Understanding diet designs that break life history trade-offs. The aim of this project is to understand the mechanisms by which organisms use nutrition to enhance fitness. Food availability is a key predictor of evolutionary fitness. Surprisingly, recent data shows that some key assumptions informing how these predictions are realised are not strictly correct, thus exposing a lack of important mechanistic knowledge. This project seeks to understand these mechanisms. The project plans to use nove ....Understanding diet designs that break life history trade-offs. The aim of this project is to understand the mechanisms by which organisms use nutrition to enhance fitness. Food availability is a key predictor of evolutionary fitness. Surprisingly, recent data shows that some key assumptions informing how these predictions are realised are not strictly correct, thus exposing a lack of important mechanistic knowledge. This project seeks to understand these mechanisms. The project plans to use novel genomics techniques to develop diets that support or improve fitness under circumstances such as stress or ageing, and to understand the molecular underpinnings of these improvements. Project outcomes may expand academic knowledge of fundamental nutritional biochemistry, and improve predictions of species’ responses to environmental change.Read moreRead less
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
Characterisation of tumour variants of Devil Facial Tumour Disease. This project will take a new approach to cancer research by studying the evolution of Devil Facial Tumour Disease. The results will directly contribute to the conservation management of the Tasmanian devil, as well as generating new information on tumour growth, metastasis and emergence of resistance.
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