All cells have a characteristic shape (morphology), which is intrinsic to cellular function. A blood cell is designed to move in a liquid medium whereas a muscle cell is optimised for physical movement of attached bones. We are studying the mechanisms which control cell shape. We focus on the components of the cell skeleton (cytoskeleton) which are implicated in the regulation of shape. In particular, we study the actin based microfilament system. We have previously shown that two types of these ....All cells have a characteristic shape (morphology), which is intrinsic to cellular function. A blood cell is designed to move in a liquid medium whereas a muscle cell is optimised for physical movement of attached bones. We are studying the mechanisms which control cell shape. We focus on the components of the cell skeleton (cytoskeleton) which are implicated in the regulation of shape. In particular, we study the actin based microfilament system. We have previously shown that two types of these components of the cytoskeleton are able to control the structure of cells. In addition, we have found that variants of these two components (called isoforms) are used to build structures in different parts of cells. This has led us to think about the anatomy of cells and tissues in a new way. In some ways its like building a city. You create different kinds of buildings to suit their purpose. Each building uses a combination of building blocks which suit the structural demands of rooms and the overall building. In this study, we are proposing to dissect out genes, or parts of genes, which supply specific types of building blocks. To do this, we plan to change these genes in mice and then examine the impact on cell and tissue anatomy. This promises to contribute to the conversion of anatomical science and pathology from descriptive to experimental-mechanistic disciplines.Read moreRead less
Role Of Beta-catenin And Its Regulator FAM In Haemopoietic Stem Cell Function
Funder
National Health and Medical Research Council
Funding Amount
$506,500.00
Summary
Haemopoietic stem cells (HSC) are currently the best characterised adult stem cell (SC) population and currently the only SC population used in cellular therapy. Adult HSC reside in the bone marrow and it is generally accepted that these rare cells cycle slowly and maintain themselves by a process involving self renewal. The cellular physiology that underlies HSC self renewal is still to be defined and no single factor has been described which is able to induce substantial proliferation and expa ....Haemopoietic stem cells (HSC) are currently the best characterised adult stem cell (SC) population and currently the only SC population used in cellular therapy. Adult HSC reside in the bone marrow and it is generally accepted that these rare cells cycle slowly and maintain themselves by a process involving self renewal. The cellular physiology that underlies HSC self renewal is still to be defined and no single factor has been described which is able to induce substantial proliferation and expansion of HSC in a defined system while maintaining critical stem cell properties. Like other SC, a critical characteristic of the rare HSC population of cells is their ability to maintain their unique stem cell properties in vivo (the process of self-renewal) while generating more committed cells which will form large numbers of differentiated and specialized mature blood cells. Recent evidence that HSC can repair other organs under some circumstances raises the possibility that this adult SC population could provide an alternative to embryonic stem cells for many stem cell therapies. If this is the case the therapeutic application of HSC becomes significantly broader. Critical to development of such applications will be an understanding of HSC self renewal and development and new approaches to expand this limited cell population. Major progress in this area will require the definition of both the intrinsic and extrinsic mechanisms that control HSC maintenance and self-renewal. Any findings in this area will have major clinical significance and be of enormous benefit to the community. Here we focus on the role of a known intrinsic regulator of SC behaviour (beta-catenin) with the aim of establishing its role in the maintenance of HSC and its regulation by a novel cofactor (FAM). We will determine if the level of beta-catenin is critical in the maintenance and-or differentiation of haemopoietic stem cells and what role FAM plays in this regulation.Read moreRead less