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
Discovery Early Career Researcher Award - Grant ID: DE240101022
Funder
Australian Research Council
Funding Amount
$457,000.00
Summary
Linking movement and animal vision to uncover functions of dynamic colours. This project aims to address a fundamental biological question: what drives the extraordinary diversity of colours in nature? Using cutting-edge, interdisciplinary techniques, this project expects to link visual properties, movement and animal vision to discover functions of animal colouration, generating significant new insights for the fields of visual ecology, animal behaviour and camouflage. The outcomes of this proj ....Linking movement and animal vision to uncover functions of dynamic colours. This project aims to address a fundamental biological question: what drives the extraordinary diversity of colours in nature? Using cutting-edge, interdisciplinary techniques, this project expects to link visual properties, movement and animal vision to discover functions of animal colouration, generating significant new insights for the fields of visual ecology, animal behaviour and camouflage. The outcomes of this project include enhanced national and international collaboration and new tools for animal behaviour, perception and camouflage research. This work will benefit our understanding of vision, colour and the relationship between the two, with significant scope for bio-inspired solutions to sensor and image processing problems.Read moreRead less
Using cane toads to eradicate cane toads. This project aims to develop effective ways to reduce the devastating ecological impact of cane toads, by exploiting the cannibalistic behaviour of tadpoles. This project expects to generate new knowledge in the area of invasion biology and amphibian development utilising recent discoveries about cannibalism. Expected outcomes of this project include a powerful new method to reduce or eliminate recruitment of juvenile toads from natural waterbodies. Bene ....Using cane toads to eradicate cane toads. This project aims to develop effective ways to reduce the devastating ecological impact of cane toads, by exploiting the cannibalistic behaviour of tadpoles. This project expects to generate new knowledge in the area of invasion biology and amphibian development utilising recent discoveries about cannibalism. Expected outcomes of this project include a powerful new method to reduce or eliminate recruitment of juvenile toads from natural waterbodies. Benefits of this project include conservation of native wildlife that are threatened by the cane toad invasion across much of tropical and subtropical Australia.Read moreRead less
Integrating theory and data to model evolution under a changing climate. This project aims to develop an innovative approach that integrates diverse data sources, from genetic sequences to geographic distributions, to improve inference of evolutionary dynamics. This will provide a powerful and efficient new method for understanding species’ responses to climate change, demonstrated by inferring past, current and future climate adaptability in a diverse and ecologically important Australian plant ....Integrating theory and data to model evolution under a changing climate. This project aims to develop an innovative approach that integrates diverse data sources, from genetic sequences to geographic distributions, to improve inference of evolutionary dynamics. This will provide a powerful and efficient new method for understanding species’ responses to climate change, demonstrated by inferring past, current and future climate adaptability in a diverse and ecologically important Australian plant family. Expected outcomes include enrichment of evolutionary theory and software tools to assess species' vulnerability to climate change. These outcomes will bring significant benefits to improve knowledge and protection of Australian biota and maximise returns on Australia's investment in biodiversity databases.Read moreRead less
Mitonuclear incompatibility, speciation, and the Z sex chromosome. This project will characterise the interaction between the mitochondrial and nuclear genome in several species and its contribution to the divergence of species. This interaction is at the heart of energy transformation and storage in all animals and its importance to evolution is yet to be fully understood. The research will provide insight into speciation processes by focusing on recent divergence in Australian finch species. W ....Mitonuclear incompatibility, speciation, and the Z sex chromosome. This project will characterise the interaction between the mitochondrial and nuclear genome in several species and its contribution to the divergence of species. This interaction is at the heart of energy transformation and storage in all animals and its importance to evolution is yet to be fully understood. The research will provide insight into speciation processes by focusing on recent divergence in Australian finch species. We will integrate genomics, bioenergetics, and whole organismal performance in growth, mobility and reproduction by studying birds in the wild and the laboratory. An overarching aim is to unite data from genomics, phenotype and physiology to understand the forces underlying the evolution of species, and biodiversityRead moreRead less
Upscaling genetic management of wildlife populations. Earth’s biodiversity is in crisis: many species are threatened with extinction and need our help. Genetic management helps to stop extinctions and promotes the health and continued existence of our wildlife. This project aims to understand how to use genome science to support preservation of four endangered species in changing climates and apply these learnings to help other species to survive and thrive. Anticipated outcomes include innovati ....Upscaling genetic management of wildlife populations. Earth’s biodiversity is in crisis: many species are threatened with extinction and need our help. Genetic management helps to stop extinctions and promotes the health and continued existence of our wildlife. This project aims to understand how to use genome science to support preservation of four endangered species in changing climates and apply these learnings to help other species to survive and thrive. Anticipated outcomes include innovative approaches to aid conservation decision-making, automated analyses of genome data, and improved conservation training. The expected benefits include larger, healthier populations of four species, new ways of saving other species, and the provision of important resources for conservation managers.Read moreRead less
Horizontal ecological networks for understanding biodiversity maintenance. The project aims to develop new ecological theory on local diversity maintenance based on an innovative interaction network model, tested on Western Australian wildflower communities. It is novel in its focus on the complexity of species interactions and their importance to diversity maintenance in nature. This project aims to explore links between plant interaction networks and coexistence theory to provide theoretical e ....Horizontal ecological networks for understanding biodiversity maintenance. The project aims to develop new ecological theory on local diversity maintenance based on an innovative interaction network model, tested on Western Australian wildflower communities. It is novel in its focus on the complexity of species interactions and their importance to diversity maintenance in nature. This project aims to explore links between plant interaction networks and coexistence theory to provide theoretical expectations for how changes to the environment are expected to alter natural plant communities. It aims to fill theory-gap about mechanisms of multi-species coexistence, advance community ecology, and provide the theoretical foundations necessary for translating ecological theory to restoration and conservation in practice.Read moreRead less
Pathways to semelparity versus early maturity in animals and plants. The project aims to resolve an important but unresolved question in life history evolution and ecology- which mechanisms and constraints lead to semelparity (breeding once, which is rare), and which lead to fast life history (breeding early, which is common) in animals and plants. Theory predicts that both may be adaptations to schedules of adult death. Understanding why males and females have either semelparous or fast life hi ....Pathways to semelparity versus early maturity in animals and plants. The project aims to resolve an important but unresolved question in life history evolution and ecology- which mechanisms and constraints lead to semelparity (breeding once, which is rare), and which lead to fast life history (breeding early, which is common) in animals and plants. Theory predicts that both may be adaptations to schedules of adult death. Understanding why males and females have either semelparous or fast life history strategies is crucial to predicting survival of harvested and threatened species under pressure from climate change, drought, predators, and diseases that kill adults. Expected project outcomes include improved ability to address agents of decline of threatened animals and plants including semelparous species.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101226
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Plant community responses to fire regime: the role of plant–soil feedbacks. We need to know how different prescribed burning regimes set the stage for long-term changes in plant community composition, diversity, and flammability. This project aims to reveal how plant community dynamics under different fire scenarios can be predicted based on contemporary interactions between plants and soil micro-organisms. This innovative approach to fire ecology integrates soil biology and plant ecophysiology ....Plant community responses to fire regime: the role of plant–soil feedbacks. We need to know how different prescribed burning regimes set the stage for long-term changes in plant community composition, diversity, and flammability. This project aims to reveal how plant community dynamics under different fire scenarios can be predicted based on contemporary interactions between plants and soil micro-organisms. This innovative approach to fire ecology integrates soil biology and plant ecophysiology with sophisticated experiments and novel modelling techniques. Expected outcomes include a much-needed mechanistic framework for early detection of major ecological changes under novel fire regimes, with direct benefits for land managers and the long-term conservation of Australia’s iconic vegetation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100003
Funder
Australian Research Council
Funding Amount
$387,373.00
Summary
The evolution of venom and its role in shaping biodiversity. This project aims to study how venom, nature's most powerful weapon, evolves and shapes biodiversity. Using the iconic Australian and New Guinean venomous snakes as a model, this project expects to develop a novel approach to profile venom composition from museum specimens, test competing hypotheses on the evolution of venoms, and test for the association between the evolution of venoms and the evolution of diversity in species richnes ....The evolution of venom and its role in shaping biodiversity. This project aims to study how venom, nature's most powerful weapon, evolves and shapes biodiversity. Using the iconic Australian and New Guinean venomous snakes as a model, this project expects to develop a novel approach to profile venom composition from museum specimens, test competing hypotheses on the evolution of venoms, and test for the association between the evolution of venoms and the evolution of diversity in species richness and morphology. Expected outcomes include the largest venom database for any animal group and a better understanding of how venoms evolve and what role they play in earth’s biodiversity. The generated venom data has potential to be used in future studies to aid in the development of anti-venoms and drugs.Read moreRead less