical Research Council
Funding Amount
$377,922.00
Summary
Synthetic chemicals called xenobiotics in the environment are capable of interfering with female fertility. Xenobiotics can trigger oocyte depletion of the ovary and infertility. Exhaustion of the oocyte population results in the menopause, loss of ovarian hormones and profoundly affects female health through increasing susceptibility to heart and bone disease. This research will characterise xenobiotic effects on the ovary and will lead to significant advances in reproductive healthcare.
I am a cellular biologist studying lineage commitment and differentiation in the mammary gland. Key interests include defining transcriptional regulators that are important for mammary gland development and oncogenesis, and the characterisation of normal
Analysis Of Very Early Cancer-related Methylation Abnomalities
Funder
National Health and Medical Research Council
Funding Amount
$422,310.00
Summary
The factors that are involved in triggering cancer are still unknown. Increasing evidence however indicates that the DNA in the pre-cancer cell becomes modified leading to altered expression of important genes called tumour suppressor genes. Often the DNA is deleted or mutated but it can also become chemically changed by a process called DNA methylation. We have found that an important tumour suppressor gene called p16 is inactivated and chemically methylated in breast epithelial cells at the st ....The factors that are involved in triggering cancer are still unknown. Increasing evidence however indicates that the DNA in the pre-cancer cell becomes modified leading to altered expression of important genes called tumour suppressor genes. Often the DNA is deleted or mutated but it can also become chemically changed by a process called DNA methylation. We have found that an important tumour suppressor gene called p16 is inactivated and chemically methylated in breast epithelial cells at the stage when the cell changes to a pre-cancer cell. This grant is aimed at finding what triggers the silencing and methylation of the p16 gene in this early pre-cancer stage. We also plan to identify other genes are methylated and undergo inactivation the pre-cancer breast cells. These results will have an impact on understanding the molecular mechanism that makes a breast cell susceptible to cancer and may lead to insights into new prevention and treatment strategies.Read moreRead less
Isolation And Characterisation Of Mouse Mammary Stem And Progenitor Cells
Funder
National Health and Medical Research Council
Funding Amount
$540,202.00
Summary
We have discovered the rare adult stem cell from which all breast epithelial tissue is formed. A single stem cell was found to be capable of giving rise to various cell types in the breast, including the secretory units that produce milk and the ductal cells that transmit milk to the nipple. These cell types are responsible for the majority of human breast tumours. However, the precise 'cell of origin' from which cancers ultimately develop is not known. We recently also found that the stem cell ....We have discovered the rare adult stem cell from which all breast epithelial tissue is formed. A single stem cell was found to be capable of giving rise to various cell types in the breast, including the secretory units that produce milk and the ductal cells that transmit milk to the nipple. These cell types are responsible for the majority of human breast tumours. However, the precise 'cell of origin' from which cancers ultimately develop is not known. We recently also found that the stem cell population is expanded in at least one model of mammary tumours, suggesting that some tumours may arise from the breast stem cell itself. Using mouse models and cellular assays, our aim is to characterise, for the first time, the hierarchy of stem, progenitor ('daughter cells') and mature cells in the mammary gland. These studies will provide insight into the various cell types that give rise to different types of breast cancer. An important evolving concept in cancer biology is that a rare population of cells resident within a tumour, termed 'cancer stem cells', have indefinite growth potential and drive tumour growth. These cells could even account for resistance to conventional anti-cancer treatment, as cells with stem cell-like properties would be able to proliferate extensively and form new tumours. We will apply our knowledge of normal mammary stem cells to determine whether cancer stem cells are indeed present in mouse tumours. Those findings will have direct relevance to human breast cancer. Utlimately, we wish to identify specific cell surface proteins on stem and precursor cells that could provide therapeutic targets. Our studies will provide new insights into the cell types from which breast cancer arise, and how their fate and tumour-forming capacity can be modified by altering gene expression. Delineation of cancer-prone cells and cancer stem cells could reveal new markers and provide new therapeutic strategies to target breast cancer.Read moreRead less
Genome-wide Expression Analysis In Advanced Gastric Cancer
Funder
National Health and Medical Research Council
Funding Amount
$326,761.00
Summary
Gastric cancer is the fourth ranked cancer by mortality in Australia. Therapy of gastric cancer is unsatisfactory for two reasons; firstly, how normal stomach cells become cancerous is not well defined. We know long-term infection with the bacteria Helicobacter can lead to these cancers, as can severe acid reflux. The cancers produced by these very different agents look remarkably similar, but must be arising through different pathways. Research to date has not yielded great insight. Secondly, e ....Gastric cancer is the fourth ranked cancer by mortality in Australia. Therapy of gastric cancer is unsatisfactory for two reasons; firstly, how normal stomach cells become cancerous is not well defined. We know long-term infection with the bacteria Helicobacter can lead to these cancers, as can severe acid reflux. The cancers produced by these very different agents look remarkably similar, but must be arising through different pathways. Research to date has not yielded great insight. Secondly, existing therapy, especially chemotherapy, tends to provide a Oone size fits all? solution. Whatever the cause, removal at surgery is the best option for treatment. After this, patients are often treated with chemotherapy. Although improvements in patient comfort have been made, very few patients are cured as a result of this treatment. We need more information with which to match the right patient with the right therapy. We will perform high-throughput analysis of comprehensive arrays of human genes that are affected in gastric cancer. Biopsies from cancerous and normal tissue will be obtained when patients have surgery. This tissue will have the RNA (the Omessage? from each gene) labelled with chemical tags and then applied to DNA Omicrochips?. Each microchip contains about 5000 gene targets; the RNA binds the matching DNA and produces a light reaction. We can read the light output from these 5000 (or more) signals, and perform complex statistical analysis on the results. This will result in several specific Ogene expression profiles? which we will analyse to see which profiles match each situation. Profiles matching reflux-induced cancer and Helicobacter-induced cancer can be compared. This will suggest what unique processes are occurring in the cancer cells. Profiles of patients responding well to therapy may allow the use of Otailor-made? therapy. In the future, insight into cancer pathways should also allow the design of new and more successful therapies.Read moreRead less