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Molecular control of postnatal heart development. This project aims to improve our understanding of how the heart develops after birth and the molecules that control this process. Recent advances in tissue engineering have opened up opportunities for the generation of synthetic tissues but these studies have also highlighted a fundamental knowledge gap in our understanding of how complex tissues mature to prepare for life as an adult. Much is known about the molecules that control early embryoni ....Molecular control of postnatal heart development. This project aims to improve our understanding of how the heart develops after birth and the molecules that control this process. Recent advances in tissue engineering have opened up opportunities for the generation of synthetic tissues but these studies have also highlighted a fundamental knowledge gap in our understanding of how complex tissues mature to prepare for life as an adult. Much is known about the molecules that control early embryonic development but little is known about the molecules that control maturation after birth. This project aims to build new knowledge that is expected to improve our ability to generate mature heart muscle cells for stem cell applications, tissue repair and regeneration.Read moreRead less
Macrophage control of mammalian growth and development. The immediate postnatal period in mammals is crucial for survival, long term health and productivity. This project is an international collaboration that aims to investigate how cells of the innate immune system called macrophages control somatic growth and development of mature organ function in the early postnatal period. The project aims to build upon investment in new animals models and a novel discovery to generate significant new know ....Macrophage control of mammalian growth and development. The immediate postnatal period in mammals is crucial for survival, long term health and productivity. This project is an international collaboration that aims to investigate how cells of the innate immune system called macrophages control somatic growth and development of mature organ function in the early postnatal period. The project aims to build upon investment in new animals models and a novel discovery to generate significant new knowledge that will challenge current concepts of mammalian growth control. The outcomes will enhance Australia's international reputation in the fields of physiology, immunology and developmental biology. Read moreRead less
Unravelling the principles of bilateral brain wiring. This project seeks to investigate the molecular principles of brain wiring in mammals and how small changes can generate complex outcomes. Neurons in the mammalian brain must be precisely wired together for the brain to function correctly. The project aims to identify the molecular and cellular rules governing commissural wiring in the mammalian cortex to determine how the largest fibre tract in the human brain, the corpus callosum, evolved. ....Unravelling the principles of bilateral brain wiring. This project seeks to investigate the molecular principles of brain wiring in mammals and how small changes can generate complex outcomes. Neurons in the mammalian brain must be precisely wired together for the brain to function correctly. The project aims to identify the molecular and cellular rules governing commissural wiring in the mammalian cortex to determine how the largest fibre tract in the human brain, the corpus callosum, evolved. This may have involved modifications in mechanisms affecting axon guidance that differ between placentals and marsupials. The project investigates the regulatory gene networks determining commissural neuron fate, the regulation of axon guidance components, and the influence of surrounding brain tissue on the development of commissural connections.Read moreRead less
Is FGF21 the master regulator of protein intake? The project plans to bring together two major, rapidly growing disciplines – nutritional geometry and metabolic signalling – to address a topic of fundamental biological significance: the regulation of protein intake. A specific capacity to regulate protein intake has been shown for organisms spanning slime moulds to humans, yet the controlling mechanisms remain elusive. The project aims to test the hypothesis that fibroblast growth factor 21, rel ....Is FGF21 the master regulator of protein intake? The project plans to bring together two major, rapidly growing disciplines – nutritional geometry and metabolic signalling – to address a topic of fundamental biological significance: the regulation of protein intake. A specific capacity to regulate protein intake has been shown for organisms spanning slime moulds to humans, yet the controlling mechanisms remain elusive. The project aims to test the hypothesis that fibroblast growth factor 21, released from the liver under low protein nutrition, is a master regulator of protein intake. Understanding the mechanisms of protein appetite may have implications for organismal biology, understanding social interactions, the structure of food webs and the health and welfare of food and companion animals and humans.Read moreRead less
Gamete-specific knockout of Fizzy-Related to examine its meiotic role in oocytes and sperm. Fizzy-Related is a gene that appears to be essential in making an ovulated egg, and it may also have an important role to play in making sperm. A mouse knockout will be generated to examine exactly how it functions; because it affects the egg number remaining in the ovary and egg quality Fizzy-Related may be eventually an important therapeutic target.
Discovery Early Career Researcher Award - Grant ID: DE240101286
Funder
Australian Research Council
Funding Amount
$469,707.00
Summary
SARS-CoV-2-induced dead cell fragments drive viral uptake and inflammation. This project will apply advanced cell biology and imaging techniques to investigate how macrophages, which lacks a canonical receptor for viral entry, become infected with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and elicit inflammatory responses. Its insights into a novel pathway of viral entry is expected to advance our understanding of host-pathogen interaction. The project is intended to uncover t ....SARS-CoV-2-induced dead cell fragments drive viral uptake and inflammation. This project will apply advanced cell biology and imaging techniques to investigate how macrophages, which lacks a canonical receptor for viral entry, become infected with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and elicit inflammatory responses. Its insights into a novel pathway of viral entry is expected to advance our understanding of host-pathogen interaction. The project is intended to uncover the role of SARS-CoV-2-induced dead cell fragmentation in promoting viral uptake and inflammation. Its findings should provide significant scientific, health and economic benefits by informing new research directions on infection and innate immunity as well as future therapeutic designs for infection treatment.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
Discovery Early Career Researcher Award - Grant ID: DE240100561
Funder
Australian Research Council
Funding Amount
$462,237.00
Summary
Understanding how platelets mediate new neuron formation in the adult brain. Exercise boosts the generation of new nerve cells from adult neural stem cells in the part of the brain responsible for learning and memory, the hippocampus. This project aims to investigate the mechanisms behind this effect, in particular, how blood cells known as platelets mediate this process. The expected outcomes include the discovery of new communication pathways between platelets and the brain following exercise ....Understanding how platelets mediate new neuron formation in the adult brain. Exercise boosts the generation of new nerve cells from adult neural stem cells in the part of the brain responsible for learning and memory, the hippocampus. This project aims to investigate the mechanisms behind this effect, in particular, how blood cells known as platelets mediate this process. The expected outcomes include the discovery of new communication pathways between platelets and the brain following exercise and will determine the importance of these blood cells in mediating brain function. This will help to explain how exercise affects the brain and may benefit Australian society through the implementation of new methods to support learning and memory in schools and workplaces, thereby enhancing performance and productivity.Read moreRead less
Mechanisms that control the inheritance of mitochondrial DNA mutations. How do humans and other organisms prevent the accumulation of dangerous mitochondrial genome (mtDNA) mutations across generations? This Project aims to uncover the cellular and molecular pathways that help prevent the inheritance of mtDNA mutations to offspring by employing cutting-edge genetic technologies that the laboratory has recently developed in the germline of an animal model system. This Project will generate new kn ....Mechanisms that control the inheritance of mitochondrial DNA mutations. How do humans and other organisms prevent the accumulation of dangerous mitochondrial genome (mtDNA) mutations across generations? This Project aims to uncover the cellular and molecular pathways that help prevent the inheritance of mtDNA mutations to offspring by employing cutting-edge genetic technologies that the laboratory has recently developed in the germline of an animal model system. This Project will generate new knowledge in the area of mitochondrial genetics and evolution. Expected outcomes include the development of new theories for mtDNA inheritance, which should provide significant benefits for agricultural breeding programs and the interpretation of mtDNA inheritance patterns in the human population.Read moreRead less
The developmental genetics of major evolutionary transitions: a multidisciplinary investigation of limb reduction and loss in lizards. The five-toed limb is an iconic evolutionary innovation of land vertebrates, yet has been lost repeatedly. This project will use anatomical, developmental and genetic approaches to understand how vertebrates lose their legs, whether limbs can be reacquired, and the degeneration of limb genes after they lose their function (analogous to 'vestigial organs').