Quiet sleep is for repair, active sleep is for learning. Sleep is thought to achieve many different functions, from brain waste clearance to regulating emotions and perception. Understanding sleep functions in animal models has been difficult because sleep has been typically reduced to a single state. Our discovery of distinct sleep stages in the fruit fly provides a powerful way to study how different conserved sleep functions are regulated. This project will use new strategies for manipulating ....Quiet sleep is for repair, active sleep is for learning. Sleep is thought to achieve many different functions, from brain waste clearance to regulating emotions and perception. Understanding sleep functions in animal models has been difficult because sleep has been typically reduced to a single state. Our discovery of distinct sleep stages in the fruit fly provides a powerful way to study how different conserved sleep functions are regulated. This project will use new strategies for manipulating sleep stages in flies to understand their respective physiology and functions. We will test our hypothesis that different categories of sleep functions have been segregated by evolution into different stages: a quiet stage concerned primarily with brain repair and an active stage important for learning.
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How brains become lateralised. This project aims to understand how the left and right sides of the brain become specialised for different cognitive functions, a phenomenon called lateralisation. Lateralisation is one of the least understood organisational principles of the brain, yet is crucial to the way we think and behave. Manifested most clearly as handedness, the brain is lateralised for many cognitive tasks such as language, reasoning, memory and emotion. However, the developmental origin ....How brains become lateralised. This project aims to understand how the left and right sides of the brain become specialised for different cognitive functions, a phenomenon called lateralisation. Lateralisation is one of the least understood organisational principles of the brain, yet is crucial to the way we think and behave. Manifested most clearly as handedness, the brain is lateralised for many cognitive tasks such as language, reasoning, memory and emotion. However, the developmental origin and anatomical substrate of most cognitive asymmetries are unknown. This project will use a chick model of brain lateralisation to quantify and localise to specific brain circuits the patterns of differential gene expression that give rise to anatomical and functional asymmetries.Read moreRead less
Placental nutrient transport shows how complex traits evolve. This project aims to use amino acid transport in the vertebrate placenta as a model to demonstrate how genes are recruited and modified to produce a major organ. Using an innovative combination of a new technology, selected reaction monitoring, and transcriptomic and molecular approaches, plus carefully selected Australian species pairs, this project will study the evolution of a complex trait (placental amino acid transport). The pr ....Placental nutrient transport shows how complex traits evolve. This project aims to use amino acid transport in the vertebrate placenta as a model to demonstrate how genes are recruited and modified to produce a major organ. Using an innovative combination of a new technology, selected reaction monitoring, and transcriptomic and molecular approaches, plus carefully selected Australian species pairs, this project will study the evolution of a complex trait (placental amino acid transport). The project will provide fundamental advances in our knowledge of the nutrient transport during pregnancy that is required to produce a healthy baby.Read moreRead less
Combining biomechanics and movement ecology of kangaroos and relatives. Kangaroos and their relatives are unique in their body form, hopping gait and by the fact that increased speed does not come at an increased energetic cost. This project aims to build 3D musculoskeletal models to understand how muscles and tendons interact, enabling greater distances to be travelled using less energy. Further, it will use animal tracking devices and machine-learning tools to quantify movements in the wild. T ....Combining biomechanics and movement ecology of kangaroos and relatives. Kangaroos and their relatives are unique in their body form, hopping gait and by the fact that increased speed does not come at an increased energetic cost. This project aims to build 3D musculoskeletal models to understand how muscles and tendons interact, enabling greater distances to be travelled using less energy. Further, it will use animal tracking devices and machine-learning tools to quantify movements in the wild. This framework will provide novel insights into how energetics, morphology, and habitat have shaped the evolution of this unique group. This may open doors to a range of future ecological, physiological, and conservation studies and provide biological inspiration for energetically efficient robotic and assistive devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100585
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Does foot shape even matter? Rethinking the function of the human foot. Human feet are unique in shape and structure, having evolved to allow upright locomotion. Despite their importance, we don’t understand how foot shape and structure facilitates upright locomotion.This DECRA aims to explore the relationship between foot morphology and foot function. I will close a large knowledge gap by applying novel experimental and shape modelling approaches to provide unprecedented insights into human foo ....Does foot shape even matter? Rethinking the function of the human foot. Human feet are unique in shape and structure, having evolved to allow upright locomotion. Despite their importance, we don’t understand how foot shape and structure facilitates upright locomotion.This DECRA aims to explore the relationship between foot morphology and foot function. I will close a large knowledge gap by applying novel experimental and shape modelling approaches to provide unprecedented insights into human foot function. The primary expected outcome is a detailed understanding of how foot shape and structure influences our ability to walk and run. This research will create a paradigm shift in how we think about feet in the context of human evolution, human athletic performance and athletic footwear design.Read moreRead less
Skin in the game: biomimetics, fitness and the springtail cuticle. This project aims to examine the relationship between cuticle (skin) properties, water balance, and fitness in springtails, key players in soil systems. Springtail cuticles are diverse, responsive, and extremely resistant to wetting by water, alcohol and other substances. Their Australian diversity has not been well explored for biomimetic new materials. This project expects to explore options for new applications in materials sc ....Skin in the game: biomimetics, fitness and the springtail cuticle. This project aims to examine the relationship between cuticle (skin) properties, water balance, and fitness in springtails, key players in soil systems. Springtail cuticles are diverse, responsive, and extremely resistant to wetting by water, alcohol and other substances. Their Australian diversity has not been well explored for biomimetic new materials. This project expects to explore options for new applications in materials science and engineering by generalising the cuticle structure-function relationship. Expected outcomes are new information to harness for industry the diversity of nature’s self-cleaning, water repellent surfaces. Significant benefits lie in potential new biomimetic manufacturing options.Read moreRead less
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
Is SPINT1 a key regulator of placental development? . The placenta is an essential organ required for reproduction in placental species. This project aims to elucidate the fundamental biology of SPINT1 in placental development. It will generate new knowledge about whether the spatial and temporal expression of SPINT1 is conserved across several species; cow, sheep, lizard, mouse and human. It will also define the molecular mechanisms by which SPINT1 directs formation, maturation and expansion o ....Is SPINT1 a key regulator of placental development? . The placenta is an essential organ required for reproduction in placental species. This project aims to elucidate the fundamental biology of SPINT1 in placental development. It will generate new knowledge about whether the spatial and temporal expression of SPINT1 is conserved across several species; cow, sheep, lizard, mouse and human. It will also define the molecular mechanisms by which SPINT1 directs formation, maturation and expansion of the placental exchange interface which is critical for offspring survival.
The project will increase understanding of placental development, enhance collaboration and research knowhow, and promote future applied projects in all species that reproduce via placental support.Read moreRead less
Going beyond genetics: the shape of marsupial evolution and conservation. This project aims to explain the past and protect the present biodiversity of endangered marsupial mammals such as bilbies and koalas. It will generate new knowledge using an interdisciplinary combination of 3D analysis of skull shape, reflecting a mammal’s ability to feed and sense its surrounds, with the fast-moving fields of marsupial conservation and evolutionary genetics. This will help to anticipate if, and how, chan ....Going beyond genetics: the shape of marsupial evolution and conservation. This project aims to explain the past and protect the present biodiversity of endangered marsupial mammals such as bilbies and koalas. It will generate new knowledge using an interdisciplinary combination of 3D analysis of skull shape, reflecting a mammal’s ability to feed and sense its surrounds, with the fast-moving fields of marsupial conservation and evolutionary genetics. This will help to anticipate if, and how, changing environments and declining numbers reduce these species’ ability to adapt. Benefits include better information to support improved conservation decisions and identification of genes underlying the evolution of marsupial skull diversity.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100032
Funder
Australian Research Council
Funding Amount
$379,264.00
Summary
Banking on spermatogonial stem cells to safeguard Australian native fauna. Spermatogonial stem cells in the testis are an untapped resource for species conservation. This project aims to characterise metabolic pathways that control spermatogonial stem cell function, and define the conserved nature of these pathways between model species (mouse) and vulnerable Australian native fauna. Expected outcomes of this project include an enhanced capacity to culture koala spermatogonia in vitro, which wil ....Banking on spermatogonial stem cells to safeguard Australian native fauna. Spermatogonial stem cells in the testis are an untapped resource for species conservation. This project aims to characterise metabolic pathways that control spermatogonial stem cell function, and define the conserved nature of these pathways between model species (mouse) and vulnerable Australian native fauna. Expected outcomes of this project include an enhanced capacity to culture koala spermatogonia in vitro, which will be a first step towards using spermatogonial biobanking as a tool to maintain genetic diversity in this species. Outcomes from this study should provide significant benefits in safeguarding our unique Australian native species, which is of particular importance following the catastrophic 2019/20 bushfire season.Read moreRead less