Microtubule structure in nervous system repair. This Project aims to investigate the role of structural and functional cellular components known as microtubules in nervous system regeneration. This Project aims to use innovative approaches in confocal and electron microscopy, genetics, and cell biology, with the expectation of generating new knowledge into nervous system repair. Expected outcomes of this Project include a comprehensive description of how microtubules are rearranged following ner ....Microtubule structure in nervous system repair. This Project aims to investigate the role of structural and functional cellular components known as microtubules in nervous system regeneration. This Project aims to use innovative approaches in confocal and electron microscopy, genetics, and cell biology, with the expectation of generating new knowledge into nervous system repair. Expected outcomes of this Project include a comprehensive description of how microtubules are rearranged following nervous system injury and the importance of microtubule modifying proteins in promoting regeneration. This should provide significant benefits in our understanding of the cellular mechanisms behind nervous system repair, and offer new approaches for promoting regeneration after injury.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100008
Funder
Australian Research Council
Funding Amount
$347,500.00
Summary
Super Resolution Confocal Microscopy Facility. Super resolution confocal microscopy facility:
This project aims to establish a super-resolution confocal microscopy facility with unrivalled resolution, sensitivity and speed. The widespread application of super-resolution microscopy has so far been limited because of the special sample preparation and technical skills required. The project aims to provide us with the ability to image thicker samples, such as animal and plant tissue, without these ....Super Resolution Confocal Microscopy Facility. Super resolution confocal microscopy facility:
This project aims to establish a super-resolution confocal microscopy facility with unrivalled resolution, sensitivity and speed. The widespread application of super-resolution microscopy has so far been limited because of the special sample preparation and technical skills required. The project aims to provide us with the ability to image thicker samples, such as animal and plant tissue, without these limitations. This would enable us to capture three-dimensional data at both the cellular and tissue level, providing researchers with a level of detail never before seen. The facility may create new knowledge in life science, including visual neuroscience, developmental neurobiology, plant growth, stem cell regeneration, the role of trace metals in physiology, and vaccine and drug development.Read moreRead less
A toxic cycle of inflammation and iron in the ageing brain. This project investigates why our brain cells gradually die as we grow older. We believe that infections and inflammation in other parts of the body cause iron to accumulate in the brain and become toxic. Iron supplements and ageing may make this situation worse. The results of this study could lead to new treatments for memory loss and dementia.
Awaking quiescent neural stem cells. This project aims to generate new knowledge in the area of the evolutionary size of animals and plants, which is determined by intrinsic cell regulation and is constrained by nutrient availability. Brain size is perhaps the most profound example of this. Brain size regulation is underpinned by control of proliferation of neural stem cells (NSCs). Using Drosophila NSCs, the project will examine how nutrients impact on NSC quiescence versus activation, a key ch ....Awaking quiescent neural stem cells. This project aims to generate new knowledge in the area of the evolutionary size of animals and plants, which is determined by intrinsic cell regulation and is constrained by nutrient availability. Brain size is perhaps the most profound example of this. Brain size regulation is underpinned by control of proliferation of neural stem cells (NSCs). Using Drosophila NSCs, the project will examine how nutrients impact on NSC quiescence versus activation, a key characteristic of stem cell control throughout evolution. This will increase our understanding of how energy metabolism and nutrition influence organ size control in multicellular organisms, by determining how organs communicate with each other to convert nutrient signals to action stem cell proliferation.Read moreRead less
Wiring the gut's nervous system: formation and maturation of synapses. This project aims to determine how nerve circuits controlling intestinal functions develop; specifically how communication between specific nerve cells is established once they appear in the embryonic gut. It will fill a major hole in existing knowledge of mechanisms regulating the development of normal digestive behaviours.
Investigating the neuroprotective actions of metallo-complexes. Metal-based drugs offer an exciting new approach to treatment of neurodegeneration. However, little is known about how cells metabolise these drugs: information that is critical for further drug development. This project will determine how metal-based drugs are metabolized by neuronal cells and how this may result in therapeutic benefit.
Understanding the changes in brain chemistry associated with schizophrenia. Current drugs for schizophrenia only work in 30% of patients. To develop better therapies, we must understand the changes in the brains of people with the disorder. This research will explore a chemical system in the brain that is changed in schizophrenia and begin to investigate whether counteracting these changes are therapeutically beneficial.
Discovery Early Career Researcher Award - Grant ID: DE170100152
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Molecular insight into allosteric modulation of G protein-coupled receptors. The project aims to understand the molecular mechanisms underlying signal transduction and allosteric modulation of G protein-coupled receptors (GPCRs). Allosteric modulation of proteins is a fundamental process where two distinctly different binding sites are linked through a conformational change. This project will use structural biology, medicinal chemistry and analytical pharmacology to investigate how chemical prob ....Molecular insight into allosteric modulation of G protein-coupled receptors. The project aims to understand the molecular mechanisms underlying signal transduction and allosteric modulation of G protein-coupled receptors (GPCRs). Allosteric modulation of proteins is a fundamental process where two distinctly different binding sites are linked through a conformational change. This project will use structural biology, medicinal chemistry and analytical pharmacology to investigate how chemical probes modulate GPCRs at an atomic level, and understand the mechanisms underlying signal transduction. Project outcomes are intended to advance membrane protein crystallography and GPCR biology, and benefit the pharmaceutical industry.Read moreRead less
Modelling the human nervous system with human pluripotent stem cells. The human nervous system is one of the most complex structures evolved to date. In order to understand how it functions, and dysfunctions in a diseased state, it is fundamental to decipher how it develops to generate various neuronal populations that form this elaborate network. Human stem cells provide a valuable source to study such processes. The aim of this project is to use human stem cells to study how early progenitor c ....Modelling the human nervous system with human pluripotent stem cells. The human nervous system is one of the most complex structures evolved to date. In order to understand how it functions, and dysfunctions in a diseased state, it is fundamental to decipher how it develops to generate various neuronal populations that form this elaborate network. Human stem cells provide a valuable source to study such processes. The aim of this project is to use human stem cells to study how early progenitor cell types that structure the nervous system are generated and how their neuronal derivatives form connectivity and functional synapses. The outcome of these studies is that we will establish a cellular model of human neurogenesis that can be utilised to study developmental disease processes.Read moreRead less
Biosynthesis, folding and modification of conotoxins. Disulfide-rich peptides represent a diverse family of bioactive molecules which have been developed as drugs for the treatment of severe pain. This project seeks to understand their biosynthesis and how their functional diversity is generated. Such information will assist the translation of more of these novel peptides into new drugs.