This proposal concerns the biochemical investigation of a protein called GABA receptor which is a known target for various anti-anxiety drugs (anxiolytics), anti-convulsants, sedatives, depressants, anti-epilespy drugs, alcohol and anaesthetics. This work is expected to lead to the determination of the three-dimensional shape of the protein which will provide essential information about how the protein works and lay the foundation for the design and development of new drugs to control epilepsy, ....This proposal concerns the biochemical investigation of a protein called GABA receptor which is a known target for various anti-anxiety drugs (anxiolytics), anti-convulsants, sedatives, depressants, anti-epilespy drugs, alcohol and anaesthetics. This work is expected to lead to the determination of the three-dimensional shape of the protein which will provide essential information about how the protein works and lay the foundation for the design and development of new drugs to control epilepsy, act as general anaesthetics, relieve anxiety and induce sleep.Read moreRead less
The general aim of this work is to investigate the three-dimensional structures of important target proteins using X-ray crystallography. Protein crystallography is the study of the three-dimensional shapes of proteins at near atomic resolution. In this method proteins are made to form crystals. X-ray beams are then shone on the crystals causing the X-rays to scatter in a pattern which is characteristic of the protein's three-dimensional shape. Knowledge of the structure of proteins is necessary ....The general aim of this work is to investigate the three-dimensional structures of important target proteins using X-ray crystallography. Protein crystallography is the study of the three-dimensional shapes of proteins at near atomic resolution. In this method proteins are made to form crystals. X-ray beams are then shone on the crystals causing the X-rays to scatter in a pattern which is characteristic of the protein's three-dimensional shape. Knowledge of the structure of proteins is necessary for the complete understanding of their biological activity and is also very useful for the rational design of new drugs that may alter their activity. Approximately one third of the body's proteins are attached to membranes. However, relatively little is known about the three-dimensional structures of this important class of proteins. In this project the structures of proteins that form pores in membrane cell walls are being determined. Some of these proteins are bacterial toxins and knowledge of their structure may prove useful in the design of new antibiotics. Another project involves work on a protein called GABA. The structure of GABA could lead to new drugs that control epilepsy, act as general anaesthetics, relieve anxiety and induce sleep.Read moreRead less
The Role Of The Gastric H/K ATPase In Parietal Cell Function
Funder
National Health and Medical Research Council
Funding Amount
$166,885.00
Summary
The cells of the body contain many specialised membrane structures. At present it is not clear how the synthesis of these stuctures is directed. To study this problem we are examining the acid secretory parietal cells of the stomach. These cells have a very elaborate membrane system that contains a major proton pump protein. By manipulating the levels and form of the proton pump we will gain novel insights into the mechanism of membrane structure and function.
Proteins form up to 25% of our diet. The first step in protein absorption is the digestion of protein into smaller units called peptides and amino acids. Both components are subsequently taken up by specialised cells in the wall of the intestine. In this project we plan to study how protein absorption occurs at the surface of these intestinal cells and investigate why this process fails in malabsorption syndromes, where the uptake of amino acids is impaired.
Regulation Of Voltage-Gated Potassium Channels: X-ray Structures Of Cytosolic Components Of The BK Nd Kv Families
Funder
National Health and Medical Research Council
Funding Amount
$235,500.00
Summary
This research will investigate aspects of ion channel gating (opening). Ion channels are specialised pores perforating cell membranes that facilitate transport of ions, or charged atoms, across its breadth. The flow of ions from one side to another is measurable as an electrical current. The pore, or channel, through which ions pass narrows in regions, creating an impasse, or gate , prohibiting passage. The gate is controlled by external factors, such as the binding of certain molecules (ligands ....This research will investigate aspects of ion channel gating (opening). Ion channels are specialised pores perforating cell membranes that facilitate transport of ions, or charged atoms, across its breadth. The flow of ions from one side to another is measurable as an electrical current. The pore, or channel, through which ions pass narrows in regions, creating an impasse, or gate , prohibiting passage. The gate is controlled by external factors, such as the binding of certain molecules (ligands), or, in the case of voltage-dependent ion channels, the application of a voltage to the membrane. Such perturbations widen the pore sufficiently to permit conduction. Voltage-gated potassium channels specifically transport potassium ions. They fall into multiple categories, and generally form large complexes with intracellular, as well as membrane-bound, portions. For some types, cues from intracellular chemical processes are known to regulate electrical excitability, using the intracellular domains to transfer information to the membrane. In others it is not clear if and how this might happen. Our efforts will focus on exploring this theme in two contrasting systems, Kv and BK channels. Kv channels open in response to voltage, whereas activation of BK channels requires both voltage and moderate levels of intracellular calcium. X-ray crystallography will be used to generate accurate three-dimensional images of selected potassium channel components, allowing us to visualise discrete steps in the regulation processes. Potassium channels are essential for life. They effect transmission of our nerve impulses, and are thus fundamental to central nervous system activity. This research will help us to understand the factors that control them.Read moreRead less
The functional organisation of the trans-Golgi network: From cultured cells to physiological systems. This research will result in a better understanding of the secretory pathway of all eukaryotic cells, a process of broad biological and biomedical significance. It will impact on cell biology in the broadest sense, from membrane biogenesis to lipid domain organization, as well as membrane transport, protein structure and protein targeting. Furthermore, this work will utilize and develop fronti ....The functional organisation of the trans-Golgi network: From cultured cells to physiological systems. This research will result in a better understanding of the secretory pathway of all eukaryotic cells, a process of broad biological and biomedical significance. It will impact on cell biology in the broadest sense, from membrane biogenesis to lipid domain organization, as well as membrane transport, protein structure and protein targeting. Furthermore, this work will utilize and develop frontier technologies of live cell imaging and RNA interference as a genetic tool to investigate functions of a protein family. By training post-graduate students and post-doctoral staff, it will contribute to the expertise of cell biology in Australia. International collaborations will enhance connections between Australia and overseas research.Read moreRead less
Molecular microscopy: protein and membrane dynamics in resting and activated T cells. The aim of this research, to understand the molecular organization and dynamics of the plasma membrane that underlie the signal transduction events, is at the very heart of understanding cell communication. T cell recognition and activation initiates an adaptive immune response to invading pathogens and structurally altered proteins that can be found in cancers. By providing functional insights into the molecul ....Molecular microscopy: protein and membrane dynamics in resting and activated T cells. The aim of this research, to understand the molecular organization and dynamics of the plasma membrane that underlie the signal transduction events, is at the very heart of understanding cell communication. T cell recognition and activation initiates an adaptive immune response to invading pathogens and structurally altered proteins that can be found in cancers. By providing functional insights into the molecular mechanism of T cell activation, we will not only provide fundamental knowledge of receptor signalling but also specific details of T cell receptort triggering that may lead to the development of new therapeutic strategies to control T cell activation.Read moreRead less
The structure and function of the trans-Golgi network: role of golgins and G proteins. This research will provide a better understanding of the secretory pathway of all eukaryotic cells, a process of broad biological and biomedical significance. It will also contribute to a better understanding of how a cell works, including how cell membranes are organization, how the transport processes of the cell are regulated and how proteins are targeted to their intracellular destination. Further, this ....The structure and function of the trans-Golgi network: role of golgins and G proteins. This research will provide a better understanding of the secretory pathway of all eukaryotic cells, a process of broad biological and biomedical significance. It will also contribute to a better understanding of how a cell works, including how cell membranes are organization, how the transport processes of the cell are regulated and how proteins are targeted to their intracellular destination. Further, this work will utilize the frontier technology of RNA interference as a genetic tool to investigate functions of genes. By training post-graduate students and post-doctoral staff, it will contribute to the expertise of cell biology in Australia. International collaborations will enhance connections with overseas researchers.Read moreRead less
The role of a novel family of Golgi proteins in maintaining the structure and function of the trans-Golgi network. The secretory pathway of eukaryotic cells is fundamental for proper cell growth. The Golgi apparatus is a key organelle of this pathway where newly made proteins are selectively packaged into membrane-bound transport vehicles and then shipped to their correct destination, such as the surface of the cell. This research aims to understand the mechanism by which these cargo-loaded tr ....The role of a novel family of Golgi proteins in maintaining the structure and function of the trans-Golgi network. The secretory pathway of eukaryotic cells is fundamental for proper cell growth. The Golgi apparatus is a key organelle of this pathway where newly made proteins are selectively packaged into membrane-bound transport vehicles and then shipped to their correct destination, such as the surface of the cell. This research aims to understand the mechanism by which these cargo-loaded transport vehicles are generated from the Golgi apparatus. This information is of fundamental importance in understanding how a cell survives and grows, and is necessary to allow a rational basis for the engineering of secreted recombinant molecules.Read moreRead less
The activation of T lymphocytes is essential part of our immune system to fend off harmful intruders. Our research aims to understand the process of T cell activation, in particular, the contribution of fats. We found that fats create a highly ordered patch at the T cell activation site. We want to understand how lipids and proteins work together to activate T cells, how this ordered regions function in T cell activation and whether dietary lipids alter these patches and thus T cell activation.