In Vivo Role Of LMO4 And Isolation Of An LMO4-containing Proteosome In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$455,250.00
Summary
Breast cancer is the most common cancer to affect women, with one in 10 developing the disease. Although treatment of breast cancer has substantially improved over the last few years, 25% of women diagnosed with this cancer will die from the disease. A major objective of cancer research is the identification of genes involved in tumour development and definition of their precise role in both normal and cancer cells. The design of effective therapeutic inhibitors of cancer requires an understandi ....Breast cancer is the most common cancer to affect women, with one in 10 developing the disease. Although treatment of breast cancer has substantially improved over the last few years, 25% of women diagnosed with this cancer will die from the disease. A major objective of cancer research is the identification of genes involved in tumour development and definition of their precise role in both normal and cancer cells. The design of effective therapeutic inhibitors of cancer requires an understanding of the basic molecular and cellular biology behind the genetic changes thought to contribute to cancer. The focus of our research is to understand normal cellular mechanisms that drive growth and differentiation of breast tissue, and those changes that lead to breast cancer. Nuclear regulatory proteins have been implicated in many different types of cancers and leukaemias. We aim to identify the key regulators in breast tissue, characterising both their structural properties and biological roles, with the ultimate view of understanding how they divert a normal cell to a cancerous cell. This proposal centres on the characterisation of a specific regulatory molecule which we recently demonstrated to be overexpressed in 56% of human primary breast cancers and in 38% of pre-invasive ductal carcinoma in situ. These studies will include defining its normal biologic function and identification of the proteins that this regulator associates with in breast cancer cells.Read moreRead less
Convergence Of Activated C-myb And Wnt Pathways In Colon Cancer
Funder
National Health and Medical Research Council
Funding Amount
$256,320.00
Summary
c-myb is essential for the normal biology of the blood system and the colon. It is involved in regulating the balance between the production of new cells and their timely removal once they have completed their assigned tasks. Another group of factors that make up theWnt pathway also contribute to the normal biology of the colon in man and mouse. Defects that lead to too much c-myb and ineffective control of the Wnt pathway appear to work together to increase the risk and severity of colon cancer ....c-myb is essential for the normal biology of the blood system and the colon. It is involved in regulating the balance between the production of new cells and their timely removal once they have completed their assigned tasks. Another group of factors that make up theWnt pathway also contribute to the normal biology of the colon in man and mouse. Defects that lead to too much c-myb and ineffective control of the Wnt pathway appear to work together to increase the risk and severity of colon cancer. This project is designed to specifically test this observation in animals. In addition it examines in fine detail how c-myb levels increase in colon cancer and how it combines with the Wnt pathway to regulate other genes in colon cancer.Read moreRead less
Interaction Of Mc1r With The PRb And P53 Pathways In UVR-induced Melanoma Development
Funder
National Health and Medical Research Council
Funding Amount
$553,479.00
Summary
This project will shed light onto fundamental processes causing UV-induced melanoma (MM). Innate differences between individuals, independent of pigmentation, influence MM development. We will study the mechanisms of UVR-induced MM development in mice carrying gene mutations (Cdk4, Arf, Mc1r) that underpin human MM susceptibility. Knowledge of the sensitivity of an one's MCs to UV could be critical for targeting susceptible groups for health education campaigns and more intense screening.
Genetic Dissection Of The Gp130 Signalling Network; Implications In The Initiation Of Gastric Cancer
Funder
National Health and Medical Research Council
Funding Amount
$447,500.00
Summary
Stomach cancer is a major health problem in the world. It is the second most common cancer and the second leading cause of death from cancer, behind lung cancer. In fact, approximately 10% of all new reported cancer cases world-wide are stomach cancer. The risk of stomach cancer increases with age, with risk rising progressively and peaking at about 60 years of age. Men are affected twice as often as women Like all cancers, stomach cancer results from the progressive acquisition of mutations in ....Stomach cancer is a major health problem in the world. It is the second most common cancer and the second leading cause of death from cancer, behind lung cancer. In fact, approximately 10% of all new reported cancer cases world-wide are stomach cancer. The risk of stomach cancer increases with age, with risk rising progressively and peaking at about 60 years of age. Men are affected twice as often as women Like all cancers, stomach cancer results from the progressive acquisition of mutations in genes that normally ensure a balance between cell growth and cell death. Mutations which predispose individuals to stomach cancer accumulate in the epithelial cells that provide the lining to the stomach. The progression of stomach cancer proceeds through a number of distinct anatomical stages which can be easily recognised by pathologists. Mutations in a number of genes (known as Kirsten-ras, p53) are commonly found in stomach tumours. Moreover, some of the mutations are highly associated with distinct stages of tumour development. As yet, however, we have no real insights into how these mutations cooperate with each other to produce full-blown (malignant) stomach cancer. In our proposal, we are aiming to establish stomach cancer in mice. Our approach will be to use an existing animal model which is predisposed to stomach cancer. We will progressively introduce mutant genes into stomach epithelial cells and study how they cooperate with each other to produce benign, and ultimately, malignant tumours in the stomach of mice. This will help us to understand which mutant genes are required for each stage in tumour development and may provide more rational approaches to stomac cancer screening and treatment.Read moreRead less
Contribution Of Tumour And Stroma Derived Cysteine Cathepsins To Breast Cancer Metastasis To Bone
Funder
National Health and Medical Research Council
Funding Amount
$447,094.00
Summary
Breast cancer is a serious clinical problem once the disease spreads to distant tissues such as lung and bone. We have identified a group of genes called the cysteine cathepsin proteases that have increased activity in breast cancers that spread to bone and we have shown this in a mouse model and also in human cancer. We will investigate the contribution of these genes to invasion and test whether inhibiting specific cathepsins can prevent spread of breast cancer to bone in our mouse model .
Understanding The Development Of Pancreatic Islet Cell Tumours
Funder
National Health and Medical Research Council
Funding Amount
$579,163.00
Summary
We will use mouse models of pancreatic cancer that we have established previously to investigate the molecular basis of the development and progression of tumours in the insulin-producing cells of the pancreas. We propose to manipulate a small number of candidate genes using established islet cultures and new mouse models in order to characterise the effect they have on islet cell biology and tumorigenesis.
Conditional Knockout Of The Murine Patched Gene For The Study Of Skin Differentiation And Cancer.
Funder
National Health and Medical Research Council
Funding Amount
$423,564.00
Summary
Basal cell carcinoma (BCC) is the most common cancer in Australia. We recently isolated the BCC gene, Patched (PTCH) from analysis of patients with Naevoid Basal Cell Carcinoma Syndrome (NBCCS). Individuals with NBCCS have a wide variety of developmental defects in addition to a cancer predisposition which includes medulloblastoma, rhabdomyosarcoma and ovarian fibroma as well as multiple BCCs. This application proposes the generation of an animal model for skin development and cancer by selectiv ....Basal cell carcinoma (BCC) is the most common cancer in Australia. We recently isolated the BCC gene, Patched (PTCH) from analysis of patients with Naevoid Basal Cell Carcinoma Syndrome (NBCCS). Individuals with NBCCS have a wide variety of developmental defects in addition to a cancer predisposition which includes medulloblastoma, rhabdomyosarcoma and ovarian fibroma as well as multiple BCCs. This application proposes the generation of an animal model for skin development and cancer by selectively removing patched gene function from specific cell of the skin. In doing this we will be able to determine the exact role of this gene in skin development, and how mutation causes common skin cancer.Read moreRead less
Integrin Beta3 As A Therapeutic Target For Breast Cancer Metastasis To Bone
Funder
National Health and Medical Research Council
Funding Amount
$431,675.00
Summary
There are limited effective treatments for advanced breast cancer. The project investigates the role of a protein called integrin beta3 in the spread of breast tumours to bone, the most common site of secondary tumour formation (metastasis) in breast cancer patients. We will determine if the presence of integrin beta3 in breast tumours identifies patients at risk of developing bone metastases and test novel drugs against integrin beta3 in mice.
The Role Of The EphA1 In The Normal Epithelial Organs And In Epithelial Tumour Progression.
Funder
National Health and Medical Research Council
Funding Amount
$564,500.00
Summary
The Eph family of proteins were initially found to be important in normal development. In humans this corresponds to the first 12 weeks of pregnancy. In parallel with these studies, other work provided evidence of abnormally high levels of these proteins in a number of human cancers. More recent evidence suggests that these proteins have important roles in the maintenance of normal tissues and in non-malignant diseases. This proposal seeks to understand how one of these proteins (EphA1) works in ....The Eph family of proteins were initially found to be important in normal development. In humans this corresponds to the first 12 weeks of pregnancy. In parallel with these studies, other work provided evidence of abnormally high levels of these proteins in a number of human cancers. More recent evidence suggests that these proteins have important roles in the maintenance of normal tissues and in non-malignant diseases. This proposal seeks to understand how one of these proteins (EphA1) works in the cells which form the skin, liver, kidneys, breast and prostate. These cells also form the lining of the mouth, stomach, bowel and lungs. Understanding how the EphA1 protein and other members of this family cooperate to control the development and maintenance of these organs will allow us to determine whether this protein might be involved in congenital defects and diseases in these organs (such as kidney failure, cirrhosis of the liver and skin diseases). A second main aim of this project is to explore further the observation that Eph proteins are abnormally highly expressed in a wide rangre of human cancers. This abnormal expression is directly correlated with the tumours spreading throughout the body. EphA1 is abnormally highly expressed in cancers of the bowel, lung, breast and prostate. These are the commonest cancers in man and some of the most difficult to treat. The work proposed asks how EphA1 contributes to the development and progression of these cancers. These results will have very direct implications for the development of therapies which target the EphA1 protein.Read moreRead less
Transgenic Expression Of The EWS-WT1 Fusion Protein,inducing The Development Of Tumour That Replicates The Human Disease
Funder
National Health and Medical Research Council
Funding Amount
$112,976.00
Summary
A genetic translocation encoding the EWS-WT1 fusion protein is found desmoplastic small round cell tumours. Our aim is to examine the effect of this protein in inducing tumour growth in tissue cell lines. A virus will then be used to introduce the genetic translocation into mice to examine the effect of this protein on tumour growth in a mammal, thereby serving as a 'solid tumour model' to try and identify therapeutic targets.