Discovery Early Career Researcher Award - Grant ID: DE180100526
Funder
Australian Research Council
Funding Amount
$342,551.00
Summary
Unifying cornerstones of social evolution: theory and application. This proposal aims to reconcile and unify alternative methods in social evolution theory, one of the foundations of our modern understanding of evolutionary and behavioural ecology. Social evolution has been controversial, but recent years have seen major developments. By combining mathematical models and empirical data, this project expects to end the controversies by removing boundaries between theoretical approaches. Specific ....Unifying cornerstones of social evolution: theory and application. This proposal aims to reconcile and unify alternative methods in social evolution theory, one of the foundations of our modern understanding of evolutionary and behavioural ecology. Social evolution has been controversial, but recent years have seen major developments. By combining mathematical models and empirical data, this project expects to end the controversies by removing boundaries between theoretical approaches. Specific applications of theory include social insect evolution, individuality and selection in plants. Unification of theory is expected to enhance research capacity in Australia and internationally.Read moreRead less
How evolution is constrained by trade-offs between the multiplication and survival of organisms. The negative correlation between reproduction (production of large numbers of progeny) and survival (resistance to external challenges) is a crucial trade-off that limits the evolution of perfect organisms. Such trade-offs are extremely difficult to study in closely controlled experiments because of the complexities in biological organisation and life-cycles. This project will explore trade-offs usin ....How evolution is constrained by trade-offs between the multiplication and survival of organisms. The negative correlation between reproduction (production of large numbers of progeny) and survival (resistance to external challenges) is a crucial trade-off that limits the evolution of perfect organisms. Such trade-offs are extremely difficult to study in closely controlled experiments because of the complexities in biological organisation and life-cycles. This project will explore trade-offs using a novel synthetic biology strategy. Genes in bacteria will be engineered to produce strains with a range of fixed but different trade-off settings. The strain sets will allow unprecedented analysis of reproduction-survival trade-offs and testing of important models of how trade-offs control fitness and evolutionary outcomes.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100202
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Interplay between plasticity and senescence. This project aims at bridging two fundamental human stressors together in a quantitative genetic framework. The environment changes globally on a huge scale coupled with effect on the age-structures and genetic composition of countless populations by over-harvesting and exploitation. This project will provide significant benefits, such as potential strategies of dealing with future human-induced changes more effectively.
Australian and global plant diversity from first principles. This project aims to explain the composition of vegetation in Australia and worldwide using ecological and evolutionary first principles. Researchers have studied how climate shapes vegetation for centuries, but still lack a basic quantitative theory predicting what types of plants should be found where and why. Combining first principles models, statistics and large Australian data synthesis, this project will determine whether vegeta ....Australian and global plant diversity from first principles. This project aims to explain the composition of vegetation in Australia and worldwide using ecological and evolutionary first principles. Researchers have studied how climate shapes vegetation for centuries, but still lack a basic quantitative theory predicting what types of plants should be found where and why. Combining first principles models, statistics and large Australian data synthesis, this project will determine whether vegetation structure and diversity is predictable and thus improve predictive models. Predicting the long term effects of evolutionary adaptation and humans on ecosystems could enable the management of terrestrial carbon and underpin effective ecosystem management and restoration.Read moreRead less
Escalating the arms race: Understanding when and how trees get really tall. Australia's giant Eucalypt trees are an amazing phenomenon and resource; underpinning unique ecosystems, rich in timber, stored carbon, and animal habitat. While tree height generally arises via an evolutionary arms race for light, the race has escalated dramatically in some locations and species. Using a computational framework that simulates adaptation driven by size-structured competition, this project will quantify h ....Escalating the arms race: Understanding when and how trees get really tall. Australia's giant Eucalypt trees are an amazing phenomenon and resource; underpinning unique ecosystems, rich in timber, stored carbon, and animal habitat. While tree height generally arises via an evolutionary arms race for light, the race has escalated dramatically in some locations and species. Using a computational framework that simulates adaptation driven by size-structured competition, this project will quantify how distinct factors-including climate, recruitment, and disturbance-enhance the race for light and can thereby explain the origins of Australia's giant Eucalypt. With calibrated models of species evolution, coupled with targeted fieldwork and big data, this project clarifies key forces shaping present and future vegetation.Read moreRead less
The sparrows in the mining towns: a century of adaptation to contamination. Our research will characterise how contamination from the extraction of precious metals can spread through the environment and how it effects a highly urbanised bird – the house sparrow. In many cases, populations of these birds have been intimately associated with mining operations for over a century, and our recent work has provided evidence of adaptation over time. House sparrows provide a great natural system to unde ....The sparrows in the mining towns: a century of adaptation to contamination. Our research will characterise how contamination from the extraction of precious metals can spread through the environment and how it effects a highly urbanised bird – the house sparrow. In many cases, populations of these birds have been intimately associated with mining operations for over a century, and our recent work has provided evidence of adaptation over time. House sparrows provide a great natural system to understand the genetic potential of organisms to adapt to anthropomorphic change in the environment connected with the resources industry. Our work, will bring new insight into the future management of environmental contamination, and the mitigation of adverse effects arising from resource extraction.Read moreRead less
Origin and evolution of plant functional traits in relation to fire. This project addresses the fundamental question as to what extent the Australian flora is adapted to fire by tracing the evolutionary history of the iconic family Proteaceae over the last 100 million years. The answer to this question has significant implications for informing Australia’s fire management and nature conservation policies.
Dimensions of ecological strategy for plants. A more fundamental understanding will be sought about the architecture and ecology of vegetation and why it varies around the world. Under a high- CO2 future, models will be needed that operate through fundamental mechanisms of evolution, competition and physiology, rather than through extrapolation from present-day plants.
Increased phenotypic variation via evolutionarily novel stressors. This project aims to understand how evolutionarily novel stressors such as obesogenic diets induce phenotypic variation in organismal traits. Such increased phenotypic variation is traditionally thought to be genetic. However, growing evidence points to non-genetic mechanisms that are capable of transgenerational inheritance. The project will use complementary approaches to study how novel stressors generate phenotypic variation ....Increased phenotypic variation via evolutionarily novel stressors. This project aims to understand how evolutionarily novel stressors such as obesogenic diets induce phenotypic variation in organismal traits. Such increased phenotypic variation is traditionally thought to be genetic. However, growing evidence points to non-genetic mechanisms that are capable of transgenerational inheritance. The project will use complementary approaches to study how novel stressors generate phenotypic variation. The project aims to deliver a more integrated evolutionary perspective not only on phenotypic evolution and the maintenance of variation, but also on the transgenerational cost of obesity.Read moreRead less
Putting adaptation into vegetation models: towards a predictive theory of trait diversity and stand structure. By incorporating natural selection into models of vegetation, this project will help to predict what sorts of plants are found where and why. This will greatly improve the ability to predict the likely outcomes of human impacts (changing climates, increased disturbance, logging) for future vegetation and species diversity.