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In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, ....In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, to investigate the role of Siah in the hypoxia signalling cascade. How cells sense and react to low oxygen levels is complex and involves several proteins. A key protein is called Hypoxia induced factor, Hif-1. It accumulates under hypoxia and is responsible for the expression of genes enabling the cell to tolerate and function under hypoxic conditions. tolerate and function under hypoxic conditions, which is involved in new blood vessel formation. PHD protein directs the degradation of Hif1, while Siah directs the degradation of PHD, when oxygen is limiting. Loss of Siah proteins (eg in our knockout models) leads to an increase in PHD proteins under hypoxia thus no stabilisation of Hif-1 and impaired response to hypoxia. Thus, sitting on the top of a cascade, which controls the trashing of proteins in the cell (focus of this year's Nobel price for medicine), Siah has primary control on the response to oxygen deprivation. The relative immunity of multicellular organisms to acquired defects is through redundancy. Oxygen is a unique case, for which organisms can not bypass the defect via redundancy, making it an attractive target for future therapy. Therefore, understanding the molecular and cellular response to hypoxia may allow us to identify key molecules which could be targeted for the development of novel anti inflammatory and cancer drugs. The scope of this study is to understand the key role of Siah utilising our knockout mice in models of inflammation and cancer.Read moreRead less
Non-viral Vectors For Targeted Delivery Of RNAi Nucleotides To Cervical Cancers
Funder
National Health and Medical Research Council
Funding Amount
$415,738.00
Summary
RNA interference (or gene silencing) is a new technique whereby we are able to turn off the expression of a particular gene either temporarily or permanently. Cancer is basically a genetic disease where certain protective genes are lost or cancer-causing genes expressed. Gene silencing holds great promise in the treatment of genetic disorders, infectious diseases and cancer. Cervical cancer is caused by infection with the human papillomavirus and the expression of two cancer-causing genes. Using ....RNA interference (or gene silencing) is a new technique whereby we are able to turn off the expression of a particular gene either temporarily or permanently. Cancer is basically a genetic disease where certain protective genes are lost or cancer-causing genes expressed. Gene silencing holds great promise in the treatment of genetic disorders, infectious diseases and cancer. Cervical cancer is caused by infection with the human papillomavirus and the expression of two cancer-causing genes. Using RNA interference we can turn off the expression of these two genes which results in the death of the cancer cell. We are also able to cure mice of tumours derived from human cervical cancer. The major issue with gene silencing is how to deliver it effectively to patients. Here we are investigating novel nanoparticulate systems to deliver this new gene-inhibiting drugs preferentially to the tumour site.Read moreRead less
BMP4 - A Metastasis Suppressor Gene In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$454,220.00
Summary
Breast cancer is the most common cause of cancer death in western women. Whilst the primary tumour can often be eradicated successfully, in many cases, it may have already spread to other organs, including lungs, liver and bone, causing severe morbidity. Current treatments are largely palliative and new therapies that specifically prevent to spread of breast cancer are urgently required. However, little is known about the molecular pathways regulating the spread of cancer cells. We have shown th ....Breast cancer is the most common cause of cancer death in western women. Whilst the primary tumour can often be eradicated successfully, in many cases, it may have already spread to other organs, including lungs, liver and bone, causing severe morbidity. Current treatments are largely palliative and new therapies that specifically prevent to spread of breast cancer are urgently required. However, little is known about the molecular pathways regulating the spread of cancer cells. We have shown that expression of a gene called BMP4 in tumours blocks the spread of breast cancer in a mouse model. The aim of this project is to develop the application of BMP4 as a therapy for advanced breast cancer using our mouse model. We will measure the expression of BMP4 in human breast cancer and test whether treatment with purified BMP4 protein can protect mice from the spread of breast cancer. If successful, this study will offer a new therapy for women with currently incurable breast cancer.Read moreRead less
Proteomic Screening For Apoptotic Markers In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$531,696.00
Summary
The induction of apoptosis, or programmed cell death, is a key factor in the response of tumours to chemotherapeutic agents and ionising radiation; therefore biological markers that predict the clinical outcome to these therapies are needed. Over the past 2 years, our laboratory has developed techniques of protein analysis to evaluate changes in proteins during apoptosis caused by chemotherapeutic agents. Preliminary protein profiling studies of apoptosis induction in human breast cancer cell li ....The induction of apoptosis, or programmed cell death, is a key factor in the response of tumours to chemotherapeutic agents and ionising radiation; therefore biological markers that predict the clinical outcome to these therapies are needed. Over the past 2 years, our laboratory has developed techniques of protein analysis to evaluate changes in proteins during apoptosis caused by chemotherapeutic agents. Preliminary protein profiling studies of apoptosis induction in human breast cancer cell lines showed time-dependent decreases in two proteins, identified as S100A6 and ubiquitin. Both are known to be important in cell function. In the proposed project we will build on our preliminary findings to provide important new information central to the understanding of cancer cell biology and apoptosis in addition to evaluating the ability of anti-cancer treatments to induce apoptosis. Using a combination of protein analysis technologies, this project has the potential to provide reliable and novel biomarkers which will indicate the efficacy and selectivity of anti-cancer treatments in inducing tumour cell death. The knowledge gained in this project will aid clinical assessment of the response to cancer treatment(s) in patients in the form of specific screening assays, and may result in identification and development of effective new agents for cancer treatment and prevention. Furthermore, the outcomes of this project will increase our understanding of fundamental cancer cell biology and apoptosis.Read moreRead less