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
Can mitochondrial and nuclear co-evolution drive climate adaptation? This project aims to reveal whether co-evolution between the mitochondrial genome of a wild bird and partner nuclear genes is causing the species to split into two forms, one adapted to inland environments and one to coastal conditions. Mitochondrial-nuclear co-evolution has great potential to illuminate new modes of climate adaptation and lineage divergence. This understanding will provide significant benefits, with implicatio ....Can mitochondrial and nuclear co-evolution drive climate adaptation? This project aims to reveal whether co-evolution between the mitochondrial genome of a wild bird and partner nuclear genes is causing the species to split into two forms, one adapted to inland environments and one to coastal conditions. Mitochondrial-nuclear co-evolution has great potential to illuminate new modes of climate adaptation and lineage divergence. This understanding will provide significant benefits, with implications for conservation management.Read moreRead less
Defining the Molecular Targets of Evolution. With significant advances in next-generation sequencing technologies we now have the genomes of hundreds vertebrate species, but understanding how the differences and similarities within these genomes control species diversity is largely unknown. The similarity in skull shape between the thylacine and dogs coupled with their deep ancestry, having last shared a common ancestor over 160 million years ago, provides an unprecedented opportunity to examine ....Defining the Molecular Targets of Evolution. With significant advances in next-generation sequencing technologies we now have the genomes of hundreds vertebrate species, but understanding how the differences and similarities within these genomes control species diversity is largely unknown. The similarity in skull shape between the thylacine and dogs coupled with their deep ancestry, having last shared a common ancestor over 160 million years ago, provides an unprecedented opportunity to examine how evolution works at the DNA level. This proposal will determine if animals that develop identical skull shapes, also show identical changes in their DNA. The findings will define new developmental genes and explain how selection, adaptation and evolution works at the DNA level. Read moreRead less
Conservation genomics of a critically endangered insect. This project aims to develop tools genotyping large animal genomes, focusing on the case of the Lord Howe Island stick insect, once thought to be extinct and now critically endangered. This project expects to generate molecular tools to monitor the genetic health the insect which has a large, complex and poorly understood genome. Expected outcomes include the development of a preservation and reintroduction strategy for the insect. This pr ....Conservation genomics of a critically endangered insect. This project aims to develop tools genotyping large animal genomes, focusing on the case of the Lord Howe Island stick insect, once thought to be extinct and now critically endangered. This project expects to generate molecular tools to monitor the genetic health the insect which has a large, complex and poorly understood genome. Expected outcomes include the development of a preservation and reintroduction strategy for the insect. This project will benefit ongoing conservation efforts, and is timely given the ongoing eradication of rats from Lord Howe Island where this species once lived. Read moreRead less
Unlocking the secrets of the mitochondrion. This project aims to determine the frequency and mechanisms by which male-harming mutations (those with negative effects limited to males) accrue within the mitochondrial DNA. Theory predicts maternal inheritance of mitochondrial DNA will lead to accumulation of these mutations, but the real-world implications of this theory are unknown. Leveraging an innovative approach, this project expects to generate new knowledge into the causes of sex differences ....Unlocking the secrets of the mitochondrion. This project aims to determine the frequency and mechanisms by which male-harming mutations (those with negative effects limited to males) accrue within the mitochondrial DNA. Theory predicts maternal inheritance of mitochondrial DNA will lead to accumulation of these mutations, but the real-world implications of this theory are unknown. Leveraging an innovative approach, this project expects to generate new knowledge into the causes of sex differences in physiology and health. Expected outcomes include insights that advance understanding of fundamental biological processes, and training of students. Expected benefits include strengthening of Australia’s research capacity, by setting the research agenda in this rapidly developing field.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL190100134
Funder
Australian Research Council
Funding Amount
$3,010,635.00
Summary
Sexual conflict and evolutionary dynamics of insecticide resistance genes. This project aims to develop new approaches to mitigate resistance evolution by applying sexual selection theory to predict evolution of insecticide resistance in flies. A key assumption of current agriculture management strategies is that resistance carries fecundity or survival costs, but this is rarely demonstrated, especially in nature. Not all resistance mutations are novel; many represent pre-existing variants maint ....Sexual conflict and evolutionary dynamics of insecticide resistance genes. This project aims to develop new approaches to mitigate resistance evolution by applying sexual selection theory to predict evolution of insecticide resistance in flies. A key assumption of current agriculture management strategies is that resistance carries fecundity or survival costs, but this is rarely demonstrated, especially in nature. Not all resistance mutations are novel; many represent pre-existing variants maintained by balancing selection i.e. opposing effects in males and females, or by environmental fluctuations. This research will provide new insight into how resistance evolves and is maintained in natural populations and may result in potential reduction in pesticide use with associated economic and biodiversity benefits. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101019
Funder
Australian Research Council
Funding Amount
$414,331.00
Summary
Mechanisms determining ecological resilience to climate change. This project aims to improve our understanding of the evolutionary mechanisms by which organisms adapt to climate change, and how this may lead to ecological resilience. It will test how rapid adaptation can occur in response to stressful environments predicted under climate change scenarios. By understanding the genetic mechanisms by which organisms adapt to environmental stresses, we can better forecast the effects of climate cha ....Mechanisms determining ecological resilience to climate change. This project aims to improve our understanding of the evolutionary mechanisms by which organisms adapt to climate change, and how this may lead to ecological resilience. It will test how rapid adaptation can occur in response to stressful environments predicted under climate change scenarios. By understanding the genetic mechanisms by which organisms adapt to environmental stresses, we can better forecast the effects of climate change on natural systems. Expected outcomes include an improved ability to make informed conservation and management decisions, with resulting benefits including the protection of human health, agricultural industries, and our iconic flora and fauna. Read moreRead less
Evolutionary impacts of gene interactions in a rapidly changing world. This project aims to understand how gene interactions impact evolution in our warming marine environments. The role of gene interactions is controversial because they are assumed to have little effect on genetic variation for fitness in natural populations. Yet new data show that this effect can be substantial and is enhanced by heat stress, explaining most of the genetic variation available for evolution under stressful cond ....Evolutionary impacts of gene interactions in a rapidly changing world. This project aims to understand how gene interactions impact evolution in our warming marine environments. The role of gene interactions is controversial because they are assumed to have little effect on genetic variation for fitness in natural populations. Yet new data show that this effect can be substantial and is enhanced by heat stress, explaining most of the genetic variation available for evolution under stressful conditions. The project aims to use quantitative genetics, genomics, and theory to determine the evolutionary impacts on marine populations facing rapid ocean warming in southeast Australia. The outcomes could change how we view gene interactions, and help us to better predict biological responses to environmental change.Read moreRead less
Natural selection and the Tasmanian devil. This project aims to explain evolution of immune capabilities in response to disease threats in the wild by assessing the immune adaptive capabilities of Tasmanian devils in response to facial tumour disease. It plans to determine how the expression of immune genes differs between wild and captive populations. The project will combine immunology, epidemiology and evolutionary biology, to understand the role of host genetic and phenotypic adaptations to ....Natural selection and the Tasmanian devil. This project aims to explain evolution of immune capabilities in response to disease threats in the wild by assessing the immune adaptive capabilities of Tasmanian devils in response to facial tumour disease. It plans to determine how the expression of immune genes differs between wild and captive populations. The project will combine immunology, epidemiology and evolutionary biology, to understand the role of host genetic and phenotypic adaptations to disease threats. The project will assist in the development of diagnostic tools for managing this and other threatened species and for screening disease resistance markers across wild and captive insurance populations.Read moreRead less