Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347727
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Computational infrastructure for high-throughput genome bioinformatics. We propose a high-performance computing and web facility for genome bioinformatics. It will provide a common software development environment in support of molecular biosciences, systems biology and complex systems modelling at the Institute for Molecular Bioscience at University of Queensland, and at Queensland University of Technology. The platform will support Australia's first genome-scale bioinformatics research website ....Computational infrastructure for high-throughput genome bioinformatics. We propose a high-performance computing and web facility for genome bioinformatics. It will provide a common software development environment in support of molecular biosciences, systems biology and complex systems modelling at the Institute for Molecular Bioscience at University of Queensland, and at Queensland University of Technology. The platform will support Australia's first genome-scale bioinformatics research website, with unique software and mirrors of the IBM Biological Pattern Discovery, UC San Diego MEME/MetaMEME/MAST, and NGI comparative genomics websites. Australian/NZ researchers will access the facility at no cost for high-throughput use of unique software, website mirrors and other important tools for genome bioinformatics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347962
Funder
Australian Research Council
Funding Amount
$218,000.00
Summary
Adelaide Mass Spectrometry and Analysis Facility. This joint proposal by two South Australian universities and the Hanson Institute seeks to establish a facility for rapid characterisation and identification of biomolecules by means of MALDI-TOF and Nano LC mass spectrometry. The requested equipment is not available in South Australia. This proposal would establish a Nano LC (Q-TOF) node at the University of Adelaide-University of South Australia location and a MALDI-TOF node at the Flinders loc ....Adelaide Mass Spectrometry and Analysis Facility. This joint proposal by two South Australian universities and the Hanson Institute seeks to establish a facility for rapid characterisation and identification of biomolecules by means of MALDI-TOF and Nano LC mass spectrometry. The requested equipment is not available in South Australia. This proposal would establish a Nano LC (Q-TOF) node at the University of Adelaide-University of South Australia location and a MALDI-TOF node at the Flinders location. Its presence would greatly enhance the quality of research and teaching in priority areas such as proteomics, bioinformatics and nanotechnology and would provide a basis for fostering university and biotechnology industry collaborations.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239035
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
Regional facility for surface and micro-structure analysis. Adelaide, Flinders and SA Universities seek to enhance the regional facility for surface and microstructure analysis. Equipment includes electron back scatter pattern imaging, high resolution coater, microprobe (CAMECA SX51) upgrade and X ray microtomography to be located at Adelaide University Centre for Electron Microscopy and Microstructure Analysis, the hub of the regional facility. The University of South Australia Ian Wark Researc ....Regional facility for surface and micro-structure analysis. Adelaide, Flinders and SA Universities seek to enhance the regional facility for surface and microstructure analysis. Equipment includes electron back scatter pattern imaging, high resolution coater, microprobe (CAMECA SX51) upgrade and X ray microtomography to be located at Adelaide University Centre for Electron Microscopy and Microstructure Analysis, the hub of the regional facility. The University of South Australia Ian Wark Research Institute node will house ToF-SIMS and SAM upgrades, the Flinders node a multimode STM atomic force microscope, and the Adelaide University Waite Campus node confocal xyz control and digital camera. Applications include biological, materials and geological research projects.Read moreRead less
Infrakingdom Alveolata: searching for a defining structural feature. This project will establish the first molecular nexus between a cellular structure currently used to define an Infrakingdom of life. It will aid in the higher order systematics of our microscopic diversity and allow us to interpret how important parasites learned to penetrate host cells to establish infection. We will train excellent graduate and Honours students in cellular and molecular biology.
Early evolutionary origins of mechanosensory transduction: structure, function and phylogenetic studies of the family of mechanosensitive channels in cell-walled organisms. The proposed project is based on the recent progress the applicants have made by (i) identifying a novel family of mechanosensitive (MS) channels in cell-walled organisms, which include Archaea and Bacteria (prokaryotes), as well as fungi and plants (eukaryotes), and (ii) determining basic aspects of the structural dynamics ....Early evolutionary origins of mechanosensory transduction: structure, function and phylogenetic studies of the family of mechanosensitive channels in cell-walled organisms. The proposed project is based on the recent progress the applicants have made by (i) identifying a novel family of mechanosensitive (MS) channels in cell-walled organisms, which include Archaea and Bacteria (prokaryotes), as well as fungi and plants (eukaryotes), and (ii) determining basic aspects of the structural dynamics of MscL, the prototype MS channel, using electronparamagnetic resonance spectroscopy and molecular dynamics simulations in combination with the patch clamp technique. The aim of the project is to elucidate the molecular principles underlying the function of MS channels, which is of fundamental importance for understanding of the biophysics and physiology of mechanosensory transduction throughout the biological world.Read moreRead less
Force from lipids: the role of the lipid bilayer in mechanosensory transduction. The proposed research will significantly contribute to a better understanding of the wide range of physiological processes underlying mechanosensory transduction in living cells. The direct benefit for Australian science consists of: (i) strengthening international links with leading overseas laboratories, and (ii) accessing the state-of-the-art expertise not available in Australia. The acquired knowledge will aid i ....Force from lipids: the role of the lipid bilayer in mechanosensory transduction. The proposed research will significantly contribute to a better understanding of the wide range of physiological processes underlying mechanosensory transduction in living cells. The direct benefit for Australian science consists of: (i) strengthening international links with leading overseas laboratories, and (ii) accessing the state-of-the-art expertise not available in Australia. The acquired knowledge will aid in developing and designing artificial tactile sensors inspired by their biological models studied in this project. Long-term, the project is expected to make an original contribution towards developing new technologies and novel medical applications, both of which promise to be of great national benefit.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453973
Funder
Australian Research Council
Funding Amount
$696,093.00
Summary
Surface Spectroscopic and Microstructure Analysis. Funding is requested for an X-ray Photoelectron Spectrometer (XPS) and an Image Plate Guinier Camera (IPGC), to update and expand capabilities in surface spectroscopic and microstructural analysis of a wide range of materials. The XPS unit, to be located at the University of SA, will replace two 18-year old XPS units at UniSA and Flinders University. The IPGC is a new and unique instrument which will be located at the University of Adelaide. The ....Surface Spectroscopic and Microstructure Analysis. Funding is requested for an X-ray Photoelectron Spectrometer (XPS) and an Image Plate Guinier Camera (IPGC), to update and expand capabilities in surface spectroscopic and microstructural analysis of a wide range of materials. The XPS unit, to be located at the University of SA, will replace two 18-year old XPS units at UniSA and Flinders University. The IPGC is a new and unique instrument which will be located at the University of Adelaide. These items will be incorporated into the SA Regional Facility, which provides seamless access to instrumentation across nodes. Applications include materials science, geological and biological research projects.Read moreRead less
Functionally characterizing mammalian microRNAs and mRNA interactions controlling cell division. This project addresses some of the most burning issues in molecular biology and genetic research, and the results will be widely applicable to a broad range of fields, including biotechnology, animal breeding, agricultural production, genetic engineering, medical science, and computational biology. By understanding the regulatory potential of microRNA molecules, we will understand more about species ....Functionally characterizing mammalian microRNAs and mRNA interactions controlling cell division. This project addresses some of the most burning issues in molecular biology and genetic research, and the results will be widely applicable to a broad range of fields, including biotechnology, animal breeding, agricultural production, genetic engineering, medical science, and computational biology. By understanding the regulatory potential of microRNA molecules, we will understand more about species diversity, regulatory networks, and plant and animal development. The early adoption of multi-gigabase next-generation sequencing technology in Australia provides rare and exciting opportunity to lead the world in genome-scale research, and to ensure that Australia has the necessary skill base to remain internationally competitive in this field.Read moreRead less
Higher cognition and hemispheric specialization in an avian species: referential and intentional communication. We will discover whether alarm calls of Australian magpies, noted for their outstanding range of vocalisations, are referential (signalling predator type and location) and intentional (vocalised in specific contexts). Such complex communication , once thought to be unique to humans, has been found in some mammals and just one avian species, the domestic chick. This project will be the ....Higher cognition and hemispheric specialization in an avian species: referential and intentional communication. We will discover whether alarm calls of Australian magpies, noted for their outstanding range of vocalisations, are referential (signalling predator type and location) and intentional (vocalised in specific contexts). Such complex communication , once thought to be unique to humans, has been found in some mammals and just one avian species, the domestic chick. This project will be the first such investigation of an avian species in its natural habitat. This is important also because bird and mammalian brains are organised differently and birds offer a unique opportunity to discover whether one hemisphere is specialised for this purpose.Read moreRead less
Elucidating structure and function of activation-associated secreted proteins (ASPs) in blood-feeding hookworms – toward new methods of control. The national/community benefits are: (1) to develop a long-term, high quality scientific and technological program contributing to national objectives, including the maintenance of a strong capability in basic research, the development of new scientific concepts and the enhancement of international collaborative links; (2) to strengthen the links betwee ....Elucidating structure and function of activation-associated secreted proteins (ASPs) in blood-feeding hookworms – toward new methods of control. The national/community benefits are: (1) to develop a long-term, high quality scientific and technological program contributing to national objectives, including the maintenance of a strong capability in basic research, the development of new scientific concepts and the enhancement of international collaborative links; (2) to strengthen the links between basic and applied research; (3) to develop excellence in research by promoting collaborative research, resulting in a more efficient use of resources in a national and international context; (4) to enhance the skills-base in biology and biotechnology; (5) to substantially increase global visibility through quality research, leading to an increased investment in Australian science.Read moreRead less