Epigenetic Predictors Of Outcome In Malignant Glioma
Funder
National Health and Medical Research Council
Funding Amount
$697,720.00
Summary
Human high grade gliomas (HGG) present as heterogeneous disease, primarily defined by the histologic appearance of the tumor cells.Glioblastoma multiforme (GBM) is the most common illness and continues to have a very poor prognosis, despite the use of multimodality therapy including surgery, radiation therapy and chemotherapy. We will use our existing biobank of specimens, clinical information and molecular investigation to identify factors that determine outcomes.
This study will address the idea that cancer commonly involves a genetic pathway that is normally used by stem cells to proliferate in an undifferentiated state. We have evidence to indicate that this system is active in cancer cells and believe this could explain how cancer cells manage to divide rapidly in a primitive state. This project may bring a new perspective to the study of malignant transformation and has the potential to reveal multiple new targets for cancer therapy.
Somatic Retrotransposition Drives Neoplastic Mutagenesis In Glioblastoma Multiforme
Funder
National Health and Medical Research Council
Funding Amount
$667,342.00
Summary
Retrotransposons are mobile genes that copy-and-paste themselves in our genome. Previously thought to represent “junk DNA”, retrotransposons are increasingly found to play major roles in biology. In a recent landmark publication in Nature, we demonstrated that retrotransposons move in the healthy human brain. In the current study, we will use cutting-edge technologies to determine whether brain cancer can occur as a result. This will provide new perspectives of the genetic basis for cancer.
Genetic And Genomic Dissection Of Polycomb Repressive Complex 2 (PRC2) In Cancer
Funder
National Health and Medical Research Council
Funding Amount
$576,598.00
Summary
The evolution of normal cells to cancer involves mutations that activate cancer-causing genes and/or prevent the actions of anti-cancer genes. It has become increasingly evident that cancer development also involves changes to epigenetic regulation, or control of gene activity by chemical modification of the gene or its environment rather that changes in DNA sequence. This project aims to explore the tumour suppressor activity of an important epigenetic regulatory complex in lymphoma.
Novel Epigenetic And Molecular Determinants Of Gastric Cancer Initation And Progression
Funder
National Health and Medical Research Council
Funding Amount
$432,909.00
Summary
Over one million deaths from stomach cancer occur annually. This often fatal disease can be caused by infection with the bacterium H. pylori. I am a molecular biologist seeking to understand how inflammation caused by H. pylori drives a genetic signature which can be used to predict stomach cancer risk. I will also study how a new family of stomach proteins can prevent tumour growth. My research aims to lead new initiatives for early detection and treatment of stomach cancer.
HIC1 Prevents Tumour Initiation By Maintaining Genomic Stability
Funder
National Health and Medical Research Council
Funding Amount
$531,681.00
Summary
Chromosomes are large structures that package the genome. Abnormalities in the structure and function of chromosomes are now recognised an in important driver of cancer. Using a genetically engineered mouse model this project seeks to understand how this process evolves from the very earliest stages in the evolution of a tumour.
Hereditary Non-Polyposis Colorectal Cancer (HNPCC) confers a high lifetime risk of developing cancer, especially colorectal and endometrial cancer. By characterising disease presentation in the patient cohort, HNPCC in an Australian context will be better defined. The aim of this proposal is to undertake a genetic investigation such that a more comprehensive personalised patient risk-assessment can be completed by identifying genes related to disease development.
Genomic Analysis Of The Novel Epigenetic Modifier Smchd1 As A Tumour Suppressor
Funder
National Health and Medical Research Council
Funding Amount
$619,142.00
Summary
Epigenetic modifications are changes made to our DNA that act like punctuation marks in the genome, to instruct the cell when to turn genes on and when to switch them off. Epigenetic control is critical to range of different biological processes, and also goes awry in cancer. We are specifically interested in the role of one new protein involved in epigentic control and characterising its role as a tumour suppressor.
Determining The Causes And Consequences Of Epigenetic Remodelling In Cancer And Disease
Funder
National Health and Medical Research Council
Funding Amount
$863,413.00
Summary
The study of epigenetics and its role in gene control is proving to be the next major contributor to our future understanding and improvement of health outcomes. Professor Clark and her team are on a quest to unravel the secrets of human epigenome to help reduce the burden of human disease. Their research will help contribute to the discovery of genetic and epigenetic aberrations in cancer and other complex diseases with the development of new diagnostic tests and potential new epigenetic-based ....The study of epigenetics and its role in gene control is proving to be the next major contributor to our future understanding and improvement of health outcomes. Professor Clark and her team are on a quest to unravel the secrets of human epigenome to help reduce the burden of human disease. Their research will help contribute to the discovery of genetic and epigenetic aberrations in cancer and other complex diseases with the development of new diagnostic tests and potential new epigenetic-based therapies.Read moreRead less
Lung cancer is a leading cause of cancer death globally. Symptoms may not develop until disease is advanced, so it is often incurable at diagnosis. Scientific developments have greatly improved our ability to test for the changes in DNA structure and function responsible for this deadly disease and its progression. This study examines whole lung cancer genomes then uses these findings to develop safer methods for detection based on changes in DNA sequence.