Discovery Early Career Researcher Award - Grant ID: DE190100805
Funder
Australian Research Council
Funding Amount
$382,656.00
Summary
Phylogenetic methods for genome surveillance of microbial pathogens. This project aims to develop phylogenetic approaches to harness the potential evolution of bacterial and virus pathogens data and to improve early detection of infectious outbreaks. Genome surveillance programs consist in routine sequencing of particular organisms to track their evolution over time. Such programs currently exist for important bacterial and virus pathogens. This project expects to develop computational methods t ....Phylogenetic methods for genome surveillance of microbial pathogens. This project aims to develop phylogenetic approaches to harness the potential evolution of bacterial and virus pathogens data and to improve early detection of infectious outbreaks. Genome surveillance programs consist in routine sequencing of particular organisms to track their evolution over time. Such programs currently exist for important bacterial and virus pathogens. This project expects to develop computational methods to improve our understanding of pathogen outbreak emergence and infectious spread using genome data. This project will expand our knowledge base and research capability in the evolution and epidemiology of infectious agents, and aid in the prevention and control strategies of infectious disease benefiting the research priorities of food and health.Read moreRead less
Nowcasting outbreaks leveraging genomic and epidemiological data. This project aims to inform outbreak response planning by developing new models of infectious disease outbreaks. The project expects to generate new knowledge on the processes driving ongoing outbreaks including those of the novel coronavirus (COVID-19) and African swine fever by integrating the latest advances in Bayesian outbreak inference alongside unique simulation approaches. Expected outcomes should include a shift in how mo ....Nowcasting outbreaks leveraging genomic and epidemiological data. This project aims to inform outbreak response planning by developing new models of infectious disease outbreaks. The project expects to generate new knowledge on the processes driving ongoing outbreaks including those of the novel coronavirus (COVID-19) and African swine fever by integrating the latest advances in Bayesian outbreak inference alongside unique simulation approaches. Expected outcomes should include a shift in how models are developed and used to inform the response to outbreaks as they unfold. This should enable more rapid outbreak containment in Australia and overseas, leading to reduced impacts on public and animal health, and associated industries.Read moreRead less
A new universal mechanism controlling body proportions in animals. This project aims to establish that a recently-discovered mechanism, the inhibitory cascade, determines the basic proportions of appendages and body segments in a diverse range of animal groups, particularly vertebrates and arthropods. The goals of the project are to reveal the molecular mechanisms in mice and insects, and build computer simulations to show how to manipulate the control of development by the inhibitory cascade. T ....A new universal mechanism controlling body proportions in animals. This project aims to establish that a recently-discovered mechanism, the inhibitory cascade, determines the basic proportions of appendages and body segments in a diverse range of animal groups, particularly vertebrates and arthropods. The goals of the project are to reveal the molecular mechanisms in mice and insects, and build computer simulations to show how to manipulate the control of development by the inhibitory cascade. The project should benefit bioengineering by establishing control mechanisms for the manipulation and regeneration of teeth and limbs.Read moreRead less
Evolution of defensive and predatory venom in cone snails. This project aims to determine the molecular and cellular origins and mechanisms regulating venom production and release to establish how defensive venoms evolved in cone snails. Cone snails possess a remarkable ability to rapidly and reversibly switch between separate venoms in response to predatory or defensive stimuli, implying that these are separately evolved and regulated mechanisms. The investigators hypothesise that defensive ven ....Evolution of defensive and predatory venom in cone snails. This project aims to determine the molecular and cellular origins and mechanisms regulating venom production and release to establish how defensive venoms evolved in cone snails. Cone snails possess a remarkable ability to rapidly and reversibly switch between separate venoms in response to predatory or defensive stimuli, implying that these are separately evolved and regulated mechanisms. The investigators hypothesise that defensive venoms, originally evolved in the proximal venom duct to protect against threats such as cephalopod and fish predation, have been repurposed in the proximal duct to allow predators to become prey, facilitating the switch from worm to mollusc and fish hunting. The project aims to show the broad implications for the evolution of venoms in animals and discover the regulatory mechanisms driving venom peptide expression.Read moreRead less
Increased phenotypic variation via evolutionarily novel stressors. This project aims to understand how evolutionarily novel stressors such as obesogenic diets induce phenotypic variation in organismal traits. Such increased phenotypic variation is traditionally thought to be genetic. However, growing evidence points to non-genetic mechanisms that are capable of transgenerational inheritance. The project will use complementary approaches to study how novel stressors generate phenotypic variation ....Increased phenotypic variation via evolutionarily novel stressors. This project aims to understand how evolutionarily novel stressors such as obesogenic diets induce phenotypic variation in organismal traits. Such increased phenotypic variation is traditionally thought to be genetic. However, growing evidence points to non-genetic mechanisms that are capable of transgenerational inheritance. The project will use complementary approaches to study how novel stressors generate phenotypic variation. The project aims to deliver a more integrated evolutionary perspective not only on phenotypic evolution and the maintenance of variation, but also on the transgenerational cost of obesity.Read moreRead less
Fossils, rocks and early Cambrian clocks: calibrating body plan assembly and lineage splits in ancestral animals from Gondwana. The precise timing of when animal body plans evolved and rapidly diversified during the Cambrian Explosion remains mysterious. This project will investigate vast collections of exquisitely preserved early-middle Cambrian fossils from Australia to determine the precise order of evolutionary events at the root of the animal tree of life.
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
How males alter their mates' ageing rates and lifespans. The proposed project investigates how males affect the lifespan, ageing and subsequent reproduction of their mates. It seeks to draw on and adapt tools and approaches used in molecular genetics and physiology to test predictions from evolutionary theories of sexual conflict, life-histories and ageing in an organism of biomedical and ecological significance, the house mouse. It is expected that this approach will allow the study, in unsurpa ....How males alter their mates' ageing rates and lifespans. The proposed project investigates how males affect the lifespan, ageing and subsequent reproduction of their mates. It seeks to draw on and adapt tools and approaches used in molecular genetics and physiology to test predictions from evolutionary theories of sexual conflict, life-histories and ageing in an organism of biomedical and ecological significance, the house mouse. It is expected that this approach will allow the study, in unsurpassed detail, of the costs males impose on females via mating, insemination, territoriality and via conflict over how many offspring to have and how to invest in their care.Read moreRead less
Unravelling the role of heteroplasmy in mitochondrial adaptation. This project aims to unravel the evolutionary implications of heteroplasmy – a scenario in which multiple mitochondrial DNA genotypes exist in one individual. Recent studies indicate heteroplasmy is widespread, and can be caused by paternal transmission of mtDNA. But the effects of heteroplasmy on evolutionary processes remain unknown. Leveraging state-of-the-art methods, this project expects to generate new knowledge in the areas ....Unravelling the role of heteroplasmy in mitochondrial adaptation. This project aims to unravel the evolutionary implications of heteroplasmy – a scenario in which multiple mitochondrial DNA genotypes exist in one individual. Recent studies indicate heteroplasmy is widespread, and can be caused by paternal transmission of mtDNA. But the effects of heteroplasmy on evolutionary processes remain unknown. Leveraging state-of-the-art methods, this project expects to generate new knowledge in the areas of evolutionary ecology and mitochondrial genetics. Expected outcomes include discoveries that advance understanding of fundamental biological processes, and student training. Expected benefits include strengthening of Australia’s research capacity, by setting the research agenda in this rapidly developing field.Read moreRead less
Evolutionary limits. This project aims to understand the processes that limit adaptation to rapid environmental change. Adaption to rapid environmental change determines population persistence. Species with restricted distributions may lack the genetic variation necessary to adapt to changing environments, although they represent the vast majority of biodiversity. Understanding why they lack the necessary genetic variation for adaptation is important for identifying and managing vulnerable biolo ....Evolutionary limits. This project aims to understand the processes that limit adaptation to rapid environmental change. Adaption to rapid environmental change determines population persistence. Species with restricted distributions may lack the genetic variation necessary to adapt to changing environments, although they represent the vast majority of biodiversity. Understanding why they lack the necessary genetic variation for adaptation is important for identifying and managing vulnerable biological systems. This project will empirically determine the contribution of mutations to key traits to better understand what limits evolutionary adaptation. Better prediction of extinction risk should inform conservation and biodiversity management.Read moreRead less