Convergent Regulation Of Sympathetic Neuronal Excitability By Peptide Hormones And Transmitters
Funder
National Health and Medical Research Council
Funding Amount
$498,465.00
Summary
This project will examine how hormones involved in regulating blood pressure interact with the nerves that control blood flow to the gut. We will combine electrical recordings of the activity of single nerve cells with an innovative new method of optically tracking the movements of single molecules, including hormons and neuronal messengers, that send signals to the nerve cells. Our results will reveal how blood pressure is normally maintained at healthy levels, even if we are ill.
Investigation Of Lipid-protein Interactions Of Mechanosensitive Ion Channels
Funder
National Health and Medical Research Council
Funding Amount
$409,785.00
Summary
Living organisms are imminently exposed to mechanical stimuli such as gravity, touch or sound. Sensing mechanical stimuli is therefore crucial for survival. One biological tool for sensing mechanical stress are the mechanosensitive ion channels that open in response to tension in cell membranes. We will study the interactions and coupling between membrane lipids and mechanosensitive ion channels. These interactions are essential for the function of these fascinating sensory biological molecules.
A Novel Patch-fluorimetry Technique For Investigating Structural Changes During Gating Of Mechanosensitive Ion Channnels
Funder
National Health and Medical Research Council
Funding Amount
$387,018.00
Summary
Membrane proteins, especially membrane channels play an important role in regulating the flow of substances across the cell. Dysfunction in these channels can lead to a variety of diseases. Thus approximately 60% of drug development is targeted against such proteins. In our research, we are looking at membrane channels found in bacteria. Understanding the function of these channels will help us develop novel anti-bacterial agents. It will also aid to understand a role of ion channels in disease.
Use Of Novel Transfection Protocols To Study Protein Trafficking In Malaria-infected Erythrocytes
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
Malaria kills between 1 and 3 million children each year. In addition, the disease debilitates the adult population in malaria-endemic areas, thereby contributing to the cycle of poverty in many third world countries. As resistance to existing antimalarial drugs increases, there is an urgent need to understand the workings of the parasite at a molecular level to enable the development of alternative antimalarial strategies. During part of its life cycle, the malaria parasite infects the erythroc ....Malaria kills between 1 and 3 million children each year. In addition, the disease debilitates the adult population in malaria-endemic areas, thereby contributing to the cycle of poverty in many third world countries. As resistance to existing antimalarial drugs increases, there is an urgent need to understand the workings of the parasite at a molecular level to enable the development of alternative antimalarial strategies. During part of its life cycle, the malaria parasite infects the erythrocytes of its human host. The parasite transports proteins to the erythrocyte membrane so as to modify the properties of its adopted cellular residence. The parasite proteins that are deposited at or in the erythrocyte membrane increase the leakiness and the stickiness of the parasitised erythrocytes. This allows more efficient uptake of nutrients and allows the parasitised erythrocytes to adhere to blood vessel walls, thereby avoiding passage through the spleen. Adherence of parasitised erythrocytes to capillaries in the brain is thought to lead to the development of the complication known as cerebral malaria. This complication is responsible for most of the deaths due to malaria. In order to traffic the adherence proteins to the erythrocyte surface, the parasite establishes a novel transport pathway for moving proteins across the erythrocyte cytoplasm. As the uninfected erythrocyte has no means, nor requirement, for moving proteins, this novel transport mechanism may represent a target for drugs that kill the malaria parasite without being toxic to humans. The pathways for the movement of proteins around the infected erythrocyte are largely unknown. We propose to use techniques to introduce foreign genes into malaria-infected erythrocytes to unravel the details of the molecular machinery and the ticketing system that the parasite uses to traffic proteins to their correct destinations in its adopted home.Read moreRead less
Protein Trafficking In Malaria Parasite-infected Erythrocytes
Funder
National Health and Medical Research Council
Funding Amount
$417,750.00
Summary
Malaria kills between 1 and 3 million children each year. In addition, the disease debilitates the adult population in malaria-endemic areas, thereby contributing to the cycle of poverty in many third world countries. As resistance to existing antimalarial drugs increases, there is an urgent need to understand the workings of the parasite at a molecular level to enable the development of alternative antimalarial strategies. During part of its life cycle, the malaria parasite infects the erythroc ....Malaria kills between 1 and 3 million children each year. In addition, the disease debilitates the adult population in malaria-endemic areas, thereby contributing to the cycle of poverty in many third world countries. As resistance to existing antimalarial drugs increases, there is an urgent need to understand the workings of the parasite at a molecular level to enable the development of alternative antimalarial strategies. During part of its life cycle, the malaria parasite infects the erythrocytes of its human host. The parasite transports proteins to the erythrocyte membrane so as to modify the properties of its adopted cellular residence. The parasite proteins that are deposited at or in the erythrocyte membrane increase the leakiness and the stickiness of the parasitised erythrocytes. This allows more efficient uptake of nutrients and allows the parasitised erythrocytes to adhere to blood vessel walls, thereby avoiding passage through the spleen. Adherence of parasitised erythrocytes to capillaries in the brain is thought to lead to the development of the complication known as cerebral malaria. This complication is responsible for most of the deaths due to malaria. In order to traffic the adherence proteins to the erythrocyte surface, the parasite establishes novel transport pathways for moving proteins across the erythrocyte cytoplasm. As the uninfected erythrocyte has no means, nor requirement, for moving proteins, this novel transport mechanism may represent a target for drugs that kill the malaria parasite without being toxic to humans. The pathways for the movement of proteins around the infected erythrocyte are largely unknown. We propose to use cell biology techniques and techniques to introduce foreign genes into malaria-infected erythrocytes to unravel the details of the molecular machinery and the ticketing system that the parasite uses to traffic proteins to their correct destinations in its adopted home.Read moreRead less
Examining The Role Of Profilin As A Regulator Of Cancer Aggressiveness
Funder
National Health and Medical Research Council
Funding Amount
$261,778.00
Summary
Cancer treatment in Australia costs ~ $2.7 billion per annum. Current mainstream treatments often cause major side effects and thus less toxic therapeutic approaches are urgently needed. Profilin has recently emerged as a promising anti-cancer target. We will investigate how cancer can be suppressed by altering the interaction between profilin and its partners (lipids, phosphoinositides, and actin). This project will provide essential groundwork for the development of novel cancer therapeutics.
Regulation Of Nuclear Calcium Concentration In The Life Or Death Of Cells
Funder
National Health and Medical Research Council
Funding Amount
$195,047.00
Summary
The nucleus is the most prominent of all cell organelles and contains the primary genetic material for cellular development and growth. It performs some of the most important functions in the life and death of all living cells. However, little is known about many of the regulatory signals and events that control nuclear function. We will use new genetically-encoded sensor molecules that a living cell can be instructed to produce at various internal locations to explore important features of cell ....The nucleus is the most prominent of all cell organelles and contains the primary genetic material for cellular development and growth. It performs some of the most important functions in the life and death of all living cells. However, little is known about many of the regulatory signals and events that control nuclear function. We will use new genetically-encoded sensor molecules that a living cell can be instructed to produce at various internal locations to explore important features of cell control. This study will look specifically at how changes in the concentration of ionised Ca2+ in the nucleus control the switching on of genes and the initiation of programmed cell death pathways. This information is of significance to our understanding of normal cell growth and development, as well as abnormal growth (e.g. cancer).Read moreRead less