The evolution of biological scaling. This project aims to understand why so few biological traits scale proportionally with body size. In contrast to previous mechanistic studies of this longstanding question, the problem will be approached from an evolutionary viewpoint, using artificial selection to engineer animals in which biological scaling laws are either broken or enhanced. By measuring the consequences of this for fitness, the project will provide a new understanding of how organismal si ....The evolution of biological scaling. This project aims to understand why so few biological traits scale proportionally with body size. In contrast to previous mechanistic studies of this longstanding question, the problem will be approached from an evolutionary viewpoint, using artificial selection to engineer animals in which biological scaling laws are either broken or enhanced. By measuring the consequences of this for fitness, the project will provide a new understanding of how organismal size and physiology evolve in nature. The approach should provide significant benefits to our understanding of the role of genetic constraints in hindering or facilitating biological adaptation, furthering our understanding of the capacity of animals to respond to environmental change.Read moreRead less
Mechanisms of colour production and the evolution of animal signals. This project aims to reveal how diverse colours are produced in reptiles and the information these colours convey about individual health, condition and performance. The project evaluates how stress affects both pigment deposition and the nano-structure of cells and tissues, which together produce colour. By comparing similar colours generated by two entirely different classes of pigment (carotenoids and pteridines), this proje ....Mechanisms of colour production and the evolution of animal signals. This project aims to reveal how diverse colours are produced in reptiles and the information these colours convey about individual health, condition and performance. The project evaluates how stress affects both pigment deposition and the nano-structure of cells and tissues, which together produce colour. By comparing similar colours generated by two entirely different classes of pigment (carotenoids and pteridines), this project will provide new insights into the evolution of animal coloration, and will significantly enhance our understanding of pteridines, one of the most prevalent but least understood classes of pigment in vertebrates.Read moreRead less
Exposing the complex and flexible genetic basis to polygenic adaptation: integrating population and quantitative genomic approaches. Using leading-edge genomic approaches, the project will dissect the genetic basis to adaptation across an entire species range. The results will highlight the complex nature of adaptation to environmental change and will deliver new approaches to study it in natural populations.
Discovery Early Career Researcher Award - Grant ID: DE150101393
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Genetic and epigenetic drivers of the Australian cane toad invasion. Although invasive species are a massive threat to biodiversity, and costly to society, we still do not understand the evolutionary processes that shape invasions. Invasive populations often show rapid evolutionary change in novel environments but attempts to identify the underlying genetic mechanisms have been largely unsuccessful. This project aims to explore an innovative and untested alternative possibility: that invader evo ....Genetic and epigenetic drivers of the Australian cane toad invasion. Although invasive species are a massive threat to biodiversity, and costly to society, we still do not understand the evolutionary processes that shape invasions. Invasive populations often show rapid evolutionary change in novel environments but attempts to identify the underlying genetic mechanisms have been largely unsuccessful. This project aims to explore an innovative and untested alternative possibility: that invader evolution is primarily driven by epigenetic change. Using an iconic Australian invasive species, the cane toad, the project aims to quantify genetic and epigenetic change across the invasion and use manipulative experiments to determine the influence of epigenetic change on the evolution of phenotypic traits important to invasion.Read moreRead less
The role of leaf veins in vascular plant evolution. Leaves are continuously irrigated by a system of internal plumbing that defines their maximum photosynthetic output, and angiosperms are the most productive plants on earth largely by virtue of a uniquely efficient system of leaf plumbing. This project will identify how such an important modification of leaf water transport came to evolve.
Discovery Early Career Researcher Award - Grant ID: DE220101296
Funder
Australian Research Council
Funding Amount
$397,908.00
Summary
Diving into deep-time: macroevolutionary patterns of aquatic tetrapods. This project aims to compare and contrast the broad-scale evolutionary patterns of the disparate lineages of aquatic tetrapod (e.g. whales, penguins, plesiosaurs). This project expects to generate new knowledge by utilising cutting-edge methods from several fields, e.g. three-dimensional scans, phylogenetic comparative methods and functional morphology. Expected outcomes include multiple high-quality publications and the dev ....Diving into deep-time: macroevolutionary patterns of aquatic tetrapods. This project aims to compare and contrast the broad-scale evolutionary patterns of the disparate lineages of aquatic tetrapod (e.g. whales, penguins, plesiosaurs). This project expects to generate new knowledge by utilising cutting-edge methods from several fields, e.g. three-dimensional scans, phylogenetic comparative methods and functional morphology. Expected outcomes include multiple high-quality publications and the development of new local and international collaborations. This will provide significant benefits, including revealing aquatic tetrapod evolution on an unprecedented scale and a better understanding of how some of Australia’s most iconic animals respond to global change, helping inform eco-tourism and conservation policies.Read moreRead less
Evolution and role of neo-sex chromosomes in mitonuclear co-evolution. This project aims to characterize the evolution of novel, extended sex chromosomes in an Australian bird, then elucidate their role in climate-associated adaptive evolution. The species falls into two lineages bearing distinct mitochondrial genomes and nuclear-encoded mitochondrial genes carried on sex chromosomes. The project aims to test whether this extraordinary genome arrangement is splitting the species into two forms: ....Evolution and role of neo-sex chromosomes in mitonuclear co-evolution. This project aims to characterize the evolution of novel, extended sex chromosomes in an Australian bird, then elucidate their role in climate-associated adaptive evolution. The species falls into two lineages bearing distinct mitochondrial genomes and nuclear-encoded mitochondrial genes carried on sex chromosomes. The project aims to test whether this extraordinary genome arrangement is splitting the species into two forms: one adapted to hotter, drier environments, one to milder ones. This would be tackled using an innovative combination of genomics, cytogenetics, and metabolic data. Understanding the mechanisms at play would represent a major advance in ecology and evolution, with potential implications for conservation management.Read moreRead less
The evolutionary genetics of adaptation in species with separate sexes. This project aims to provide new theory and analysis methods for studying the genetic basis of female and male fitness. The project expects to provide new insights into the evolutionary, genetic and demographic mechanisms that influence evolutionary genetic diversity within populations. The project will reveal how sex differences in selection affect adaptation, and provide a framework for predicting whether populations with ....The evolutionary genetics of adaptation in species with separate sexes. This project aims to provide new theory and analysis methods for studying the genetic basis of female and male fitness. The project expects to provide new insights into the evolutionary, genetic and demographic mechanisms that influence evolutionary genetic diversity within populations. The project will reveal how sex differences in selection affect adaptation, and provide a framework for predicting whether populations with separate sexes are able to persist under changing environmental conditions. By developing a rigorous theoretical foundation for sex-specific adaptation – including genome inference methods that follow logically from the theory – the proposal will define new approaches for studying evolutionary processes in natural populations.Read moreRead less
Sex-specific selection and adaptation in spatially variable environments. This project aims to outline a broadly applicable approach for estimating sex-specific selection, which is based on an extension of the theory of local adaptation with gene flow. Adaptive evolution can be constrained when patterns of selection differ between the sexes. Experiments using model organisms provide strong evidence for adaptive constraints due to sex differences in selection. Outside of these model systems, sex- ....Sex-specific selection and adaptation in spatially variable environments. This project aims to outline a broadly applicable approach for estimating sex-specific selection, which is based on an extension of the theory of local adaptation with gene flow. Adaptive evolution can be constrained when patterns of selection differ between the sexes. Experiments using model organisms provide strong evidence for adaptive constraints due to sex differences in selection. Outside of these model systems, sex-specific selection estimates are difficult to obtain because methods for estimating selection are not easily applied to natural populations. Experiments, using a clinally variable Drosophila population from Eastern Australia constitute the first tests of the new theory.Read moreRead less
Detecting sex differences in natural selection. This project aims to develop new genomic approaches for understanding how genetic mutations can differentially affect reproductive success in males and females. Applying novel tests, this project aims to uncover previously hidden genetic conflicts between the sexes. This will provide significant benefits, such as new tools that will be broadly applicable to the wider research community, and help to answer key questions in genetics and evolutionary ....Detecting sex differences in natural selection. This project aims to develop new genomic approaches for understanding how genetic mutations can differentially affect reproductive success in males and females. Applying novel tests, this project aims to uncover previously hidden genetic conflicts between the sexes. This will provide significant benefits, such as new tools that will be broadly applicable to the wider research community, and help to answer key questions in genetics and evolutionary biology in the current genomic era.Read moreRead less