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The evolutionary transition from anaerobic to aerobic metabolism. This project aims to find out how life on Earth survived the revolutionary changes when cyanobacteria first released oxygen into the atmosphere. These events led to a transition from anoxic (oxygen-free) to oxic (oxygen-rich) conditions. A comparative genomic view across a series of photosynthetic organisms will be performed at the molecular level with ecological interpretation. Understanding of what metabolic changes occurred in ....The evolutionary transition from anaerobic to aerobic metabolism. This project aims to find out how life on Earth survived the revolutionary changes when cyanobacteria first released oxygen into the atmosphere. These events led to a transition from anoxic (oxygen-free) to oxic (oxygen-rich) conditions. A comparative genomic view across a series of photosynthetic organisms will be performed at the molecular level with ecological interpretation. Understanding of what metabolic changes occurred in response to the shifts in the environment will have wide implications for predicting the evolutionary events that are still occurring today, such as rapidly changing climatic conditions. This fundamental research will enhance Australia's profile in this field.Read moreRead less
Using venoms to map critical and evolutionary conserved vulnerabilities. We have developed and applied new functional genomic approaches to study venom evolution. Using CRISPR screening, we find that unrelated venoms act on cells by exploiting the same vulnerabilities. By functionally mapping these vulnerabilities for all venom classes, we can begin to develop universal venom antidotes. Conversely, much of what we know about venom mechanisms comes from a small percentage of the biodiversity with ....Using venoms to map critical and evolutionary conserved vulnerabilities. We have developed and applied new functional genomic approaches to study venom evolution. Using CRISPR screening, we find that unrelated venoms act on cells by exploiting the same vulnerabilities. By functionally mapping these vulnerabilities for all venom classes, we can begin to develop universal venom antidotes. Conversely, much of what we know about venom mechanisms comes from a small percentage of the biodiversity within a venom, and we have developed genomic tools to study the venom “dark matter”. This work will lead to the full molecular characterisation of venom biodiversity, and new venom components will be useful for research or as novel medicines.Read moreRead less
Modern reptiles with ancient toxins: the molecular origin and evolution of novel bioactive proteins from squamate dental glands. Animal venoms provide a rich source of novel bioactive proteins, some of which have demonstrated therapeutically useful activities. Through this researcher's unique approach of investigating previously unmapped squamate venom systems, there is potential for the identification of divergent, bioactive proteins. Those already identified by the applicant in the dental gl ....Modern reptiles with ancient toxins: the molecular origin and evolution of novel bioactive proteins from squamate dental glands. Animal venoms provide a rich source of novel bioactive proteins, some of which have demonstrated therapeutically useful activities. Through this researcher's unique approach of investigating previously unmapped squamate venom systems, there is potential for the identification of divergent, bioactive proteins. Those already identified by the applicant in the dental glands of Australian monitor lizard species represent a tremendous opportunity for biodiscovery. Further knowledge in this area will increase medical understandings of bites and aid conservation measures informed by the natural history of these animals.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
Discovery Early Career Researcher Award - Grant ID: DE230100271
Funder
Australian Research Council
Funding Amount
$463,618.00
Summary
Coordinating gene expression and cell size: the role of feedback regulation. This project aims to reveal how human cells coordinate the kinetics of messenger RNA (mRNA) transcript production, processing and degradation at the single-cell level. It expects to generate significant new biological knowledge of gene regulation by combining innovative interdisciplinary research methodologies in genetics, single-molecule imaging, mathematical modelling and quantitative cell biology. Expected outcomes i ....Coordinating gene expression and cell size: the role of feedback regulation. This project aims to reveal how human cells coordinate the kinetics of messenger RNA (mRNA) transcript production, processing and degradation at the single-cell level. It expects to generate significant new biological knowledge of gene regulation by combining innovative interdisciplinary research methodologies in genetics, single-molecule imaging, mathematical modelling and quantitative cell biology. Expected outcomes include enhanced training of researchers and to build Australia’s capability in the rapidly expanding fields of RNA biology and high-throughput microscopy. This should provide significant benefits for a myriad of applications including health, agriculture and veterinary sciences.Read moreRead less
Evolution of the biofabrication of mineralized structures in animals. Shells and skeletons are produced by a wide range of animals. These highly-order crystalline structures are genetically-encoded and produce high-performance composite materials that exceed present capabilities in human engineering. This international collaboration will elucidate the molecular mechanisms controlling the fabrication of these architectures. This knowledge will contribute significantly to the development of materi ....Evolution of the biofabrication of mineralized structures in animals. Shells and skeletons are produced by a wide range of animals. These highly-order crystalline structures are genetically-encoded and produce high-performance composite materials that exceed present capabilities in human engineering. This international collaboration will elucidate the molecular mechanisms controlling the fabrication of these architectures. This knowledge will contribute significantly to the development of materials for advanced electronics and energy transducers, human bone therapeutics and marine-based products such as pearls and cements, through the identification of genes underlying biofabrication networks and the development of in vitro bioproduction systems.Read moreRead less
Evolution and ecology of integron gene cassettes: exploring the protein universe. Bacteria rapidly adapt to new conditions by sharing diverse genes via lateral genetic transfer, best illustrated by the spread of antibiotic resistance. This study will characterise mobile genes, discovering new gene families and proteins, and will expand existing knowledge of bacterial evolution.
Defining a role for non-coding RNAs in gonadal sex differentiation. This project aims to increase knowledge in the area of developmental biology, studying how gene regulation by so-called non-coding RNAs contributes to tissue patterning. The project plans to use a unique model system: gonadal development in the chicken embryo. It also plans to use novel molecular approaches that exploit the chicken model to study the role of microRNAs and a long non-coding RNA in patterning the embryonic gonad. ....Defining a role for non-coding RNAs in gonadal sex differentiation. This project aims to increase knowledge in the area of developmental biology, studying how gene regulation by so-called non-coding RNAs contributes to tissue patterning. The project plans to use a unique model system: gonadal development in the chicken embryo. It also plans to use novel molecular approaches that exploit the chicken model to study the role of microRNAs and a long non-coding RNA in patterning the embryonic gonad. The project aims to provide a deeper understanding of how genes operate to control tissue patterning and organogenesis. It may thus inform the field of sex determination specifically, and, more broadly, stem cell biology and tissue engineering.Read moreRead less
Function and evolution of insect odorant receptors. This project aims to shed light on how insect odorant receptors function by using comparative genomic studies between the genetic model insect Drosophila melanogaster and a pest species, the Australian sheep blowfly. This project expects to generate knowledge of how specific chemicals activate specific receptors in order to excite sensory neurons and drive behaviour, which is not well understood. Expected outcomes include increased understandin ....Function and evolution of insect odorant receptors. This project aims to shed light on how insect odorant receptors function by using comparative genomic studies between the genetic model insect Drosophila melanogaster and a pest species, the Australian sheep blowfly. This project expects to generate knowledge of how specific chemicals activate specific receptors in order to excite sensory neurons and drive behaviour, which is not well understood. Expected outcomes include increased understanding of olfaction in insects, increased national and international collaboration, and outstanding graduate student training. This research will be of significant future benefit in deriving methods to modify the behaviour of insects of agricultural or medical importance, for example the sheep blowfly. Read moreRead less
The genomics of adaptation in Wolbachia pipientis, an emerging biocontrol agent. Australians are increasingly exposed to insect-transmitted diseases such as dengue fever. Novel biocontrol methods using the bacterium Wolbachia aim to control insect populations to reduce disease transmission. Our research will be the first to investigate genomic variation and the process of adaptation to new insect hosts in Wolbachia. The novel data and understanding of evolutionary processes we generate will be c ....The genomics of adaptation in Wolbachia pipientis, an emerging biocontrol agent. Australians are increasingly exposed to insect-transmitted diseases such as dengue fever. Novel biocontrol methods using the bacterium Wolbachia aim to control insect populations to reduce disease transmission. Our research will be the first to investigate genomic variation and the process of adaptation to new insect hosts in Wolbachia. The novel data and understanding of evolutionary processes we generate will be critical for screening bacterial biocontrol candidates and designing biocontrol release strategies. It will also strengthen the position of Australian research as a world-leader in the fusion of post-genomics and applied microbiology. Read moreRead less