Testing links between life-history and genome evolution. Chromosomes are fundamental units of inheritance. They often differ in number, size and structure between species, and may also differ between individuals within a species. The evolution of chromosomes is tied to that of organisms themselves, making them important for understanding the generation and maintenance of biodiversity. Yet, our understanding of the forces that influence chromosome evolution remains limited. This project will inve ....Testing links between life-history and genome evolution. Chromosomes are fundamental units of inheritance. They often differ in number, size and structure between species, and may also differ between individuals within a species. The evolution of chromosomes is tied to that of organisms themselves, making them important for understanding the generation and maintenance of biodiversity. Yet, our understanding of the forces that influence chromosome evolution remains limited. This project will investigate the formation of unusual chains of chromosomes that are increasingly being found in various vertebrate and invertebrate taxa, using an organism in which they are most commonly found: termites. We will test the hypothesis that inbreeding drives the evolution of meiotic sex linked chromosomes.Read moreRead less
Towards a balanced veiw of parental effects: gaps, biases and opportunities. This project aims to identify and address knowledge gaps in research on parental effects by employing different methodologies (bibliometrics, systematic mapping) and developing novel methods of meta-analysis. This project expects to generate a more holistic and complete view of parental effects on offspring traits than currently appreciated, by elucidating the role of fathers and offspring in addition to mothers. Expect ....Towards a balanced veiw of parental effects: gaps, biases and opportunities. This project aims to identify and address knowledge gaps in research on parental effects by employing different methodologies (bibliometrics, systematic mapping) and developing novel methods of meta-analysis. This project expects to generate a more holistic and complete view of parental effects on offspring traits than currently appreciated, by elucidating the role of fathers and offspring in addition to mothers. Expected outcomes of the project include advancing the field of parental effects and creating new and powerful meta-analytic methods, opening up new avenues for research synthesis. This should provide significant benefits by directing future research in related fields and inspiring new kinds of meta-analyses across disciplines.Read moreRead less
Sex Differences in Trait Associations & Shapes: Analysis beyond Average. This project aims to identify and address current knowledge gaps in research on sex differences by employing different methodologies (bibliometrics, systematic mapping) and developing novel methods of meta-analysis. This project expects to generate a more holistic and complete view of sex differences than currently appreciated, by (meta-)analyzing the shapes of traits and associations between traits. Expected outcomes of th ....Sex Differences in Trait Associations & Shapes: Analysis beyond Average. This project aims to identify and address current knowledge gaps in research on sex differences by employing different methodologies (bibliometrics, systematic mapping) and developing novel methods of meta-analysis. This project expects to generate a more holistic and complete view of sex differences than currently appreciated, by (meta-)analyzing the shapes of traits and associations between traits. Expected outcomes of the project include taking the field of sex differences to the next level, and creating new and powerful meta-analytic methods, opening new avenues for research synthesis. This should provide significant benefits by directing future research in related fields and inspiring new kinds of (meta-)analyses across disciplines.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100087
Funder
Australian Research Council
Funding Amount
$411,567.00
Summary
Illuminating the function and evolution of iridescence. This project seeks to reveal how dynamic colour signals enable effective communication by connecting the production, transmission, and perception of visual information through space and time. By integrating innovative analyses of behaviour, physiology, and optics, it will offer original insight into how information is encoded and fluidly exchanged under real-world conditions, and produce new tools for interrogating the subjective visual wor ....Illuminating the function and evolution of iridescence. This project seeks to reveal how dynamic colour signals enable effective communication by connecting the production, transmission, and perception of visual information through space and time. By integrating innovative analyses of behaviour, physiology, and optics, it will offer original insight into how information is encoded and fluidly exchanged under real-world conditions, and produce new tools for interrogating the subjective visual world of animals. This work promises benefits to our understanding of how the universal process of communication drives adaptation amidst environmental change, with significant scope for bio-inspired solutions to contemporary problems of vision and efficient information processing, including among humans.Read moreRead less
Uncovering the transgenerational dimension of ageing. Despite over a century of research on the biology of ageing, one intriguing aspect of ageing – the widely observed tendency for older parents to produce offspring with reduced lifespan and fitness – remains poorly understood. Such effects could be a major source of variation in individual fitness, could play a role in the evolution of ageing, and could impact human health. Building on recent discoveries by CI Bonduriansky’s research group and ....Uncovering the transgenerational dimension of ageing. Despite over a century of research on the biology of ageing, one intriguing aspect of ageing – the widely observed tendency for older parents to produce offspring with reduced lifespan and fitness – remains poorly understood. Such effects could be a major source of variation in individual fitness, could play a role in the evolution of ageing, and could impact human health. Building on recent discoveries by CI Bonduriansky’s research group and others, this project’s aims will address significant questions about the mechanisms mediating these effects, the roles of mothers vs. fathers, and the role of the ambient environment. This project will also contribute new theory on the evolutionary implications of such effects. Read moreRead less
Quantifying the impact of phenotypic plasticity on population persistence. This project aims to understand how environmental sensitivity in growth, survival and reproduction of individuals in a population influence population dynamics using terrestrial ectotherms. It will provide significant new insights into whether phenotypic plasticity promotes population persistence in the face of environmental change. Expected outcomes include approaches for incorporating environmental effects in population ....Quantifying the impact of phenotypic plasticity on population persistence. This project aims to understand how environmental sensitivity in growth, survival and reproduction of individuals in a population influence population dynamics using terrestrial ectotherms. It will provide significant new insights into whether phenotypic plasticity promotes population persistence in the face of environmental change. Expected outcomes include approaches for incorporating environmental effects in population models for threatened species, open databases that can be used to estimate demographic information for species lacking data, and an assessment of what characteristics make some species more sensitive to the environment than others. Benefits include quantitative training and tools for managing Australia's rich biodiversity.Read moreRead less
The role of genome reorganisation in adaptation and speciation. Local adaptation and speciation are fundamental evolutionary processes that rely on changes to the genome. However, the role of genome architecture (e.g. chromosomal rearrangements, gene duplications) in driving these processes is poorly understood. This project will use advanced comparative genomics and bioinformatics to examine the role of chromosome rearrangements in driving adaptation and speciation, and evaluate rates of molec ....The role of genome reorganisation in adaptation and speciation. Local adaptation and speciation are fundamental evolutionary processes that rely on changes to the genome. However, the role of genome architecture (e.g. chromosomal rearrangements, gene duplications) in driving these processes is poorly understood. This project will use advanced comparative genomics and bioinformatics to examine the role of chromosome rearrangements in driving adaptation and speciation, and evaluate rates of molecular evolution between the X-chromosome and autosomes. Utilising Australia’s endemic mammalian fauna as a tractable model system, I will link population processes with macro-evolutionary outcomes to show how genome architecture underpins biodiversity.Read moreRead less
Does dynamic ecological change cause rapid evolution? This project aims to increase understanding of how Australia’s native biota responds to rapid environmental changes. Abrupt environmental change has the potential to drive rapid evolution, which may facilitate species persistence in the face of novel challenges. This project will use long-term genomic data to quantify rates of evolutionary change in species living in arid environments, whose populations fluctuate markedly in response to rainf ....Does dynamic ecological change cause rapid evolution? This project aims to increase understanding of how Australia’s native biota responds to rapid environmental changes. Abrupt environmental change has the potential to drive rapid evolution, which may facilitate species persistence in the face of novel challenges. This project will use long-term genomic data to quantify rates of evolutionary change in species living in arid environments, whose populations fluctuate markedly in response to rainfall variation. By measuring the pace of genomic change in these species, and the evolutionary processes driving that change, this project will reveal species’ evolutionary responses to major environmental fluctuations.Read moreRead less
Can sexual conflict contribute to a resolution of the paradox of sex? Despite over a century of research, it remains unclear why most animals can reproduce only via sex. An exciting new hypothesis proposes that sexual conflict can promote sexual reproduction and inhibit asexual strategies, suggesting a potential solution to this long-standing paradox. Building on my research expertise, and using a native Australian insect species in which the role of sexual conflict can be studied in natural pop ....Can sexual conflict contribute to a resolution of the paradox of sex? Despite over a century of research, it remains unclear why most animals can reproduce only via sex. An exciting new hypothesis proposes that sexual conflict can promote sexual reproduction and inhibit asexual strategies, suggesting a potential solution to this long-standing paradox. Building on my research expertise, and using a native Australian insect species in which the role of sexual conflict can be studied in natural populations, this ambitious project aims to test this hypothesis for the first time. This research will expand knowledge in the biological sciences by helping to answer one of the most challenging questions in evolutionary biology. This work will also contribute to efforts to monitor Australia's unique insect fauna.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100466
Funder
Australian Research Council
Funding Amount
$462,647.00
Summary
Mito-nuclear coevolution as an engine of biodiversity. This project aims to advance understanding of the processes that drive speciation and generate biodiversity. It will use Australia’s native social bees to test whether genetic diversity in mitochondrial genomes drives biodiversity at the population level, combining molecular and field studies in this uniquely tractable natural system. The expected outcome is a significant advance in knowledge of how coevolution between the two genomes of euk ....Mito-nuclear coevolution as an engine of biodiversity. This project aims to advance understanding of the processes that drive speciation and generate biodiversity. It will use Australia’s native social bees to test whether genetic diversity in mitochondrial genomes drives biodiversity at the population level, combining molecular and field studies in this uniquely tractable natural system. The expected outcome is a significant advance in knowledge of how coevolution between the two genomes of eukaryotic cells - mitochondrial and nuclear - affect the observable diversity of the natural world. The project is also expected to benefit the management and conservation of Australian native bees, which are vital pollinators in our natural and agro-ecosystems. Read moreRead less