The evolution of species traits and spread during biological invasions. Exotic species pose a dire threat to Australia's biodiversity and natural resources due to the speed at which non-indigenous pests spread and the ecological and environmental damage they are capable of causing. The proposed research, on identifying traits associated with the spread of exotic vertebrate species and modelling the reproductive and dispersal parameters among different populations, will provide new knowledge and ....The evolution of species traits and spread during biological invasions. Exotic species pose a dire threat to Australia's biodiversity and natural resources due to the speed at which non-indigenous pests spread and the ecological and environmental damage they are capable of causing. The proposed research, on identifying traits associated with the spread of exotic vertebrate species and modelling the reproductive and dispersal parameters among different populations, will provide new knowledge and aid in developing innovative solutions for arresting the spread of exotic species. The validation of current models of spread will represent a major and timely addition to the national research capability on exotic species, and add substantially to Australia's reputation as a global leader in evolutionary ecology.Read moreRead less
From individuals to mass organisation: aggregation, synchronisation and collective movement in locusts. By combining field biology, robotics and mathematics, this project will determine how animals flock or swarm and, in particular, how locust nymphs control their collective movement over their lifetime. The mathematical models derived during the project will be directly applied to controlling outbreaks of locusts in Australia, South and North Africa.
Neural noise in human cognitive ageing and reserve. Age-related increases in neural noise degrade information transfer in the brain and lead to diminished cognitive function. Yet with cognitive reserve, some people are able to maintain healthy functioning well into their later years. This project aims to investigate the effects of neural noise on brain connectivity, cognitive performance and reserve, advancing breakthrough work on the neural physiology of healthy cognitive ageing and malleabilit ....Neural noise in human cognitive ageing and reserve. Age-related increases in neural noise degrade information transfer in the brain and lead to diminished cognitive function. Yet with cognitive reserve, some people are able to maintain healthy functioning well into their later years. This project aims to investigate the effects of neural noise on brain connectivity, cognitive performance and reserve, advancing breakthrough work on the neural physiology of healthy cognitive ageing and malleability of neural noise. This will be delivered by novel combinations of electrophysiology, neuroimaging and non-invasive brain stimulation. Benefits extend from developing neural markers for measuring cognitive reserve to new strategies for building resilience to age-related cognitive decline.Read moreRead less
Understanding working memory: from cells to brain stimulation. This project aims to understand the neural mechanisms of working memory, a fundamental cognitive function in humans, using a novel framework which combines non-invasive brain stimulation, neuroimaging, pharmacological and experimental manipulations, and biological modelling. Expected outcomes include a critical understanding of the cellular mechanisms underlying both neural activity and working memory ability in healthy individuals a ....Understanding working memory: from cells to brain stimulation. This project aims to understand the neural mechanisms of working memory, a fundamental cognitive function in humans, using a novel framework which combines non-invasive brain stimulation, neuroimaging, pharmacological and experimental manipulations, and biological modelling. Expected outcomes include a critical understanding of the cellular mechanisms underlying both neural activity and working memory ability in healthy individuals and a detailed knowledge of how to non-invasively interact with these mechanisms using brain stimulation. This will provide significant benefits such as the development of individually optimised brain stimulation protocols, enabling tailored approaches to reliably alter brain function and cognition.Read moreRead less
Deciphering Electron Transfer Pathways in Bacteria. Enzyme catalysed oxidation reactions are key players in the production of naturally occurring biologically active molecules. These processes are tightly regulated by their electron transfer partners. This project aims to characterise new electron transfer ferredoxin proteins from a metabolically diverse bacterium. These ferredoxins, important in many bacteria, contain different non-cysteine amino acids in their iron-sulfur cluster binding motif ....Deciphering Electron Transfer Pathways in Bacteria. Enzyme catalysed oxidation reactions are key players in the production of naturally occurring biologically active molecules. These processes are tightly regulated by their electron transfer partners. This project aims to characterise new electron transfer ferredoxin proteins from a metabolically diverse bacterium. These ferredoxins, important in many bacteria, contain different non-cysteine amino acids in their iron-sulfur cluster binding motifs and are poorly defined. The outcomes will advance understandings of electron transfer, a fundamental process. This will allow strategies to combat human and plant pathogens and unlock the potential of these systems as biocatalysts for the green chemical synthesis of complex and valuable chemicals.Read moreRead less
Adapting to a changing world: mothers as drivers of evolutionary change. This project will improve our understanding of how organisms will adapt to the unprecedented speed and magnitude of human-induced environmental change. By identifying how mothers modify their offspring to better match the prevailing environment, it will address the role of mothers in directing and accelerating adaptation in our changing world.
Adaptive Morphology and Evolution of Invasive Rabbits and Hares. This project aims to uncover the morphological variation that allows rapid adaptive evolution in two invasive species, the rabbit and hare. This project expects to generate new knowledge at the interface between invasion biology and evolutionary biology, using cutting-edge methods to phenotype widespread populations. This project will address key inter-related hypotheses of rapid adaptive evolution at temporal, spatial and phylogen ....Adaptive Morphology and Evolution of Invasive Rabbits and Hares. This project aims to uncover the morphological variation that allows rapid adaptive evolution in two invasive species, the rabbit and hare. This project expects to generate new knowledge at the interface between invasion biology and evolutionary biology, using cutting-edge methods to phenotype widespread populations. This project will address key inter-related hypotheses of rapid adaptive evolution at temporal, spatial and phylogenetic scales, particularly about changing morphologies involved role in locomotion and dispersal ability. Expected outcomes of this project include a comprehensive phenotypic database of these two species and identifying how these invasive species are adapting to the Australian landscape.Read moreRead less
Continuous tooth replacement in mammals: revealing the fundamental processes in tooth generation and movement. This project will investigate how molar teeth are made in mammals by examining the nabarlek, or little rock-wallaby, which is one of a handful of mammals that is able to regenerate new molars throughout its life. These new teeth migrate through the bone in order to move into the correct position in the mouth. By investigating two well-studied organisms, the mouse and the tammar wallaby, ....Continuous tooth replacement in mammals: revealing the fundamental processes in tooth generation and movement. This project will investigate how molar teeth are made in mammals by examining the nabarlek, or little rock-wallaby, which is one of a handful of mammals that is able to regenerate new molars throughout its life. These new teeth migrate through the bone in order to move into the correct position in the mouth. By investigating two well-studied organisms, the mouse and the tammar wallaby, as well as the nabarlek itself, the developmental processes and genes involved in molar generation and movement will be revealed. This project will integrate findings in regenerative medicine, evolutionary biology, materials engineering and palaeontology to reveal the mechanisms and origins of this astounding capability.Read moreRead less
The mechanochemical basis of cell polarity. This project aims to study how epithelial cells initiate polarisation, a major question in biology that conventional biochemical, cell biological and genetic approaches have not answered. This project will investigate the mechanochemical basis of symmetry breaking in the cellular cortex, a thin layer of actomyosin filaments underneath the plasma membrane, and how this forms signalling zones. Understanding polarity is expected to improve epithelia manip ....The mechanochemical basis of cell polarity. This project aims to study how epithelial cells initiate polarisation, a major question in biology that conventional biochemical, cell biological and genetic approaches have not answered. This project will investigate the mechanochemical basis of symmetry breaking in the cellular cortex, a thin layer of actomyosin filaments underneath the plasma membrane, and how this forms signalling zones. Understanding polarity is expected to improve epithelia manipulation in disciplines from tissue engineering to regenerative biology and reveal how epithelial architecture and physiology are generated.Read moreRead less
Benchmarking the neurophysiology of human cortex models in vitro. This project aims to improve human brain models in vitro by developing an analytical tool benchmarking biophysical similarities to the adult human cortex. This project expects to generate new knowledge by testing for the first time the theory that integrating sensory-like inputs and awake/sleep-like cycles of electrical activity in vitro may complete the maturation of human brain organoid models. It will also generate new methods ....Benchmarking the neurophysiology of human cortex models in vitro. This project aims to improve human brain models in vitro by developing an analytical tool benchmarking biophysical similarities to the adult human cortex. This project expects to generate new knowledge by testing for the first time the theory that integrating sensory-like inputs and awake/sleep-like cycles of electrical activity in vitro may complete the maturation of human brain organoid models. It will also generate new methods to simplify the analysis of multimodal path-clamping data (Patch-seq). Expected outcomes will facilitate research collaboration and the reproducibility of accurate experimental replicates of the human brain. This will provide significant benefits in the global race to understand human brain computation mechanisms.Read moreRead less