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 identify the specific job that one of these types of building blocks must play in order to allow normal cell growth and embryo development. 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. This in turn will lead to a new tool set of diagnostic agents for the pathologist and the development of drugs which target specific functions of the cytoskeleton.Read moreRead less
The Role Of Reduced Lung Volume In The Pathogenesis Of Asthma.
Funder
National Health and Medical Research Council
Funding Amount
$275,095.00
Summary
Asthma is a disease for which the cause is not understood. This project is designed to examine the possibilty that breathing at low volumes causes an abnormality in the smooth muscle of the airways that predisposes them to the airway hyperresponsiveness of asthma.
Myo1b Bridges The Actin-membrane Interface During Osteoclastic Bone Resorption
Funder
National Health and Medical Research Council
Funding Amount
$429,387.00
Summary
Osteoporosis is a debilitating bone disease which features progressive bone loss. Bone loss (resorption) is driven by the bone resident cell the osteoclast. Identifying molecules that regulate bone resorption by osteoclasts is a crucial first step towards developing new targets for theraputic intervention. This proposal explores the role of Myo1b, a novel protein that appears to facilitate osteoclastic bone resorption and thus represents an attractive new candidate to target bone loss.
Uncover How Myosin-6 Underpins The Ca2+-dependent Recruitment Of Secretory Vesicles To The Cortical Actin Network
Funder
National Health and Medical Research Council
Funding Amount
$559,295.00
Summary
Neuronal communication relies on the process of exocytosis by which neurons release a neurotransmitter. Exocytosis underpins processes such as the simplest muscle movement to complex tasks such as learning and memory, and is altered in several neurodegenerative pathologies. We will investigate how the protein Myosin-6 controls exocytosis. This research will be important for understanding how neurons communicate in health and disease and will be relevant to other processes such as insulin release ....Neuronal communication relies on the process of exocytosis by which neurons release a neurotransmitter. Exocytosis underpins processes such as the simplest muscle movement to complex tasks such as learning and memory, and is altered in several neurodegenerative pathologies. We will investigate how the protein Myosin-6 controls exocytosis. This research will be important for understanding how neurons communicate in health and disease and will be relevant to other processes such as insulin release in diabetes.Read moreRead less