DNA Damage Induced By UVA And UVB In Squamous Cell Carcinoma Progression
Funder
National Health and Medical Research Council
Funding Amount
$65,000.00
Summary
Australia has the highest incidence of skin cancer in the world. This results from immigration of individuals with fair skin to Australia. Skin cancer is three times as common as all other cancers combined. Overall, the incidence of skin cancer continues to rise in Australia and it will be several years before the true effectiveness of preventative programs are known. In the meantime, 1000 Australians die each year from skin cancer. Modern sunscreens, even those with high SPF and labelled as bro ....Australia has the highest incidence of skin cancer in the world. This results from immigration of individuals with fair skin to Australia. Skin cancer is three times as common as all other cancers combined. Overall, the incidence of skin cancer continues to rise in Australia and it will be several years before the true effectiveness of preventative programs are known. In the meantime, 1000 Australians die each year from skin cancer. Modern sunscreens, even those with high SPF and labelled as broad spectrum do not protect very well from UVA, though they are very effective UVB filters. Most sunscreens absorb or reflect only about 50% as much UVA as UVB. Thus sunscreen use alters the spectrum of UV received. This is an important issue, because if sunscreens are used to prolong sun exposure they will selectively increase the amount of UVA reaching the skin, and the sun contains a lot more UVA than UVB. There is only limited evidence to suggest they protect from skin cancer in humans whereas there is good evidence that they protect from precursor lesions. We have developed a new hypothesis, that UVB is primarily responsible for development of preneoplastic lesions (solar keratosis and dysplastic nevi) whereas UVA plays a relatively more important role in their progression to malignancy. This hypothesis would explain why sunscreens are more effective at preventing nevi and solar keratosis formation than they are at preventing melanoma and squamous cell carcinoma. Until the action spectrum defining the wavelengths responsible for skin cancer induction is known, the optimal methods for protection from skin cancer will be difficult if not impossible to design. That different wavelengths may be involved in different phases of skin cancer development in humans is a novel hypothesis: if it is correct it will have profound implications for both the design of sunscreens and our current public health programmes for skin cancer prevention.Read moreRead less
Effects Of A Novel Hotspot Mutation Of Brm In Non-Melanoma Skin Cancer Development
Funder
National Health and Medical Research Council
Funding Amount
$92,314.00
Summary
Australia has the highest incidence of skin cancer in the world. SWI/SNF, a yeast nucleosome remodeling complex, is known destabilise interactions in DNA. It is made up of 8-10 proteins, including a novel tumour suppressor Brm. There is some evidence that Brm acts as a tumour suppressor in skin cancer, but relevance of a recently found mutation in Brm is yet to be characterised. This project aims to identify the effect of this mutation, on cellular sensitivity to UV radiation and examine transfo ....Australia has the highest incidence of skin cancer in the world. SWI/SNF, a yeast nucleosome remodeling complex, is known destabilise interactions in DNA. It is made up of 8-10 proteins, including a novel tumour suppressor Brm. There is some evidence that Brm acts as a tumour suppressor in skin cancer, but relevance of a recently found mutation in Brm is yet to be characterised. This project aims to identify the effect of this mutation, on cellular sensitivity to UV radiation and examine transformation to malignancy.Read moreRead less
The Nature And Significance Of Clonal Evolution In Human Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$665,420.00
Summary
Cancers can progress in patients by developing genetic changes that favor the growth, survival and spread of cancer cells. However, the rate at which genetic changes occur in human cancer is not known. This project will determine the degree and biological significance of genetic change in human melanoma by using a novel method of growing tumors from single cells and comparing genetic differences between them.
The Transcriptional Profile Of A Metastatic Circulating Melanoma Cell
Funder
National Health and Medical Research Council
Funding Amount
$273,630.00
Summary
Melanoma is an aggressive skin cancer, and the leading cause of skin cancer related deaths. Disease spread is difficult to detect and difficult to cure. We previously identified circulating melanoma cells in patient peripheral blood and showed that their presence is associated with disease stage and recurrence. We will now fully characterise the phenotype of actively metastatic circulating melanoma cells for better patient prognosis and routine monitoring.
Effects Of Nevogenesis Susceptibility Genes And Phenotypic Correlation With Dermoscopic Characteristics Of Nevi
Funder
National Health and Medical Research Council
Funding Amount
$554,099.00
Summary
Melanoma is a form of skin cancer that arises from the cells that produce pigment and is a major public health issue in Australia. We will examine the relationship between the form, structure and colour of existing types of moles and their subsequent risk of developing into melanoma. This will be the first study to combine dermoscopy, a non-invasive examination technique, with DNA tests of the genes that determine skin, hair and eye colour, aiding in the early prediction and diagnosis of skin ca ....Melanoma is a form of skin cancer that arises from the cells that produce pigment and is a major public health issue in Australia. We will examine the relationship between the form, structure and colour of existing types of moles and their subsequent risk of developing into melanoma. This will be the first study to combine dermoscopy, a non-invasive examination technique, with DNA tests of the genes that determine skin, hair and eye colour, aiding in the early prediction and diagnosis of skin cancer.Read moreRead less
Role Of Brm In Skin Tumour Progression From Benign To Malignant
Funder
National Health and Medical Research Council
Funding Amount
$457,267.00
Summary
Australia has the highest incidence of skin cancer in the world. Skin cancer is 3 times as common as all other cancers combined and continues to increase in incidence, particularly in the aging population. Skin cancer is caused by exposure to the ultraviolet radiation found in sunlight. Ultraviolet radiation causes the appearance of solar keratosis, or sunspots, benign lesions that are not particularly dangerous to human health. Some of these develop into malignant squamous cell carcinomas that ....Australia has the highest incidence of skin cancer in the world. Skin cancer is 3 times as common as all other cancers combined and continues to increase in incidence, particularly in the aging population. Skin cancer is caused by exposure to the ultraviolet radiation found in sunlight. Ultraviolet radiation causes the appearance of solar keratosis, or sunspots, benign lesions that are not particularly dangerous to human health. Some of these develop into malignant squamous cell carcinomas that can spread to other tissues and are potentially fatal. Little is known about the biological mechanisms involved in solar keratosis development into squamous cell carcinomas. We have identified the gene brm as being involved in this process. It has not previously been recognised that this gene is important for skin cancer development and therefore our preliminary studies have identified a potential new target. We will study the role of this gene in ultraviolet radiation induced skin carcinogenesis, determine whether it is mutated by ultraviolet radiation in human skin cancer, and what role in plays in some key biological processes in skin cancer development. This study will expand our understanding of malignant conversion during human skin carcinogenesis, the most prevalent human cancer in Australia.Read moreRead less
Comprehensive Assessment Of Genetic And Environmental Risk Factors For Melanoma: A Population-based Family Study
Funder
National Health and Medical Research Council
Funding Amount
$150,679.00
Summary
Excessive sunlight can cause melanoma, a serious type of skin cancer. However, there are other factors including a person's genetic make-up that are thought to put some people at higher risk. Many 'healthy' people have small changes in their genes that might make them more likely to develop melanoma. We need to know more about these genetic factors. Our study will investigate how particular small genetic changes influence a person's likelihood of developing melanoma.
I am a molecular geneticist with a special interest in molecular pathology determining the inherited and somatic genetic events that predispose to, and advance cancer development. Much of this work has immediate translatability to clinical genetics practi
Kallikrein Gene Variants In Prostate Cancer: Analysis Of Gene Regulation And Diagnostic/Prognostic Use
Funder
National Health and Medical Research Council
Funding Amount
$486,801.00
Summary
Prostate cancer is the most common male cancer in Australia. However, early detection through screening programs has proven challenging, and about 30% of the 10,000 new cases diagnosed annually already have advanced disease. Hence, there is a fundamental need for increased basic research in prostate cancer etiology (cause) and tumour biology, and a critical requirement for methods that will assist in earlier detection of the disease and predict progression. A family of proteins called kallikrein ....Prostate cancer is the most common male cancer in Australia. However, early detection through screening programs has proven challenging, and about 30% of the 10,000 new cases diagnosed annually already have advanced disease. Hence, there is a fundamental need for increased basic research in prostate cancer etiology (cause) and tumour biology, and a critical requirement for methods that will assist in earlier detection of the disease and predict progression. A family of proteins called kallikreins (including prostate specific antigen, PSA) are often associated with clinical features of prostate cancer. We will characterise genetic variants (polymorphisms) in kallikrein genes that are consistently over-produced in prostate cancer, and determine whether they cause more protein to be produced in cells grown in the laboratory and in tumour tissue, and-or give rise to different expression products or splice variants. We will use bioinformatics (computer programs) to characterise published kallikrein gene sequences and to examine them for genetic variants that might be related to changes in gene expression or to splice variants. We will then use a case-control study, involving 1200 men with prostate cancer and 1200 healthy men, to determine whether these gene variants are associated with an increased risk of prostate cancer or with clinical aspects of the disease. Finally, we will examine the functional significance of the gene variants. This project represents an important and novel combination of molecular biology with the study of clinical disease at the population level, in the relatively new field of molecular epidemiology. It will clarify the role of kallikrein gene variants in prostate cancer risk and progression. The technologies may ultimately prove useful clinically for diagnosis of prostate cancer or for monitoring of treatment and prognosis, and hopefully will assist in clinical decision-making.Read moreRead less