Alternative reproductive tactics and threshold evolution. This research is focussed at the highest level in the field of evolutionary biology; testing recent theory for the evolution of alternative reproductive tactics and using these species to test hypotheses about adaptation. The proposal involves collaborations with high-profile researchers from three European countries and will increase Australia's standing as a world-leader in evolutionary biology. Australian students will benefit from exp ....Alternative reproductive tactics and threshold evolution. This research is focussed at the highest level in the field of evolutionary biology; testing recent theory for the evolution of alternative reproductive tactics and using these species to test hypotheses about adaptation. The proposal involves collaborations with high-profile researchers from three European countries and will increase Australia's standing as a world-leader in evolutionary biology. Australian students will benefit from exposure to high quality international collaborators. We will also increase our understanding of the biology of the European earwig, a pest species in Australia. Reproductive tactics are exciting topics for media attention and this research will reach a wide and interested Australian and world audience.Read moreRead less
Are good males bad females? Sexual conflict in hermaphrodites. Animal hermaphrodites (organisms that are both males and females) are extremely common and important from both an economic and ecological perspective but we know little about the evolution of this group. This project will examine how sexual conflict, so pervasive in organisms with separate sexes, affects the evolution of hermaphrodites.
How does developmental plasticity shape adaptation to environmental change? This project aims to address how animals adapt to environmental change by examining a process largely ignored in current studies: how the environment alters animal development. This project expects to generate new knowledge in the area of the genetics of adaptation using an innovative approach to determine how genetic variation, environmental conditions, and development interact to shape adaptation to changing environmen ....How does developmental plasticity shape adaptation to environmental change? This project aims to address how animals adapt to environmental change by examining a process largely ignored in current studies: how the environment alters animal development. This project expects to generate new knowledge in the area of the genetics of adaptation using an innovative approach to determine how genetic variation, environmental conditions, and development interact to shape adaptation to changing environments. Expected outcomes of this project include enhancing predictions of how species respond to climate change and building capacity for international collaborations. The intended impact of this project is to increase our understanding of how animals respond to environmental change by determining how multiple environmental cues act together to alter development, and how the genetic makeup of the individual affects these responses.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.
Environmental stress profiling (ESP): Molecular profiling of sediment microbial communities for improved biological monitoring in aquatic ecosystems. Water resource management is a key issue for environmental sustainability in Australia and strategies that include ecological principles are important to improve present conditions and reduce further degradation. Current biomonitoring methods suffer from a low degree of sensitivity that can seriously impact their effectiveness as early warning sign ....Environmental stress profiling (ESP): Molecular profiling of sediment microbial communities for improved biological monitoring in aquatic ecosystems. Water resource management is a key issue for environmental sustainability in Australia and strategies that include ecological principles are important to improve present conditions and reduce further degradation. Current biomonitoring methods suffer from a low degree of sensitivity that can seriously impact their effectiveness as early warning signals of ecological disturbance. We propose to combine molecular and ecotoxicological assessment of the effect of zinc toxicity on microbial communities to provide rapid pollution sensitive bioassessment. Our research will lead to a better understanding of the cause and effect of heavy metal pollution within aquatic ecosystems and greater insight on how to reduce and repair the negative effects.Read moreRead less
Genomic vulnerability . Aims: This project aims to validate genomic predictions of species’ vulnerability to climate change.
Significance: Species are already responding to climate change, and many face high predicted rates of extinction. Some species will be able to avoid extinction via evolutionary adaptation. Yet we currently lack the ability to accurately predict which species do and do not have the capacity to adapt and avoid extinction.
Expected outcomes: Expected outcomes of this project ....Genomic vulnerability . Aims: This project aims to validate genomic predictions of species’ vulnerability to climate change.
Significance: Species are already responding to climate change, and many face high predicted rates of extinction. Some species will be able to avoid extinction via evolutionary adaptation. Yet we currently lack the ability to accurately predict which species do and do not have the capacity to adapt and avoid extinction.
Expected outcomes: Expected outcomes of this project include enhanced ability to predict species’ vulnerability to ongoing climate change.
Benefits: This project should significantly improve our capacity to manage threatened and keystone species by identifying those that will require targeted conservation management.
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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
The evolution of the alternation of generations in land plants. This project aims to investigate how a genetic system, comprised of a homeodomain protein encoding gene family controlling the haploid to diploid transition, has evolved during land plant evolution.
The project expects to generate new knowledge concerning the evolution of land plants from which our food and fibre are derived.
The intended outcomes include an elucidation of how an ancestral genetic network was elaborated during the e ....The evolution of the alternation of generations in land plants. This project aims to investigate how a genetic system, comprised of a homeodomain protein encoding gene family controlling the haploid to diploid transition, has evolved during land plant evolution.
The project expects to generate new knowledge concerning the evolution of land plants from which our food and fibre are derived.
The intended outcomes include an elucidation of how an ancestral genetic network was elaborated during the evolution of a multicelluar organism, including the retention of ancestral functions and the origins of new functions.
An anticipated benefit is the ability to manipulate the the growth and development of plants based on fundamental principles, which has broad agricultural implications.Read moreRead less
The origin and evolution of the land plant meristem. This project aims to identify the extent of overlap between the genetic determinants of the gametophyte and sporophyte shoot meristems.
The project expects to generate new knowledge of the evolution and development of land plants by applying comparative genomics and new technologies to a novel model genetic system.
Expected outcomes include an elucidation of the genetic basis for one of the key morphological adaptations for life on land.
Th ....The origin and evolution of the land plant meristem. This project aims to identify the extent of overlap between the genetic determinants of the gametophyte and sporophyte shoot meristems.
The project expects to generate new knowledge of the evolution and development of land plants by applying comparative genomics and new technologies to a novel model genetic system.
Expected outcomes include an elucidation of the genetic basis for one of the key morphological adaptations for life on land.
The ability to manipulate the growth and development of plants via the activity of meristems based on fundamental principles has broad agricultural implications.
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Discovery Early Career Researcher Award - Grant ID: DE120102821
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Molecular genetic adaptive processes in natural co-evolution between rabbits and the rabbit haemorrhagic disease virus. This project will use extensive sampling and long-term field data to reveal ongoing co-evolutionary mechanisms behind the increasing resistance of pest Australian wild rabbits against a viral pathogen. The results will increase the understanding of evolutionary mechanisms in nature and will provide basic information for biological pest control of rabbits.