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Microenvironmental Regulation Of The Tissue Regenerative Capacity Of Keratinocyte Stem Cells And Their Progeny.
Funder
National Health and Medical Research Council
Funding Amount
$391,762.00
Summary
The protective outer layers of the skin known as the epidermis belongs to a group of tissues in the body that are turning over at a rapid rate. The majority ofepidermal cells have a lifespan of just 2-3 weeks, and are shed as mature cells from the skin's surface. These cells are replaced by continuous cell regeneration which is dependent on growth factors and adhesive molecules (and other signals). It has recently come to light that the connective tissue of the skin i.e. the dermis, which lies d ....The protective outer layers of the skin known as the epidermis belongs to a group of tissues in the body that are turning over at a rapid rate. The majority ofepidermal cells have a lifespan of just 2-3 weeks, and are shed as mature cells from the skin's surface. These cells are replaced by continuous cell regeneration which is dependent on growth factors and adhesive molecules (and other signals). It has recently come to light that the connective tissue of the skin i.e. the dermis, which lies directly below the epidermal cells has a critical role in providing some of these factors required for their growth and maturation. Indeed, it is becoming increasingly clear that the epidermal and dermal cells co-operate to regulate epidermal proliferation and maturation. Recent work from our laboratory has shown that a newly recognised adhesive protein laminin-10 may be produced as the result of such co-operation and that it stimulates the growth of both normal and tumour epidermal cells. We have also recently identified an interesting subset of dermal cells that may have a role in promoting the growth of the epidermal cells. Thus, the aims of the proposed stuides are to investigate the role of laminin-10 and this specific dermal cell subset in epidermal proliferation and maturation. These studies may also provide an insight into the role of these factors in skin cancers.Read moreRead less
Cortactin: Molecular Regulation Of Cadherin Activity And Epithelial Morphogenesis.
Funder
National Health and Medical Research Council
Funding Amount
$239,250.00
Summary
Interactions between cells and their neighbouring cells control many important processes in the body. The adhesion molecule E-cadherin is a major protein that controls how cells interact with one another in many epithelial tissues (e.g. breast, lung, gut). These tissues are the source of many common diseases, particular cancer and inflammation. E-cadherin is essential for these tissues to form normally, and loss of E-cadherin function contributes to disease in these tissues (especially common ca ....Interactions between cells and their neighbouring cells control many important processes in the body. The adhesion molecule E-cadherin is a major protein that controls how cells interact with one another in many epithelial tissues (e.g. breast, lung, gut). These tissues are the source of many common diseases, particular cancer and inflammation. E-cadherin is essential for these tissues to form normally, and loss of E-cadherin function contributes to disease in these tissues (especially common cancers, such as breast and lung). Understanding how E-cadherin controls normal cell function in these tissues will therefore provide key insights into how disease arises. In this study we will investigate how a protein which binds to E-cadherin, cortactin, contributes to the biological effect of E-cadherin in supporting tissue architecture. Understanding the fundamental elements of how cortactin works with E-cadherin will provide invaluable information into how cells recognize one another in health, and fail to adequately recognize each other in common diseases.Read moreRead less
Microtubule Capture By E-cadherin: A Novel Mechanism For Dynamic Cell-cell Adhesion.
Funder
National Health and Medical Research Council
Funding Amount
$439,500.00
Summary
This project studies the molecular mechanisms responsible for holding cells together in normal tissues. Such cell-to-cell adhesion is mediated by the cadherin family of molecules, which reside at the surfaces of cells. Cadherins allow cells to recognize one another and, upon recognition, adhere to one another. By this means populations of individual cells can be linked together into cohesive populations (i.e. the tissues or organs of the body). The importance of cadherin adhesion is exemplified ....This project studies the molecular mechanisms responsible for holding cells together in normal tissues. Such cell-to-cell adhesion is mediated by the cadherin family of molecules, which reside at the surfaces of cells. Cadherins allow cells to recognize one another and, upon recognition, adhere to one another. By this means populations of individual cells can be linked together into cohesive populations (i.e. the tissues or organs of the body). The importance of cadherin adhesion is exemplified by the well-documented observation that disruption of cadherin adhesion contributes to many important diseases, including inflammation of epithelia and cancers. Thus understanding the mechanisms by which cadherins hold cells together is necessary for us to understand the molecular basis of commondisease. It has long been known that cadherins work in cooperation with elements within the cell, called the cytoskeleton. My lab has recently made the novel discovery that microtubules, specific components of the cytoskeleton, can regulate the functionof cadherin adhesion molecules. Inparticular, microtubules appear to affect how cadherins can participate in dynamic cell processes necessary for cells to be properly organized in tissues. In this project we will probe the molecular mechanisms responsible for this effect of microtubules. The information obtained will provide important new insights into how dynamic cadherin adhesion is controlled, to help our understanding of the cellular mechanisms that couple cells into tissues, and how they may be disrupted in diesase.Read moreRead less
Preserving Junctions: Regulating Cadherins By Rho And Myosin 2.
Funder
National Health and Medical Research Council
Funding Amount
$425,500.00
Summary
This project studies the molecular mechanisms responsible for holding cells together in normal tissues. Such cell-to-cell adhesion is mediated by the cadherin family of molecules, which reside at the surfaces of cells. Cadherins allow cells to recognize one another and, upon recognition, adhere to one another. By this means populations of individual cells can be linked together into cohesive populations (i.e. the tissues or organs of the body). The importance of cadherin adhesion is exemplified ....This project studies the molecular mechanisms responsible for holding cells together in normal tissues. Such cell-to-cell adhesion is mediated by the cadherin family of molecules, which reside at the surfaces of cells. Cadherins allow cells to recognize one another and, upon recognition, adhere to one another. By this means populations of individual cells can be linked together into cohesive populations (i.e. the tissues or organs of the body). The importance of cadherin adhesion is exemplified by the well-documented observation that disruption of cadherin adhesion contributes to many important diseases, including inflammation of epithelia and cancers. Thus understanding the mechanisms by which cadherins hold cells together is necessary for us to understand the molecular basis of commondisease. Characteristically, cadherins accumulate in structures called adherens junctions, and preserving those junctions is important both for tissues to organize and also to prevent tumor progression. Despite this, we know very little about how junctions are preserved in epithelia. The research to be conducted in this grant will examine exactly this problem. It builds upon recent findings from my lab which indicate that the motor molecule, myosin 2 plays an essential role in preserving junctions. Furthermore, we will test the role for signaling pathways within cells to control the activity of myosin 2 at junctions. This research will provide important novel insights into the cellular mechanisms that couple cells into tissues, and how they may be disrupted in diesase.Read moreRead less
Barrett's oesophagus (BO) is a condition that arises in some patients with chronic reflux (heartburn) and increases the risk of developing cancer of the oesophagus. However, the exact mechanisms involved in its development are unknown. This project aims to investigate how a protein called sonic hedgehog might be involved using novel cell culturing techniques that allow us to model the growth of oesophageal tissue in the laboratory. This could lead to development of new therapies for treating BO.
Discovery And Analysis Of Vertebrate Intestinal Development Genes That May Play A Role In Colon Cancer
Funder
National Health and Medical Research Council
Funding Amount
$376,613.00
Summary
Colorectal cancer (CRC) causes more cancer deaths in Australia than any other cancer. While early detection improves survival rate, nearly half of all CRC patients succumb to the disease within five years. In general, metastatic CRC is resistant to chemotherapy and radiotherapy and new therapies are required. An increased knowledge of the processes that contribute to the malignant state is likely to suggest new targets for treatment. CRC, like all cancer, is the result of genetic abnormalities ( ....Colorectal cancer (CRC) causes more cancer deaths in Australia than any other cancer. While early detection improves survival rate, nearly half of all CRC patients succumb to the disease within five years. In general, metastatic CRC is resistant to chemotherapy and radiotherapy and new therapies are required. An increased knowledge of the processes that contribute to the malignant state is likely to suggest new targets for treatment. CRC, like all cancer, is the result of genetic abnormalities (mutations) that are acquired over the course of a lifetime. Together the mutated genes produce changes in cell behaviour in processes such as growth, migration, angiogenesis (the ability to attract a blood supply) and cell death. All of these processes are active during normal development of a vertebrate organism, but are generally shutdown in the adult state, except in cancer. In this study we will analyse a group of genes that we have recently shown to be indispensable for normal intestinal development in zebrafish. Zebrafish are small tropical fish that are used frequently for genetic studies. They are very closely related to mammals and it has been shown that the genetic pathways that control the development of this animal are highly conserved in fish and mammals. Importantly, the genetic pathways that lead to cancer in humans are also strikingly similar in zebrafish. Our experiments will use mouse models to discover whether the zebrafish genes we have identified can lead to cancer when they are aberrantly expressed in the intestines of mice. Any genes that are found to contribute to the development of cancer in these models could become potential new targets for cancer therapy.Read moreRead less
Interactions Between Hedgehog And Ras Signaling In Lung Adenocarcinoma
Funder
National Health and Medical Research Council
Funding Amount
$295,983.00
Summary
Lung cancer is a common and lethal disease in our community. In this project, we explore how signaling pathways that regulate the development of the lung in embryos contribute to the initation and progression of lung cancer. To do this, we use a mouse model of lung cancer in which we can activate embryonic signaling pathways in adult mice to study there effect on the disease. Understanding these pathways will help us to better treat and prevent lung cancer in humans.
Using A Novel Gut Culture System To Analyse The Influence Of Genes Mutated In Colon Cancer On Epithelial Cell Growth
Funder
National Health and Medical Research Council
Funding Amount
$436,650.00
Summary
Colorectal (or bowel) cancer is a major health problem in Australia. Approximately 1 in 21 Australians will develop the disease in his-her lifetime. The risk of bowel cancer increases with age, with the risk rising progressively and sharply from the age of 50. Current therapies for colorectal cancer are not very effective and the median survival for patients with this disease is poor at 7- 12 months. The development of colorectal cancer is complex and is affected by both genetic and environmenta ....Colorectal (or bowel) cancer is a major health problem in Australia. Approximately 1 in 21 Australians will develop the disease in his-her lifetime. The risk of bowel cancer increases with age, with the risk rising progressively and sharply from the age of 50. Current therapies for colorectal cancer are not very effective and the median survival for patients with this disease is poor at 7- 12 months. The development of colorectal cancer is complex and is affected by both genetic and environmental factors. Colorectal cancer progresses through a number of distinct pathological stages. This is thought to be the result of the progressive aquisition of mutations in genes that normally ensure a balance between cell growth and cell death. Mutations in a number of genes (known as APC, K-ras, p53, SMAD2, SMAD4) are commonly found in colorectal tumours. This research is aimed at understanding how genes which are altered in colon cancer influence the growth of cells in normal intestine. We have developed a system where normal mouse gut can be maintained and grown intact. Genes containing the alterations found in colon cancer will be introduced into the normal gut epithelial cells and the effects on the growth and behaviour of these cells analysed. This should improve our knowledge of how these altered genes contribute to the development of colon cancer.Read moreRead less
Recycling Of E-cadherin: Implications For Dynamic Cell Adhesion
Funder
National Health and Medical Research Council
Funding Amount
$250,494.00
Summary
E-cadherin is one of the major proteins responsible for mediating cell-to-cell adhesion in the body. During embryonic development E-cadherin is essential for establishing the normal body pattern and the cellular architecture of many epithelial organs. Throughout life E-cadherin serves to maintain epithelial barriers, such as the lining of the digestive tract. E-cadherin has been clearly identified as a tumour suppressor molecule: loss of normal E-cadherin function leads to tumour metastasis and ....E-cadherin is one of the major proteins responsible for mediating cell-to-cell adhesion in the body. During embryonic development E-cadherin is essential for establishing the normal body pattern and the cellular architecture of many epithelial organs. Throughout life E-cadherin serves to maintain epithelial barriers, such as the lining of the digestive tract. E-cadherin has been clearly identified as a tumour suppressor molecule: loss of normal E-cadherin function leads to tumour metastasis and cancer invasion. It is therefore essential to understand the physiological function and regulation of E-cadherin in cells. E-cadherin is normally expressed on the surface of cells for adhesion to neighbouring cells. Recently, we found that cells can internalise and recycle this surface E-cadherin: even in mature epithelia, a proportion of the E-cadherin molecules appear to undergo constant movement in and out of the cell. It is likely that this mechanism participates in the dynamic remodelling of adhesive contacts between cells in organs such as the gastrointestinal tract and during wound healing. Corruption of this recycling mechanism could also potentially contribute to tumorigenesis. In this grant we propose to build upon this discovery by investigating molecular and cellular mechanisms that mediate E-cadherin recycling. We will characterize the cellular pathways by which E-cadherin is trafficked. The signaling pathways that regulate recycling will be analysed, since these may be perturbed in cancer and inflammation. Other molecules that interact with E-cadherin will be studied to determine whether they too recycle. The information from these studies will have broad implications for understanding the role of E-cadherin in healthy organs and in common cancers.Read moreRead less
A Fluorescent Zebrafish Model Of Endodermal Cell Migration.
Funder
National Health and Medical Research Council
Funding Amount
$535,333.00
Summary
The most catastrophic event in cancer progression is when individual cancer cells move to other areas of the body and develop into secondary tumours. This very complex process shows striking similarities to cell movements during embryogenesis. In this project, we use a model system, the zebrafish, to analyse how cells move during embryogenesis. We will determine the genes required for cell movements in the zebrafish embryo, so we can find the corresponding genes in human cancers.