This work will analyse how cells, the building blocks of tissues, are organized together to form functioning organs. It focuses on the adhesion molecules that allow cells to recognize one another, which cooperate with the internal skeleton of cells to link them together. We aim to understand how these cellular systems work normally and how they are targeted to disrupt tissue integrity in diseases like cancer and inflammation.
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
Inhibition Of Cellcell Actin-based Motility During Poxvirus Infection By The Kinase Inhibitor Glivec
Funder
National Health and Medical Research Council
Funding Amount
$92,950.00
Summary
Although smallpox, one of the deadliest human pathogens, was eradicated in 1980, the current global climate has resulted in fears that smallpox may be used as a biological weapon. Unfortunately the smallpox vaccine poses a serious health hazard to certain people. We have shown that Glivec, a drug used to treat cancer, has potent anti-viral affects on poxvirus replication. This project will test the effectiveness of Glivec in treating smallpox in an animal model and study how it acts.
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
Aberrant Mesenchymal-epithelial Transition: A Pathogenic Mechanism In Tissue Maintenance And Differentiation
Funder
National Health and Medical Research Council
Funding Amount
$522,299.00
Summary
The causative genetic factors associated with aberrant changes of cellular properties are identified by analysing the profile and the control mechanism of gene expression. Specifically,this project will reveal how the transition of different patterns of tissue organization may be manifested in birth defects and malignant diseases.
Aberrant Ependymal Development And The Formation Of Hydrocephalus
Funder
National Health and Medical Research Council
Funding Amount
$660,005.00
Summary
Foetal hydrocephalus is a prevalent neurodevelopmental condition associated with severe intellectual impairment. Breakdown of the ependymal cell layer, which acts as a barrier between brain tissue and the ventricular space, is a major cause of hydrocephalus. Despite the importance of these cells, we have little understanding of the molecular mechanisms that regulate their production. This project will identify critical signalling pathways governing the establishment of the ependymal layer.
Deciphering The Role Of Scribble In Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$628,789.00
Summary
Scribble is a protein that controls the orientation and organization of all cells within our body. Mutations in the Scribble gene are found in many cancers and also in some patients with spina bifida, however how these mutations cause these diseases is not understood. Here we propose experiments that can be used to link Scribble mutations to specific cellular functions. This information will help us design new therapies to treat diseases driven by tissue disorganization such as cancer.