Multiscale Analysis Of Plasma Membrane Microdomains In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$863,413.00
Summary
The cell surface encloses the cell in a protective barrier but it must also respond to signals coming from outside the cell. To accomplish this, the cell surface is made up of numerous regions each with a specialised role. This proposal aims to examine how lipids and proteins work together to make these specialised regions and aims to understand what goes wrong in diseases such as muscular dystrophy.
A unified model of amino acid homeostasis. This project aims to develop a unified model of amino acid homeostasis in mammalian cells and apply it to brain cells. The model will be underpinned by a mathematical algorithm that allows predicting amino acid levels in the cytosol based on fundamental parameters such as transport and metabolism. This project should provide the significant benefit of enabling the prediction of essential functions such as cell growth and survival.
Molecular interactions in cell membranes. Cell membranes are a complex composite of proteins and lipids and we have only a rough idea about how they perform their many functions. Together with Leica Microsystems, this project will develop a new microscope that can map the molecular interactions within the membrane revealing details that have never been seen before.
Deciphering Signalling Pathways Regulating Iron Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$407,402.00
Summary
Iron overload and anaemia are two of the most significant health problems affecting humans. Understanding how the body regulates iron levels is key to our understanding of these disorders and to the future development of new therapies. This research is aimed at understanding how a hormone produced in the liver called hepcidin that maintains iron balance is regulated. This research may lead to novel therapies aimed at correcting the iron balance in conditions of iron overload or anaemia.
Exploring The Role Of Arrcd4 In Extracellular Vesicle Biogenesis And Its Implications In Tissue Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$678,742.00
Summary
Most cells in the body release small packages known as extracellular vesicles (or EVs in short), which carry proteins and other cellular material. EVs transport important cellular messages required for the everyday function of cells and play crucial roles both in normal wellbeing and disease. This proposal will investigate how EVs are formed, how they select their protein content and how they contribute to the maturation of some cell types in the body.
A Novel Mechanism For Regulating Membrane Proteins By Ubiquitin Ligases And Their Adaptors
Funder
National Health and Medical Research Council
Funding Amount
$627,897.00
Summary
Many membrane proteins act as ion channels, transporters or receptors for extracellular ligands and are critical to normal functioning of the cell. These proteins are generally regulated by transport to or from the membrane to ensure that correct levels are maintained at the membrane. This proposal is to study a novel way of regulating membrane proteins. The successful completion of the work will provide important knowledge relevant to many human diseases.
Discovery Early Career Researcher Award - Grant ID: DE150101777
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding the role of exosomes in intercellular communication. Exosomes, small packages released by cells, are powerful signalling organelles that can activate neighbouring cells by transferring proteins and RNA. Currently, it is unknown whether exosomes have similar membrane protein/lipid composition to that of the host cell. This project aims to explore the similarities and differences between the exosomal and host cell membranes in terms of the protein/lipid composition. In addition, the ....Understanding the role of exosomes in intercellular communication. Exosomes, small packages released by cells, are powerful signalling organelles that can activate neighbouring cells by transferring proteins and RNA. Currently, it is unknown whether exosomes have similar membrane protein/lipid composition to that of the host cell. This project aims to explore the similarities and differences between the exosomal and host cell membranes in terms of the protein/lipid composition. In addition, the project aims to study how the proteins and RNA are packaged into exosomes. Membrane molecules that are detected only in the exosomes may have important signalling implications and may aid in the uptake/fusion of exosomes by/with target cells. The project aims to improve our understanding on signalling mediated by exosomes.Read moreRead less
Phage display derived antibody fragments for membrane protein research. Membrane proteins are key components of all living organisms and represent more than 50 per cent of all drug targets. This project will redefine the way membrane proteins are studied and will be highly beneficial to basic research, human disease and the biotechnology industry.
The mechanism of pore formation by Membrane Attack Complex/Perforin-like proteins. Members of the Membrane Attack Complex / Perforin (MACPF) family of proteins are essential for life, playing fundamental roles in immunity, tissue development and neuron formation. This project seeks to understand the basic mechanism of how MACPF proteins can form pores in target cells, a process central for killing in mammalian immunity.