Do ‘classical’ Or ‘oxidative’ UVR-induced DNA Adducts Drive Melanoma Induction After Ultraviolet Radiation
Funder
National Health and Medical Research Council
Funding Amount
$335,757.00
Summary
There is debate about the mechanisms by which sun exposure influences melanoma development. This leads to difficulties in formulating adequate sunscreens and guidelines for safe levels of exposure. We will elucidate the critical UV-induced DNA adducts that are necessary for MM development. This will introduce experimental evidence into the debate about sun exposure and melanoma. The use of post sunburn creams containing enzymes which rapidly remove the dangerous DNA adducts will be indicated.
There is a need for a greater understanding of the complex relationship between sun exposure and the production of Vitamin D. This study will expand on the recently-completed AusD study to examine how personal, behavioural, and environmental factors impact on intra-individual seasonality in Vitamin D production. The study findings will guide the development of specific, evidence-based public health recommendation that balance the risks and benefits of sun exposure.
Squamous cell carcinoma of the skin is extremely common in Australia, resulting in disfiguring surgeries and deaths. Although cumulative sun exposure is important, some people are very susceptible, and we do not know why. This project hinges on the notion that skin cancer is a complex (many genes involved). We will utilize novel systems to harness this complexity to understand why some people are resistant and others very susceptible so as to design appropriate control measures and treatments.
Fighting Epidermal Skin Cancers By Targeting Epidermal Clones That Accumulate Mutations
Funder
National Health and Medical Research Council
Funding Amount
$1,149,373.00
Summary
Common skin cancers such as basal and squamous cell carcinomas (BCC and SCC) are by far the most frequent cancer worldwide and require over a million interventions per year in Australia. This project will identify the skin cells that are most susceptible to give rise to cancer if excessively exposed to the sun and explores ways to prevent cancer formation. This will inform on new strategies to prevent new skin cancer development.
Tracking Epidermal Clonal Evolution During Skin Cancer Induction And Progression
Funder
National Health and Medical Research Council
Funding Amount
$558,168.00
Summary
Skin cancer is the most frequent form of cancer in Australia and in many parts of the world. It is strongly connected to ultraviolet radiation from the sun. In this project, we will use our capacity to track individual cells, to observe the heterogeneity of tumours and the lesions that precede them. We will show the importance of this heterogeneity in tumour progression unveiling the limits of current therapies against skin cancer.
Synthetic Lethality Screen Targeting A Defective Checkpoint In Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$552,121.00
Summary
All cancers have defects in the mechanisms that regulate normal cell growth and division. These defects provide a growth advantage for the cancer, but can also be an Achilles Heel. In this project we will investigate targeting a defective control mechanism we found in a high proportion of melanomas. We will identify genes that when inhibited combine with the defective control to specifically kill tumour cells with this defect. Normal tissue is protected by its intact regulatory mechanism.
Brm And Brg-1 Protect From Ultraviolet Radiation-induced Skin And Ocular Damage
Funder
National Health and Medical Research Council
Funding Amount
$555,325.00
Summary
Ultraviolet radiation within sunlight is the most important environmental hazard to which Australians are exposed. It causes cancers of the skin and eye, in addition to other forms of skin and eye damage. However sunlight also has health benefits such as vitamin D production. To protect our health from the sun we need to understand how it causes damage and the meachanisms involved. We have discovered a new pathway that we plan to study, called Brm and Brg-1, that provides protection from UV.
First Ever System To Continuously And Directly Measure The Internal Anatomy To Guide Breast Cancer Radiation Treatment Under Deep Inspiration Breath Hold
Funder
National Health and Medical Research Council
Funding Amount
$409,766.00
Summary
We propose a first ever system to continuously and directly measure the internal anatomy of the patient during radiotherapy of left sided breast cancer to ensure correct position of patient and radiation beam. The proposed method involves no additional radiation dose to the patient. It relies on existing components of modern radiation treatment machines, requiring no additional equipment, which will make it easy to implement widely.
Improving Radiation Therapy Of Static And Moving Targets Using High Spatial Resolution Real-time Dosimeters
Funder
National Health and Medical Research Council
Funding Amount
$544,425.00
Summary
Radiation therapy is a major oncology modality for cancer treatment and more than 50% of cancer patients can benefit from radiotherapy at some stage of management. This project will develop two real-time, high spatial resolution dosimetry systems for quality assurance of contemporary radiation treatments of static and movable targets. It will be possible to minimize human and robotic system error so as to guarantee accurate cancer treatment delivery and improve the clinical outcomes of radiother ....Radiation therapy is a major oncology modality for cancer treatment and more than 50% of cancer patients can benefit from radiotherapy at some stage of management. This project will develop two real-time, high spatial resolution dosimetry systems for quality assurance of contemporary radiation treatments of static and movable targets. It will be possible to minimize human and robotic system error so as to guarantee accurate cancer treatment delivery and improve the clinical outcomes of radiotherapy.Read moreRead less
REVEALING MOLECULAR MECHANISMS OF THE SYNCHROTRON RADIATION-INDUCED BYSTANDER EFFECT
Funder
National Health and Medical Research Council
Funding Amount
$429,294.00
Summary
Radiotherapy, a major treatment for more than half of cancer patients, is based on the dogma that radiation kills targeted cells. The radiation-induced bystander effect, by which the neighbours of irradiated cells can also damaged, is a new paradigm. What is the "danger signal" which induces DNA damage in un-irradiated normal tissues, and what minimal volume of tissue needs to be irradiated to induce bystander damage? The answers could have a major impact on optimising radiotherapy treatment.