The role of turgor in hyphal extension of the Ascomycete Neurospora crassa. Cellular expansion is an absolute necessity during the growth and development of plants and fungi. This process relies heavily upon the accumulation of inorganic ions. Osmotically driven water influx then creates the hydrostatic pressure that underlies the increase in cell volume. Cellular expansion is normally asymmetric and localised in one small region, such as hyphal tip. How does the cell maintain the turgor that dr ....The role of turgor in hyphal extension of the Ascomycete Neurospora crassa. Cellular expansion is an absolute necessity during the growth and development of plants and fungi. This process relies heavily upon the accumulation of inorganic ions. Osmotically driven water influx then creates the hydrostatic pressure that underlies the increase in cell volume. Cellular expansion is normally asymmetric and localised in one small region, such as hyphal tip. How does the cell maintain the turgor that drives expansion? How is expansion controlled spatially? These questions will be addressed in this project by comprehensive study of ion transport processes in a model organism, Neurospora crassa, using osmotic sensitive and transport mutants.Read moreRead less
Membrane Attack Complex / Perforin like proteins in Defence, Attack and Developmental Biology. This proposal will result in a major advancement of knowledge, for example, in our understanding of the emerging links between immunity and development as well as the role and mechanism of function of the pore forming family of MACPF proteins in host defence, attack, embryo development and diseases such as cancer. These data will be crucial for developing approaches to control unwanted MACPF function, ....Membrane Attack Complex / Perforin like proteins in Defence, Attack and Developmental Biology. This proposal will result in a major advancement of knowledge, for example, in our understanding of the emerging links between immunity and development as well as the role and mechanism of function of the pore forming family of MACPF proteins in host defence, attack, embryo development and diseases such as cancer. These data will be crucial for developing approaches to control unwanted MACPF function, for example in disease such as diabetes or transplant rejection. Furthermore, a detailed understanding of how MACPF proteins assemble into rings and punch holes in membranes will facilitate the development of these proteins as technological tools.Read moreRead less
Delineating the role of the GxxxG motif in transmembrane protein metabolism. This study will define how a well defined motif involved in transmembrane interactions affects the metabolism of proteins. Since this motif is present in proteins involved in Alzheimer's disease it has potential benefits for community health and combating ageing.
Conductance states of a brain glutamine transporter. Brain transporters are the target for many neuroactive drugs that are used to treat anxiety, depression and other psychotic disorders. Transport processes are also targeted to deliver neurotransmitter precursors to the brain to treat disorders such as Parkinson's disease. In this project we will study a transport process crucial for the function of neurons that release glutamate and GABA (gamma-aminobutyric acid) as neurotransmitters. The stud ....Conductance states of a brain glutamine transporter. Brain transporters are the target for many neuroactive drugs that are used to treat anxiety, depression and other psychotic disorders. Transport processes are also targeted to deliver neurotransmitter precursors to the brain to treat disorders such as Parkinson's disease. In this project we will study a transport process crucial for the function of neurons that release glutamate and GABA (gamma-aminobutyric acid) as neurotransmitters. The study of this transport process will be important for understanding disorders like epilepsy and other disorders affecting neuronal excitability.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882295
Funder
Australian Research Council
Funding Amount
$225,000.00
Summary
X-ray crystallography resource for membrane proteins and large macromolecular complexes. Structural biology is the underpinning of biotechnology, biopharmaceuticals and rational therapeutic design. The most successful technique for determining the structures of proteins and large macromolecular complexes is x-ray crystallography. This proposal will set up a network of state of the art resources in the Sydney region to capitalise on expertise in these areas. The facilities will foster basic re ....X-ray crystallography resource for membrane proteins and large macromolecular complexes. Structural biology is the underpinning of biotechnology, biopharmaceuticals and rational therapeutic design. The most successful technique for determining the structures of proteins and large macromolecular complexes is x-ray crystallography. This proposal will set up a network of state of the art resources in the Sydney region to capitalise on expertise in these areas. The facilities will foster basic research and collaborations with industry, which will enhance Australia's profile and commercialisation of research. The facility will enhance the usage of the Australian synchrotron, producing flagship projects on the edge of technical possibilities.Read moreRead less
Structure, dynamics and interactions of Plasmodium falciparum merozoite surface protein-2. The solution structure of the merozoite surface protein-2 (MSP-2), from Plasmodium falciparum the causative agent of malaria, will be determined along with an analysis of the motions of residues within the protein. This will allow insights into interactions occurring at the surface coat of the organism, where MSP-2 is a major component. An understanding of how this protein interacts with antibodies of the ....Structure, dynamics and interactions of Plasmodium falciparum merozoite surface protein-2. The solution structure of the merozoite surface protein-2 (MSP-2), from Plasmodium falciparum the causative agent of malaria, will be determined along with an analysis of the motions of residues within the protein. This will allow insights into interactions occurring at the surface coat of the organism, where MSP-2 is a major component. An understanding of how this protein interacts with antibodies of the host's immune system will also be gained. The techniques established during the study of MSP-2 will be useful for the study of larger proteins and protein complexes from many systems in the future.Read moreRead less
Molecular and Cellular Characterisations of the Cortical Actin Cytoskeleton in the Plant Arabidopsis thaliana. Plant cells contain extensive arrays of the cytoskeletal protein actin that attach to the plasma membrane and may play important roles in cell elongation through interactions with cortical microtubules. However, the organisation, dynamics and functions of cortical actin remain poorly understood. I will combine cell and molecular approaches to understanding cortical actin in living tissu ....Molecular and Cellular Characterisations of the Cortical Actin Cytoskeleton in the Plant Arabidopsis thaliana. Plant cells contain extensive arrays of the cytoskeletal protein actin that attach to the plasma membrane and may play important roles in cell elongation through interactions with cortical microtubules. However, the organisation, dynamics and functions of cortical actin remain poorly understood. I will combine cell and molecular approaches to understanding cortical actin in living tissue of Arabidopsis, using both wild-type and previously uncharacterised mutants, and will develop a novel mutational screening strategy to isolate mutants disrupted in plasma membrane or microtubule binding. This research will contribute significantly to a greater understanding of how the plant grows and develops.Read moreRead less
Understanding the molecular mechanism of force generation in the bacterial flagellar motor. The proposed research will advance the knowledge about how the bacterial flagellar motor works, enabling scientists to learn more about nature's blueprint of a nanoscale engine. It will address the fundamental question of how bacterial cells convert electrochemical energy into mechanical energy of rotation. At present, the smallest artificial electric motor is still on a micro-, rather than nanoscale. Nan ....Understanding the molecular mechanism of force generation in the bacterial flagellar motor. The proposed research will advance the knowledge about how the bacterial flagellar motor works, enabling scientists to learn more about nature's blueprint of a nanoscale engine. It will address the fundamental question of how bacterial cells convert electrochemical energy into mechanical energy of rotation. At present, the smallest artificial electric motor is still on a micro-, rather than nanoscale. Nanotechnology would therefore benefit from this work by basing their designs on the principles behind the mechanism of the bacterial motor. This research is also of interest for veterinary science, as motility by flagellar motor is a key virulence factor of common animal pathogens associated with, for example, listeriosis and gastroenteritis.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0226463
Funder
Australian Research Council
Funding Amount
$160,000.00
Summary
Fluorescence Lifetime Imaging Facility. The aim of this proposal is to establish the first fluorescence lifetime imaging facility (FLIM) in Australia. The imaging technique provided by the new facility when combined with the use of novel fluorescent protein technology will enable many different events, represented by protein-protein interactions, to be non-invasively, visualised spatially and temporally inside the living cell. The new facility will provide timely state-of -the-art infrastructu ....Fluorescence Lifetime Imaging Facility. The aim of this proposal is to establish the first fluorescence lifetime imaging facility (FLIM) in Australia. The imaging technique provided by the new facility when combined with the use of novel fluorescent protein technology will enable many different events, represented by protein-protein interactions, to be non-invasively, visualised spatially and temporally inside the living cell. The new facility will provide timely state-of -the-art infrastructure necessary for research groups to further develop and maintain their international reputations, will build stronger research collaborations between partner institutions and will attract researchers from overseas.Read moreRead less
In situ measurements of the electrostatic properties inside photosynthetic reaction centres: correlation with the energy conversion function of the protein. The photochemical reaction centre is a key protein complex involved in energy conversion. It converts solar energy into chemical energy as a transmembrane charge separation. Coupling of electron and proton transfer is catalysed at the level of a ubiquinone cofactor. In order to understand how the redox properties of this cofactor are fine tu ....In situ measurements of the electrostatic properties inside photosynthetic reaction centres: correlation with the energy conversion function of the protein. The photochemical reaction centre is a key protein complex involved in energy conversion. It converts solar energy into chemical energy as a transmembrane charge separation. Coupling of electron and proton transfer is catalysed at the level of a ubiquinone cofactor. In order to understand how the redox properties of this cofactor are fine tuned by the protein environment, we plan to probe the ubiquinone site using a voltage-sensitive fluorescent dye. This exciting multidisciplinary project will contribute to the understanding of how protein matrices influence and govern the midpoint redox potential of their cofactors and the environments of theirRead moreRead less