The Role Of Nuclear Architecture In The DNA Damage Response
Funder
National Health and Medical Research Council
Funding Amount
$561,966.00
Summary
The goal of the proposed research is to understand how dynamic changes to the chromatin genome packaging network, interact with the DNA damage response and gene expression machinery, to repair damaged DNA and the impact this has on cancer biology. To do so we are combining cutting edge molecular biology techniques with innovative novel microscopy methods developed by our research team, that far exceed the spatiotemporal resolution currently used to study chromatin biology.
How Replication Stress Activates The Mitotic Telomere DNA Damage Response To Kill Cancer Cells
Funder
National Health and Medical Research Council
Funding Amount
$486,467.00
Summary
We discovered a novel mechanism linking stress during DNA replication to difficulties with the cell division process, and identified how this turns on DNA damage response signals from the chromosome ends (i.e. “telomeres”). We have further identified that we can exploit this mechanism to kill cancer cells. In this project we will explore this newly discovered mechanism and identify how it can be targeted for therapeutic purposes.
How Do Bone-active Drugs Increase Patient Survival?
Funder
National Health and Medical Research Council
Funding Amount
$613,952.00
Summary
Bisphosphonates are a class of drugs used to prevent bone destruction in diseases such as osteoporosis. Evidence is emerging that these drugs also act on cells outside the skeleton to have additional beneficial effects, for example prolonging patient survival. This project will identify the cells affected and the mechanisms involved. With this knowledge, these drugs could be used more effectively and in different ways for the prevention or treatment of cancer and chronic human illnesses.
Deciphering The Role Of Atypical DNA Methylation In Neuronal Genome Regulation And Neurological Disorders
Funder
National Health and Medical Research Council
Funding Amount
$773,484.00
Summary
This research will use a combination of genomic, biochemical and functional genomics approaches to investigate the role of the atypical mCH form of DNA methylation in neuronal genome regulation and function, and provide new insights into the role of the epigenome in healthy brain function and neural pathologies.
Real-time Optical Window Imaging Of AKT-FRET Biosensor Mice To Maximise PI3K/AKT Drug Targeting Within The Hypoxic Microenvironment Of Pancreatic Cancer.
Funder
National Health and Medical Research Council
Funding Amount
$683,447.00
Summary
Inefficient drug response in solid tumour tissue is often a limiting factor in the clinical effectiveness of cancer therapies. Using cutting-edge imaging technology and 3D models that mimic the disease, we have mapped areas of poor drug response within distinct regions of tumours with low oxygen levels known as hypoxia. Here, we will specifically target factors limiting efficient drug targeting in these areas to improve the encouraging anti-cancer profile of AKT inhibitors in pancreatic cancer.
PARP And PI3K Inhibition In Pancreatic Cancer: Intravital Insights And ‘fine-tune’ Priming Using AKT And Single/double-strand DNA Break Biosensor Mice.
Funder
National Health and Medical Research Council
Funding Amount
$760,505.00
Summary
Inefficient drug response in solid tumour tissue is often a limiting factor in the clinical effectiveness of cancer therapies. Using cutting-edge imaging technology and 3D models that mimic the disease, we can map areas of poor drug response within distinct regions of tumours with chemotherapy. Here, we will shift factors limiting efficient drug targeting in these areas to improve the encouraging anti-cancer profile of PI3K and DNA repair inhibitors in pancreatic cancer.
Epigenetic Changes In The Prostate Cancer Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$848,954.00
Summary
Many men with prostate cancer have slow-growing tumours that are unlikely to spread outside the prostate. These men with low-risk cancer are often monitored to prevent unnecessary aggressive treatments. However, the current methods used to distinguish between slow-growing and aggressive tumours are imprecise and there is a risk of missing aggressive tumours. We aim to identify new biomarkers of prostate cancer by measuring modifications to the DNA in the tumour and surrounding cells
Circulating Tumour DNA To Monitor Treatment Response And Resistance In Chronic Lymphocytic Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$876,950.00
Summary
Many cancers shed small amounts of DNA (ctDNA) into the patient’s bloodstream and recent advances in genomic technologies now allow levels of ctDNA to be accurately measured in the blood. Changes in ctDNA levels have potential to be used as specific markers of disease progression and/or response to cancer therapy. This project will evaluate if ctDNA can be used to monitor treatment responses and individualise treatment decisions in patients with chronic lymphocytic leukaemia.
The Use Of Gene-Silencing Nanodrugs To Inhibit Lung Cancer Growth
Funder
National Health and Medical Research Council
Funding Amount
$452,950.00
Summary
Lung cancer accounts for the most cancer deaths worldwide. This research proposal will use state-of-the-art nanomedicines designed to penetrate lung tumours and suppress a gene which drives cancer growth and resistance to chemotherapy drugs. Our results could underpin new approaches that revolutionise more effective and less toxic treatments for a highly lethal malignancy.
CTCF is a unique architectural protein that regulates the three-dimensional (3D) folding of the genome to switch our genes on, or off. This is important, as it affects how DNA is arranged inside the cells, which is turn assures correct gene expression patterns. Here, we will define the role of CTCF in organizing the 3D genome architecture and identify genetic and epigenetic states that control its function.