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
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
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
Vocal mimicry in songbirds. Many of the world’s largest clade of birds - the songbirds - incorporate vocal mimicry in their songs, but while scientific interest in vocal mimicry dates from Aristotle, limited progress has been made. With our unique research program we aim to provide an empirically based, theoretically informed understanding of avian vocal mimicry. In an important advance, we will examine both sexes to test long-held male-centric assumptions about evolutionary origins and maintena ....Vocal mimicry in songbirds. Many of the world’s largest clade of birds - the songbirds - incorporate vocal mimicry in their songs, but while scientific interest in vocal mimicry dates from Aristotle, limited progress has been made. With our unique research program we aim to provide an empirically based, theoretically informed understanding of avian vocal mimicry. In an important advance, we will examine both sexes to test long-held male-centric assumptions about evolutionary origins and maintenance of this trait. Crucially, we focus on lineages found only in Australia and PNG, where songbirds originated, to develop a robust scientific understanding of vocal mimicry across the entire songbird clade, and so provide an important new perspective on why and how song began.Read moreRead less
Determining the links between size and function in phytoplankton. Marine phytoplankton are responsible for around 50% of the carbon fixation on planet. This project will examine how phytoplankton size declines will alter marine food webs and carbon sequestration. Changes in nutrients and temperature will cause phytoplankton to be smaller but the consequences of these changes are uncertain because of a lack of knowledge regarding how changes in cell size affect function within a species. This pro ....Determining the links between size and function in phytoplankton. Marine phytoplankton are responsible for around 50% of the carbon fixation on planet. This project will examine how phytoplankton size declines will alter marine food webs and carbon sequestration. Changes in nutrients and temperature will cause phytoplankton to be smaller but the consequences of these changes are uncertain because of a lack of knowledge regarding how changes in cell size affect function within a species. This project will evolve 20 species of algae to be different sizes and estimate the consequences of these size changes for biological functions. The project will then use these data to refine global models of carbon budgets, leading to better predictions about how the global carbon pump will change. Read moreRead less
Untangling environmental effects on bee health in the face of Varroa . This project aims to assess bee health, disease and evolution in European honeybees and bumblebees. Bee viruses transmitted by the destructive Varroa mite cause worldwide pollinator declines. Factors determining bee health will be identified across Australia, New Zealand and the United Kingdom, which differ in Varroa impact and bee introduction histories. Harnessing Australia’s currently threatened Varroa-free status, the bum ....Untangling environmental effects on bee health in the face of Varroa . This project aims to assess bee health, disease and evolution in European honeybees and bumblebees. Bee viruses transmitted by the destructive Varroa mite cause worldwide pollinator declines. Factors determining bee health will be identified across Australia, New Zealand and the United Kingdom, which differ in Varroa impact and bee introduction histories. Harnessing Australia’s currently threatened Varroa-free status, the bumblebee invasion in Tasmania, and cutting-edge multi-omics techniques (for microbiomes, viruses and genomes), predictors of disease dynamics will be identified for two globally important bee pollinators. The project outcomes will boost Australia's capacity to manage threats to pollination services at landscape scales.Read moreRead less
Using genetic Allee effects to manage invasive populations. An invasion can be started with only a small number of individuals, and it is very difficult to reliably detect these individuals. This project aims to develop new genetic technology that can send small founder populations extinct without affecting large populations. This technology removes the problem of having to detect small populations; these small populations will go extinct on their own, without the need for management interventio ....Using genetic Allee effects to manage invasive populations. An invasion can be started with only a small number of individuals, and it is very difficult to reliably detect these individuals. This project aims to develop new genetic technology that can send small founder populations extinct without affecting large populations. This technology removes the problem of having to detect small populations; these small populations will go extinct on their own, without the need for management intervention. This technology could be used to prevent establishment and spread of invasive species and agricultural pests. Through a combination of experimentation and modelling, the project develops this technology and assesses its use in applied problems ranging across environment, agriculture, and health.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
Fitness and evolutionary consequences of developmental plasticity. This project aims to develop a framework for accurately predicting species responses to global change. Phenotypic plasticity will act as a rapid-response mechanism, enabling organisms to survive climatic shifts in the first instance. Understanding how and when plasticity underpins species’ persistence under climate change is lacking. This project aims to integrate developmental responses to environmental change with evolutionary ....Fitness and evolutionary consequences of developmental plasticity. This project aims to develop a framework for accurately predicting species responses to global change. Phenotypic plasticity will act as a rapid-response mechanism, enabling organisms to survive climatic shifts in the first instance. Understanding how and when plasticity underpins species’ persistence under climate change is lacking. This project aims to integrate developmental responses to environmental change with evolutionary adaptation and population persistence in a spatially explicit context. The intended outcome is a powerful and general tool for predicting the impact of environmental change on the distribution and abundance of organisms. Benefits include improved conservation outcomes and better control of pest/disease vectors.Read moreRead less
Hybridisation leading to lost sex: genomic and experimental insights. The project intends to apply advanced genomics to two classic Australian systems and quantitative genetics to one to address long-standing questions about why asexual reproduction is rare. It aims to test for rapid changes in genomes accompanying hybrid-origins of asexuals and whether this new diversity enables their ongoing evolution. The significance is that support for this hypothesis would challenge current theory for why ....Hybridisation leading to lost sex: genomic and experimental insights. The project intends to apply advanced genomics to two classic Australian systems and quantitative genetics to one to address long-standing questions about why asexual reproduction is rare. It aims to test for rapid changes in genomes accompanying hybrid-origins of asexuals and whether this new diversity enables their ongoing evolution. The significance is that support for this hypothesis would challenge current theory for why sex is so common. The expected outcome is to understand how variation is generated in natural populations with different ways of reproducing. Benefits would include significant contributions to global science, evolutionary training and potential applications in using hybridisation to manage threatened species or pests.Read moreRead less